By means of a selective DNA amplification technique called polymerase chain reaction, proviral sequences of the human immunodeficiency virus (HIV-1) were identified directly in DNA isolated from peripheral blood mononuclear cells (PBMCs) of persons seropositive but not in DNA isolated from PBMCs of persons seronegative for the virus. Primer pairs from multiple regions of the HIV-1 genome were used to achieve maximum sensitivity of provirus detection. HIV-1 sequences were detected in 100% of DNA specimens from seropositive, homosexual men from whom the virus was isolated by coculture, but in none of the DNA specimens from a control group of seronegative, virus culture-negative persons. However, HIV-1 sequences were detected in 64% of DNA specimens from seropositive, virus culture-negative homosexual men. This method of DNA amplification made it possible to obtain results within 3 days, whereas virus isolation takes up to 3 to 4 weeks. The method may therefore be used to complement or replace virus isolation as a routine means of determining HIV-1 infection.
Efforts to solve the epidemiologic puzzle of AIDS in Africa are complicated by the presence of multiple human retroviruses. Simple serologic tests that unambiguously distinguish among infections by these retroviruses are essential. To that end, a partially conserved immunoreactive epitope was identified in the transmembrane glycoproteins of human immunodeficiency viruses (HIV) types 1 and 2. Synthetic peptides derived from these conserved domains were used in sensitive and specific immunoassays that detect antibodies in sera from patients infected with HIV-1 or HIV-2. By making single amino acid substitutions in the HIV-1 peptide, it was possible to demonstrate HIV-1 strain-specific antibody responses to this epitope. Such custom-designed peptides synthesized from this domain are likely to detect newly discovered HIV types, define infection with specific HIV strains, and allow detection of group-common antibodies.
The degree of cell and organ damage in clinical and histological studies of patients dying of Lassa fever has been insufficient to explain the catastrophic shock characteristic of the fatal illness. To explore this issue further, we conducted a study of the evolution of shock in three Lassa virus-infected rhesus monkeys. By the sixth day after infection, a marked, progressive reduction of in vitro platelet aggregation occurred despite normal numbers of circulating platelets and a normal platelet survival time and was accompanied by loss of prostacyclin production by postmortem endothelium. Both of these functions recovered rapidly in a surviving animal. There was no evidence of disseminated intravascular coagulation, nor were clotting factors significantly abnormal. We observed association of viral antigen with neutrophils and progressive neutrophilia. Viremia was not reduced by a brisk antibody response in our animals, and there was a general depression of response to mitogens in mixed lymphocyte stimulation assays. Our findings suggest that shock in Lassa fever is due to biochemical dysfunctions of platelets and endothelial cells and results from loss of intravascular plasma volume, effusions, and hemorrhage.
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