Kamalendu Nath

Effects of ethidium bromide and SYBR® Green I on different polymerase chain reaction systems

In an in-gel polymerase chain reaction (PCR), the generation of a 1750-bp yeast DNA fragment was inhibited when yeast DNA gel-stabs or gel-slices stained with ethidium bromide (EtBr) or SYBR Green I were used. Similar inhibition occurred to a varying degree in the reamplification of PCR fragments in prokaryotic systems. Inclusion of the dyes in PCR resulted in an inhibition at about 10 microg/ml EtBr and at 10,000-20,000-fold dilution of SYBR Green I in all systems. The effect remained unchanged despite increasing the PCR cycles to 40. However, increasing the magnesium chloride concentration did reverse the inhibitory actions, although the PCR specificity was lost. In an unusual observation, we find that, at higher dye concentrations (50 microg/ml EtBr, or thousand fold dilution of SYBR Green I), the input yeast DNA electrophoretic profile is maintained following 25 PCR cycles (despite a denaturation temperature of 94 degrees C). It varied significantly in different DNA systems and was readily reversed by high Mg++ concentrations. It is concluded that, at low Mg++ concentrations, different PCR systems are inhibited to varying extents by intercalating dyes and, in some PCR systems, intercalating dyes at unusually high concentrations maintain input DNA electrophoretic profile.

Cloning of a yeast dihydrofolate reductase gene in Escherichia coli

SummaryThe dihydrofolate reductase gene of Saccharomyces cerevisiae has been isolated by selection of trimethoprim resistant Escherichia coli transformed with a gene bank of yeast DNA in plasmid pBR322. From 9.2 kilobase pair BamHI DNA fragment this gene has been localized to a 1.76 kb fragment, the restriction map of which appears different from those reported for the E. coli and the mouse dihydrofolate reductase genes.The enzyme encoded by the chimeric plasmid was established as yeast dihydrofolate reductase by its sensitivity to antifolates in vivo through growth studies and in vitro by enzyme assay. Since, the expression of this gene occurs independent of its orientation within the chimeric plasmid, the 1.76 kb fragment may contain functional regulatory sequences in addition to the structural sequences for yeast dihydrofolate reductase.

Heterogeneity in restriction patterns of Gardnerella vaginalis isolates from individuals with bacterial vaginosis

This study was undertaken to resolve the genetic make up of Gardnerella vaginalis present in bacterial vaginosis (BV). DNA from several G. vaginalis isolates from within and between individual BV patients were compared by BamHI, ClaI and EcoRI restriction endonuclease analysis (REA) followed by a restriction fragment length polymorphism (RFLP) study, utilizing a 5.7-kb BamHI G. vaginalis ATCC14018 DNA probe. Four G. vaginalis isolates from one patient (GVP-062) were composed of 3 different biotypes (biotypes 3, 5 and 8), and while the REA mirrored the biotype, in RFLP studies at least 3 isolates had DNA fragments in common. All of the isolates from 2 other patients (GVP-063 and GVP-072) represented a single biotype (biotype 2), but under REA and in RFLP studies, the isolates GVP-063 differed from GVP-072. An opposite case existed with the isolates GVP-072 (biotype 2) and GVP-065 (biotype 5), which appeared similar under REA and in RFLP studies. Finally, reisolates after 8 weeks (GVP-080) from a BV patient (isolates GVP-065) representing the same biotype (biotype 5) differed under REA and in RFLP studies. Thus, lacking any unique DNA fingerprint, G. vaginalis occurring in BV represents a (genetically) mixed population.

The characterization of Gardnerella vaginalis DNA using non-radioactive DNA probes

DNA restriction profiles of various Gardnerella vaginalis isolates, generated by BamHI, EcoRI, PstI and other restriction enzymes, varied considerably. Only a few DNA fragments were identified as common in ethidium bromide fluorescence profile and Southern-blot hybridization patterns (employing a digoxigenin-labelled G. vaginalis DNA probe and an enzyme-linked immunoassay detection method). While the efficiencies of Southern-blot hybridization appeared inconsistent, in dot-blot assays, DNA from each isolate hybridized readily, enabling the detection of at least 10 ng DNA. A 5.7-kb DNA fragment from G. vaginalis ATCC 14018 genomic library, cloned in the BamHI site of pBR322, could replace the total genomic DNA probe. This specific DNA fragment was present in different sizes in 12 analysed G. vaginalis strains, describing a restriction fragment length polymorphism. In control studies, none of the DNA from bacteria other than G. vaginalis (including some genitourinary tract residents) hybridized with the G. vaginalis total or specific DNA probes. Non-radioactive G. vaginalis DNA probes can thus form the basis of a useful detection method for further studies of this organism.

Isolation and restriction endonuclease analysis of Gardnerella vaginalis chromosomal DNA

We describe the isolation conditions and the restriction endonuclease analysis of chromosomal DNA from two strains of Gardnerella vaginalis, ATCC 14018 and ATCC 14019. When bacterial lysis was performed in an agarose gel, subsequent electrophoresis indicated that the G. vaginalis genomic DNA was comparable in size to that of Escherichia coli genomic DNA. G. vaginalis grown in Casman broth and subjected to a ‘lysozyme—proteinase K digestion method’ yielded a DNA preparation that was suitable for DNA restriction endonuclease analysis. The DNA-banding patterns of two different G. vaginalis isolates, ATCC 14018 and ATCC 14019, were identical for all restriction enzymes tested. The restriction endonuclease analyses can be useful in a comparative analysis of G. vaginalis, a controversial organism in bacterial vaginosis.

Characterization of the 16S rRNA gene V2 region and the rrn operonsof Gardnerella vaginalis

Ribosomal RNA (rRNA) gene polymorphism was apparent when Gardnerella vaginalis DNA restriction profiles were hybridized with nonradioactively labeled total rRNA isolated from this bacterium. In contrast, use of a polymerase chain reaction (PCR)-based 16S rRNA gene V2 region resulted in a 118-bp V2-PCR amplicon that was specific and common in all 30 tested G. vaginalis isolates. In addition to providing a G. vaginalis-specific fingerprint, when the V2-PCR amplicon along with total rRNA were utilized as probes, a partial rRNA gene restriction map could be constructed. G. vaginalis contains two rrn operons with an EcoRI fragment of 1.6 kb common to both.

Differential Expression of Cloned Yeast Dihydrofolate Reductase Gene in Escherichia coli

The enzyme dihydrofolate reductase has been isolated from numerous sources (Escherichia coli. Laciobacillus casei. and other procaryotes; sheep, rat, bovine, and other higher eucaryotes). In all cases, it has been found to be a single polypeptide of about 20,000 molecular weight with a highly conserved catalytic site.’ However, very little information exists on this enzyme from the lower eucaryote, Saccharomyces cerevisiae. We have cloned the S. cerevisiae dihydrofolate reductase gene in E. coli.* For this we had to establish a selective procedure using a folate analogue, trimethoprim, that discriminated the yeast enzyme from the enzyme in E. coli. As summarized in TABLE