|Title of Invention||
PROCESS FOR RAPID BACTERIAL TYPING
|Abstract||Disclosed is a method for rapidly typifying yeasts, parasites and bacteria. The method involves the following steps: a) Preparing intact and immobilized DNA within 5 to 60 minutes by means of a method which uses a set of reagents that only contains a buffer solution, a detergent, a chelating agent and an agent that breaks up the hydrogen bridges, b) Separating intact DNA molecules or their restriction fragments using pulsed field electrophoresis mini-equipment of systems CHEF (Contour Clamped Homogeneous Electric Field) and TAFE (Transversal Alternating Field Electrophoresis) for time periods ranging between 2.5 and 7 hours, c) Selecting the optimal conditions that will be applied in the miniCHEF by using a method simulating a priori the electrophoretic patterns that would be obtained in said gels, d) Providing the reorientation times, migration speeds and molecule sizes without using size markers but using a method that analyzes migrated distances.|
|Full Text||PROCESS FOR RAPID MICROORGANISM TYPING AND ASSOCIATED KIT OF REAGENTS
INTERNATIONAL PATENT CLASSIFICATION INDEX: C12N 1/00
REFERENCE TO RELATED APPLICATION
The present invention is related to molecular biology. In particular, a process is provided. Said process includes the use of methods and procedures, as well as a reagent kit for rapid microorganism typing. The microorganisms to be typed can be yeast, parasites and bacteria Gram-positive or Gram-negative. The microorganism typing is done by Pulsed Field miniGel Electrophoresis performed in miniequipments of CHEF or TAFE system.
BACKGROUND OF THE INVENTION
During the past years, infectious diseases have increased and multi-drug resistance microorganisms have arisen (Acar J and Courvalein P pp 50-53; Aubry-Damon H and Andremot A, pp 54-55; Trieu-Cout P and Poyart C, pp 62-66, in 'La Recherche', vol 314,1998).
Outbreaks of infectious diseases have generated the necessity of typing the causative microorganisms. Typing is the process by which different species of microorganisms of a given genus are classified in different subgroups or subtypes (Busch U and Nitschko H, J Chromatogr B, 1999, 722:263-278). Typing is important, from the epidemiological point of view, for recognizing outbreaks of infection, determining the way of transmission of nosocomial pathogens in the health centers and detecting the sources of the infections. It is also useful for identifying new virulent strains and monitoring vaccination programs. A typing process is been considered adequate if it fulfill the following criteria (Maslow JN et al., Clin Infect Dis, 1993, 17:153-164):
1. To give unambiguous results for each isolate analyzed.
2. To give reproducible results.
3. To differentiate unrelated strains within specie.
There are several microorganism typing methods. Some of them are based on the analysis of phenotypic features (phenotypic methods) and others on the analysis of genotypic features (genotypic methods). Phenotypic methods detect features expressed by microorganisms, whereas the genotypic ones evidence the differences among the DNA of microorganisms. Thus, phenotypic methods have the disadvantage of giving an indirect measure of the changes in the genetic background. Said disadvantage does not occur with the use of genotypic methods.
One of the genotypic typing methods most widely used is Pulsed Field Gel Electrophoresis (PFGE). This method is considered the gold standard for the molecular typing of microorganisms. PFGE typing is performed by separating in gels DNA molecules that are subjected to the action of electric pulses in two different directions. After electrophoresis, the band patterns given by DNA molecules of an isolate of microorganism are highly reproducible and discriminatory and characterize unequivocally its DNA (Oliver DM and Bean P, J Clin Microbiol, 1999, 37(6):1661-1669). Additionally, the whole genomes of numerous isolates can be compared in a single gel. Thus, PFGE has been proposed as the optimal typing method (Maslow JN, Mulligan ME and Arbeit RD, Clin Infect Dis, 1993(17):153-164; Busch U and Nitschko H, J Chromatogr B, 1999(722):263-278). The results obtained by PFGE depend on the experimental conditions applied in DNA separation and on the genus and specie of the microorganism subjected to study. Thus,
a) If the microorganism has several lineal chromosomes of sizes lower than 10 Mb (1j megabase = 1 000 000 base pairs) the band pattern given by its chromosomes is| obtained. Said band pattern is called 'the electrophoretic karyotype'. For instances, the microorganism can be yeast, unicellular parasites, etc.
b) If the microorganism has a single large circular chromosome the band pattern given by the macrorestriction fragments of said circular DNA is obtained. These patterns are called pulsetypes, since they are obtained in specific experimental conditions. For instances, the microorganism can be bacteria such as Escherichia coli. Staphylococcus aureus, etc.
The comparison of the electrophoretic karyotypes of different strains permits their characterization and differentiation. The same occurs with the restriction fragments of the bacterial DNA. Thus, both, the molecular karyotypes and the pulsotypes are used in the comparative study of fungi, bacteria and parasites. The routinely use of PFGE in medical microbiology has generated the necessity of improving the methods of sample preparation.
It also generated the need of designing a priori the running conditions to adequately separate the molecules and for analyzing the resulting electrophoresis patterns. In general, the process of microorganism typing by PFGE comprises the following steps and procedures:
1) Preparing the samples: growing the microorganisms in nutrient broth, embedding the cells in gel and obtaining immobilized and deproteinized intact DNA molecules.
2) Designing the electrophoresis run: selecting the experimental conditions that should be set in PFGE equipments to obtain the optimal separation between the molecules.
3) Loading the samples in the gels and performing pulsed field gel electrophoresis to separate the DNA molecules.
4) Analyzing the band patterns obtained after the electrophoresis and comparing the results given by different isolates of microorganisms.
The equipments and procedures currently used in microorganism typing by PFGE are analyzed.
Pulsed field gel electrophoresis.
Pulsed field gel electrophoresis (PFGE) dates from 1984, when Schwartz and Cantor (Cell, 37, 67-75, 1984; US Patent No. 4,473,452) observed that applying electric pulses that periodically switched their orientation by a certain angle in relation to the agarose gel, large intact DNA molecules were resolved as band patterns.
The authors also determined that the separations of the molecules essentially depend on the duration of the electric pulses. Later, the angle formed by the field force lines, the electric field strength, the experimental temperature, the ionic strength of the buffer solution, the concentration of the agarose gel and the thickness of the agarose plugs, where the samples are embedded, were determined as the most important factors that influenced the resolution of DNA molecules. (Birren B. and Lai E. Pulsed Field Gel Electrophoresis: a practical guide. Academic Press. New York, 1993, p 107, 111, 129, 131, 135; Lopez-Canovas L. et al., J. of Chromatogr. A, 1998, 806, 123-139; Lopez-Canovas L. et al., J. of Chromatogr. A, 1998, 806, 187-197).
Different systems to perform PFGE have been developed. They have characteristic chambers with electrodes placed in different arrangements. Among these chambers are the OFAGE (Orthogonal Field Alternating Gel Electrophoresis, Carle C.F. and Olson M.V. Nucleic Acids Res. 1984, 12,5647-5664) CHEF ('Contour Clamped
Homogeneous Electric Field', Chu G. Science 234, 1986, 1582-1585), TAFE (Transversal Alternating Field Electrophoresis', Patent US. No. 4,740,283), FIGE ('Field Inversion Gel Electrophoresis', Patent US. No. 4,737,251 of Carle G.F. and Olson M.V) arrangements of electrodes, and the minichambers MiniTAFE and MiniCHEF (Riveron, A.M. et al., Anal. Lett, 1995, 28, 1973-1991; European Patent Application EP 0 745 844, Bula. 1996/49; US Patent Application 08/688,607, 1995; Cuban patent RPI Nro. 02/95, 1995).
Commonly used systems for microorganism typing by PFGE.
The most used systems for microorganism typing based on DNA analysis by PFGE are CHEF and TAFE. They provide straight band patterns in every lane of the gel, and thus, allow the comparison of the results obtained in a single run or in different electrophoresis runs.
The electrodes of CHEF system are placed in a hexagonal array around the gel and the voltages are clamped in them to guarantee homogenous electric field throughout the gel. The generation of homogeneous electric field throughout the chamber permits to obtain straight bands and reproducible migrations in the lanes of the gel. The electrodes of opposed polarities are 33.5 cm separated in CHEF chambers. It uses submarine gels that can be up to 21x14 cm in width and length. The gels are placed horizontally (CHEF Mapper XA Pulsed Field Electrophoresis System. Instruction Manual and Application Guide. Catalog Numbers 170-3670 to 170-3673, BioRad, pp 11, 1995). As mentioned, CHEF systems have been extensively used for microorganism typing. For instances, bacteria (Beverly, S, Anal Biochem, 1989, 177:110-114; Dingwall A and Shapiro L, Proc Natl Acad Sci USA, 1989, 86:119-123; Ferdows MS and Barbour AG, Proc Natl Acad Sci USA, 1989, 86:5960-5973; Kohara Y, Akiyma K and Isono K, Cell, 1987, 50:495-508; Ohki M and Smith CI, Nucleic Acids Res, 1989, 17:3479-3490; Schoenline PV, Gallman LM and Ely B, Gene, 1989, 70:321-329; Ventra L and Weiss AS, Gene, 1989, 78:29-36), Pseudomonas (Bautsch W, Grothues D and Tummler B, FEMS Microbiol Lett, 1988, 52:255-258; Romling U and Tummler B, J Clin Microbiol, 2000, 38(1):464-465), S. cerevisiae (Albig W and Entian KD, Gene, 1988, 73:141-152; Zerva L et al., J Clin Microbiol, 1996, 34(12):3031-3034), E. histolytica (Petter R et al., Infect Immun, 1993, 61(8):3574-3577), S. pneumoniae (McEllistrem MC et al., J Clin Microbiol, 2000, 38(1 ):351-353), S. aureus (Wichelhaus TA et al., J Clin Microbiol,
1999, 37(3):690-693), M. tuberculosis (Singh SP et al., J Clin Microbiol, 1999, 37(6):1927-1931), P. haemolytica (Kodjo A et al., J Clin Microbiol, 1999, 37(2):380-385), etc.
Due to the large dimensions of the CHEF chamber, it requires large amount of buffer solution to cover its electrode platform. Thus, the current intensity in the chamber can reach high values, even when low electric fields intensities are applied. Therefore, CHEF experiments demand power supplies of high rated power output. Besides it, large amount of heat is generated in the chambers, avoiding the reduction of run duration by increasing the electric field. CHEF chambers need at least 20 hours of electrophoresis to separate Saccharomyces cerevisiae chromosomes (molecules smaller than 1.6 Mb. 1 Mb = 106 base pairs) in the characteristic pattern of 11 bands, and to type different strains of this yeast (Zerva L, et al., J Clin Microbiol, 1996, 34(12): 3031-3034). The CHEF chamber takes long time for separating the macrorestriction fragments of bacterial DNA molecules, since 20 hours, or more, are needed (van Belkum A et al., J Clin Microbiol 1998, 36(6):1653-1659; Marchadin H et al., Antimicrob Agents Chemother, 2000, 44(1):213-216; Romling U and Tummler B, J Clin Microbiol, 2000, 38(1):464-465). Similarly, long running times are needed to study parasites such as Entamoeba histolytica. To separate its chromosomes 24 hours are needed, at least (Petter R et al., Infect Immun, 1993, 61(8):3574-3577).
