Abstract. Expression of human immunodeficiency virus type 1 (HIV-1) structural proteins requires the presence of the viral trans-activator protein Rev. Rev is localized in the nucleus and binds specifically to the Rev response element (RRE) sequence in viral RNA. Furthermore, the interaction of the Rev activation domain with a cellular cofactor is essential for Rev function in vivo. Using cross-linking experiments and Biospecific Interaction Analysis (BIA) we identify eukaryotic initiation factor 5A (elF-5A) as a cellular factor binding specifically to the HIV-1 Rev activation domain. Indirect immunofluorescence studies demonstrate that a significant fraction of elF-5A localizes to the nucleus. We also provide evidence that Rev transactivation is functionally mediated by elF-5A in Xenopus oocytes. Furthermore, we are able to block Rev function in mammalian cells by antisense inhibition of elF-5A gene expression. Thus, regulation of HIV-1 gene expression by Rev involves the targeting of RREcontaining RNA to components of the cellular translation initiation complex.
Eukaryotic initiation factor 5A(eIF-5A) is a cellular cofactor require d for the function of the human immunodeficiency virus type-1 (HIV-1) Rev trans-activator protein. The majority of a set of eIF-5A mutants did not support growth of yeast cells having an inactivated genomic copy of eIF-5A, indicating that the introduced mutation eliminated eIF-5A activity. Two nonfunctional mutants, eIF-5AM13 and eIF-5AM14, retained their binding capacity for the HIV-1 Rev response element:Rev complex. Both mutants were constitutively expressed in human T cells. When these T cells were infected with replication-competent HIV-1, virus replication was inhibited. The eIF-5AM13 and eIF5AM14 proteins blocked Rev trans-activation and Rev-mediated nuclear export.
The E1A pre-mRNA of adenovirus is spliced into three mRNA species (13S, 12S, and 9S mRNAsl by the use of three alternative 5'-splice sites. The 13S and 9S mRNAs predominate during the early and late periods of infection, respectively. With HeLa nuclear extracts isolated in early and late periods of infection, we were able to reproduce a 13S-9S modulation that resembles that occurring in infected cells. An in vitro analysis of the c/s-acting parameters involved in the 13S-9S switch indicates that the 13S mRNA splicing inhibition is one of the first events of the late period and leads to the subsequent stimulation of the 9S mRNA reaction. The new abilities of the late nuclear extract for the 9S mRNA reaction were also confirmed by analyzing splicing of a major late transcript containing leaders 1 and 2 separated by the wild-type intervening sequence (IVS) of 1021 nucleotides. Complementation experiments show that the trans-acting factor(sl are micrococcal nuclease sensitive. They were partially characterized by induction experiments, and we show that the primary factors responsible for the 13S-9S modulation in vitro are viral RNAs of high molecular weight that accumulate late in infection. We postulate that the splicing modulation of E1A pre-mRNA results from an indirect mode of action for these viral RNAs, based on a sequestration of common splicing factors that are not present in vast excess in HeLa cells.
The human endoprotease furin is involved in the proteolytic maturation of the precursor molecules of a wide variety of bioactive proteins. Despite its localization in the membranes of the trans-Golgi system by means of a transmembrane domain, it has repeatedly been reported to form a C-terminally truncated, naturally secreted form referred to as 'shed' furin. In order to identify the cleavage site, internal deletion mutants of increasing size, N-terminal to Leu(708), and subsequently individual amino acid substitutions were introduced, and Arg(683) was identified as the prime determinant for shedding. MS analysis determined Ser(682) as the C-terminus of shed furin, suggesting that monobasic cleavage may occur N-terminal to Arg(683). Alteration of Arg(683) directs the shedding mechanism to alternative cleaving sites previously unused.
The human endoprotease furin is involved in the proteolytic maturation of the precursor molecules of a wide variety of bioactive proteins. Despite its localization in the membranes of the trans-Golgi system by means of a transmembrane domain, it has repeatedly been reported to form a C-terminally truncated, naturally secreted form referred to as ‘shed’ furin. In order to identify the cleavage site, internal deletion mutants of increasing size, N-terminal to Leu708, and subsequently individual amino acid substitutions were introduced, and Arg683 was identified as the prime determinant for shedding. MS analysis determined Ser682 as the C-terminus of shed furin, suggesting that monobasic cleavage may occur N-terminal to Arg683. Alteration of Arg683 directs the shedding mechanism to alternative cleaving sites previously unused.
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