In vitro evolution of a highly replicating, doxycycline-dependent HIV for applications in vaccine studies.

A major concern associated with the use of vaccines based on live-attenuated viruses is the possible and well documented reversion to pathogenic phenotypes. In the case of HIV, genomic deletions or mutations introduced to attenuate viral pathogenicity can be repaired by selection of compensating mutations. These events lead to increased virus replication rates and, eventually, disease progression. Because replication competence and degree of protection appear to be directly correlated, further attenuation of a vaccine virus may compromise the ability to elicit a protective immune response. Here, we describe an approach toward a safe attenuated HIV vaccine. The system is not based on permanent reduction of infectivity by alteration of important viral genomic sequences, but on strict control of replication through the insertion of the tetracycline (Tet) system in the HIV genome. Furthermore, extensive in vitro evolution was applied to the prototype Tet-controlled HIV to select for variants with optimized rather than diminished replication capacity. The final product of evolution has properties uniquely suited for use as a vaccine strain. The evolved virus is highly infectious, as opposed to a canonically attenuated virus. It replicates efficiently in T cell lines and in activated and unstimulated peripheral blood mononuclear cells. Most importantly, replication is strictly dependent on the nontoxic Tetanalogue doxycycline and can be turned on and off. These results suggest that this in vitro evolved, doxycycline-dependent HIV might represent a useful tool toward the development of a safer, live-attenuated HIV vaccine.

Repair of a Rev-minus human immunodeficiency virus type 1 mutant by activation of a cryptic splice site.

We isolated a revertant virus after prolonged culturing of a replication-impaired human immunodeficiency virus type 1 (HIV-1) mutant of which the Rev open reading frame was inactivated by mutation of the AUG translation initiation codon. Sequencing of the tat-rev region of this revertant virus identified a second-site mutation in tat that restored virus replication in the mutant background. This mutation activated a cryptic 5' splice site (ss) that, when used in conjunction with the regular HIV 3' ss #5, fuses the tat and rev reading frames to encode a novel T-Rev fusion protein that rescues Rev function. We also demonstrate an alternative route to indirectly activate this cryptic 5' ss by mutational inactivation of an adjacent exon splicing silencer element.

Strict control of human immunodeficiency virus type 1 replication by a genetic switch: Tet for Tat.

Live-attenuated human immunodeficiency virus type 1 (HIV-1) variants have shown great promise as AIDS vaccines, but continued replication can lead to the selection of faster-replicating variants that are pathogenic. We therefore designed HIV-1 genomes that replicate exclusively upon addition of the nontoxic effector doxycycline (dox). This was achieved by replacement of the viral TAR-Tat system for transcriptional activation by the Escherichia coli-derived Tet system for inducible gene expression. These designer "HIV-rtTA" viruses replicate in a strictly dox-dependent manner both in a T-cell line and in primary blood cells, and the rate of replication can be fine-tuned by simple variation of the dox concentration. These HIV-rtTA viruses provide a tool to perform genetics, e.g., selection and optimization experiments, with the E. coli-derived Tet reagents in a eukaryotic background. Furthermore, such viruses may represent improved vaccine candidates because their replication can be turned on and off at will.

Functional differences between the long terminal repeat transcriptional promoters of human immunodeficiency virus type 1 subtypes A through G.

The current human immunodeficiency virus type 1 (HIV-1) shows an increasing number of distinct viral subtypes, as well as viruses that are recombinants of at least two subtypes. Although no biological differences have been described so far for viruses that belong to different subtypes, there is considerable sequence variation between the different HIV-1 subtypes. The HIV-1 long terminal repeat (LTR) encodes the transcriptional promoter, and the LTR of subtypes A through G was cloned and analyzed to test if there are subtype-specific differences in gene expression. Sequence analysis demonstrated a unique LTR enhancer-promoter configuration for each subtype. Transcription assays with luciferase reporter constructs showed that all subtype LTRs are functional promoters with a low basal transcriptional activity and a high activity in the presence of the viral Tat transcriptional activator protein. All subtype LTRs responded equally well to the Tat trans activator protein of subtype B. This result suggests that there are no major differences in the mechanism of Tat-mediated trans activation among the subtypes. Nevertheless, subtype-specific differences in the activity of the basal LTR promoter were measured in different cell types. Furthermore, we measured a differential response to tumor necrosis factor alpha treatment, and the induction level correlated with the number of NF-kappaB sites in the respective LTRs, which varies from one (subtype E) to three (subtype C). In general, subtype E was found to encode the most potent LTR, and we therefore inserted the core promoter elements of subtype E in the infectious molecular clone of the LAI isolate (subtype B). This recombinant LAI-E virus exhibited a profound replication advantage compared with the original LAI virus in the SupT1 T-cell line, indicating that subtle differences in LTR promoter activity can have a significant impact on viral replication kinetics. These results suggest that there may be considerable biological differences among the HIV-1 subtypes.

