Cellular replication of human immunodeficiency virus type 1 occurs in vaginal secretions.

Most human immunodeficiency virus type 1 (HIV-1) transmission worldwide is the result of exposure to infectious virus in genital secretions. However, current vaccine candidates are based on virus isolates from blood. In this study, vaginal secretions from HIV-1-infected women were examined for evidence of cellular viral replication that produced virus with properties different from that in blood. Multiply spliced HIV-1 messenger RNA, which is found only in cells replicating virus, was detected in all vaginal lavage samples tested. There was a strong correlation between the amounts of multiply spliced HIV-1 messenger RNA and of cell-free HIV-1 RNA in the lavage samples. In addition, significant genotypic differences were found in cell-free virus from matched blood plasma and vaginal secretions. Moreover, drug resistance-associated mutations appeared in plasma virus several months before appearing in vaginal virus. These findings indicate that cellular replication of HIV-1 occurs in vaginal secretions and can result in a virus population with important differences from that in blood.

A rapid non-culture-based assay for clinical monitoring of phenotypic resistance of human immunodeficiency virus type 1 to lamivudine (3TC).

Monitoring for lamivudine (3TC) resistance is important both for the clinical management of human immunodeficiency virus type 1 (HIV-1)-infected patients treated with 3TC and for surveillance of transmission of 3TC-resistant HIV-1. We developed a novel non-culture-based assay for the rapid analysis of phenotypic resistance to 3TC of HIV-1 in plasma. The assay measures the susceptibility of HIV-1 reverse transcriptase (RT) activity to 3TC triphosphate (3TC-TP) in plasma. RT detection was done by the Amp-RT assay, an ultrasensitive PCR-based RT assay. Under our assay conditions, we found that 5 microM 3TC-TP inhibited RT activity from wild-type (WT), zidovudine-resistant, or nevirapine-resistant HIV-1 but not from HIV-1 carrying either the M184V mutation or multidrug (MD) resistance mutations (77L/116Y/151M or 62V/75I/77L/116Y/151M). Mixing experiments showed a detection threshold of 10% 3TC-resistant virus (M184V) in a background of WT HIV-1. To validate the assay for the detection of phenotypic resistance of HIV-1 to 3TC in plasma samples, HIV-1 RT in 30 plasma specimens collected from 15 patients before and during therapy with 3TC was tested for evidence of phenotypic resistance by the Amp-RT assay. The results were compared with those of genotypic analysis. The RT in 12 samples was found to be 3TC sensitive, while the RT in 18 samples had evidence of phenotypic resistance. All 12 samples with 3TC-sensitive RT had WT genotypes at codon 184 and were retrieved before treatment with 3TC. In contrast, all 18 specimens with 3TC-resistant RT were posttherapy samples. This assay provides a simple, rapid, and reliable method for the detection of phenotypic resistance of HIV-1 to 3TC in plasma.

sigma E changed to sigma B specificity by amino acid substitutions in its -10 binding region.

The association of a sigma factor (sigma) with RNA polymerase in bacteria determines its specificity of promoter utilization. To identify amino acid residues in sigma E from Bacillus subtilis that determine the specificity of its interaction with the nucleotides at the -10 region of its cognate promoters, we tested whether base pair substitutions in the -10 region of a sigma B-dependent promoter could signal its utilization by sigma E-RNA polymerase. We found that a combination of base pair substitutions at positions -15 and -14 of the sigma B-dependent ctc promoter resulted in its utilization by sigma E-RNA polymerase in vivo. We also found that the combination of two amino acid substitutions at positions 119 and 120 in sigma E changed its specificity for promoter utilization, resulting in a sigma factor that directed transcription from the sigma B-dependent ctc promoter, but not from sigma E-dependent promoters. These results suggest that amino acid residues at positions 119 and 120 determine, at least in part, the specificity of interactions between sigma E and the nucleotides in the -10 region of its cognate promoters.

Sequence-specific interactions between promoter DNA and the RNA polymerase sigma factor E.

