Population genetic analysis of the protease locus of human immunodeficiency virus type 1 quasispecies undergoing drug selection, using a denaturing gradient-heteroduplex tracking assay.

Monitoring the evolution of human immunodeficiency virus type 1 (HIV-1) drug resistance requires measuring the frequency of closely related genetic variants making up the complex viral quasispecies found in vivo. In order to resolve both major and minor (>/=2%) protease gene variants differing by one or more nucleotide substitutions, we analyzed PCR products derived from plasma viral quasispecies by using a combination of denaturing gradient gel electrophoresis and DNA heteroduplex tracking assays. Correct population sampling of the high level of genetic diversity present within viral quasispecies could be documented by parallel analysis of duplicate, independently generated PCR products. The composition of genetically complex protease gene quasispecies remained constant over short periods of time in the absence of treatment and while plasma viremia fell >100-fold following the initiation of protease inhibitor ritonavir monotherapy. Within a month of initiating therapy, a strong reduction in the genetic diversity of plasma viral populations at the selected protease locus was associated with rising plasma viremia and the emergence of drug resistance. The high levels of protease genetic diversity seen before treatment reemerged only months later. In one patient, reduction in genetic diversity at the protease gene was observed concomitantly with an increase in diversity at the envelope gene (E. L. Delwart, P. Heng, A. Neumann, and M. Markowitz, J. Virol. 72:2416-2421, 1998), indicating that opposite population genetic changes can take place in different HIV-1 loci. The rapid emergence of drug-resistant HIV-1 was therefore associated with a strong, although only transient, reduction in genetic diversity at the selected locus. The denaturing gradient-heteroduplex tracking assay is a simple method for the separation and quantitation of very closely related, low-frequency, genetic variants within complex viral populations.

High-resolution analysis of T-cell receptor beta-chain repertoires using DNA heteroduplex tracking: generally stable, clonal CD8+ expansions in all healthy young adults.

The accurate measurement of T-cell receptor (TCR) repertoire changes requires the analysis of a representative sampling of complex T-cell populations. The number and frequency of clonally expanded TCR beta-chain transcripts bearing distinct CDR3 sequences were accurately determined using a simple DNA heteroduplex tracking assay. This method allowed major and minor clonal expansions (> or = 1% of a Vbeta subfamily's transcripts) to be rapidly and reproducibly quantified. Oligoclonal CD8 + cell expansions were detected in all young adults tested, while CD4 + cells generally expressed more polyclonal beta-chain repertoires. The same pattern of CD8 + cells oligoclonality and CD4 + cells polyclonality was observed in asymptomatic HIV-1 infected individuals with high CD4 + cell counts. CD8 + CD45RA + and CD8 + CD45RO + cell fractions both displayed oligoclonal, although distinct, TCR beta chain repertoires while CD8 + cells from umbilical cord blood were generally polyclonal. Oligoclonal CD8 + cell repertoires from young adults were generally stable over a period of weeks, although minor, transient, clonal expansions could also be detected in the absence of symptomatic infections. DNA heteroduplex tracking analysis provided a higher level of sensitivity for the detection of TCR beta chain transcript expansions than CDR3 length (spectrotyping/immunoscope) analysis. DNA heteroduplex tracking of TCR beta-chain transcripts is therefore a simple and sensitive method for assessing the level of clonality and for measuring changes in the TCR beta chain repertoire of different T-cell populations.

sigA is an essential gene in Mycobacterium smegmatis.

sigA encodes a sigma factor of the sigma70 family, sigmaA, that is found in all mycobacterial species. As sigmaA shows high similarity to the primary sigma factor in Streptomyces coelicolor, it was postulated that sigmaA has the same role in mycobacteria. However, a point mutation in sigA, resulting in the replacement of arginine 522 by histidine, was found responsible for the attenuated virulence of the Mycobacterium bovis strain ATCC 35721. This raised the possibility that sigmaA was an alternative sigma factor specifically required for virulence gene expression. In this work, we show that sigA can not be disrupted in Mycobacterium smegmatis unless an extra copy of the gene is provided at another chromosomal site, which demonstrates that sigA is essential. To characterize the pattern of sigA expression during exponential and stationary phase in M. smegmatis, we measured the beta-galactosidase activity in a strain carrying a sigA-lacZ transcriptional fusion and monitored sigmaA levels using Western blotting. Our results indicate that sigA is expressed throughout the growth of the culture. The essential character of sigA and its pattern of expression corroborate the hypothesis that sigA codes for the primary sigma factor in M. smegmatis and, most likely, in all mycobacteria.