A second-site mutation that restores replication of a Tat-defective human immunodeficiency virus.

We previously constructed a large set of mutants of the human immunodeficiency virus type 1 (HIV-1) regulatory protein Tat with conservative amino acid substitutions in the activation domain. These Tat variants were analyzed in the context of the infectious virus, and several mutants were found to be defective for replication. In an attempt to obtain second-site suppressor mutations that could provide information on the Tat protein structure, some of the replication-impaired viruses were used as a parent for the isolation of revertant viruses with improved replication capacity. Sequence analysis of revertant viruses frequently revealed changes within the tat gene, most often first-site reversions either to the wild-type amino acid or to related amino acids that restore, at least partially, the Tat function and virus replication. Of 30 revertant cultures, we identified only one second-site suppressor mutation. The inactive Y26A mutant yielded the second-site suppressor mutation Y47N that partially restored trans-activation activity and virus replication. Surprisingly, when the suppressor mutation was introduced in the wild-type Tat background, it also improved the trans-activation function of this protein about twofold. We conclude that the gain of function measured for the Y47N change is not specific for the Y26A mutant, arguing against a direct interaction of Tat amino acids 26 and 47 in the three-dimensional fold of this protein. Other revertant viruses did not contain any additional Tat changes, and some viruses revealed putative second-site Tat mutations that did not significantly improve Tat function and virus replication. We reason that these mutations were introduced by chance through founder effects or by linkage to suppressor mutations elsewhere in the virus genome. In conclusion, the forced evolution of mutant HIV-1 genomes, which is an efficient approach for the analysis of RNA regulatory motifs, seems less suited for the analysis of the structure of this small transcription factor, although protein variants with interesting properties can be generated.

Genetic instability of live, attenuated human immunodeficiency virus type 1 vaccine strains.

Live, attenuated viruses have been the most successful vaccines in monkey models of human immunodeficiency virus type 1 (HIV-1) infection. However, there are several safety concerns about using such an anti-HIV vaccine in humans, including reversion of the vaccine strain to virulence and recombination with endogenous retroviral sequences to produce new infectious and potentially pathogenic viruses. Because testing in humans would inevitably carry a substantial risk, we set out to test the genetic stability of multiply deleted HIV constructs in perpetuated tissue culture infections. The Delta3 candidate vaccine strain of HIV-1 contains deletions in the viral long terminal repeat (LTR) promoter and the vpr and nef genes. This virus replicates with delayed kinetics, but a profound enhancement of virus replication was observed after approximately 2 months of culturing. Analysis of the revertant viral genome indicated that the three introduced deletions were maintained but a 39-nucleotide sequence was inserted in the LTR promoter region. This insert was formed by duplication of the region encoding three binding sites for the Sp1 transcription factor. The duplicated Sp1 region was demonstrated to increase the LTR promoter activity, and a concomitant increase in the virus replication rate was measured. In fact, duplication of the Sp1 sites increased the fitness of the Delta3 virus (Vpr/Nef/U3) to levels higher than that of the singly deleted DeltaVpr virus. These results indicate that deleted HIV-1 vaccine strains can evolve into fast-replicating variants by multiplication of remaining sequence motifs, and their safety is therefore not guaranteed. This insight may guide future efforts to develop more stable anti-HIV vaccines.

Evolution of the human immunodeficiency virus type 1 long terminal repeat promoter by conversion of an NF-kappaB enhancer element into a GABP binding site.