In order to determine which amino acyl residues in a secondary sigma factor govern its specificity of recognition at the -35 region of promoters, we examined the effects of amino acid substitutions in sigma E in Bacillus subtilis that made the sequence of its putative -35 recognition region more similar to another sigma factor in B. subtilis, sigma K. We found that a single amino acid substitution at position 217 of sigma E resulted in a sigma factor that could direct transcription from sigma K-dependent promoters. Furthermore, we tested whether this amino acid substitution in sigma E had changed the specificity of interactions of the sigma with -35 region sequences by examining the activity of the mutant sigma E on derivatives of sigma E-dependent promoters that contained single base-pair substitutions. We found that this substitution in sigma E specifically suppressed the effect of a single base-pair substitution at position -31 in a sigma E-dependent promoter spoIIID. The amino acyl residue at another position (219) on sigma E affected the specificity of interaction with position -33 in spoIIID promoter. The amino acyl residues at the two positions in sigma E, 217 and 219, that determine the specificity of interactions between the sigma and base-pairs in the -35 region of its cognate promoters (positions -33 and -31, respectively, in the spoIIID promoter) probably closely contact these base-pairs.

A single amino acid substitution in sigma E affects its ability to bind core RNA polymerase.

We have examined the role of the most highly conserved region of bacterial RNA polymerase sigma factors by analyzing the effect of amino acid substitutions and small deletions in sigma E from Bacillus subtilis. sigma E is required for the production of endospores in B. subtilis but not for vegetative growth. Strains expressing each of several mutant forms of sigE were found to be deficient in their ability to form endospores. Single amino acid substitutions at positions 68 and 94 resulted in sigma factors that bind with less affinity to the core subunits of RNA polymerase. The substitution at position 68 did not affect the stability of the protein in B. subtilis; therefore, this substitution probably did not have large effects on the overall structure of the sigma factor. The substitution at position 68 probably defines a position in sigma E that closely contacts a subunit of RNA polymerase, while the substitution at position 94 may define a position that is important for protein stability or for binding to core RNA polymerase.

Effects of amino acid substitutions in the -10 binding region of sigma E from Bacillus subtilis.

The sigma subunit of bacterial RNA polymerase is required for specific binding to promoters. One region in most sigma factors makes sequence-specific contacts at the -10 region of its cognate promoters. To test the role of the amino acids in this -10 binding region, we examined the effects of 49 single-amino-acid substitutions in sigma E from Bacillus subtilis. We assayed the effect of each amino acid substitution on spore formation because sigma E is essential for endospore formation in B. subtilis. Our results showed that substitutions at several positions, including the highly conserved aromatic amino acid at position 102, had little or no detectable effect. Substitutions at another position, position 117, produced dominant negative mutations; we suggest that these mutations allow RNA polymerase containing the mutant sigma factor to bind specifically to promoters but prevent transcription initiation. Of the recessive defective alleles, those that produced substitutions at positions 113, 115, and 120 produced the most defective sigma factors. These results suggest that the residues at or near these positions in wild-type sigma E play important roles in sigma E function.

Genetic suppression analysis of sigma E interaction with three promoters in sporulating Bacillus subtilis.

Genetic evidence suggests that the sigma (sigma) subunit of RNA polymerase determines the specificity of promoter utilization, by making sequence-specific contacts with DNA. We examined the effects of two single amino acid(aa) substitutions in sigma E on the utilization of mutated derivatives of three different promoters in sporulating Bacillus subtilis. We found allele-specific suppression of mutations in all three promoters by each aa substitution in sigma E. These results provide strong evidence that sigma E interacts with each of these promoters in vivo. Moreover, the specificity of suppression of the mutations by the aa substitutions in sigma E lead us to speculate that the Met124 of sigma E closely contacts two adjacent bp in the -10 region of the promoters.

Genetic evidence for interaction of sigma E with the spoIIID promoter in Bacillus subtilis.

During sporulation in Bacillus subtilis, new RNA polymerase sigma factors are produced. These sigma factors direct the transcription of genes that are required for this cellular differentiation. In order to determine the role of each sigma factor in this process, it is necessary to know which promoters are recognized by each sigma factor. The spoIIID gene product plays an important role in the establishment of mother cell-specific gene expression during sporulation. We found that substitution of an alanine at position 124 of the sporulation-specific sigma factor sigma E suppressed the effect of a single-base-pair transition at position -13 of the spoIIID promoter. This alanine substitution in sigma E did not suppress the effect of a transversion at position -12 of the spoIIID promoter. The allele specificity of the interaction between sigma E and the spoIIID promoter is strong evidence that sigma E directs transcription from the spoIIID promoter during sporulation. Position 124 in sigma E is located within a region that is highly conserved among the regions in other sigma factors that probably interact with the -10 regions of their cognate promoters.

Transcription of the Bacillus subtilis spoIIA locus.