Genomic organization of the mycobacterial sigma gene cluster.

We have previously described sigma A and sigma B and their structural genes, mysA and mysB, respectively, in Mycobacterium smegmatis. We have now sequenced the corresponding regions in the M. tuberculosis and M. leprae chromosomes, and have found the two homologous genes. The chromosomal linkage and the deduced amino acid (aa) sequences of the two genes show very high similarity in the three species of mycobacteria. We also report the finding of two other open reading frames (ORF) in these clusters. orfX, which has an unknown function, is located between mysA and mysB. The other ORF, located downstream from mysB, encodes a homolog of DtxR, the iron regulatory protein from Corynebacterium diphtheriae (Cd).

Characterization of an iron-dependent regulatory protein (IdeR) of Mycobacterium tuberculosis as a functional homolog of the diphtheria toxin repressor (DtxR) from Corynebacterium diphtheriae.

The DtxR protein from Corynebacterium diphtheriae is an iron-dependent repressor that regulates transcription from the tox, IRP1, and IRP2 promoters. A gene from virulent Mycobacterium tuberculosis H37Rv was recently shown to encode a protein, here designated iron-dependent regulator (IdeR), that is almost 60% homologous to DtxR from C. diphtheriae. A 750-bp PCR-derived DNA fragment carrying the M. tuberculosis ideR allele was subcloned to both high- and low-copy-number vectors. In Escherichia coli, transcription from the C. diphtheriae tox, IRP1, and IRP2 promoters was strongly repressed by ideR under high-iron conditions, and ideR restored normal iron-dependent expression of the corynebacterial siderophore in the C. diphtheriae dtxR mutant C7(beta)hm723. The M. tuberculosis IdeR protein was overexpressed in E. coli and purified to near homogeneity by nickel affinity chromatography. Gel mobility shift experiments revealed that IdeR bound to a DNA fragment that carried the C. diphtheriae tox promoter/operator sequence. DNAse I footprint analysis demonstrated that IdeR, in the presence of Cd2+, Co2+, Fe2+, Mn2+, Ni2+, or Zn2+, protected an approximately 30-bp region on DNA fragments carrying the tox, IRP1, or IRP2 promoter/operator sequences. IdeR reacted very weakly in Western blots (immunoblots) with antiserum against the C. diphtheriae DtxR protein, suggesting that the immunodominant epitopes of DtxR may be located in its poorly conserved carboxyl-terminal domain.

The Bacillus subtilis SinR protein is a repressor of the key sporulation gene spo0A.

SinR is a pleiotropic DNA binding protein that is essential for the late-growth processes of competence and motility in Bacillus subtilis and is also a repressor of others, e.g., sporulation and subtilisin synthesis. In this report, we show that SinR, in addition to being an inhibitor of sporulation stage II gene expression, is a repressor of the key early sporulation gene spo0A. The sporulation-specific rise in spo0A expression at time zero is absent in a SinR-overproducing strain and is much higher than normal in strains with a disrupted sinR gene. This effect is direct, since SinR binds specifically to spo0A in vitro, in a region overlapping the -10 region of the sporulation-specific Ps promoter that is recognized by E-sigma H polymerase. Methyl interference and site-directed mutagenesis studies have identified guanine residues that are important for SinR recognition of this DNA sequence. Finally, we present evidence that SinR controls sporulation through several independent genes, i.e., sp0A, spoIIA, and possibly spoIIG and spoIIE.

Characterization of RNA polymerase and two sigma-factor genes from Mycobacterium smegmatis.

A search for Mycobacterium smegmatis genes showing similarity to the conserved family encoding major sigma factors in diverse prokaryotes has identified two such determinants. Both genes are expressed in exponentially growing cells, as judged by Western immunoassays. A series of chromatographic steps was used to purify M. smegmatis RNA polymerase holoenzyme and it was shown that its ability to initiate in vitro transcription with a heterologous Bacillus subtilis promoter is dependent on the presence of these sigma factor(s). Reconstitution of specific in vitro transcription activity was obtained upon mixing of M. smegmatis core RNA polymerase with the major sigma factor of Bacillus subtilis. We also demonstrated in vitro transcription of the M. smegmatis rrnB promoter by the M. smegmatis RNA polymerase. Significantly, highly active B. subtilis RNA polymerase holoenzyme was unable to transcribe this gene.