The advantage of currently used CHEF equipments is the possibility of analyzing 40 samples in a single run. This high throughput sample format facilitates the comparative analysis of the electrophoresis patterns given by samples of numerous isolates. The TAFE system was proposed by KJ Gardiner, W Laas and D Patterson in the paper published in Somatic Cell Mol Genet, 1986(12): 185. They called initially the system as "Vertical Pulsed Field Electrophoresis" (VPFE) and developed the equipment that was protected by the US Patent 4,740,283 of April 26th, 1988.
In TAFE system, two electrode pairs are placed parallel to both faces of the submarine gel (10 x 7.6 x 0.64 cm, length x width x thick), that is placed vertically in the chamber. Said electrode disposition generates electric field force lines that cross transversally the gel and compels the molecules to migrate through the gel thickness during each pulse. In TAFE, homogeneously sized molecules travel similar distances and migrate up to the same height in the gel leaving straight tracks, regardless the positions of the wells (into which the samples were loaded) in the gel. Thus, this system is useful for microorganism typing,
since it facilitates the comparative analysis of the electrophoresis patterns given by samples of numerous isolates.
Based on these principles, Beckman Instruments manufactured the equipment called "Geneline I, or Transverse Alternating Field Electrophoresis System"
(Beckman, The Geneline System Instruction Manual, ed. Spinco Division of Beckman Instruments Inc., 1988), which is also known as TAFE. This system uses a gel (11 x 7.2 x 0.6 cm, length x width x thickness) into which 20 samples can be loaded. Nevertheless, TAFE also requires large amount of buffer solution (3.5 liters) and biological sample. The equipment demands, at least, 20 hours to resolve the E. histolytica chromosomes (Baez-Camargo M et al., Mol Gen Genet 1996, 253:289-296). So, TAFE share the drawbacks with CHEF in microorganism typing.
As a conclusion, the commercially available equipments most frequently used to characterize the genome of microorganisms and parasites require long running time, and large amount of reagents and biological samples to resolve large DNA molecules in their band pattern.
FIGE system has been used for rapid typing of bacteria (Goering RV and Winters MA, J Clin Microbiol, 30(3):577-580, 1992; Grothues D et al., J Clin Microbiol, 26(10):1973-19771988). However, electrophoretic mobility inversion of DNA has been documented in FIGE experiments. Mobility inversion of DNA prevents correct size estimations and makes difficult the interpretation and comparison of the patterns given by numerous samples. The impossibility of predicting the moment of occurrence of DNA mobility inversion is one of the problems associated with said phenomenon (Birren B and Lai E. Pulsed Field Gel Electrophoresis: a practical guide, pp 10, Academic Press, Inc. San Diego, California. 1993). The main disadvantage of mobility inversion is the impossibility of identifying unambiguously the molecules present in a given band. To do it, the bands should be transferred and hybridized with specific probes. Hybridization notably increases the prices of the assay and is time demanding, thus the typing process will be more expensive and time consuming.
The attempts to reduce the electrophoresis time in current CHEF equipments, such as GeneNavigator (Amersham-Pharmacia-LKB, Pharmacia Molecular and Cell Biology Catalogue, Pulsed Field Gel Electrophoresis, Nucleic Acids Electrophoresis. 1998, pp 77-79), CHEF DRII and CHEF Mapper (CHEF Mapper XA Pulsed Field Electrophoresis System. Instruction Manual and Application Guide. Catalog
Numbers 170-3670 to 170-3673. Bio-Rad, pp 11, 1995) by increasing the voltage applied to the electrodes is nearly impossible. It is due to the limit of power supply output and the cooling system. Consequently, manufacturers recommend 9 V/cm as maximum electric field to apply in said equipments (CHEF Mapper XA Pulsed Field Electrophoresis System. Instruction Manual and Application Guide. Catalog Numbers 170-3670 to 170-3673. Bio-Rad, pp 2, 1995). Therefore, the reduction of the electrophoresis duration by increasing the electric field intensity is prevented in CHEF system. Current TAFE equipments have similar problems.
MiniPFGE equipments, miniCHEF and miniTAFE versions, were reported in 1995 (Riveron AM et al., Anal. Lett., 1995, vol. 28, pp 1973-1991; European Patent Application EP 0 745 844, Bull. 1996/49; US Patent Application 08/688,607, 1995; Cuban Patent RPI 02/95, 1995). Miniequipments overcome most of the mentioned drawbacks of the PFGE equipments. Pulsed field electrophoresis experiments are performed in a minigel (4 x 4 x 0.5 cm; length x width x thickness) loaded with 7 samples in 4 to 6 hours. Electric field strength reaching 16 V/cm can be applied in MiniCHEF, providing good resolution of the electrophoresis band patterns in 2.7 hours. The short distance between the electrodes of opposed polarities permits to construct small chambers and to use small amount of buffer volumes to cover the electrodes. By applying a given voltage to a miniCHEF and CHEF chambers (certain electric field strength value 'E') the heat generated in the minichamber is always lesser than the heat generated in the commercially available CHEF (Riveron AM et al., Anal. Lett., 1995 vol. 28, pp. 1973-1991).
MiniTAFE equipments admit 22 V/cm, achieving resolution among the bands (Riveron AM et al., Anal. Lett., 1995 vol. 28, pp. 1973-1991). MiniTAFE permits to obtain the S. cerevisiae electrophoretic karyotype in 5 hours. MiniTAFE chambers with short separation (7.8 cm) between opposite electrodes are small and use small amount of buffer solution. However, if samples thicker than 0.1 cm are loaded in the minigels, longer running times are needed to achieve good resolution of the electrophoresis patterns. According to previous reports, sample thickness influences electrophoresis running time (Lopez-Canovas et al., J. Chromatogr. A, 1998, 806, pp. 187-197). As the samples are thicker, longer gels are needed to obtain the same band patterns. However, the reported miniCHEF minigels admit only 7 samples, whereas the miniTAFE supports 13 samples.
They are low throughput sample formats for typing isolates of microorganisms in clinical laboratories.
Despite miniPFGE equipments have advantages over currently used systems, neither miniCHEF nor MiniTAFE were used for microorganism typing. Maybe, it obeys to the attempting of using samples as thick as the ones used in conventional gels. In addition, simple procedures to select miniequipment running parameters are not available.
Preparation of immobilized DNA
A method to prepare intact DNA molecules is essential for microorganism typing by PFGE in current equipments or miniequipments. Previously reported methods of DNA isolation and purification in solution provoke shearing of said molecules (Schwartz DC and Cantor CR, Cell, 1984, 37, pp. 66-75). Schwartz and Cantor proposed a methodology to prepare samples for PFGE and only excluded the molecules with sizes smaller than 1 Mb (106 base pairs). The methodology consists in harvesting the cultured cells, washing the cells and embedding them in agarose plugs. In ulterior steps, spheroplasts (if cellular wall exists) are formed 'in situ' and further lysed in said plugs. Finally, the immobilized DNA molecules are deproteinized using proteinase K. The method has been effective to prepare samples from microorganisms of different genus, species and origins. However, spheroplasts need to be formed if said microorganisms possess cell wall, and the enzymes needed to form spheroplasts, as well as the proteases, are expensive. The reported procedure requires that samples were incubated overnight twice, which is 32 hours for sample preparation (US Patent No. 4,473,452, Sept. 25th of 1984). More recently, Gardner (Gardner DCJ et al., Yeast, 1993, 9, 1053-1055) obtained band patterns of S. cerevisiae chromosomes from cells that did not form spheroplasts. In parallel, Higginson et al (Higginson D. et al., Anal. Lett, 1994, 27:7, 1255-1264) showed that S. cerevisiae DNA can be deproteinized using 8 M urea instead of proteinase K. However, the method described by Gardner is still expensive, because he used proteases to deproteinize the DNA, whereas, the method described by Higginson is cheap, but consumes 72 hours of incubation, which is a long time. Later, S. cerevisiae samples were prepared, and enzymes were not used: The plugs were sequentially incubated with LETK (10 mM Tris, 500 mM EDTA, 600 mM KCI, pH 7.5) for 4 hours, NDS (10 mM Tris, 500 mM EDTA, 1% sarcosyl, pH 9.5) for 2 hours, and NDS plus 4 M urea (NDSU) for 2 hours. This method needed 10 hours for sample preparation (Lopez-Canovas L, et al., Anal. Lett,
1996, 29:12, 2079-2084). Rapid methods for the preparation of immobilized DNA were described also, but they use enzymes (for instance, in Guidet F and Langridge P, Biotech, 1992,12:2, 222-223).
As general rule, immobilized DNA for PFGE experiments requires the formation of spheroplasts and DNA deproteinization using proteases. These requirements are independent from the cell type studied (bacteria, yeast, etc) (Maule J, Mol. Biotech. 1998, 9: 107-126; Olive DM and Bean P, J. Clin. Microbiol, 1996, 37:6, 1661-1669). For instances, immobilized Staphilococcus aureus DNA were reported to be prepared in 2 hours by immobilizing cells with lysostaphin and incubating the plugs with detergents, whereas Streptococcus fecalis cells needed to be incubated with lysozyme and mutanolysin prior to the immobilization (Goering RV. and Winter MA., J. Clin. Microbiol, 1992, 30:3, 577-580). In the mentioned work, authors did not incubate the samples with proteinase K. However, Matushek et al. (Matushek MG et al., J. Clin. Microbiol, 1996, 34:10, 2598-2600) reported that they were unable to obtain the band patterns if the samples were not incubated with proteinase k. As alternative, they proposed a rapid method to prepare immobilized DNA samples using proteinase K. Recently, McEllistrem et al. (McEllistrem MC et al., J. Clin. Microbiol, 2000, 38:1, 351-353) reported a complete non-enzymatic, method to prepare immobilized DNA of Streptococcus pneumoniae. However, it consumes 6 hours and the authors attributed the protocol success to the activation of an autolysin of the Streptococcus. At present, the spheroplast formation enzymes and the proteases have been deleted only from the protocols of preparation of intact DNA molecules of S. cerevisiae and Streptococcus pneumoniae, but the times required to complete these preparations are 10 and 6 hours, respectively, which are long times. Consensus does not exist about the feasibility of deleting the protoplast formation enzymes and proteinase K in sample preparation of microorganisms. Therefore, current methods are expensive and consume long times.
Most of the above methods rest on the assumption that microorganisms with cell walls must be immobilized previously to the enzymatic treatment. An exception is presented in the paper published by Goering and Winter (Goering RV and Winter MA, J. Clin. Microbiol, 1992, 30:3, 577-580). The authors suspended cells in a solution containing lysozyme and mutanolysin (two enzymes to form spheroplast) prior to their immobilization. However, a general non-enzymatic method to treat microorganisms with cell walls prior to
their embedding in agarose gels has not been presented yet. Such method would be cheaper and simpler that current protocols in the preparation of samples. Methods to isolate nuclei acids in solution, starting from cells heated in the presence of agents that provoke the permeability of the microorganism cell wall, were reported (European Patent 0,657,530, 1994, bulletin 95/24; US Patent 158,940, 1993). The method releases large fragments of undegraded nucleic acids from microorganisms without physically disrupting the entire cell wall. This method does not require lytic enzymes. However, intact DNA molecules are not obtained, because DNA is isolated in solution; and the authors did not propose the method to obtain the molecular karyotypes or the pulsetypes of the mentioned microorganisms. Authors reported that the obtained DNA is suitable for hybridization, but they did not address the possibility of DNA restriction with endonucleases. In conclusion, said method does not guarantee the obtaining of intact DNA molecules, whereas the possibility of digesting them with restriction enzymes remains unknown.
