Identification of an isoschizomer of the HhaI DNA methyltransferase in Mycoplasma arthritidis

The genome of Mycoplasma arthritidis strain 158 has modified cytosine residues at AGCT sequences that render the DNA resistant to digestion with the AluI restriction endonuclease. The DNA methyltransferase responsible for the base modification has previously been designated MarI. From the complete genome sequence of M. arthritidis , we identify Marth_orf138 as a candidate marI gene. Marth_orf138 was cloned in Escherichia coli and its TGA codons converted to TGG. DNA isolated from E. coli cells expressing the modified Marth_orf138 gene was degraded by the AluI nuclease, indicating that Marth_orf138 does not code for MarI. However, the DNA from E. coli was found to have acquired resistance to the restriction endonuclease HhaI. Genomic DNA from M. arthritidis was also found to be resistant to HhaI (recognizes GCGC). The M. arthritidis isoschizomer of the HhaI DNA methyltransferase, coded by Marth_orf138, is designated MarII. Transformation of M. arthritidis was not significantly affected by modification of plasmid at HhaI sites, indicating that the mycoplasma lacks a restriction endonuclease that recognizes GCGC sites.     

Cloning, characterization, and expression of a gene region from Pseudomonas sp. strain ADP involved in the dechlorination of atrazine.

We previously identified a Pseudomonas sp. strain, ADP, which rapidly metabolized atrazine in liquid culture, agar plates, and soils (R. T. Mandelbaum, D. L. Allan, L. P. Wackett, Appl. Environ. Microbiol. 61:1451-1457, 1995). In this study, we report the cloning and partial characterization of a gene region from Pseudomonas sp. strain ADP that encodes atrazine degradation activity. A 22-kb EcoRI genomic DNA fragment, designated pMD1, was shown to encode atrazine dechlorination activity in Escherichia coli DH5 alpha. Atrazine degradation was demonstrated by a zone-clearing assay on agar medium containing crystalline atrazine and by chromatographic methods. A gene conferring the atrazine-clearing phenotype was subsequently subcloned as a 1.9-kb AvaI fragment in pACYC184, designated pMD4, and was expressed in E. coli. This result and random Tn5 mutagenesis established that the 1.9-kb AvaI fragment was essential for atrazine dechlorination. High-pressure liquid and thin-layer chromatographic analyses were used to rigorously establish that E. coli containing pMD4 degraded atrazine and accumulated hydroxyatrazine. Hydroxyatrazine was detected only transiently in E. coli containing pMD1. This is consistent with the idea that hydroxyatrazine is the first metabolite in atrazine degradation by Pseudomonas sp. strain ADP. A 0.6-kb ApaI-PstI fragment from pMD4, containing the putative atrazine chlorohydrolase gene, hybridized to DNA from atrazine-degrading bacteria isolated in Switzerland and Louisiana.(ABSTRACT TRUNCATED AT 250 WORDS)     

Molecular cloning, DNA structure and expression of the Escherichia coli D-xylose isomerase.

The D-xylose isomerase (EC 5.3.1.5) gene from Escherichia coli was cloned and isolated by complementation of an isomerase-deficient E. coli strain. The insert containing the gene was restriction mapped and further subcloning located the gene in a 1.6-kb Bg/II fragment. This fragment was sequenced by the chain termination method, and showed the gene to be 1002 bp in size. The Bg/II fragment was cloned into a yeast expression vector utilising the CYCl yeast promoter. This construct allowed expression in E. coli grown on xylose but not glucose suggesting that the yeast promoter is responding to the E. coli catabolite repression system. No expression was detected in yeast from this construct and this is discussed in terms of the upstream region in the E. coli insert with suggestions of how improved constructs may permit achievement of the goal of a xylose-fermenting yeast.     

Characterization and expression of the Escherichia coli Mrr restriction system.

