Lentiviral vectors pseudotyped with baculovirus gp64 efficiently transduce mouse cells in vivo and show tropism restriction against hematopoietic cell types in vitro.

The envelope glycoprotein from vesicular stomatitis virus (VSV-G) has been used extensively to pseudotype lentiviral vectors, but has several drawbacks including cytotoxicity, potential for priming of immune responses against transgene products through efficient transduction of antigen-presenting cells (APCs) and sensitivity to inactivation by human complement. As an alternative to VSV-G, we extensively characterized lentiviral vectors pseudotyped with the gp64 envelope glycoprotein from baculovirus both in vitro and in vivo. We demonstrated for the first time that gp64-pseudotyped vectors could be delivered efficiently in vivo in mice via portal vein injection. Following delivery, the efficiency of mouse cell transduction and the transgene expression is comparable to VSV-G-pseudotyped vectors. In addition, we found that gp64-pseudotyped lentiviral vectors could efficiently transduce a variety of cell lines in vitro, although gp64 showed a more restricted tropism than VSV-G, with especially poor ability to transduce hematopoietic cell types including dendritic cells (DCs). Although we found that gp64-pseudotyped vectors are also sensitive to inactivation by human complement, gp64 nevertheless has advantages over VSV-G, because of its lack of cytotoxicity and narrower tropism. Consequently, gp64 is an attractive alternative to VSV-G because it can efficiently transduce cells in vivo and may reduce immune responses against the transgene product or viral vector by avoiding transduction of APCs such as DCs.

The DNA repair protein rad23 is a negative regulator of multi-ubiquitin chain assembly.

Rad23 is a nucleotide-excision repair protein with a previously unknown biochemical function. We determined that yeast and human Rad23 inhibited multi-ubiquitin (Ub) chain formation and the degradation of proteolytic substrates. Significantly, Rad23 could be co-precipitated with a substrate that contained a short multi-Ub chain. The UV sensitivity of rad23Delta was reduced in mutants lacking the E2 enzyme Ubc4, or the multi-Ub chain-promoting factor Ufd2. These studies suggest that the stability of proteolytic substrates is governed by the competing action of multi-Ub chain-promoting and chain-inhibiting factors. The stabilization of DNA repair and stress factors could represent an important biological function of Rad23.

Sequence elements that contribute to the degradation of yeast G alpha.

BACKGROUND: Gpa1 is the alpha subunit of the yeast G-protein that regulates signal transduction during mating. The stability of Galpha/Gpa1 is influenced by the ubiquitin-dependent N-end rule pathway, suggesting that the regulation of G alpha levels may be important for effective mating response and recovery. RESULTS: The G alpha sequences that confer sensitivity to degradation by the N-end rule pathway were identified. The insertion of this degradation signal (G1-Deg) into the ordinarily stable Gpa2 protein conferred proteolytic targeting. We examined G alpha degradation under different conditions and found that it was efficiently degraded in haploid and diploid cells, but was stable if it was synthesized prior to expression of the N-end rule pathway. Interestingly, a specific mutation in G alpha that is believed to promote the GTP-bound form (N388K) caused accelerated degradation. CONCLUSION: A region encompassing a putative effector-binding domain (G1-Deg) is required for G alpha degradation via the N-end rule pathway. Our studies have shown that G alpha is susceptible to proteolysis soon after synthesis. These results are in agreement with the idea that G alpha is more unstable in the GTP-bound form, which is the predominant state of monomeric/free G alpha soon after synthesis. It is likely that the signal transduced by Gbetagamma can be regulated by adjusting the levels of G alpha through proteolysis.

Rad23 links DNA repair to the ubiquitin/proteasome pathway.

Rad23 is an evolutionarily conserved protein that is important for nucleotide excision repair. A regulatory role has been proposed for Rad23 because rad23 mutants are sensitive to ultraviolet light but are still capable of incising damaged DNA. Here we show that Rad23 interacts with the 26S proteasome through an amino-terminal ubiquitin-like domain (UbL[R23]). The carboxy terminus of Rad23 binds to the Rad4 DNA repair protein and creates a link between the DNA repair and proteasome pathways. The ultraviolet sensitivity caused by deletion of the UbL(R23) domain may therefore arise from its inability to interact with the proteasome. The fusion proteins glutathione S-transferase (GST)-Rad23 and Rad4-haemagglutinin (HA), and the proteasome subunits Cim3 and Cim5, cofractionate through consecutive chromatography steps. The ubiquitin-like domain of human Rad23 (UbL[HRB]) also interacts with the human proteasome. These results demonstrate that ubiquitin-like domains (UbLs) represent a new class of proteasome-interacting motifs.

Template-directed pausing of DNA synthesis by HIV-1 reverse transcriptase during polymerization of HIV-1 sequences in vitro.

Replication of human immunodeficiency virus type 1 (HIV-1) requires reverse transcriptase (RT) to synthesize double-stranded proviral DNA (9.7 kilobases) through a complex mechanism utilizing both RNA and DNA templates. We have examined DNA synthesis by HIV-1 RT on RNA and DNA templates derived from the HIV-1 genome using a primer extension assay in vitro. Analysis of polymerization products on sequencing gels revealed strong pauses in synthesis, on both RNA and DNA templates, in homopolymeric nucleotide runs, and at regions of predicted secondary structure. Polymerization pauses occurred in runs of template rGs (> or = 4 bases) and rCs (> or = 3 bases) during minus-strand synthesis on RNA templates, and in most runs (> or = 4 bases) of template dTs and dAs during plus-strand synthesis on DNA templates. Pausing also occurred on both templates within the first few nucleotides of the predicted hairpin structures of the Rev response element. The locations of pauses were dependent on template sequence and were unaffected by primer positioning, RT concentration, and ionic strength. Recombinant and virion-derived HIV-1 RTs showed similar pausing patterns. DNA products that accumulated at HIV-1 RT pause sites on RNA templates were extended by continued incubation with excess RT from Moloney murine leukemia virus, showing that the RNA templates were not broken or otherwise unable to support polymerization. Polymerizations conducted in the presence of a poly(rA) oligo(dT) trap showed that pausing results from two mechanisms: 1) RT remaining bound to the primer-template and polymerizing at a greatly reduced rate, or 2) RT dissociating from the primer-template. These results demonstrate that specific HIV-1 RNA and DNA template sequences are capable of interrupting processive DNA synthesis by HIV-1 RT in vitro. Pausing may serve specific functions in HIV-1 replication and mutagenesis. Moreover, these data suggest that one or more accessory factors are required to complete proviral DNA synthesis in vivo and that efficient HIV-1 DNA synthesis may require multiple origins.