Therefore, a general procedure has not been proposed yet for the preparation of immobilized intact DNA from yeast, gram-positive and gram-negative bacteria and parasites by non-enzymatic methods in short times.
The preparation of immobilized DNA samples needs molds to form said samples. These molds can be reusable or disposable. The reusable molds should allow the sterilization. This is important for handling samples from pathogenic microorganism. The use of disposable molds requires continuous supply, which can be a limiting factor in laboratories with low budget. Known molds are the following:
a) Molds that form independent and similar plugs (US Patent 4,473,452, Sept. 25th of 1984);
b) Molds that form long ribbons, which are cut to form independent plugs;
c) Molds that form long square 'noodle' or long agarose rods, which are cut to form independent plugs (Birren B and Lai E. Pulsed Field Gel Electrophoresis: a practical guide, Academic Press, Inc. San Diego, California, 1993, pp 29-30).
In general, samples of dimensions larger than the gel slot are generated in said molds. For this reason, to obtain plugs with dimensions similar to the ones of slots, the ribbons, noodle, etc, need to be cut with a razor blade or another device. (CHEF Mapper XA Pulsed Field Electrophoresis System. Instruction Manual and Application Guide pp
40aSection 7. Catalog Numbers 170-3670 to 170-3673. Bio-Rad. 1995). However, cutting the ribbons or noodles provokes plugs of non-homogeneous sizes and dimensions, which influence the quality of the electrophoresis patterns. DNA molecule resolutions in the gel depend on the sample thickness. Consequently, the comparison of the patterns obtained in different lanes of the gel is difficult. Difficulties in the comparisons of band patterns represent a disadvantage in microorganism typing.
A mold for embedding cells in agarose gels and treat plugs was disclosed in the US Patent 5,457,050, Oct. 10th of 1995. The mold could be disposable or reusable, depending on the material used to make it. It is claimed that the facility of the mold is that samples are formed and treated inside said mold. However, it is a disadvantage: if the plugs are kept inside the mold during the incubations, the time needed to obtain the samples suitable for PFGE analysis is notably lengthened. The effector molecules of the lysis and deproteinization solutions can poorly reach the target molecules inside the cells, because the contact area between the plugs and the incubation solutions is at least reduced to half.
Selection of the PFGE experimental conditions
The selection of the experimental conditions is complex. Methods to select the running PFGE conditions have been reported.
For example, the CHEF Mapper from Bio-Rad has an option of auto-algorithm and another one of interactive algorithm (CHEF Mapper XA Pulsed Field Electrophoresis System. Instruction Manual and Application Guide, pp 31-40 Catalog Numbers 170-3670 to 170-3673. Bio-Rad. 1995). Both options permit to calculate the pulse times, pulse ramp durations, reorientation angle, electric field and optimal running time to separate DNA molecules of a given sample. In contrast to the auto-algorithm, in which fixed experimental conditions are assumed, the buffer type, temperature and concentration, and the agarose type and concentration are permitted to vary as inputs in the interactive algorithm. Both algorithms work based on empirical and theoretical data collected during 5 years of experience (Bio-Rad Catalogue. Life Science Research Products. Bio-Rad Laboratories, pp185. 1998/99). However, the manufacturers recommend feed the auto-algorithm with DNA sizes smaller and larger than the expected sizes of the sample molecules. In addition, if extremely wide size ranges are entered to the auto-algorithm, as well as to the interactive program, erroneous results, such as band inversion in the mid range of the gel, can be generated.
Another empirical expression was proposed to give the electric pulse duration that separates the group of molecules of sizes falling between a given value and a higher one called RSL (Resolution Size Limit) (Smith DR. Methods I, 1990, 195-203). However, said expression is valid on specific experimental conditions alone, and it does not predict the resolution between two any molecules. Another function was proposed. It provides the approximate conditions of electric field and pulse time needed to separate a given group of molecules (Gunderson K and Chu G, Mol. Cell. Biol., 1991, 11:3348-3354). However, said function only permits to obtain rough estimates of the two mentioned variables, and does not provide the molecule migrations at any experimental condition. Despite various theoretical studies were performed about DNA molecular reorientation during PFGE (Noolandi J, Adv. Electrophoresis, 1992, 5: 1-57; Maule J, Mol. Biotech. 1998, 9:107-126), said studies have not given a practical and useful result in the laboratories yet. They did not generate methods allowing the PFGE user to select and set the experimental conditions needed to separate the molecules under analysis. The equations proposed by Lopez-Canovas et al. (Lopez-Canovas L et al., J. Chromatogr. A, 1998, 806:123-139) to describe DNA migration in PFGE, have not been used to predict the band patterns that should be obtained when varying the pulse time ramps, the electric field, temperature and running time. These variables are usually modified in microorganism typing.
PFGE band pattern analysis
Computerized systems for image acquisition data from PFGE gels are available for band pattern analysis (Gerner-Smidt P et al., J. Clin. Microbiol, 1998, 37(3):876-877; Tenover F et al., J. Clin. Microbiol, 1995, 33(9):2233-2239; van Belkum A et al., J. Clin. Microbiol, 1998, 36(6): 1653-1659). However, the comparison of the restriction patterns remains a subjective process, and it cannot be totally reduced to rigid algorithms (Tenover F et al., J. Clin. Microbiol, 1995, 33(9):2233-2239). Although computer based analyses were performed, the final interpretation of the patterns must be subordinated to previous visual inspection.
Automatic and non-automatic band pattern analysis give as result the number of bands and the sizes of the molecules in the bands. It is usually done by comparing unknown DNA migrations with the migrations of molecular weight markers. However, PFGE is relatively new, and size markers for wide DNA size range are not always available. Consequently, the criteria used for bacterial typing, based on the interpretation of PFGE band patterns,
consist in the determination of the number of different restriction fragments found when digesting the DNA of the microorganisms under comparison.
Equations to describe DNA molecule migrations under a single pulse ramp, different electric field strength and distinct temperature were proposed from electrophoresis data collected in experiments done in 1.5 % agarose, Lachema and 0.5X TBE, 1X TBE: 89 mM Tris, 89 mM Boric Acid, 2 mM EDTA (Lopez-Canovas L et al., J. Chromatogr. A, 1998, 806:123-139). However, a method to extend and apply said equations to the analysis of band patterns after the application of pulse time ramps does not exist. The application of pulse time ramps is usually done in the comparative study of microorganisms.
Current process for microorganism typing by PFGE.
Total process for microorganism typing needs long time and many resources. Electrophoresis demands around 20 hours, methods of sample preparation, recommended by manufacturers or reported in the literature, require to use large amounts of enzymes (For instances, 80 mg/ml proteinase k) and long incubation times (CHEF Mapper XA Pulsed Field Electrophoresis System. Instruction Manual and Application Guide, pp 40-43 Catalog Numbers 170-3670 to 170-3673. Bio-Rad. 1995). A factor limiting the use of PFGE for microorganism typing is the time needed to complete the analysis of isolates, It is from 2 to 3 days, thus reducing the capacity of the laboratories to analyze many samples (Olive DM and Bean P, J. Clin. Microbiol, 1999, 37:6,1661-1669).
DETAILED DESCRIPTION OF THE INVENTION
The present invention provides a process and a kit of reagents for typing isolates of microorganisms in a single working day (between 7 and 13 hours). Typing is done by the obtainment of the typical band patterns given by the separation of DNA molecules subjected to pulsed field gel electrophoresis in miniequipments. Specifically:
i) A method and the associated reagent kit to prepare, in 60 minutes at the most, intact DNA samples embedded in miniplugs of a gel, is provided herein. The method is based on the treatment of the cells with solutions that do not contain lytic enzymes. Said treatment can be done before or after the embedding of such cells in the gel. The cells may be yeast, parasites, gram-positive and gram-negative bacteria. Cells are embedded by means of a mold made of a flexible material that can be sterilized. It renders homogeneously sized miniplugs. The miniplug thickness varies from 0.03 to 0.1 cm depending on the mold dimensions used, ii) Methods to predict lineal DNA migrations are provided. The methods are based on theoretical equations that permit the calculation of the migrations of lineal DNA molecules at any condition of electric field, temperature, pulse duration ramps and electrophoresis durations in the CHEF system. These methods permit to select the optimal electrophoresis condition to be applied to the gels, as well as to analyze the resulting band patterns obtained after performing the electrophoresis, iii) Processes for the separation and analysis of DNA molecules of microorganisms are provided here. The separations are done in miniequipments for pulsed field gel electrophoresis. The miniCHEF miniequipments gives the band patterns in 2.5 to 5 hours and the MiniTAFE in 5 to 7 hours. The process permits to study up to 27 samples of immobilized DNA of microorganisms. Said samples are: a) prepared by the non-enzymatic procedure; b) separated in the minigels of miniequipments at the optimal electrophoresis conditions, conditions selected with the aid of the predictive methods, c) analyzed to estimate the sizes of DNA molecules. The estimations are performed with the aid of the methods of lineal DNA migration analysis, and are done for all DNA molecules loaded into the wells of the minigel and subjected to the action of two electrical fields in the
miniequipments. Previously to the analysis, DNA molecules are detected in the gel by any staining procedure.
The method of sample preparation provided in this invention takes at the most 60 minutes, and it is simple and inexpensive, It neither require lytic enzymes nor proteases in the solutions to incubate microorganism cells and renders immobilized intact DNA. Intact DNA molecules can be digested with restriction enzymes and when they are subjected to pulsed field gel electrophoresis, intact DNA molecules or their restriction fragments migrate in the minigels forming band patterns corresponding to the molecular karyotypes or pulsetypes of the microorganisms.
The method is based on the chemical modification of the bacterial wall to allow the lysis of the microorganisms, or the diffusion of small effector molecules toward the target molecules in the cells. Undesired intracellular components are also eliminated during the preparation by dialysis. As results, intact DNA molecules are obtained in the miniplugs where the cells were embedded.
The method comprises the following general steps:
1) The cells of microorganisms are initially isolated from the fluids of hospitalized persons, or from a biotechnological collection or from the experiments done in a common laboratory of molecular biology, genetics or other.
2) The cells are grown in broth or on solid media of the proper composition for each microorganism.
3) The cells are collected by centrifugation and further washed.
4) The cells are a) embedded in the gel and incubated with the non-enzymatic solutions, or b) incubated with said solution(s) and further embedded in gel. In the case of 'a', the miniplugs containing immobilized cells are incubated first in the non-enzymatic solution for 5 to 30 minutes at 50°C. In the case of 'b', cells are incubated with the non-enzymatic solution for 5 to 30 minutes at 50°C and later they are embedded in the agarose miniplugs.