The mrr gene of Escherichia coli K-12 is involved in the acceptance of foreign DNA which is modified. The introduction of plasmids carrying the HincII, HpaI, and TaqI R and M genes is severely restricted in E. coli strains that are Mrr+. A 2-kb EcoRI fragment from the plasmid pBg3 (B. Sain and N. E. Murray, Mol. Gen. Genet. 180:35-46, 1980) was cloned. The resulting plasmid restores Mrr function to mrr strains of E. coli. The boundaries of the mrr gene were determined from an analysis of subclones, and plasmids with a functional mrr gene produce a polypeptide of 33.5 kDa. The nucleotide sequence of the entire fragment was determined; in addition to mrr, it includes two open reading frames, one of which encodes part of the hsdR. By using Southern blot analysis, E. coli RR1 and HB101 were found to lack the region containing mrr. The acceptance of various cloned methylases in E. coli containing the cloned mrr gene was tested. Plasmid constructs containing the AccI, CviRI, HincII, Hinfl (HhaII), HpaI, NlaIII, PstI, and TaqI N6-adenine methylases and SssI and HhaI C5-cytosine methylases were found to be restricted. Plasmid constructs containing 16 other adenine methylases and 12 cytosine methylases were not restricted. No simple consensus sequence causing restriction has been determined. The Mrr protein has been overproduced, an antibody has been prepared, and the expression of mrr under various conditions has been examined. The use of mrr strains of E. coli is suggested for the cloning of N6-adenine and C5-cytosine methyl-containing DNA.     

Physical and genetic analyses of streptococcal plasmid pAM beta 1 and cloning of its replication region.

Plasmid pAM beta 1, originally isolated from Streptococcus faecalis DS5, mediates resistance to the MLS (macrolide, lincosamide, and streptogramin B alpha) group of antibiotics. A restriction endonuclease map of the 26.5-kilobase (kb) pAM beta 1 molecule was constructed by using the enzymes AvaI, HpaII, EcoRI, PvuII, Kpn1, BstEII, HpaI, HhaI, and HindIII. A comparison of this map to those of four independently isolated deletion derivatives of pAM beta 1 located the MLS resistance determinant within a 2-kb DNA segment and at least one conjugative function within an 8-kb region. The 5.0-kb EcoRI-B fragment from pAM beta 1 was ligated onto the 4.0-kb Escherichia coli plasmid vector, pACKC1, and used to transform E. coli HB101. The 9.0-kb chimeric plasmid was then used to transform Streptococcus sanguis Challis with concurrent expression of the E. coli kanamycin resistance determinant. The 5.0-kb EcoRI-B fragment from pAM beta 1 was subsequently used as a vector to clone a streptomycin resistance determinant from a strain of Streptococcus mutans containing no detectable plasmid DNA. Subcloning experiments, using a HindIII partial digest of pAM beta 1 DNA, narrowed the replication region of this plasmid to a 2.95-kb fragment.     

Cloning and sequence analysis of the Escherichia coli metH gene encoding cobalamin-dependent methionine synthase and isolation of a tryptic fragment containing the cobalamin-binding domain

A gene encoding cobalamin-dependent methionine synthase (EC 2.1.1.13) has been isolated from a plasmid library of Escherichia coli K-12 DNA by complementation to methionine prototrophy in an E. coli strain lacking both cobalamin-dependent and -independent methionine synthase activities (RK4536:metE, metHH). Maxicell expression of a series of plasmids containing deletions in the metH structural gene was employed to map the position and orientation of the gene on the cloned DNA fragment. A 6.3-kilobase EcoRI-SalI fragment containing the gene was cloned into the sequencing vector pGEM3B for double-stranded DNA sequencing; the MetH coding region consists of 3372 nucleotides. The enzyme was purified from an overproducing strain of E. coli harboring the recombinant plasmid, in which the level of methionine synthase was elevated 30- to 40-fold over wild-type E. coli. Recombinant enzyme is a protein of 123,640 molecular weight and has a turnover number of 1,450 min-1 in the standard assay. These values are to be compared with previously reported values of 133,000 for the molecular weight and 1,240-1,560 min-1 for the turnover number of the homogenous enzyme purified from a wild-type strain of E. coli B (Frasca, V., Banerjee, R. V., Dunham, W. R., Sands, R. H., and Matthews, R. G. (1988) Biochemistry 27, 8458-8465). Limited proteolysis of the native enzyme with trypsin resulted in loss of enzyme activity but retention of bound cobalamin on a peptide fragment of 28,000 molecular weight. This fragment has been shown to extend from residue 643 to residue 900 of the 1124-residue deduced amino acid sequence.     

Restriction isotyping of human apolipoprotein E by gene amplification and cleavage with HhaI

We have used restriction isotyping (restriction enzyme isoform genotyping) for rapid typing of common apolipoprotein E isoforms (E2, E3, E4). ApoE restriction isotyping used oligonucleotides to amplify apolipoprotein E gene sequences containing amino acid positions 112 and 158. The amplification products were digested with HhaI and subjected to electrophoresis on polyacrylamide gels. Each of the isoforms was distinguished by a unique combination of HhaI fragment sizes that enabled unambiguous typing of all homozygotic and heterozygotic combinations. HhaI cleaves at GCGC encoding 112arg (E4) and 158arg (E3, E4), but does not cut at GTGC encoding 112cys (E2, E3) and 158cys (E2).     

