Identification of an intracellular trafficking and assembly pathway for HIV-1 gag

Retroviral Gag proteins are membrane-bound polyproteins that are necessary and sufficient for virus-like particle (VLP) formation. It is not known how Gag traffics through the cell or how the site of particle production is determined. Here we use two techniques, biarsenical/tetracysteine (TC) labeling and release from a cycloheximide block, to follow the trafficking of newly synthesized HIV-1 Gag. Gag first appears diffusely distributed in the cytosol, accumulates in perinuclear clusters, passes transiently through a multivesicular body (MVB)-like compartment, and then travels to the plasma membrane (PM). Sequential passage of Gag through these temporal intermediates was confirmed by live cell imaging. Induction of a transient rise in cytoplasmic calcium increased the amounts of Gag, Gag assembly intermediates and VLPs in MVBs, and resulted in a dramatic increase in VLP release. These results define an intracellular trafficking pathway for HIV-1 Gag that uses perinuclear compartments and the MVB as trafficking intermediates. We propose that the regulation of Gag association with MVB-like compartments regulates the site of HIV-1 budding and particle formation.     

Cytoplasmic incompatibility and multiple symbiont infection in the ash whitefly parasitoid, Encarsia inaron

Terrestrial arthropods are commonly infected with maternally inherited symbionts that cause reproductive incompatibilities between hosts with differing infection status. Such symbionts can have major effects on the efficacy of a biological control program if releases are comprised of mixtures of differentially infected individuals. In this study, the ash whitefly parasitoid, Encarsia inaron (Hymenoptera: Aphelinidae) from Arizona was surveyed for the presence of heritable bacterial symbionts; experiments were also performed to test for two phenotypes known to be caused by Encarsia symbionts—cytoplasmic incompatibility and changes in oviposition behavior and host use. E. inaron has successfully reduced ash whitefly to non-pest status in all three locations it has been released (California, Arizona, and North Carolina) and is also notable as one of the only Encarsia species that is not autoparasitic, with both male and female wasps developing as primary parasitoids of whiteflies. We show that E. inaron is infected with both Wolbachia and Cardinium. While there was no effect of the symbionts on oviposition behavior or host use, crosses between doubly infected male wasps and uninfected females resulted in a severe reduction in the number of female offspring; male offspring production was unaffected. This study thus serves as a further warning that ascribing a phenotype to a symbiont with confidence depends on eliminating the possibility of a mixed infection, and establishes E. inaron as a useful model for dissecting Wolbachia–Cardinium interactions.     

The Impact of Using Mature Compost on Nitrous Oxide Emission and the Denitrifier Community in the Cattle Manure Composting Process

The diversity and dynamics of the denitrifying genes (nirS, nirK, and nosZ) encoding nitrite reductase and nitrous oxide (N₂O) reductase in the dairy cattle manure composting process were investigated. A mixture of dried grass with a cattle manure compost pile and a mature compost-added pile were used, and denaturing gradient gel electrophoresis was used for denitrifier community analysis. The diversity of nirK and nosZ genes significantly changed in the initial stage of composting. These variations might have been induced by the high temperature. The diversity of nirK was constant after the initial variation. On the other hand, the diversity of nosZ changed in the latter half of the process, a change which might have been induced by the accumulation of nitrate and nitrite. The nirS gene fragments could not be detected. The use of mature compost that contains nitrate and nitrite promoted the N₂O emission and significantly affected the variation of nosZ diversity in the initial stage of composting, but did not affect the variation of nirK diversity. Many Pseudomonas-like nirK and nosZ gene fragments were detected in the stage in which N₂O was actively emitted.     

Purification of a site-specific endonuclease, I-Sce II, encoded by intron 4 alpha of the mitochondrial coxI gene of Saccharomyces cerevisiae

We have purified to near homogeneity a site-specific, double-stranded DNA endonuclease (I-Sce II) encoded by intron 4 alpha (aI4 alpha) of the yeast mitochondrial coxI gene. Our purification starts with a high salt extract of mitochondria isolated from a yeast strain that overproduces the enzyme because of a block in splicing of aI4 alpha. The final step of purification is an affinity column consisting of covalently bound double-stranded DNA multimers of a synthetic sequence, 5'-TTGGTCATCCAGAAGTAT-3', which contains the I-Sce II cleavage/recognition site. Typical yields of enzyme are 3-5% with a specific activity of approximately 500,000 units/mg, where 1 unit of activity cleaves 50 ng of DNA substrate/h at 30 degrees C. I-Sce II has a monomer molecular mass of 31 kDa as estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Active enzyme purifies as a 55-kDa species, which we presume to be a homodimer. I-Sce II monomer comigrates with an in vivo synthesized mitochondrial translation product made in the strain that overproduces the enzyme. We conclude that I-Sce II is derived by proteolytic processing of a precursor polypeptide, p62, encoded by an in-frame fusion of coxI exons 1-4 with the downstream aI4 alpha reading frame. I-Sce II is most active at pH 7.5 and at 20-30 degrees C. Endonuclease activity is sensitive to salt and is dependent upon Mg2+ or Mn2+, but is unaffected by inclusion of ATP or GTP. I-Sce II is the first intron-encoded protein to be purified and characterized from yeast mitochondria.     

A latent intron-encoded maturase is also an endonuclease needed for intron mobility

Some yeast mitochondrial introns encode proteins that promote either splicing (maturases) or intron propagation via gene conversion (the fit1 endonuclease). We surveyed introns in the coxl gene for their ability to engage in gene conversion and found that the group I intron, al4 alpha, was efficiently transmitted to genes lacking it. An endonucleolytic cleavage is detectable in recipient DNA molecules near the site of intron insertion in vivo and in vitro. Conversion is dependent on an intact al4 alpha open reading frame. This intron product is a latent maturase, but these data show that it is also a potent endonuclease involved in recombination. Dual function proteins that cleave DNA and facilitate RNA splicing may have played a pivotal role in the propagation and tolerance of introns.