Human immunodeficiency virus (HIV) is the causative agent of AIDS (acquired immune deficiency syndrome) a disease which poses a serious challenge to modern medicine. If we are to conquer this disease we will need a protective vaccine or effective drugs able to block the life cycle of the virus. An early stage in the invasion of the host cell is the conversion of the RNA genome of the virus to a double-stranded DNA intermediate which subsequently becomes integrated into the host cell chromosome. The enzyme reverse transcriptase is crucial in this process and is thus an obvious chemotherapeutic target. In this study we have used site-directed mutagenesis of this enzyme expressed in Escherichia coli to reveal several important functional regions of the protein including putative components of the triphosphate binding site and pyrophosphate exchange sites.
There is considerable interest in the potential of human immunodeficiency virus type 1 (lIV-1) to develop drug resistance, especially as 3'-azido-3'-deoxythymidine (Retrovir) is now in widespread clinical use to treat people with AIDS and AIDS-related complex (ARC replicate. However, although the reverse transcriptase from these mutant viruses showed decreased sensitivity to azidothymidine triphosphate, paradoxically these viruses were hypersensitive to azidothymidine when tested in culture.
Bacterially expressed recombinant HIV-1 reverse transcriptase is active as both a homodimer of Mr 66,000 subunits and a heterodimer of Mr 66,000 and 51,000 subunits. The heterodimer is formed by cleavage of a C-terminal fragment from one Mr 66,000 polypeptide, which occurs during purification and crystallization of reverse transcriptase. Thus, crystals obtained from purified Mr 66,000 polypeptide preparations consisted of an apparently equimolar mixture of Mr 66,000 and 51,000 polypeptides, which were apparently analogous to the Mr 66,000 and 51,000 polypeptides detected in HIV-infected cells and in virions. Limited proteolysis of the homodimer with alpha-chymotrypsin also resulted in cleavage to a stable Mr 66,000/51,000 mixture, and proteolysis with trypsin resulted in the transient formation of some Mr 51,000 polypeptide. These results are consistent with the reverse transcriptase molecule having a protease-sensitive linker region following a structured domain of Mr 51,000. Further digestion with trypsin resulted in cleavage of the Mr 51,000 polypeptide after residue 223, yielding peptides of apparent Mr 29,000 and 30,000. A minor peptide of Mr 40,000 was also produced by cleavage of the Mr 66,000 polypeptide after residue 223. About half the original Mr 66,000 polypeptides remained resistant to proteolysis and existed in complex with the above peptides in solution. During both chymotrypsin and trypsin digestion there was an increase in the reverse transcriptase activity caused by a doubling of Vmax with little change in Km for dTTP.(ABSTRACT TRUNCATED AT 250 WORDS)
The causative agent of AIDS the human immunodeficiency virus (HIV) encodes as part of its pol gene a reverse transcriptase (RT) which has a key role in the replication of the virus and thus constitutes an ideal target for antiviral chemotherapy. The purified HIV RT from virus particles consists of two related polypeptides of 66 and 51 kd mol. wt and similar polypeptides are found on expression of the complete HIV pol gene using prokaryotic systems. Here we describe the expression of the 66‐kd protein in Escherichia coli and demonstrate that this polypeptide alone has authentic RT activity. Thus, a central HIV pol gene segment encodes and is sufficient for high levels of RT activity. The RT has been purified from E. coli extracts using a purification procedure involving two chromotography steps resulting in an enzyme preparation near homogeneity. Deletion of the C‐terminal region of the RT thought to encode the RNase H domain resulted in loss of polymerase activity.
Herpes simplex virus-induced DNA polymerase purified by published methods was found to be contaminated with many other proteins, including virus structural proteins. Thus, DEAE-cellulose and phosphocellulose chromatography were used in combination with affinity chromatography to purify DNA polymerase from herpes simplex virus type 1-and type 2-infected cells. The purified enzyme retained unique features of the herpesvirus-induced DNA polymerase, including a requirement for high salt concentrations for maximal activity, a sensitivity to low phosphonoacetate concentrations, and the capacity to be neutralized by rabbit antiserum to herpesvirus-infected cells. By polyacrylamide gel electrophoresis, the purified DNA polymerase was associated with a virus-induced polypeptide of about 150,000 molecular weight.
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