Cloning and physical mapping of the ADE1 gene of the yeast Saccharomyces cerevisiae

ADE1 gene of Saccharomyces cerevisiae codes for the primary structure of SAICAR-synthetase. Mutational changes of ADE1 gene result in the accumulation of red pigment in cells. Colour differences, thus, serve as a basis for the selection of mutants or transformants. ADE1 gene was cloned as a 4.0 kb HindIII fragment of yeast DNA in a shuttle vector by complementing the ade1 mutation in yeast. The study of ADE1 gene expression in Escherichia coli showed that the 4.0 kb fragment containing the ADE1 gene does not complement purC mutations in E. coli. However, prototrophic colonies appeared at a frequency of 10(-7)-10(-8) after incubating clones bearing the recombinant plasmid with ADE1 gene on selective media. The plasmid DNA isolated from such clones complements the purC mutation in E. coli and the ade1 mutation in S. cerevisiae. Structural analysis of the plasmid demonstrated that the cloned DNA fragment contained an additional insertion of the bacterial origin. Further restriction enzyme analysis proved the insertion to be the bacterial element IS1. Expression of the cloned ADE1 gene in S. cerevisiae is controlled by its own promoter, whereas in E. coli it is controlled by the IS1 bacterial element.     

Cloning, sequencing, and species relatedness of the Escherichia coli cca gene encoding the enzyme tRNA nucleotidyltransferase

The Escherichia coli cca gene which encodes the enzyme tRNA nucleotidyltransferase has been cloned by taking advantage of its proximity to the previously cloned dnaG locus. A series of recombinant bacteriophages, spanning the chromosomal region between the dnaG and cca genes at 66 min on the E. coli linkage map, were isolated from a lambda Charon 28 partial Sau3A E. coli DNA library using recombinant plasmids containing regions between dnaG and cca as probes. Two of the recombinant phage isolates, lambda c1 and lambda c4, contained the cca gene. A BamHI fragment from lambda c1 was subcloned into pBR328, and cells containing this recombinant plasmid, pRH9, expressed tRNA nucleotidyltransferase activity at about 10-fold higher level than the wild type control. The cca gene was further localized to a 1.4-kilobase stretch of DNA by Bal31 deletion analysis. The nucleotide sequence of the cca gene was determined by the dideoxy method, and revealed an open reading frame extending for a total of 412 codons from an initiator GTG codon that would encode a protein of about 47,000 daltons. Southern analysis using genomic blots demonstrated that the cca gene is present as a single copy on the E. coli chromosome and that there is no homology on the DNA level between the E. coli cca gene, and the corresponding gene in the Bacillus subtilis, Saccharomyces cerevisiae, Petunia hybrida, or Homo sapiens genomes. Homology was found only with DNA from the closely related species, Salmonella typhimurium. These studies have also allowed exact placement of the cca gene on the E. coli genetic map, and have shown that it is transcribed in a clockwise direction.     

Cloning, sequencing, and expression of the gene encoding a large S-layer-associated endoxylanase from Thermoanaerobacterium sp. strain JW/SL-YS 485 in Escherichia coli.

The gene (xynA) encoding a surface-exposed, S-layer-associated endoxylanase from Thermoanaerobacterium sp. strain JW/SL-YS 485 was cloned and expressed in Escherichia coli. A 3.8-kb fragment was amplified from chromosomal DNA by using primers directed against conserved sequences of endoxylanases isolated from other thermophilic bacteria. This PCR product was used as a probe in Southern hybridizations to identify a 4.6-kb EcoRI fragment containing the complete xynA gene. This fragment was cloned into E. coli, and recombinant clones expressed significant levels of xylanase activity. The purified recombinant protein had an estimated molecular mass (150 kDa), temperature maximum (80 degrees C), pH optimum (pH 6.3), and isoelectric point (pH 4.5) that were similar to those of the endoxylanase isolated from strain JW/SL-YS 485. The entire insert was sequenced and analysis revealed a 4,044-bp open reading frame encoding a protein containing 1,348 amino acid residues (estimated molecular mass of 148 kDa).xynA was preceded by a putative promoter at -35 (TTAAT) and -10 (TATATT) and a potential ribosome binding site (AGGGAG) and was expressed constitutively in E. coli. The deduced amino acid sequence showed 30 to 96% similarity to sequences of family F beta-glycanases. A putative 32-amino-acid signal peptide was identified, and the C-terminal end of the protein contained three repeating sequences 59, 64, and 57 amino acids) that showed 46 to 68% similarity to repeating sequences at the N-terminal end of S-layer and S-layer-associated proteins from other gram-positive bacteria. These repeats could permit an interaction of the enzyme with the S-layer and tether it to the cell surface.     

