Mutations in the principal neutralization determinant of human immunodeficiency virus type 1 affect syncytium formation, virus infectivity, growth kinetics, and neutralization.

The principal neutralization determinant (PND) of human immunodeficiency virus type 1 envelope glycoprotein gp120 contains a conserved GPG sequence. The effects of a 29-amino-acid deletion of most of the PND, a 3-amino-acid deletion in the GPG sequence, and 16 single-amino-acid substitutions in the GPG sequence were determined in a transient expression assay. All mutant envelope glycoproteins were expressed at levels comparable to that of the wild-type envelope, and mutations in the GPG sequence did not affect processing to gp120 or, except for the 29-amino-acid deletion, binding to CD4. Of all of the mutants, only the GHG and GFG mutants induced formation of syncytia similar in size and number to those induced by the wild-type envelope. When the envelope expression level was increased 10-fold or more, several additional mutants (APG, GAG, GSG, GQG, GVG, and GPF) also induced syncytium formation. Transfection with infectious proviral molecular clones containing the GHG, GFG, APG, GAG, GSG, or GPF mutations induced production of viral particles; however, only the GPG, GHG, and GFG viruses produced active infections in CD4-bearing cells. Furthermore, whereas the wild-type virus was efficiently neutralized by PND polyclonal and monoclonal antibodies, the GHG- and GFG-containing viruses were not. These results show that mutations in the GPG sequence found within the PND do not affect envelope expression and do not significantly affect CD4 binding or production of viral particles but that they do affect the ability of the envelope to induce syncytia and those of the viral particles to infect CD4 cells and be neutralized by PND antibodies.

Expression and purification of active recombinant platelet factor 4 from a cleavable fusion protein.

A synthetic gene for human platelet factor 4 (hPF4) has been expressed at high levels as a fusion protein in Escherichia coli. The hPF4 sequence has been cleaved from the fusion protein by cyanogen bromide treatment and purified by column chromatography. Like hPF4, our recombinant hPF4 (rhPF4) is tetrameric under physiological conditions, binds heparin, and inhibits angiogenesis. Extensive purification to remove trace amounts of uncleaved fusion protein completely from the desired product rhPF4 was difficult. We have exploited recombinant DNA technology by modifying the fusion moiety to accomplish separation. This type of modification, which did not affect expression level, could be applied to other recombinant fusion proteins.

S gene product: identification and membrane localization of a lysis control protein.

The product of the bacteriophage S gene has been previously shown to be required for an essential step in triggering host cell lysis. By using two different protein labeling systems, maxicells and UV-irradiated infected cells, we identified the S gene product as an 8,500-molecular-weight polypeptide associated with the cell envelope. The apparent molecular weight is significantly less than the 11,500 predicted from the S gene sequence. We were unable to confirm two previous identifications of S gene products, an acidic 15,000-molecular-weight polypeptide found by two-dimensional gel electrophoresis of infected cells and a 5,500-molecular-weight polypeptide in purified phage particles.