The human immunodeficiency virus type 1 (HIV-1) is a major health problem worldwide. In this study, 17 analogues of l-chicoric acid, a potent inhibitor of HIV integrase, were studied. Of these analogues, five submicromolar inhibitors of integrase were discovered and 13 compounds with activity against integrase at less than 10 μM were identified. Six demonstrated greater than 10-fold selectivity for HIV replication over cellular toxicity. Ten analogues inhibited HIV replication at nontoxic concentrations. Alteration of the linkages between the two bis-catechol rings, including the use of amides, mixed amide esters, cholate, and alkyl bridges, was explored. Amides were as active as esters but were more toxic in tissue culture. Alkyl and cholate bridges were significantly less potent against HIV-1 integrase in vitro and were inactive against HIV-1 replication. Two amino acid derivates and one digalloylderivative of l-chicoric acid (l-CA) showed improved selectivity over l-CA against integration in cell culture. These data suggest that in addition to the bis-catechols and free carboxylic acid groups reported previously, polar linkages are important constituents for optimal activity against HIV-1 integrase and that new derivatives can be developed with increased specificity for integration over HIV entry in vivo.
Viral particles in stool samples from wild-living chimpanzees were analysed using random PCR amplification and sequencing. Sequences encoding proteins distantly related to the replicase protein of single-stranded circular DNA viruses were identified. Inverse PCR was used to amplify and sequence multiple small circular DNA viral genomes. The viral genomes were related in size and genome organization to vertebrate circoviruses and plant geminiviruses but with a different location for the stem-loop structure involved in rolling circle DNA replication. The replicase genes of these viruses were most closely related to those of the much smaller (approximately 1 kb) plant nanovirus circular DNA chromosomes. Because the viruses have characteristics of both animal and plant viruses, we named them chimpanzee stool-associated circular viruses (ChiSCV). Further metagenomic studies of animal samples will greatly increase our knowledge of viral diversity and evolution.
Abstract Retroviruses are membrane‐enveloped, RNA‐containing viruses that produce a wide range of threatening diseases in higher animals. Among these are human immunodeficiency virus (HIV), which produces acquired immune deficiency syndrome (AIDS) in humans, and murine leukemia virus (MuLV), which produces leukemias in rodents. We have obtained the first atomic force microscopy (AFM) images of these two retroviruses, both isolated from culture media and emerging from infected cell surfaces. The HIV virions are 127 nm diameter on average, and those of MuLV are 145 nm, although there are wide distributions about the means. The AFM images show the arrangement of the envelope protein, responsible for host cell entry, on the surfaces of both virions. Disruption of the viruses using detergents or physical means allowed us to visualize interior structures, including the outer shells of both MuLVand HIV, the cores of MuLV, and the nucleic acid of HIV complexed with core proteins. Using immunolabeling techniques borrowed from electron microscopy, we were able to demonstrate the binding of gold‐labeled antibodies directed against the envelope protein of MuLV. The AFM images are revealing, not only in terms of surface topology, but in terms of interior features as well, and they reveal the eccentricities and uniqueness of individual virus particles rather than yielding the average member of the population. Further application of AFM to viruses associated with other pathologies may ultimately have a significant impact on the diagnosis and treatment of virus‐promoted diseases.
We report here the complete genome sequence of raccoonpox virus (RCNV), a naturally occurring North American poxvirus. This is the first such North American sequence to the best of our knowledge, and the data showed that RCNV forms a new phylogenetic branch between orthopoxviruses and Yoka poxvirus. RCNV shared overall similarity in genome organization with orthopoxviruses, and the proteins in the central conserved region shared approximately 90 % amino acid identity with orthopoxviruses. RCNV proteins shared approximately 81 % amino acid identity with Yokapox virus proteins. RCNV is missing 10 genes normally conserved in orthopoxviruses, most of which are implicated in virulence. These gene deletions may explain the attenuated phenotype of RCNV in mammals. RCNV contained one unique genome region containing approximately 1 kb of DNA sequence that is not present in any reported poxvirus. It contained a unique ORF predicted to encode a protein with a transmembrane domain. RCNV replicates well in mammalian cells, is naturally attenuated and has been shown to be effective as a vaccine vector platform, so we further tested its safety. We showed here that RCNV is substantially more attenuated than even the highly attenuated VACV-A35Del mutant virus in pregnant, nude and severe combined immunodeficient (SCID) mouse models. RCNV was much safer in pregnant mice and was cleared rapidly from tissues, even in immunocompromised animals, whereas the VACV-A35Del mutant retains virulence and persists in tissues. Thus, RCNV is expected to be a superior vaccine vector for infectious diseases and cancer due to its excellent safety profile, reported vaccine efficacy and ability to replicate in mammalian cells.
A quantitative and sensitive measure of human immunodeficiency virus type 1 (HIV-1) replication is quantitative real-time polymerase chain reaction (PCR). Real-time PCR using SYBR green I and oligonucleotide primers that amplify early, intermediate, and late products of reverse transcription were optimized to measure HIV-1 replication of clade A, B, C, and D HIV-1 isolates in peripheral blood lymphocytes and in both transformed and viral-transformed CD4+ lymphocyte cell lines. Real-time PCR can detect HIV-1 replication as early as 1 hr postinfection and demonstrates that in established cell lines cDNA can be detected as early as 4 hr postinfection. The first round of HIV-1 replication in established cell lines is complete between 12 and 24 hr postinfection. Furthermore, real-time PCR can detect HIV-1 replication in fewer than 0.1% of cells. Patient isolates replicated at different rates in peripheral blood lymphocytes, with viral cDNA peaking between 48 and 120 hr, depending on the virus being studied. Real-time PCR differentiated the mechanisms of action of drugs targeted at HIV-1 entry, reverse transcription, and proteolytic processing and identified differences in the kinetics of reverse transcription between zidovudine-sensitive and zidovudine-resistant HIV in the presence of zidovudine. In summary, real-time PCR using SYBR green I dye is a sensitive, quantitative, and reproducible measure of replication kinetics for a variety of group M HIV-1 isolates.
The variations in enzyme activities involved in the main pathways of liver energetic metabolism--glycolysis, Krebs cycle, gluconeogenesis and lipogenesis--have been studied in rats ranging between the age of 4 days and 21 months. The major changes observed are the following: (1) enzymes involved in glycolysis (pyruvate kinase) and lipogenesis (NADP-malic enzyme, ATP-citrate lyase) decrease in activity during ageing, and (2) gluconeogenic enzymes (phosphoenolpyruvate carboxykinase, glucose-6-phosphatase) are maintained or slightly increased over the same period. The results suggest that an increase in the capacity for gluconeogenesis with respect to that for lipogenesis takes place in the aged rat liver.