Cloning and expression of the Escherichia coli D-xylose isomerase gene in Bacillus subtilis

A DNA fragment containing the Escherichia coli D-xylose isomerase gene and D-xylulokinase gene had been isolated from an E. coli genomic bank constructed by Clarke and Carbon. The D-xylose isomerase gene coding for the synthesis of an important industrial enzyme, xylose isomerase, was subcloned into a Bacillus-E. coli bifunctional plasmid. It was found that the intact E. coli gene was not expressed in B. subtilis, a host traditionally used to produce industrial enzymes. An attempt was then made to express the E. coli gene in B. subtilis by fusion of the E. coli xylose isomerase structural gene downstream to the promoter of the penicillinase gene isolated from Bacillus licheniformis. Two such fused genes were constructed and they were found able to be expressed in both B. subtilis and E. coli.     

Cloning the gyrA gene of Bacillus subtilis.

We have isolated an eight kilobase fragment of Bacillus subtilis DNA by specific integration and excision of a plasmid containing a sequence adjacent to ribosomal operon rrn O. The genetic locus of the cloned fragment was verified by linkage of the integrated vector to nearby genetic markers using both transduction and transformation. Functional gyrA activity encoded by this fragment complements E. coli gyrA mutants. Recombination between the Bacillus sequences and the E. coli chromosome did not occur. The Bacillus wild type gyrA gene, which confers sensitivity to nalidixic acid, is dominant in E. coli as is the E. coli gene. The cloned DNA precisely defines the physical location of the gyrA mutation on the B. subtilis chromosome. Since an analogous fragment from a nalidixic acid resistant strain has also been isolated, and shown to transform B. subtilis to nalidixic acid resistance, both alleles have been cloned.     

Cloning in Escherichia coli of the mutant gene coding the diphtheria toxin

Bacteriophage beta 45 of Corynebacterium diphtheriae was harvested. The extracted DNA of the bacteriophage was digested by the restriction endonuclease BamHI and inserted into the BamHI cleavage site of pUC19 vector plasmid. Plasmid pNVY5 containing a mutant gene crm45 of diphtheriae toxin in a 3.9 bpn fragment was isolated from the hybrid plasmids obtained. Cell free extracts of E. coli strain TG1 (pVNY5) contain the nontoxic protein crm45 possessing the specific enzymatic activity of diphtheriae toxin (ADP ribosylation on wheat elongation factor two). According to orientation of BamHI fragment in pNVY5 plasmid it is concluded that the crm45 gene is expressed using its own promoter.     

Diverse backmutations at an ochre defect in the tyrA gene sequence of E. coli B/r

A DNA fragment including most of the tyrA gene from E. coli B/r strain WU (Tyr-, Leu-) was amplified in vitro by polymerase chain reaction. The sequence was determined, first, for essentially all of the fragment to locate an ochre nonsense defect, and second, repeatedly for a region of the fragment from several independent isolates containing backmutations at the ochre codon (spontaneous and UV-induced). There were 20 single base differences in the tyrA gene region from the analogous wild-type E. coli K12 sequence: an ochre codon at amino acid position 161, 18 silent changes (1 at the first codon base and 17 at the third) and one replacement of valine by alanine. Different backmutations at the ochre codon encoded lysine, glutamine, glutamic acid, leucine, cysteine, phenylalanine, serine or tyrosine. The diversities of base substitutions at the ochre codon after UV mutagenesis or after mutagenesis where targeting by dimers was reduced or eliminated (after photoreversal of irradiated cells treated with nalidixic acid to induce SOS functions or after UV mutagenesis of cells containing amplified DNA photolyase) were similar (with two notable exceptions). The overall differences between the gene sequences for E. coli K12 or B/r seemed consistent with the neutral theory of molecular evolution.     

Cloning of genes responsible for acetic acid resistance in Acetobacter aceti.