Human immunodeficiency virus type 1 (HIV-1) transcription is regulated by the viral Tat protein and cellular factors, of which the concentration and activity may depend on the cell type. Viral long terminal repeat (LTR) promoter sequences are therefore optimized to suit the specific nuclear environment of the target host cell. In long-term cultures of a Tat-defective, poorly replicating HIV-1 mutant, we selected for a faster-replicating virus with a 1-nucleotide deletion in the upstream copy of two highly conserved NF-kappaB binding sites. The variant enhancer sequence demonstrated a severe loss of NF-kappaB binding in protein binding assays. Interestingly, we observed a new binding activity that is specific for the variant NF-kappaB sequence and is present in the nuclear extract of unstimulated cells that lack NF-kappaB. These results suggest that inactivation of the NF-kappaB site coincides with binding of another transcription factor. Fine mapping of the sequence requirements for binding of this factor revealed a core sequence similar to that of Ets binding sites, and supershift assays with antibodies demonstrated the involvement of the GABP transcription factor. Transient transfection experiments with LTR-chloramphenicol acetyltransferase constructs indicated that the variant LTR promoter is specifically inhibited by GABP in the absence of Tat, but this promoter was dramatically more responsive to Tat than the wild-type LTR. Introduction of this GABP site into the LAI virus yielded a specific gain of fitness in SupT1 cells, which contain little NF-kappaB protein. These results suggest that GABP potentiates Tat-mediated activation of LTR transcription and viral replication in some cell types. Conversion of an NF-kappaB into a GABP binding site is likely to have occurred also during the worldwide spread of HIV-1, as we noticed the same LTR modification in subtype E isolates from Thailand. This typical LTR promoter configuration may provide these viruses with unique biological properties.

On the role of the second coding exon of the HIV-1 Tat protein in virus replication and MHC class I downregulation.

Tat is an essential protein of human immunodeficiency virus type 1 (HIV-1) and activates transcription from the viral long terminal repeat (LTR) promoter. The tat gene is composed of two coding exons of which the first, corresponding to the N-terminal 72 amino acid residues, has been reported to be sufficient for its transcription function. We introduced a stop codon at the end of the first Tat-coding exon in an expression vector that produces a truncated 71-amino acid Tat protein. This Q72stop mutant displays reduced transcriptional activity of approximately 54% in transient LTR-CAT transfection assays. To test the contribution of the second Tat-coding exon to virus replication, the Q72stop mutation was also introduced in the infectious pLAI molecular clone. The effect on virus replication was analyzed in primary cells and in a transformed T cell line. The fitness of the mutant virus was calculated to be approximately 75% compared with the wild-type control. Thus, a small contribution of the C-terminal Tat domain to viral fitness was measured. It has been proposed that the second Tat-coding exon is involved in transcriptional downregulation of the MHC class I gene of the infected host cell. Cell surface expression of the MHC protein was analyzed in T cells infected with the wild-type LAI virus and the replication-competent Q72stop mutant. MHC expression was transiently reduced on infection with either virus, indicating that the second Tat-coding exon is not involved in this downregulation.

Determination of the minimal amount of Tat activity required for human immunodeficiency virus type 1 replication.

The Tat protein of human immunodeficiency virus type 1 (HIV-1) is a potent trans-activator of transcription from the viral LTR promoter. Previous mutagenesis studies have identified domains within Tat responsible for binding to its TAR RNA target and for transcriptional activation. The minimal Tat activation domain is composed of the N-terminal 48 residues, and mutational analyses identified a cluster of critical cysteines. The importance of four highly conserved aromatic amino acids within the activation domain has not been thoroughly investigated. We have systematically substituted these aromatic residues (Y26, F32, F38, Y47) of the HIV-1 LAI Tat protein with other aromatic residues (conservative mutation) or alanine (nonconservative mutation). The activity of the mutant Tat constructs was measured in different cell lines by transfection with a LTR-CAT reporter plasmid. The range of transcriptional activities measured for this set of Tat mutants allowed careful assessment of the level of Tat activity required for optimal viral replication. To test this, the mutant Tat genes were introduced into the pLAI infectious molecular clone and tested for their effect on virus replication in a T-cell line. We found that a twofold reduction in Tat activity already affects viral replication, and no virus replication was measured for Tat mutants with less than 15% activity. This strict correlation between Tat activity and viral replication demonstrates the importance of the Tat function to viral fitness. Interestingly, a less pronounced replication defect was observed in primary cell types. This finding may correlate with the frequent detection of proviruses with Tat-inactivating mutations in clinical samples.

Optimal Tat-mediated activation of the HIV-1 LTR promoter requires a full-length TAR RNA hairpin.