5) Miniplugs containing the cells are dialyzed against the electrophoresis buffer, if the electrophoresis is going to be performed; or against the conservation buffer, if miniplugs are going to be stored; or against the restriction endonuclease buffer, if DNA molecules are going to be digested.
The organisms able to be incubated in the non-enzymatic solutions previous to the immobilization are Saccharomyces cerevisiae, Hansenula polymorpha, Pichia pastoris and Staphylococcus aureus. Pseudomonas aeruginosa, Escherichia coli and Entamoeba histolytica should be first immobilized and further incubated in the non-enzymatic solutions. The most effective washing solutions of cells are presented in Table I.
Table I. The most effective washing solutions of cells to prepare immobilized DNA.
Non enzymatic solutions to incubate the cells, or the miniplugs containing ceils, have anionic detergents, a metal chelating agent, an agent able to compete for hydrogen bond formation and Tris buffer. The most efficient contains: 1% sarkosyl, 0.1 M EDTA, 0.01 M Tris-base, 4M Urea and its pH is 9.5 (NDSU). To incubate cells of gram-positive and gram-negative bacteria nonidet P-40 is added (NDSUPIus).
Some microorganisms, e.g. Escherichia coli, should be incubated first for 10 minutes at 37°C in a non-enzymatic lysis solution. It contains 1% sarkosyl, 1% nonidet P-40, 0.1 M EDTA, 0.01 M Tris base, and its pH is 8.0. Further, they are incubated for half an hour in the NDSUPIus solution.
The storage buffer of the miniplugs containing immobilized DNA is TE-100 (0.01 M Tris-base, 0.1 M EDTA, pH 8.0).
The procedure to embed cells in agarose miniplugs consists in using a mold made of flexible material that can be sterilized. The mold is a sheet of silicone, rubber or other flexible material of up to 0.5 cm wide (see in Examples, example 1). Several square depressions are stamped in the sheet. Depression may be up to 0.3 cm wide and 0.03 to 0.1 cm depth. To pour the agarose-cell suspension, the mold is pre-warmed at 42°C by putting it on a surface heated at this temperature, afterwards the suspension is poured onto the mold, and evenly distributed in the depressions with the aid of a spatula. Then, the mould is covered with a lid (It can be made of glass, acrylic, plastic or any other material) and incubated between 4 - 15°C until the miniplugs are harden. The
homogeneously sized miniplugs are extracted from the flexible mould by holding its perimeter sides and bending the mold inside of a recipient that contains the non enzymatic solution for miniplug treatment. The suspension is prepared in such a way that 0.12 to 3 x 108 bacterial cells, 8 x 107 yeast cells or 6 x 104 trophozoites of Entamoeba histolytica are embedded per each miniplug of 0.3 x 0.07 cm of dimension. All mentioned microorganisms can be prepared by using this type of mold. Altogether, this type of mold can be used to prepare miniplugs that contain any other type of cells. In the present invention, the method to select the optimal electrophoresis conditions to be applied in the miniequipments is based on calculating the migrations of lineal DNA molecules. The calculation is done by using a group of theoretical equations that describe the migration, the reorientation times and the migration velocities of lineal DNA molecules in the miniCHEF minigel. The equations are fed with the values of electric field and temperature and they should be comprised between 1 - 20 V/cm and 4 - 30°C, respectively. To apply the equations, the electrophoresis is assumed to be done in 1.5% agarose and the electrophoresis buffer should be 44.5 mM Tris, 44.5 mM Boric acid, 1 mM EDTA, pH 8.3 (TBE 0.5X). The theoretical equations that describe DNA migration are the following:
tr: reorientation time (s),
vr: migration velocity during reorientation (cm/s),
vm: migration velocity after reorientation (cm/s),
Q: 1e- x bp (DNA net charge, e-: electron charge in statcoulomb),
L: 0.34 nm x bp (DNA contour length, in cm),
E: electric field strength in statvolts/cm,
iscosity of the buffer solution in Poises, and was calculated by interpolating the experimental temperature (°C) in a polynomial function that relates water viscosity with temperature.
D: total migration of a DNA molecule in the minigel of CHEF (cm), d: migration per pulse (cm), n: number of pulse time ramps. Npr: number of pulses in the ramp Y, tpr: pulse duration in the ramp Y (s),
The method to select the optimal electrophoresis conditions includes the following steps:
I. Calculate the duration of the pulses (tpr) that will be used in the ramps. To perform it:
1) The equations are fed with the selected values of electric field and temperature. The sizes of the smallest and largest linear DNA molecules should be given also.
2) By means of the use of equation 4, the reorientation times of smallest and largest linear DNA molecules are estimated.
3) The mean of both reorientation times (a single tpr, or tp1) is calculated if DNA molecules of sizes comprised between the largest and the smallest molecules are wished to be included in a single pattern.
4) A numerical sequence of pulse duration's is calculated (tpr). It begins with pulse duration that is 1.5 times lower than the reorientation time of the smallest molecule, and ends with 1.5 times greater than the reorientation time of the largest molecule. Linear increments in the pulse duration are used in the numerical sequence of calculated tpr.
5) To carry out the electrophoresis the tp calculated in the step (3) could be taken, otherwise, the numeric sequence of tpr, calculated in step (4), is used.
II. Calculate the total run time. The total electrophoresis run time is estimated on the
basis of the calculation of the migration of the smallest linear DNA molecule. This is
performed as follows:
1) Equations 2 and 3 are fed with the values of electric field and the temperature of the electrophoresis buffer.
2) The reorientation time and the migration velocities of the smallest molecule are estimated. Equation 1 is fed with the durations of the electric pulses (tpr) estimated in step I. The initial values of the number of pulses are fixed.
3) The number of pulses of each ramp 'r' is increased one by one, and each time the migration of the smallest molecule is estimated by means of the use of equations 1 and 5. The iterations are repeated until the molecule reaches the position that is 0.1 to 1 cm far apart from the bottom of the minigel
III. By means of using equations 1 - 5, the migrations of the molecules, wished to be
separated, are calculated for the 'n' ramps, and then, the band patterns given by these
molecules in the minigels of miniCHEF are predicted for the conditions selected for electric
field, temperature, number of ramps 'r', duration of electric pulses and number of pulses
(Npr). This calculation includes the following steps:
1) It is assumed that the electrophoresis is performed in 1.5% agarose gel and 0.5XTBE buffer.
2) The values of electric field and buffer temperature (that will be used in real experiment), are defined to the equations 2 and 3.
3) According to the values estimated in the previous steps, the total number of ramps (n), the number of pulses that will be applied in each ramp (Npr) and the duration of the pulses in each ramp (tpr) are defined to the equation 1.
4) The sizes of the molecules, to be analyzed, are specified.
5) By means of the use of the equations 1 - 5, the distances that should migrate the DNA molecules (wished to be analyzed) are calculated for the specified electrophoresis conditions.
6) The migrations, calculated for the linear DNA molecules, are presented in a numerical or graphical format.
7) The steps 2-6 are repeated until the predicted pattern shows the optimal separation among the linear DNA molecules.
IV. Based on the above results, the experimental condition that render the optimal
separation between the linear DNA molecules is selected. Then, the power supply, the
electrophoresis control unit and the cooling system are fed with these data.
The preferred mean of implementing this method could be a computer program that would facifitate the simulation of the separation of DNA molecules of different sizes in miniCHEF. This program would calculate the optimal experimental conditions for DNA separations. The program would also provide a rapid mean to perform the required calculations for implementing this part of the present invention.
A program was created to simulate the band pattern. The program permits the user to vary the following variables:
1- The size of the DNA fragments or the intact DNA molecules wished to be separated in the gel.
2- The buffer temperature.
3- The voltage.
4- The pulse time and the number of electric pulses applied in each ramp.
5- The number of pulse time ramps. It is comprised between 1 and 1000 ramps.
Fed with the mentioned values, the program provides the following results:
1- DNA molecule velocities (in cm/s) during and after DNA reorientation.
2- The reorientation time of each DNA molecule (in seconds).
3- The migration of each molecule in the gel for the selected run duration.
4- The migration of each molecule and the scheme of the electrophoresis pattern.
The graphical representation of the distances that linear DNA molecules should migrate under the specified electrophoresis conditions is done as follows:
i) Drawing a minigel with the same dimensions of the real minigel, and drawing
the wells where the samples are hypothetically loaded.
ii) Placing lines under each well. They would represent the bands formed by DNA molecules of different sizes after the separation. Each line has the width of the well. These lines are drawn separated from the wells the distances that DNA molecules would migrate in the real minigel.
iii) Assigning to each line, or hypothetical band, a color. The color varies with the size of the molecules that the band contains. That's, using a color code that identifies the molecules of a given size.
This program constitutes a method to choose the proper experimental conditions to separate intact chromosome-sized DNA molecules or large DNA fragments by Pulsed Field Gel Electrophoresis in the miniCHEF. If the program is fed with distinct values of the experimental variables, different electrophoresis patterns are obtained, thus permitting the identification of the experimental conditions that should separate the molecules of interest in CHEF and miniCHEF. This approach does not spend reagents or biological samples. It is based on the theoretical equations that describe linear DNA migration in miniCHEF. Said equations were fitted using migration data of linear DNA, obtained in real miniCHEF experiments. Therefore, they describe correctly the migration of said molecules when they are subjected to electrophoresis. In addition, they do not render anomalous results of mobility inversion in the center of the gel.
In the present invention, the rapid microorganism typing is proposed by means of the electrophoretic separation of DNA in the miniequipments miniCHEF and miniTAFE. Samples of Saccharomyces cerevisiae, Hansenula polymorpha, Pichia pastoris, Pseudomonas aeruginosa, Escherichia coli, Staphylococcus aureus and Entamoeba histolytica cells, prepared using the non-enzymatic procedure, are loaded in the minigels. Samples of these or any other microorganisms, prepared by the conventional enzymatic procedures, can also be loaded.
MiniCHEF and miniTAFE minichambers are used to obtain the karyotypes, or pulsetypes. The distances between the pairs of electrodes with opposite polarity are around 11.6 cm and 7.8 cm in miniCHEF and MiniTAFE, respectively. Electric field intensity up to 20 V/cm can be applied in miniCHEF and 22 V/cm in miniTAFE.
The electrophoresis equipments, selected to carry out this part of the invention, include the miniCHEF and miniTAFE minichambers previously described by Riveron et al. 1995 (Riveron AM et al., Anal. Lett., 1995, 28:1973-1991; European Patent Application EP 0,745,844, Bull. 1996/49; US Patent Application 08/688,607, 1995; Cuban patent RPI Nro. 02/95, 1995), the disclosure of which is totally incorporated herein by reference. The floor of the miniCHEF chamber was slightly modified to support an agarose minigel from 4 to 7 cm wide. In the minigel, 12 to 27 samples can be loaded. The miniTAFE chamber was slightly widened to support a minigel of 7 cm wide. In miniTAFE minigel, 27 samples can be loaded.