The spoIIA operon encodes three genes, including the structural gene for a sporulation-induced sigma factor sigma F. We used deletion analysis of spoIIA-lacZ fusions to define the location of the spoIIA promoter. We found that sigma H-RNA polymerase transcribes spoIIA accurately in vitro and propose that sigma H directs transcription of spoIIA during sporulation.

Cloning of a promoter used by sigma H RNA polymerase in Bacillus subtilis.

The secondary RNA polymerase sigma factor sigma H is essential for endospore development in Bacillus subtilis. However, only a few promoters that are used by RNA polymerase containing sigma H (E sigma H) have been identified. We used in vitro transcription of random cloned fragments of B. subtilis chromosomal DNA to identify a promoter that is used by E sigma H. This promoter is active before the onset of sporulation.

Sigma H-directed transcription of citG in Bacillus subtilis.

The RNA polymerase sigma factor sigma H is essential for the onset of endospore formation in Bacillus subtilis. sigma H also is required for several additional stationary-phase-specific responses, including the normal expression of several genes that are required for the development of competence for DNA uptake. It is necessary to identify the genes that are transcribed by sigma H RNA polymerase (E sigma H) in order to understand the role of this sigma factor during the transition from exponential growth to stationary phase. Feavers et al. (Mol. Gen. Genet. 211:465-471, 1988) proposed that citG, the structural gene for fumarase, is transcribed from two promoters, one of which (citGp2 [P2]) may be used by E sigma H. It is likely that the citGp2 promoter is used by E sigma H because we found that this promoter was used accurately in vitro by E sigma H and directed expression of xylE in vivo. This xylE expression was dependent on spo0H, the structural gene for sigma H, and was independent of the citGp1 promoter. Comparison of the nucleotide sequences of several sigma H-dependent promoters showed that these sequences were similar at two regions approximately 10 and 35 base pairs upstream from the start points of transcription. These sequences may signal recognition of these promoters by E sigma H. Primer extension analyses were used to examine transcription from three sigma H-dependent promoters during growth and sporulation. The citGp2 promoter appeared to be active during the middle and late stages of exponential growth, whereas activation of the spoIIA promoter was delayed until after the end of exponential growth. Evidently, promoters used by E sigma H can display different temporal patterns of expression.

Genetic analysis of RNA polymerase-promoter interaction during sporulation in bacillus subtilis.

The discovery of secondary sigma factors in Bacillus subtilis that enable RNA polymerase to transcribe cloned sporulation genes in vitro has led to the proposal that the appearance of new sigma factors during sporulation directs RNA polymerase to the different temporal classes of sporulation genes. One sigma factor, which appears 2 h after the initiation of sporulation, is sigma E (formerly sigma 29). Mutations that inactivate the structural gene for sigma E prevent transcription from promoter G4. To determine whether sigma E-RNA polymerase interacts with the G4 promoter in vivo, we examined the effects of six single-base-pair substitutions in the G4 promoter on its utilization in vivo and in vitro by sigma E-RNA polymerase. The mutations in the G4 promoter affected utilization of the promoter in vivo in the same way that they affected its utilization in vitro by purified sigma E-RNA polymerase; therefore, we conclude that this polymerase interacts directly with the G4 promoter in vivo. The effects of these mutations also support the model in which sigma E-RNA polymerase utilizes promoters by interacting with two distinct sets of nucleotides located 10 and 35 base pairs upstream from the start point of transcription.

Promoter used by sigma-29 RNA polymerase from Bacillus subtilis.

Gene expression during endospore formation by Bacillus subtilis is controlled in part by a sporulation-induced form of RNA polymerase, E sigma 29. The determination of the nucleotide sequences that govern utilization of promoters by E sigma 29 has been limited by the small number of available promoters that are recognized by E sigma 29. In the present report we describe a promoter that is adjacent to the rrnB region of the B. subtilis chromosome and is utilized in vitro and in vivo by E sigma 29. S1 nuclease mapping and dinucleotide priming experiments have been used to determine the start point of transcription. The nucleotide sequences near the -10 and -35 region of this promoter, bvx, are conserved, and resemble sequences at these regions for other promoters that are utilized by E sigma 29.

Utilization of one promoter by two forms of RNA polymerase from Bacillus subtilis.