HIV-1 transcription from the LTR promoter is activated by the viral Tat protein through interaction with the nascent TAR RNA hairpin structure. The mechanism of Tat-mediated transcriptional activation has been extensively investigated with LTR-CAT reporter genes in transient transfections and, more recently, in infection experiments with mutant HIV-1 variants. Several discrepancies between these two assay systems have been reported. For instance, whereas opening of the lower part of the TAR RNA stem does not affect the promoter activity of an LTR-CAT plasmid in transient assays, the corresponding virus mutant is fully replication-impaired. With the aim to resolve this controversy, we have examined the activity of a set of TAR RNA mutants in transient transfection experiments with a variety of cell types. We now demonstrate that truncated TAR motifs exhibit a severe, but cell-type dependent transcription defect. Whereas full LTR activity is measured in COS cells that have been used regularly in previous transfection assays, a severe defect is apparent in a variety of human cell lines, including T cell lines that are typically used in HIV-1 replication studies. These results suggest the presence of a human protein that participates in Tat-mediated transcriptional activation through binding to the lower part of the TAR stem. Several candidate co-factors have been reported in literature. This study resolves the discrepancy between transfection and infection studies on the requirements of the lower TAR stem structure. The evidence also implies that LTR transcription studies should be performed preferentially in human cell types.

Paracrine activation of the HIV-1 LTR promoter by the viral Tat protein is mechanistically similar to trans-activation within a cell.

The HIV-1 Tat protein activates transcription of the viral LTR promoter through interaction with the nuclear transcription machinery of the host cell. Tat can also activate the LTR promoter in a paracrine or inter-cellular manner by a yet unknown mechanism. One possibility is that Tat protein itself is secreted by cells and taken up by other cells. According to this mechanism, inter-cellular transcriptional activation by Tat should be very similar to intra-cellular trans-activation in Tat-producing cells. A large number of cytokine genes was recently reported to be Tat-responsive, raising the possibility that such cytokines and the corresponding cellular transduction pathways are involved in inter-cellular Tat action. The transcriptional events in such an indirect route are likely to differ from intra-cellular Tat action. To discriminate between a direct or indirect mechanism of inter-cellular Tat action, we compared the activity of a set of Tat mutants and different promoter constructs in inter-cellular and intra-cellular transcriptional activation. Identical results were obtained in both assays, suggesting that Tat protein itself is exported by one and transported into the nucleus of another cell. The demonstration that Tat antibodies specifically inhibit the inter-cellular route is also consistent with cell-to-cell transport of the Tat protein. Furthermore, we found that the second Tat coding exon, including the RGD motif that has been proposed to interact with an integrin receptor, is not required for cellular uptake of the Tat protein.

Intracellular analysis of in vitro modified HIV Tat protein.

Human immunodeficiency viruses HIV-1 and HIV-2 encode a Tat protein that specifically activates transcription from the viral long terminal repeat. To characterize the properties of the Tat proteins, we have expressed them in Escherichia coli. The purified Tat protein was biochemically analyzed and tested for activity upon electroporation into human cell lines. This protein electroporation was used for the intracellular analysis of in vitro modified Tat protein. Our results indicate that the transcriptionally active form of the Tat protein is a monomer. Furthermore, we found that Tat activity is dramatically inhibited by preincubation of the protein with strongly reducing agents. In contrast, no inhibitory effect was measured upon incubation with metal-chelating reagents. These results suggest that the cysteine residues of Tat are involved in the formation of intramolecular disulfide bonds.

Architecture of the outer membrane of Escherichia coli K12. I. Action of phospholipases A2 and C on wild type strains and outer membrane mutants.

Phospholipids in whole cells of wild type Escherichia coli K12 are not degraded by exogenous phospholipases, whereas those of isolated outer membranes are completely degraded. It is concluded that the resistance of phospholipids in whole cells is due to shielding by one or more other outer membrane components. The nature of the shielding component(s) was investigated by testing the sensitivity of whole cells of a number of outer membrane mutants. Mutants lacking both major outer membrane proteins b and d or the heptose-bound glucose of their lipopolysaccharide, are sensitive to exogenous exogenous phospholipases. Moreover, cells of a mutant which lacks protein d can be sensitized by pretreatment of the cells with EDTA. From these results and from data on the chemical composition of the outer membranes, it is concluded that proteins b and d, the heptose-bound glucose of lipopolysaccharide and divalent cations are responsible for the inaccessibility of phospholipids to to exogenous phospholipases.