Five acetic acid-sensitive mutants of Acetobacter aceti subsp. aceti no. 1023 were isolated by mutagenesis with N-methyl-N'-nitro-N-nitrosoguanidine. Three recombinant plasmids that complemented the mutations were isolated from a gene bank of the chromosome DNA of the parental strain constructed in Escherichia coli by using cosmid vector pMVC1. One of these plasmids (pAR1611), carrying about a 30-kilobase-pair (kb) fragment that conferred acetic acid resistance to all five mutants, was further analyzed. Subcloning experiments indicated that a 8.3-kb fragment was sufficient to complement all five mutations. To identify the mutation loci and genes involved in acetic acid resistance, insertional inactivation was performed by insertion of the kanamycin resistance gene derived from E. coli plasmid pACYC177 into the cloned 8.3-kb fragment and successive integration into the chromosome of the parental strain. The results suggested that three genes, designated aarA, aarB, and aarC, were responsible for expression of acetic acid resistance. Gene products of these genes were detected by means of overproduction in E. coli by use of the lac promoter. The amino acid sequence of the aarA gene product deduced from the nucleotide sequence was significantly similar to those of the citrate synthases (CSs) of E. coli and other bacteria. The A. aceti mutants defective in the aarA gene were found to lack CS activity, which was restored by introduction of a plasmid containing the aarA gene. A mutation in the CS gene of E. coli was also complemented by the aarA gene. These results indicate that aarA is the CS gene.     

Cloning, nucleotide sequence, and expression of the flavodoxin gene from Desulfovibrio vulgaris (Hildenborough)

The gene coding for the flavodoxin protein from Desulfovibrio vulgaris (Hildenborough) has been identified, cloned, and sequenced. DNA fragments containing the flavodoxin gene were identified by hybridization of a mixed synthetic heptadecanucleotide probe to Southern blots of SalI-digested genomic DNA. The nucleotide sequences of the probe were derived from the published protein primary structure (Dubourdieu, M., LeGall, J., and Fox, J. L. (1973) Biochem. Biophys. Res. Commun. 52, 1418-1425). The same oligonucleotide probe was used to screen libraries (in pUC19) containing size-selected SalI fragments. One recombinant, carrying a 1.6-kilobase (kb) insert which strongly hybridizes to the probe, was found to contain a nucleotide sequence which codes for the first 104 residues of the amino-terminal portion of the flavodoxin protein sequence but lacked the remainder of the gene. Therefore, a PstI restriction fragment from this clone was used as a probe to isolate the entire gene from a partial Sau3AI library in Charon 35. Of the plaques which continued to hybridize strongly to this probe through repeated screenings, one recombinant, containing a 16-kb insert, was further characterized. The entire flavodoxin gene was localized within a 1.4-kb XhoI-SacI fragment of this clone. The complete nucleotide sequence of the structural gene for the flavodoxin protein from Desulfovibrio vulgaris and flanking sequences which may include promoter and regulatory sequences are reported here. The cloned flavodoxin gene was placed behind the hybrid tac promoter for overexpression of the protein in Escherichia coli. Modification to the 5'-end of the gene, including substitutions at the second codon, were required to obtain high levels of expression. The expressed recombinant flavodoxin protein is isolated from E. coli cells as the holoprotein with physical and spectral properties similar to the protein isolated from D. vulgaris. To our knowledge, this is the first example of the expression of a foreign flavodoxin gene in E. coli using recombinant DNA methods.     

Expression and nucleotide sequence of the Clostridium acetobutylicum beta-galactosidase gene cloned in Escherichia coli.

A gene library for Clostridium acetobutylicum NCIB 2951 was constructed in the broad-host-range cosmid pLAFR1, and cosmids containing the beta-galactosidase gene were isolated by direct selection for enzyme activity on X-Gal (5-bromo-4-chloro-3-indolyl-beta-D-galactoside) plates after conjugal transfer of the library to a lac deletion derivative of Escherichia coli. Analysis of various pSUP202 subclones of the lac cosmids on X-Gal plates localized the beta-galactosidase gene to a 5.1-kb EcoRI fragment. Expression of the Clostridium beta-galactosidase gene in E. coli was not subject to glucose repression. By using transposon Tn5 mutagenesis, two gene loci, cbgA (locus I) and cbgR (locus II), were identified as necessary for beta-galactosidase expression in E. coli. DNA sequence analysis of the entire 5.1-kb fragment identified open reading frames of 2,691 and 303 bp, corresponding to locus I and locus II, respectively, and in addition a third truncated open reading frame of 825 bp. The predicted gene product of locus I, CbgA (molecular size, 105 kDa), showed extensive amino acid sequence homology with E. coli LacZ, E. coli EbgA, and Klebsiella pneumoniae LacZ and was in agreement with the size of a polypeptide synthesized in maxicells containing the cloned 5.1-kb fragment. The predicted gene product of locus II, CbgR (molecular size, 11 kDa) shares no significant homology with any other sequence in the current DNA and protein sequence data bases, but Tn5 insertions in this gene prevent the synthesis of CbgA. Complementation experiments indicate that the gene product of cbgR is required in cis with cbgA for expression of beta-galactosidase in E. coli.     