The agarose concentration of the minigel can vary from 0.8 to 1.5%, being the preferred value 1.5 %. The 1X TBE buffer is 0.089 M Tris base, 0.089 M boric acid and 0.002 M EDTA (sodium salt of ethylenediamine tetra acetic acid) and it can be used in concentrations ranging form 0.25 to 1X, but preferably 0.5X. The buffer temperature can vary between 4 and 30°C. The 1X TAE buffer (0.04 M Tris-Acetate and 0.001 M EDTA) can also be used. To clamp the voltage in the miniCHEF electrodes, and alternate the electric field orientation in miniCHEF and miniTAFE chambers any purposely-constructed device can be used, including the equipment described by Riveron AM et al., Anal. Lett, 1995, 28(5):845-860; and Riveron AM et al., Anal. Lett, 1995, 28(11):1973-1991. To energize the electrodes, any power supply with maximum output of 300 watts can be used.
Agarose miniplugs are loaded into the wells of the minigel. The wells are formed by the teeth of the comb used to cast the minigel. Different combs can be used to load wider or narrower miniplugs. It depends on the dimensions of the miniplugs that were cast. Ethidium bromide is used to stain the molecules present in each band of the minigel. The minigel is illuminated with ultraviolet light (UV transilluminator) and the images are taken with a camera using a filter of 550 nm. Any other staining procedure can be used also. The electric field strength, buffer temperature, pulse time ramps, electrophoresis time and number of electric pulses set in each ramp come from the results of the simulator (or the method for selecting the optimal conditions to separate the molecules), or from the results of another method that the user employs, including his empirical experience. When the simulator is used, the concentration of the buffer should be 0.5X TBE, the agarose (Lachema) gel must be 1.5%, the electric field must be up to 20 V/cm, the temperature must be between 4 and 30°C and the chamber must be the miniCHEF. When the simulator is employed, but the use of miniTAFE is wished, the same conditions of electric field and temperature, given by the simulator, can be used, but the number of pulses of each ramp should be increased in 1.5 times and the duration of the pulses in 1.2 times. Under other conditions of electric field strength and temperature, the typical band patterns of the molecules contained in the sample that is going to be separated can be obtained also in the miniequipments.
In the present invention the preferred method to analyze the band patterns obtained after the electrophoresis is based on measuring distances migrated by linear DNA molecules in the minigel, and the use of equations 1 - 5 to calculate the sizes of the molecules. The
method requires that the band patterns were obtained in the minigels by electrophoresis in the miniCHEF equipment at an electric field comprised between 1 and 20 V/cm, temperature between 4 and 30°C, 1.5% agarose (Lachema), 0.5X TBE buffer and any number 'n' of pulse time ramps (comprised between 1 -1000) and electrophoresis time. The method consists in:
i) Measuring the distances migrated by linear DNA molecules in the minigels
after the electrophoresis and the staining of the bands in the minigels. ii) Feeding the equations 1 - 5 with the values of electric field, buffer temperature, number of ramps (n), number of pulses applied in each ramp (Npr) and the duration of the pulse in each ramp (tpr). iii) Feeding the program with the real distances (D in cm) migrated by the bands
after the electrophoresis, iv) Calculating the size of the molecules of each band from the migrated distances. It is done according to:
1) A hypothetical DNA molecule of an initial size of 1000 pairs of bases is defined.
2) Equations 2, 3 and 4 are used to estimate vr, vm and tr, respectively, of the hypothetical DNA molecule.
3) By means of the use of the equations 1 and 5, the theoretical migration (Dt in cm) of the hypothetical DNA molecule is estimated for the electrophoresis conditions used in the experiment.
4) D and Dt are compared. If Dt is greater than D, the size of the hypothetical molecule is increased in 1000 bp.
5) Steps 2) to 4) are repeated until the migration estimated for the hypothetical DNA molecule is lower or equal than the distance (D) migrated by the real molecule in the minigel.
6) The DNA molecules in the band are assumed to have a size equivalent to the size of the hypothetical DNA molecule that accomplishes the condition proposed in 4). The tr, vr, and vm values estimated for the hypothetical molecule are also assumed to be the ones of the real molecule.
7) Steps 1) to 6) are repeated with the distances measured for all bands; that is for all molecules separated in the minigel.
The description of the electrophoresis can be given by the electrophoresis pattern and by a matrix. It contains the ordinal of each fragment or separated molecule in the rows; whereas in the columns are the sizes, reorientation times and migration velocities of the separated molecules.
A computer program may provide the preferred method of practicing this part of the present invention. Such program would provide a rapid means of performing the calculations to estimate the size and the kinetic parameters of the fragments or intact DNA molecules separated in the electrophoresis. A program was created that permits the user to change the following variables:
1- The migrated distances of the molecules, that is the position of each band of the pattern in the gel.
2- The buffer temperature.
3- The voltage set in the electrophoresis chamber.
4- The pulse time and the number of electric pulses set in each ramp.
5- The number of ramps (limited between 1 -1000)
Feeding the program with the mentioned values, it provides the following results:
1- DNA velocities (cm/s) during and after reorientation.
2- The reorientation times (s) of each molecule.
3- The size of the molecules in kilobases (kb).
Feeding the program with the electrophoresis conditions in the miniCHEF and the resulting migrated distances of the molecules, the program can calculate the sizes and the kinetic parameters of the molecules present in each band of the gel. In general, molecular weight markers are not needed to identify the molecules of the bands. This analysis will permit the classification of the DNA fragments or the molecules according to their kinetic properties. The results of the electrophoresis can be also described with the aid of another method usually employed.
EXAMPLES Example 1. Mold able to be sterilized for the preparation of sample miniplugs.
An example of the mold able to be sterilized and made of a flexible material (silicone, rubber or any other material) is shown in the scheme of figure 1. The mold is used to prepare agarose-embedded DNA samples. The sheet (1) has 49 depressions (2). The agarose-cell suspension is poured onto the mold or sheet and distributed in the mold with the especial spatula (4). Later, the sheet (1) is cover up with the lid (3), generating the miniplugs (5) containing embedded cells. The sheet of the real mold was made with melted silicone. It was poured into another mold until the sheet (1) was formed. In the example, miniplug dimensions are 3 x 3 x 0.7 mm (length, wide x thickness). To recover the miniplugs (5) from the sheet (1), said sheet is held by its ends and bent inside a container with a solution. Consequently, the miniplugs are released from the sheet and dropped into the solution.
In other mold variants, the depression width may vary from 1.5 mm to the minigel width, whereas the thickness can vary from 0.5 mm to 1.5 mm. The number of depressions stamped on the sheet can also vary.
Example 2. Non-enzymatic preparation of agarose-embedded intact yeast DNA starting from cells cultured in broth media.
Yeasts (S. cerevisiae, H. polymorphs or P. pastoris) were grown in liquid YPG medium (YPG: 10 g yeast extract, 20 g glucose and 10 g peptone dissolved in one liter of distilled water) with shaking at 30°C until late log phase. Cells were harvested by centrifugation and washed with 0.05 M EDTA, pH 7.5 (washing solution, Table I). Agarose-embedded intact DNA is obtained performing any of the two following variants: Variant 1: Cells are incubated prior to their embedding in agarose miniplugs. Variant 2: Cells are embedded in agarose miniplugs and further the miniplugs are incubated.
In both variants the cells are embedded in agarose by preparing a cell suspension of 1.3 x 1010 cell/ml in 1.5 % low melting agarose which was first dissolved in 0.125 M EDTA. The cell suspension is poured onto the sheets (1) of the mold shown in figure 1, then, the mold is covered with the lid (3) and the agarose is let harden until the sample miniplugs (5) are formed.
In the variant 1, the cellular pellet obtained from 100 ml of broth culture is resuspended in 5 ml of NDSU and incubated for 5 minutes at 50°C. Further, the suspension is diluted fivefold in TE-100. The cells are collected by centrifugation and embedded in agarose miniplugs as it was above described.
In the variant 2, the cells are harvested, washed and further embedded in agarose miniplugs (see Table I). Agarose miniplugs with cells are incubated in NDSU for half an hour at 45°C.
Miniplugs are washed twice for 5 minutes in TE-100 (0.01 M Tris-base, 0.1 M EDTA, pH 8.0) and further stored in fresh TE-100 at 4°C. After miniplug treatments by any of the two variants and prior to electrophoresis, the miniplugs are incubated in TBE for 10 minutes at run temperature.
The photograph of the minigel (10) where the S. cerevisiae chromosomal (12) and mitochondrial (13) DNA were separated in band patterns is shown in figure 2. Samples were prepared embedding the cells in miniplugs and incubating them in NDSU (variant 2). The minigel of 7 cm wide, which permits a maximum of 27 samples (11), was used in the miniCHEF. Running electrophoresis conditions were 10 V/cm, 20°C, 1.5% agarose, 0.5X TBE, 50 seconds of pulse time and 4 hours of electrophoresis.
The photograph of the lane (16) of a miniCHEF minigel in which the H. polymorpha chromosomal (17) and mitochondrial (18) DNA were separated in band patterns is also shown in figure 2. The chromosomes of H. polymorpha were prepared according to variant 2. They were separated in the miniCHEF at 10 V/cm, 20°C, 1.5% agarose, 0.5X TBE, 120 seconds of pulse time and 4 hours of electrophoresis.
S. cerevisiae chromosomes were also separated in the miniTAFE minigel (20) shown in figure 2. Chromosomal (21) and mitochondrial (22) DNA band patterns are also shown. The samples were prepared using the variant 1, that's, incubating the cells prior to their embedding in agarose. Said samples were loaded in the 13 slots (23) formed by the comb. The minigel is 7 cm wide. In the miniTAFE were applied 10 V/cm, 20°C, 1.5% agarose, 0.5X TBE, 60 seconds of pulse time and 6 hours of electrophoresis.
Example 3. Non-enzymatic preparation of agarose-embedded intact DNA from Pseudomonas aeruginosa grew in broth and on solid media.
Two colonies of P. aeruginosa were isolated from a blood-agar plate. One of them was inoculated in 5 ml of LB medium (10 g yeast extract, 5 g sodium chloride and 10 g bacto-
triptone per liter of distilled water) and the other was streaked on a LB plate (LB plus 1.2 % bacteriologic agar).
Both cultures were incubated overnight at 37°C. Broth culture was incubated with shaking and the plates were kept static. Cells, grown in broth, were collected by centrifugation, whereas the plates were washed with the proper washing solution (shown in Table I) and further collected by centrifugation.
Cells grew in broth or solid media were washed with the solution shown in Table I, collected by centrifugation and re-suspended at a concentration of 2 x 109 cells per milliliter of 1.5 % low melting agarose dissolved in 0.15 M NaCI. Agarose-cells mix was poured onto the sheet (1) of the mold shown in figure 1, further, the sheet was cover with the lid (3) and the agarose was let to set until the plugs (5) were formed. Miniplugs were incubated with NDSUPIus for half an hour at 50°C. Later, miniplugs were washed twice for 10 minutes in TE-100 at 50°C and stored in fresh TE-100 at 4°C. Prior to restriction enzyme digestion, miniplugs were washed and incubated for 10 minutes in Xba I restriction enzyme buffer. Each miniplug was digested with 20 U of Xba I for 2 hours at 37°C. Restriction fragments were separated in the miniCHEF at 10 V/cm, 20°C, 1.5% agarose and 0.5X TBE, applying a pulse ramp of 20, 15, 10, 5 and 3 seconds and 5, 15, 320, 1020 and 100 pulses, respectively.