Bacillus subtilis possesses several forms of RNA polymerase, each differing in its sigma subunit and its specificity of promoter recognition. The sequential appearance of sigma subunits, which change the promoter recognition specificity of RNA polymerase, may have a key role in controlling the temporal pattern of gene expression required for endospore development in B. subtilis. Several genes that are expressed over relatively long periods of time during the developmental cycle are transcribed by more than one form of RNA polymerase, which initiate transcription from either tandem or overlapping promoter. The promoter region for the ctc gene is interesting because transcription is initiated at or near the same position by both sigma 37 RNA polymerase (E sigma 37), a minor form in growing cells, and sigma 29 RNA polymerase (E sigma 29), a form which appears approximately 2 h after the initiation of sproulation. Here we report that several base substitutions in the ctc promoter differentially affect the utilization of the promoter by E sigma 37 or E sigma 29.

Promoter specificity of a sporulation-induced form of RNA polymerase from Bacillus subtilis.

The program of gene expression that underlies endospore formation by Bacillus subtilis may be controlled in part by a sporulation-induced form of RNA polymerase, E sigma 29. The nucleotide sequences of four promoters, which are known to be recognized by E sigma 29, are highly conserved at two regions, 10 bp and 35 bp upstream from the start point of transcription. We have used oligonucleotide-directed mutagenesis to construct several base substitutions in the ctc promoter from B. subtilis to test the role of the highly conserved sequences in utilization of the promoter by E sigma 29. In vitro transcription analysis demonstrated that the conserved nucleotides at positions -15, -14 and -12 affect the utilization of the promoter by E sigma 29. These and previous results support a model in which E sigma 29 recognizes its cognate promoters by interacting with nucleotides near the -10 and -35 regions. We also examined the effects of these base substitutions on utilization of the promoter by two other forms of RNA polymerase from B. subtilis, E sigma 37 and E sigma 32.

Promoter recognition by sigma-37 RNA polymerase from Bacillus subtilis.

Bacillus subtilis possesses at least five different forms of RNA polymerase holoenzyme which are distinguished by their sigma subunit and their promoter recognition specificity. Sigma-37 RNA polymerase, a minor form of RNA polymerase, recognizes a class of promoters, which includes promoters for genes transcribed early during endospore formation. We have used site-directed bisulfite mutagenesis to construct a series of single and multiple base substitutions in a promoter recognized by sigma-37 RNA polymerase. In vitro transcription analysis of this series of mutant promoters demonstrated that single base substitutions at positions -36, -16, -15 and -14 most dramatically reduced the efficiency of promoter utilization by sigma-37 RNA polymerase. These results support a model in which sigma-37 RNA polymerase recognizes its cognate promoters by interacting with a sequence of nucleotides near the -10 region and the -35 region of the promoter--a sequence not recognized by B. subtilis sigma-55 RNA polymerase or Escherichia coli RNA polymerase.

Evidence for positive regulation of plasmid prophage P1 replication: integrative suppression by copy mutants.

Like low-copy-number plasmids including P1 wild type, multicopy P1 mutants (P1 cop, maintained at five to eight copies per chromosome) can suppress the thermosensitive phenotype of an Escherichia coli dnaA host by forming a cointegrate. At 40 degrees C in a dnaA host suppressed by P1 cop, the only copy of P1 is the one in the host chromosome. Trivial explanations of the lack of extrachromosomal copies of P1 cop have been eliminated: (i) during integrative suppression, the P1 cop plasmid does not revert to cop+; (ii) the dnaA+ function of the host is not required to maintain P1 cop at a high copy number; and (iii) integrative recombination does not occur within the region of the plasmid involved in regulation of copy number. Since there are no more copies of the chromosomal origin (now located within the integrated P1 plasmid) than in a P1 cop+-suppressed strain, the extra initiation potential of the P1 cop is not used to provide multiple initiations of the chromosome. When a P1 cop-suppressed dnaA strain was grown at 30 degrees C so that replication could initiate from the chromosomal origin as well as from the P1 origin, multicopy supercoiled P1 DNA was found in the cells. This plasmid DNA was lost again when the temperature was shifted back to 40 degrees C.

Rapid purification of yeast mitochondrial DNA in high yield.

A procedure is presented for the rapid isolation of mitochondrial DNA (mtDNA) in high yield from Saccharomyces cerevisiae. Yeast cells, which may be grown to late stationary phase, are broken by a combination of enzymatic and mechanical means; mtDNA is then isolated from a crude mitochondrial lysate by a single cycle of bisbenzimide-CsCl buoyant density centrifugation. mtDNA so isolated is at least 99.5% pure, and has a mean duplex molecular weight of 24.5 . 10(6). In addition to mtDNA and bulk nuclear DNA, several other yeast nucleic acid species, identified as ribosomal DNA and a mixture of duplex RNAs, form discrete bands in these gradients.