Bacillus subtilis citM, the structural gene for dihydrolipoamide transsuccinylase: cloning and expression in Escherichia coli

The 2-oxoglutarate dehydrogenase multienzyme complex is composed of three different subenzymes: 2-oxoglutarate dehydrogenase (E1o), dihydrolipoamide transsuccinylase (E2o), and dihydrolipoamide dehydrogenase (E3). Bacillus subtilis E1o and E2o are encoded by the citK and citM genes, respectively. A 3.4-kb BamHI DNA fragment containing citK and citM markers was isolated from a library of B. subtilis DNA in Escherichia coli. Functional E2o was expressed from the cloned DNA both in B. subtilis and E. coli. E2o had an apparent Mr of 60,000 when expressed in E. coli. The B. subtilis E2o component complemented an E. coli E2o-defective mutant in vivo and in vitro. It is concluded that functional B. subtilis E2o can be produced in E. coli and can interact with E. coli and E1o and E3 to form an active chimeric enzyme complex.     

Cloning and expression of Clostridium pasteurianum galactokinase gene in Escherichia coli K-12 and nucleotide sequence analysis of a region affecting the amount of the enzyme

The Clostridium pasteurianum galactokinase gene was cloned by complementation, of the galK locus, into Escherichia coli. Restriction enzyme analysis subcloning and Tn5 mutagenesis indicated that the gene was located on a 1.8 X 10(3) base-pair ClaI-Sau3A fragment that encoded a polypeptide of approximately 40 Mr. Although the C. pasteurianum and the E. coli galactokinases have similar subunit molecular weights, Southern hybridization analysis indicated no strong homology between their genes. Even though this clone showed a low level of galactokinase expression, the Gal+ phenotype, provided by the clostridial galactokinase, was unstable in E. coli, and the gene was frequently inactivated by the spontaneous acquisition of insertion sequences. A second clone containing this gene on a large restriction fragment was isolated by hybridization. This clone was unable to grow on galactose-containing media due to the overproduction of galactokinase. Comparison of the plasmids from these two clones revealed that the second contained an additional 300 base-pairs located at one end of the galactokinase gene. Appropriate operon fusions with a promoter-less E. coli galactokinase gene indicated that these additional 300 base-pairs had promoter activity in E. coli. The DNA sequence of this region which lies upstream of the C. pasteurianum galactokinase gene was determined and compared with that from several clones producing high, low or undetectable amounts of galactokinase. The reasons for the high and low level expression and for the instability of the C. pasteurianum galactokinase in E. coli are discussed. The presence of the galactokinase suggests that galactose is used in C. pasteurianum through the Leloir pathway via galactose 1-phosphate.     

Rapid method for separation of bacterial DNA from humic substances in sediments for polymerase chain reaction.

The polymerase chain reaction (PCR) was used to amplify an Escherichia coli 16S ribosomal gene fragment from sediments with high contents of humic substances. Total DNA was extracted from 1 g of E. coli seeded or unseeded samples by a rapid freeze-and-thaw method. Several approaches (use of Bio-Gel P-6 and P-30 and Sephadex G-50 and G-200 columns, as well as use of the Stoffel fragment) were used to reduce interference with the PCR. The best results were obtained when crude DNA extracts containing humic substances were purified by using Sephadex G-200 spun columns saturated with Tris-EDTA buffer (pH 8.0). Eluted fractions were collected for PCR analyses. The amplified DNA fragment was obtained from seeded sediments containing fewer than 70 E. coli cells per g. Because only 1/100 of the eluted fractions containing DNA extracts from 70 cells per g was used for the PCR, the sensitivity of detection was determined to be less than 1 E. coli cell. Thus, DNA direct extraction coupled with this technique to remove interference by humic substances and followed by the PCR can be a powerful tool to detect low numbers of bacterial cells in environmental samples containing humic substances.