The band patterns (26) separated in the miniCHEF minigel (25) are shown in the figure 3. P. aeruginosa miniplugs (27) were prepared from cultures in liquid LB media, whereas the miniplugs (28) were prepared from cultures done on LB plates. The sizes of the DNA fragments separated are also shown in the figure.
Example 4. Non-enzymatic preparation of agarose-embedded intact DNA from Staphylococcus aureus grew on solid media.
A colony of S. aureus was isolated from blood-agar medium and streaked on a Mueller-
Hinton plate (Oxoid). The plate was incubated overnight at 37°C. The plate surface was
washed with washing solution (0.15 M NaCI, 0.01 M EDTA, pH 8.0, Table I) and the cells
were collected by centrifugation.
Agarose-embedded intact DNA was prepared performing any of the two following variants:
Variant 1: Cells are incubated prior to their embedding in agarose miniplugs.
Variant 2: Cells are embedded in agarose miniplugs and further, the miniplugs are
In both variants the cells were embedded in agarose by preparing a cell suspension at a concentration of 4 x 1010 cell/ml in 1.5 % low melting agarose dissolved in washing solution (Table I). The cell suspension was poured onto the sheet (1) of the mold shown in figure 1, further the sheet was covered with the lid (3) and the agarose was let harden until the miniplugs (5) were formed.
In the variant 1, the cellular pellet was resuspended in 3 ml of NDSUPIus and incubated for 30 minutes at 50°C. After that, the suspension was diluted fivefold in TE-100. The cells were collected by centrifugation and embedded in agarose miniplugs. In the variant 2, cells were harvested, washed and further embedded in agarose miniplugs. Agarose miniplugs were incubated with NDSUPIus for one hour at 50°C. After the treatments by any of the two variants the miniplugs were washed twice for 10 minutes each in TE-100 at 50°C. Prior to restriction enzyme digestion, miniplugs were washed and incubated with Sma I restriction enzyme buffer for 10 minutes resting on ice. Each miniplug was digested with 20 U of Sma I for 2 hours at 37°C. S. aureus DNA macrorestriction fragments, separated in the band pattern (31) in the minigel (30), are shown in the figure 4. Miniplugs (32) were prepared according to variant 2, whereas the ones (33) by the variant 1. Running conditions were 10 V/cm, 20°C, 1.5% agarose, 0.5X TBE and pulse ramps of 1, 5, 9, 13, 17 and 21 seconds. In all ramps, 130 pulses were applied. The sizes of the DNA fragments separated are also shown in the figure.
Example 5. Non-enzymatic preparation of agarose-embedded intact DNA from Entamoeba histolytica.
E. histolytica (clone A) trophozoites were grown in TYI-S-33 medium to log phase. Trophozoites were harvested by chilling the culture flasks and pelleting the cells by centrifugation. The pellet was washed with cold PBS and incubated with cold hypertonic solution (0.5 M NaCI, 0.05 M EDTA, 0.01 M Tris, pH 7.0) for 15 minutes at a ratio of 2.5 x 106 trophozoites per milliliter of solution. Further, 108 trophozoites were resuspended in one milliliter of 2 % low melting agarose in hypertonic solution. Suspension was poured onto the flexible silicone mold shown in figure 1 and miniplugs were allowed to harden at 4°C. Miniplugs were incubated with NDSU (0.01 M Tris-base, 0.1 M EDTA, 1 % sarkosyl (w/v), 4 M urea, pH 9.5) at 45°C for one hour. Before the electrophoresis, the miniplugs were incubated with 0.5 X TBE for 10 minutes at run temperature. To store the miniplugs,
the were washed with TE-100 (0.01 M Tris-base, 0.1 M EDTA, pH 8.0) twice for 5 minutes each time and stored in fresh TE-100 at 4°C.
DNA band patterns (36) of E. histolytica (38), S. cerevisiae (37) and lambda-DNA mers (39) are shown in figure 5. Electrophoresis was performed at 9.03 V/cm electric field, 120 seconds of pulse time, 20°C, 1 % agarosa (Seakem), 0.5X TBE running buffer and 6 hours of electrophoresis. Miniplugs of 0.1 cm thickness were loaded.
Example 6. Design of the electrophoresis running conditions in the miniCHEF. Setting the experimental conditions by using the simulator (method for selecting the optimal conditions for DNA separation).
The pulse time ramps needed to separate the S. cerevisiae chromosomes in the miniCHEF chamber of 11.6 cm between the electrodes of opposite polarities were simulated. The purpose was to obtain the pattern that displays the 11 bands formed by all S. cerevisiae chromosomes. The electrophoresis was assumed to be performed in 1.5 % agarose gel and 0.5X TBE as running buffer. The size values of S. cerevisiae chromosomes reported by Goffeau were taken (Goffeau A et al., Science, 1996, 274: 546): 230 kb (chrom. I), 270 kb (chrom. VI), 315 kb (chrom. Ill), 440 kb (chrom. IX), 589 kb (chrom. VIII), 577 kb (chrom. V), 667 kb (chrom. XI), 745 kb (chrom. X), 784 kb (chrom. XIV), 813 kb (chrom. II), 924 kb (chrom. XIII), 948 kb (chrom. XVI), 1091 kb (chrom. VII and chrom. XV), 1554 kb (chrom. IV) and 2352 kb (chrom. XII).
The simulator predicted four pulse time ramps of 5, 40, 75 and 110 s of pulse times and 42 pulses in each ramp to achieve the optimal separation of S. cerevisiae chromosomes in a single pattern for 10 V/cm electric field strength and 20°C. The results of migration, reorientation times, migration velocities and the color code used to identify each chromosome are shown in Table II.
Table II. Quantitative results obtained using the simulator. Sizes (kb) and colors assigned to the S. cerevisiae chromosomes according to the color code of the simulator.
D experimental: Distance migrated by the molecules in the minigel (40) of figure 6.
D predicted: Distance migrated by the molecules according to the simulator predictions for the running conditions used in the experiment of figure 6.
vr: migration velocity of the molecules during reorientation.
vm: migration velocity of the molecules after reorientation.
tr: reorientation time of the molecules. The photograph of the real minigel (40) with the band patterns of the chromosomes of S. cerevisiae 196-2 (41) obtained in the miniCHEF at the conditions predicted by simulator is shown in figure 6. The band pattern simulated in the hypothetical minigel (42) and drawn by the simulator is also shown. Both patterns are similar. Agarose-embedded intact DNA molecules from S. cerevisiae 196-2 separated in the real experiment were prepared according to the non-enzymatic procedure disclosed in this invention.
The flow chart of a part of the simulator disclosed in this invention is shown in figure 7. The method of calculations to estimate the pulse ramps, based on migration data or previously known size data, is shown in the flow chart.
When the user feeds the method with migration data, the simulator initially estimates the sizes of the molecules from said data and further it estimates the set of lineal pulse time ramps. When the user feeds the method with size data, the simulator directly estimates the pulse time ramps. The criterion to finish the increments in the number of pulses is the number of pulses that provokes the smallest molecule to migrate 2.5 cm. Finally, the simulator provides the result that the user should observe in the gel (see the real band patterns in minigel 43 and the simulated in the hypothetical minigel 42 of figure 6) for the pulse ramps calculated by the program and applied to the group of molecules specified by the user. The program also gives quantitative data. This part of the diagram is not shown because the solution is trivial.
Example 7: Analysis of the electrophoresis karyotypes or pulsetypes.
The electrophoresis karyotype (61) of S. cerevisiae, obtained in the miniCHEF after the
separation of said chromosomes in 1.5 % agarose, 0.5X TBE, 10V/cm, 20°C, 2.95
seconds and 453 pulses and 21.56 seconds and 453 pulses, is shown in figure 8. The
migration of each band (62-66) was measured in said karyotype.
The method for analyzing the migrations was fed with the migration datum of each band,
the electric field strength, the duration and number of pulses and the temperature of the
The method disclosed herein allowed the calculation of the size, reorientation times and
migration velocities of the molecules separated in each band. These results are shown in
Table III. This is the type of result given by the procedure for analyzing the migrations
disclosed in this part of the invention.
Table III. Size, reorientation time and migration velocities of the molecules in each band. Estimations were done by feeding the method with the position of each band in the gel, after the application of the pulse ramps.
D exp: Distance migrated by the molecule in the minigel of figure 8.
D theor: Distance that real molecule of each size should migrate at the running
conditions of the experiment of figure 8.
vr: migration velocity of the molecule during reorientation.
vm: migration velocity of the molecule after reorientation.
tr: reorientation time.
The flow chart of the method for the analysis of DNA migrations is shown in figure 9. The diagram was drawn to process a molecule of a single size, but the steps are repeated for all analyzed molecules.
When the method described in the example 7 is fed with migration data, said method estimates the sizes of the molecules as the method described in this example does.
Example 8. MiniCHEF typing of Escherichia coli isolates.
A single colony of each isolate (INN3 and INN7), characterized at phenotypic level as Escherichia coli, was taken from blood-agar plates. Further, they were sub-cultured in 5ml of LB medium (10 g of yeast extract, 5 g of sodium chloride, 10 g of bacto-triptone per liter of distilled water). Each culture was incubated overnight at 37°C with shaking. Cells from each culture were washed (see washing solution in Table I), centrifuged and the pellet re-suspended to a ratio of 2 x 109 cell per milliliter in 1.5 % low melting point agarose
dissolved in 0.15 M NaCI. Each agarose-cell mix was poured onto the sheet (1) of the molo shown in figure 1. The sheet was covered with the lid (3) and the agarose was let harden until the miniplugs were formed (5). Both groups of miniplugs were incubated with NDSUPIus for half an hour at 50°C. Later, the miniplugs were washed and incubated for 10 minutes with Xba I restriction enzyme digestion buffer and each one was digested with 20 U of Xba I for 2 hours at 37°C.
Band patterns (87) separated in the minigel (86) of the miniCHEF are shown in figure 10. The separations achieved in the miniCHEF of the Xba l-digested total DNA from INN3 (88) and INN7 (89) E. coli isolates permitted to identify six common fragments between them (90). Then, according to Tenover (Tenover F et al., J. Clin. Microbiol., 1995, 33:9, 2233-2239) they were classified as two different E. coli subtypes. DNA restriction fragments were separated in the miniCHEF at 10 V/cm, 20°C, 1.5 % agarose and 0.5X TBE, applying pulse ramps of 25, 20, 15, and 5 seconds and 35, 40, 50, 140 and 800 pulses, respectively.
BRIEF DESCRIPTION OF DRAWINGS:
Figure 1. Scheme of the mold to cast the miniplugs. The sheet, with the stamped depressions, to pour the agarose-cell suspension is shown in the bottom of the figure. In the top, are shown the mold lid and a miniplug. The spatula to distribute the agarose-cell suspension is also shown in the right.
Figure 2. Photograph of S. cerevisiae and H. polymorpha chromosomal band patterns separated in the miniCHEF and miniTAFE minigels. Top of the figure: miniCHEF minigel with 7 cm wide, its 27 slots and the band patterns of S. cerevisiae chromosomes. The minigel, 4 cm in width, and the band patterns of H. polymorpha chromosomes are shown in the center of the figure. The samples were prepared by the non-enzymatic method by incubating the miniplugs containing immobilized cells with NDSU. Running conditions: 10V/cm, 20°C, 1.5 % agarose, 0.5X TBE, 50 seconds of pulse time and 4 hours of electrophoresis. In the bottom of the figure, the miniTAFE minigel with the band patterns of S. cerevisiae chromosomes is shown. In the MiniTAFE, 10 V/cm, 1.5 % agarose, 0.5X TBE, 60 seconds of pulse time and 6 hours of electrophoresis were used. The samples were prepared by incubating the cells with NDSU and later embedding them in agarose miniplugs.
Figure 3. Band patterns obtained in the miniCHEF for the Xba I macrorestriction DNA fragments of P. aeruginosa. In the left, P. aeruginosa miniplugs were prepared from cells grown in liquid LB medium, whereas, in the right, the miniplugs were prepared from cells grown on LB plates. MiniCHEF was used at 10 V/cm, 20°C, 1.5 % agarose and 0.5X TBE, and pulse ramps of 20, 15, 10,5 and 3 seconds and 5, 15, 320, 1020 and 100 pulses were applied, respectively.
Figure 4. Band patterns given by MiniCHEF for Sma I macrorestriction DNA fragments of S. aureus. Band patterns of samples prepared by the non-enzymatic method by incubating the miniplugs containing cells with NDSUPIus are shown in the left. Band patterns of samples prepared by incubating the cells with NDSUPIus and later embedding them in agarose miniplugs are shown in the right. In both sample preparations, the cells were cultured on plates. Running conditions were 10 V/cm, 20°C, 1.5 % agarose, 0.5X TBE, pulse times of 1, 5, 9, 13, 17 and 21. In each ramp, were applied 130 pulses. Figure 5. Photograph of the DNA band patterns of E. histolytica, S. cerevisiae and X-phage concatamers. Electrophoresis was performed in the minigel of the miniTAFE at 9.03 V/cm electric field strength, 120 s pulse time, 20°C, 1 % agarose (SeaKem), 0.5X TBE buffer and 6 hours of electrophoresis. Samples of 0.1 cm thickness were loaded. From left to right, lanel: Miniplugs from S. cerevisiae 196-2; lanes 2, 3, 4 and 5: Miniplugs containing E. histolytica trophozoites incubated with NDSUPIus at 45 °C for 0.5, 1, 2 and 16 hours, respectively, lane 6: X DNA ladders.
Figure 6. Photograph of real miniCHEF minigel (40) used to obtain the band patterns of S. cerevisiae 196-2 chromosomes (left) and graphic of the hypothetical minigel (42) predicted by the simulator (right). Real electrophoresis was performed at the conditions predicted by simulator. Immobilized intact DNA molecules of S. cerevisiae 196-2, analyzed in this electrophoresis run, were prepared by the non-enzymatic procedure disclosed in this invention. For 10 V/cm electric field strength and 20°C buffer temperature, the running conditions predicted by simulator were four pulse ramps of 5, 40, 75 and 110 seconds and 42 pulses in every ramp. The migration data and the color code used to identify the sizes of the molecules are shown in Table II.
Figure 7. Flow chart of the method to simulate the DNA band patterns in the minigels of the miniCHEF. The following parameters and variables are used in the diagram: DNA size (kb), DNA reorientation times (tr), DNA migration velocity during reorientation (vr), and after reorientation (vm) in the miniCHEF. Additionally, tpr: pulse time in each ramp, Npr:
number of pulses in each ramp, gO, g1, g2, g3, g4 coefficients obtained to describe viscosity (r|) as function of the experimental temperature (T), Dt: theoretical distance predicted by the method, n: number of ramps, E: electric field, L: DNA contour length, bp: base pairs, Q: DNA net charge.
Figure 8. Electrophoresis karyotype (61) obtained in the miniCHEF for S. cerevisiae chromosomes. Electrophoresis conditions: 10 V/cm, 1.5 % agarose gel, 0.5X TBE, 20°C, 2.95 seconds and 453 pulses and 21.56 seconds and 453 pulses.
Figure 9. Flow chart of the method that needs to be fed with migrated distances to estimate the size (kb), reorientation times (tr), migration velocity during reorientation (vr) and after reorientation (vm) of the molecules separated in the miniCHEF. tpr: pulse time in each ramp, Npr: number of pulses in each ramp, gO, g1, g2, g3, g4 coefficients obtained to describe viscosity (r|) as function of the experimental temperature (T), D: distance migrated in the gel by DNA molecules, Dt: theoretical migrated distance predicted by the simulator, n: number of ramps, E: electric field, L: DNA contour length, bp: base pairs, Q: DNA net charge.
Figure 10. MiniCHEF typing of the INN3 and INN7 E. coli isolates after Xba I restriction digestion of their DNA molecules. The non-enzymatic method to prepare the samples was used. Running conditions were: 10 V/cm, 20°C, 1.5 % agarose gel and 0.5X TBE, applying pulse ramps of 25, 20, 15, 10 and 5 seconds and 35, 40, 50, 140 and 800 pulses, respectively. Points (90) tag the restriction fragments that both isolates have in common
ADVANTAGES OF THE DISCLOSED SOLUTIONS
1- Preparation of intact DNA molecules of microorganisms, embedded in thin miniplugs of any gel, is performed between 5 minutes and 1 hour. The preparation does not require the uses of enzymes, then it is performed rapid and at low cost.
2- Non-enzymatic preparation of DNA samples for PFGE is efficient using cells grow in liquid or solid media. Some type of cells can be incubated in the non-enzymatic solutions prior to their embedding. This modification reduces the time necessary to prepare the samples.
3- Gel-embedded DNA molecules, prepared by the disclosed procedure, are free of restriction endonuclease inhibitors. These molecules are digested by restriction enzymes in 2 hours, giving their typical band patterns in pulsed field gel electrophoresis experiments performed in miniequipments.
4- Homogenously sized miniplug, containing immobilized DNA from microorganisms, are obtained, thus they do not need to be cut prior to the electrophoresis. Identical miniplugs guarantee the reproducibility of the results.
5- Molecular karyotypes or pulsetypes of many samples (up to 27) are obtained in run time ranging from 2.5 to 7 hours. The consume of buffer and matrix of separation is low. The time required for separation depends on the microorganism studied and the miniequipment used, as well as on the electric field, running temperature and pulse time ramps used.
6- The equipments that are used to analyze the genome of microorganisms through pulsed field minigel electrophoresis in miniequipments require small laboratory bench space.
7- The band patterns can be simulated in the computer as many times as required, previously to perform the experiments. The simulation permits to select the electric field, temperature and pulse time ramps that result in the best separation among the molecules without expenses of reagents and biological samples.
8- The selection of the pulse ramps is performed with the aid of a method based on equations that describe migration of DNA molecules in the miniCHEF minigels. Then, the method to select the ramps gives the picture of the optimal pattern of separation among the molecules.
Size markers are dispensable to estimate the sizes, reorientation times and migration velocities of DNA molecules. The method disclosed here to estimate these parameters, based on the distances migrated by the molecules in the gel, provide these information. The method can be applied when any condition of pulse ramps and electric field strength between 1-20 V/cm, temperature between 4-30°C were used in the electrophoresis, but it demands that the experiment were done in 1.5 % agarose gel and 0.5X TBE.
10-The bands resolved in the electrophoresis patterns can be characterized by the size of the molecules migrating in each band, the reorientation times of said molecules and their migration velocities.
11-The process disclosed herein saves time, chemical reagents and biological samples.
12-The process, that includes DNA sample preparation and the analysis of the genome of 27 microorganisms, takes a single working day.
13-A kit of reagents, to simplify intact DNA preparation of microorganisms, is provided.
1. A process for rapid bacterial typing by Pulsed Field Gel Electrophoresis (PFGE); process providing that PFGE separations of bacterial DNA restriction fragments are performed in minichambers of CHEF (Contour Clamped Homogeneous Electric Field) or TAFE (Transversal Alternating Field Electrophoresis) systems in 7 to 13 hours; and process providing that DNA migrations ('D') of said fragments are calculated at various pulse times ('tp') by replacing DNA sizes ('L'), electric field ('E'), buffer viscosity (, a function of the buffer temperature) and pulse time in a group of known theoretical equations that describe 'D' as 'd•Np' ('Np', number of pulses), 'd' (migrations per pulses) as 'vr«tp«r(tp-tr) + vm« (tp-tr)»[1-r(tp-tr)]', 'vr' (DNA reorientation velocity) as '0.027[QE1.45/8L1.35]', 'vm' (DNA velocity after reorientation) as '0.665[QE1.76/8L1.08]', 'tr' (DNA reorientation time) as '0.134(L114/vr)0.926'; where r(tp-tr)=1 if tr ≥ tp and r(tp-tr)=0 otherwise, and assuming that the electrophoresis is done in 1.5% agarose gels and 0.5X TBE buffer, said process comprising the steps of:
a) Preparing intact immobilized DNA from Escherichia coli, Pseudomonas aeruginosa or Staphylococcus aureus cells, said preparation being performed using:
i) a set of solutions of chemical reagents forming a reagent kit whereby immobilized intact DNA molecules are prepared from said bacterial cells, solutions of the kit that have the following compositions:
-a metal chelating agent (0.01 M EDTA) and/or a salt (0.15M NaCI), solutions of said kit whereby bacterial cells are washed and embedded in agarose miniplugs;
-a metal chelating agent (0.1M EDTA), two anionic detergents (1% Sarcosyl and 1% Nonidet P-40) and 0.01 M Tris base, solutions that additionally could contain 4M Urea, solutions of said kit whereby bacterial cells are treated; and
-a metal chelating agent (0.1M EDTA) and 0.01 M Tris base, solution of said kit whereby miniplugs are washed and stored;
Wherein the intact DNA is extracted by non-enzymatic method;
ii) flexible molds for casting agarose miniplugs containing bacterial cells; and methods of use of the flexible mold and said reagent kit with each bacterial specie;
characterized in that, the molds are sheets of materials such as silicone, and are covered by lids of glass; sheets which are up to 0.5 cm in thickness and have stamped in one of their surfaces various square depressions of 0.3 cm in size and
from 0.03 to about 0.1 cm in depth, depressions in which the agarose-bacterial cell mix solidifies and gives miniplugs of said sizes, molds that are flexible enough to be bent for detaching said miniplugs from them and are reusable after their autoclaving, being said molds and lids completely assembled and used for immobilizing bacterial cells according to a method such as herein described;
b) subjecting the intact immobilized DNA thus obtained to pulsed field gel electrophoresis so as to obtain necessary data sets (including but not limited to d, tr, vr and vm); and
c) calculating optimal electrophoresis conditions of running miniCHEF, said calculations being performed prior to separations of DNA restriction fragments of said bacterial species in minichambers and said calculations comprising:
i) entering of data sets of 'd', 'tr, 'vr', and 'vm' of bacterial DNA restriction fragments for electric fields from 1 to 20 V/cm and temperature from 4 to 30°C, sets of values that were obtained by replacing DNA sizes, electric field and temperature in the group of known theoretical equations describing 'tr', 'vr', 'vm' and 'd',
ii) calculation of the durations of the pulses of the ramp, or series of pulse durations that separates DNA molecules most efficiently,
iii) calculation of the total run time, or the most efficient electrophoresis run time for the series of pulse durations calculated in step (ii), and
iv) calculation of the schemes of the band patterns for said optimal electrophoresis conditions or most efficient ramp of pulse duration and run time, schemes which are given as output of the method and are characterized by bands that are drawn as lines of different colors separated according to DNA migration; schemes wherein each color identified restriction fragments of a particular size; thereby an univocal color code identifies the size of the fragments,
performing each calculation according to several steps; and being the series or ramp formed by several terms, in which each term is a pulse duration ('tp'), and each term is accompanied by the corresponding number of pulses ('Np') that gives the most efficient run duration.
2. A process for rapid bacterial typing as claimed in claim 1, wherein the sheets forming said flexible and autoclavable molds are made of silicone, rubber or any other flexible
material, sheets that have any shape, size and number of identical square depressions preferred up to 50) stamped in one surface.
3. A process for rapid bacterial typing as claimed in claims 1 and 2, wherein the method of
assembling and use of one of said flexible molds for preparing intact immobilized DNA in
agarose miniplugs has the following steps:
i) pouring the suspension of bacterial cells and agarose onto the stamped surface of
the mold; ii) distributing said suspension evenly with a spatula to fill said depressions; iii) covering the mold with its lid and led to set until the miniplugs are formed; iv) bending the mold onto any flask to detach the miniplugs.
4. A process for rapid bacterial typing as claimed in claim 1, wherein the composition of a cell washing solution of said reagent kit is 0.15M NaCI and 0.01 M EDTA, pH 8.0 (solution No. 1).
5. A process for rapid bacterial typing as claimed in claim 1, wherein the composition of a cell washing solution of said reagent kit is 0.15M NaCI (solution No. 2).
6. A process for rapid bacterial typing as claimed in claim 1, wherein the composition of a cell embedding solution of said reagent kit is 1.5 to 2% low melting temperature agarose suspended in 0.15M NaCI (solution No. 3).
7. A process for rapid bacterial typing as claimed in claim 1, wherein the composition of a cell embedding solution of said reagent kit is 1.5 to 2 % low melting temperature agarose suspended in 0.15M NaCI and 0.01M EDTA, pH 8.0 (solution No. 4).
8. A process for rapid bacterial typing as claimed in claim 1, wherein the composition of a cell treatment solution of said reagent kit is 0.1M EDTA, 1% Sarcosyl, 1% Nonidet P-40 and 0.01 M Tris base, pH 8.0 (solution No. 5).
9. A process for rapid bacterial typing as claimed in claim 1, wherein the composition of a cell treatment solution of said reagent kit is 0.1M EDTA, 1% Sarcosyl, 1% Nonidet P-40, 0.01 M Tris base and 4M Urea, pH 9.5 (solution No. 6).
10. A process for rapid bacterial typing as claimed in claim 1, wherein the composition of miniplug washing and storage solution of said reagent kit is 0.1M EDTA and 0.01 M Tris base, pH 8.0 (solution No. 7).
11. A process for rapid bacterial typing as claimed in claims 1-10, wherein the method of use of said reagent kit and one of said flexible molds for preparing intact immobilized DNA from P. aeruginosa cells comprises the steps of:
i) collecting cells from broth or plates and washing them in the solution No. 2 of said reagent kit,
ii) suspending cells in the solution No. 3 of said reagent kit and pouring the suspension onto a flexible mold,
iii) detaching miniplugs from the mold after agarose solidification by bending said mold, and incubating them for 30 minutes at 50°C in the solution No. 6 of said reagent kit,
iv) washing miniplugs twice at 50 °C for 10 minutes in the solution No. 7 of said reagent kit, and further storing them in said solution.
12. A process for rapid bacterial typing as claimed in claims 1-10 wherein the method of
use of said reagent kit and one of said flexible molds for preparing intact immobilized DNA
from S. aureus cells comprises the steps of:
i) collecting cells from broth or plates and washing them in the solution No. 1 of said
reagent kit, ii) suspending cells in the solution No. 4 of said reagent kit, and pouring the
suspension onto a flexible mold,
iii) detaching miniplugs from the mold after agarose solidification by bending said mold, and incubating them for 60 minutes at 50°C in the solution No. 6 of said reagent kit,
iv) washing miniplugs twice at 50 °C for 10 minutes in the solution No. 7 of said reagent kit, and further storing them in said solution.
13. A process for rapid bacterial typing as claimed in claims No. 1-10 wherein the method
of use of said reagent kit and one of said flexible molds for preparing intact immobilized
DNA from E. coli cells comprises the steps of:
i) collecting cells from broth or plates and washing them in the solution No. 1 of said reagent kit,
ii) suspending cells in the solution No. 3 of said kit, and pouring the suspension onto a flexible mold,
iii) detaching miniplugs from the mold after agarose solidification by bending said mold, and incubating them for 10 minutes at 37 °C in the solution No. 5 of said reagent kit,
iv) incubating miniplugs for 30 minutes at 50 °C in the solution No. 6 of said reagent kit,
v) washing miniplugs in the solution N° 7 of said reagent kit, and further storing them in said solution.
14. A process for rapid bacterial typing as claimed in claim 1 wherein the step of calculations preceding the separations of DNA restriction fragments of said bacterial species in said minichambers is accomplished by a calculation method that permits to select the optimal electrophoresis conditions of the miniCHEF run, method comprising the steps of:
i) specifying to the calculation method the data sets of migrations per pulse ('d'), reorientation times ('tr'), migration velocities during reorientation ('vr') and after reorientation ('vm') of DNA restriction fragments of said bacterial species, data sets calculated by replacing DNA sizes, electric field and running temperature in the group of known theoretical equations that describe 'tr', 'vr', 'vm' and 'd' of DNA molecules, ii) calculating the most efficient series (ramp) of pulse durations, iii) calculating the most efficient electrophoresis run time for the series of pulse
durations calculated in step (ii), iv) calculating the distances ('D') migrated by all DNA restriction fragments for the most
efficient series of pulse durations and the most efficient electrophoresis time, v) drawing the scheme of the predicted band patterns and the minigel, drawing that is
done by scaling DNA migrations to the minigel scheme, vi) repeating steps (i) to (v) with different 'd', 'tr', 'vr' and 'vm' data sets, obtained at various electric fields and temperatures, and finally selecting the series of pulse durations and number of pulses that gives the best separations among the hypothetical bands in the band pattern scheme.
15. A process for rapid bacterial typing as claimed in claims No. 1 and No. 14 wherein the
step of calculating the series (ramp) of pulse durations 'tpr' that separates DNA molecules
most efficiently is performed according to the following steps:
i) specifying to this step the reorientation times of the smallest and the largest DNA fragments ('trA' and 'trB', respectively) at the selected electric field and temperature,
ii) calculating the 'n' terms ('n' from 2 to 1000) of the series (ramp) of pulse durations (tpr = tp1, tp2,.,tpn) that starts at value 1.5 times lower than 'trA' and ends at value 1.5 times greater than 'trB'; series in which the increment 'A' is the common difference between the successive terms; so, the most efficient series is: tpi = trA/1.5, tp2 = tp1 + , tp3 = tp1 + 2, ... , tpn = 1.5 • trB; where A = | (tp1-tpn) I / (n-1), and n = te / (tp1+ tpn); being 'te' the electrophoresis running time.
16. A process for rapid bacterial typing as claimed in claims No. 1, 14 and 15 wherein the
step of calculating the most efficient electrophoresis run time for the calculated series of
pulse durations is performed according to the following steps:
i) specifying to this step the terms (tp1, tp2,..,tpn) of said series of pulse durations ('tpr' for 'r'=1..n), and the number 'n' of terms of said series,
ii) specifying to this step the set of migrations per pulses ('drA') of the smallest DNA restriction fragment; wherein the set of migrations per pulses of said molecule is defined for the pulses of the series (tp1, tp2,..,tpn) and the electric field and temperature selected; set of migrations per pulses that is calculated replacing 'tr', 'vr' and 'vm' of the smallest DNA restriction fragment in the known theoretical equation describing 'd',
iii) setting an initial value to the numbers of pulses ('Npr') that correspond to all terms of the series; being 1 the initial recommended value for all 'Npr' for 'r' between 1 and 'n',
iv) increasing by one the 'Npr' that accompany each term 'tpr' (for all tpr, Npr and r = 1..n), and calculating the migration 'D' of the smallest molecule for the 'n' terms of
the series; calculation that is done as
v) repeating step iv) until the value of 'D' indicates that said molecule reaches a region of the minigel that is from 0.1 to 1 cm apart from the bottom of said hypothetical
minigel; then, ending the increments of 'Npr', and selecting the current 'Npr' values to estimate the most efficient run duration,
vi) taking as the total run time the one calculated as
17. A process for rapid bacterial typing as claimed in claims No. 1 and 14 - 16 wherein the step for drawing the scheme of the band patterns scaled to a given minigel is based on the calculation of the distances 'D' migrated by all DNA fragments at the most efficient series (ramp) of pulse durations and at the most efficient electrophoresis run time; drawing comprising steps of:
i) specifying to this step the number of terms 'n' of the series (ramp) of pulse durations, the pulse duration (tpr) of each term of the series, and the number of pulses (Npr) accompanying each 'tpr', for 'r' between 1 and 'n',
ii) specifying to this step the sets of migrations per pulses (dr1, dr2.) of all DNA restriction fragments (f1, f2..) of said bacterial species; wherein said sets of migrations per pulses of said fragments are defined for the pulses of the series (tp1, tp2,-,tpn) and the electric field and temperature selected; sets of migrations per pulses that are calculated replacing 'tr', 'vr' and 'vm' of each DNA restriction fragment in said known theoretical equation describing 'd'; being 'dr1', 'dr2' the sets of migrations per pulses of two different fragments,
iii) calculating the distances that said DNA fragments would migrate in the hypothetical minigel, calculation in which the distance 'D' migrated by each fragment in the
minigel is obtained as
iv) drawing a rectangle identical to the real minigel, and drawing various smaller rectangles inside of said larger rectangle, scheme in which the smaller rectangles represent the slots where the DNA samples would be hypothetically loaded,
v) assigning to each fragment an unique color in the scheme of the pattern, color that will identify said fragment and its size after the prediction and drawing of the band patterns; that is, using a color code that identifies the sizes of the molecules that are hypothetically contained in the bands drawn as lines in the separation scheme,
vi) drawing the colored lines below each smaller rectangle to represent the hypothetical bands formed by the fragments, in which each line is apart from said
smaller rectangle, or slot, the distance 'D' that the corresponding fragment would migrate in the real minigel.
|Indian Patent Application Number||715/DELNP/2003|
|PG Journal Number||41/2010|
|Date of Filing||07-May-2003|
|Name of Patentee||CENTRO NACIONAL DE INVESTIGACIONES CIENTIFICAS|
|Applicant Address||AVE. 25 NO. 15202, ESQ. A 158, CUBANACAN, PLAYA, CIUDAD DE LA HABANA, 12100, CUBA|
|PCT International Classification Number||C12N 1/00|
|PCT International Application Number||PCT/CU2001/000008|
|PCT International Filing date||2001-11-02|