Regulated exocytosis by secretory organelles is important for malaria parasite invasion and egress. Many parasite effector proteins, including perforins, adhesins, and proteases, are extensively proteolytically processed both pre-and post-exocytosis. Here, we report the multi-stage antiplasmodial activity of the aspartic protease inhibitor hydroxyl-ethyl-amine-based scaffold compound, 49c. This scaffold inhibits the pre-exocytosis processing of several secreted rhoptry and microneme proteins by targeting the corresponding maturases plasmepsins IX (PfPMIX) and X (PfPMX), respectively. Conditional excision of PfPMIX revealed its crucial role in invasion, and recombinantly active PfPMIX and PfPMX cleave egress and invasion factors in a 49c sensitive manner. KeywordsMalaria; Plasmodium falciparum; Plasmodium berghei; aspartic protease; invasion; egress; exflagellation; transmission; hydroxyl-ethyl-amine scaffold; peptidomimetic inhibitor; protein maturase Malaria remains a major cause of mortality worldwide, and resistance to existing antimalarials is a growing problem, that requires the development of new drugs urgently. Aspartic proteases are potential targets for chemotherapy (1), and key contributors to Plasmodium falciparum pathogenicity (2, 3). P. falciparum possesses a repertoire of 10 aspartic proteases, named plasmepsins (PMI to X). PMIX and PMX are expressed in mature blood-stage schizonts and invasive merozoites and fulfill indispensable but unknown functions. The activity of several serine and cysteine proteases promotes the destabilization * Corresponding authors: Paco.Pino@unige.ch, Dominique.Soldati-favre@unige.ch.
During the early phase of the retroviral life cycle, only a fraction of internalized virions end up integrating their genome into the chromosome, even though the resulting proviruses are almost systematically expressed. Here, we reveal that incoming retroviral preintegration complexes trigger the exportin-mediated cytoplasmic export of the SWI/SNF component INI1 and of the nuclear body constituent PML. We further show that the HIV genome associates with these proteins before nuclear migration. In the presence of arsenic, PML is sequestered in the nucleus, and the efficiency of HIV-mediated transduction is markedly increased. These results unveil a so far unsuspected cellular response that interferes with the early steps of HIV replication.
Eukaryotic transcriptional activators may stimulate RNA polymerase II activity by promoting assembly of preinitiation complexes on promoters through their interactions with one or more components of the basal machinery. On the basis of its central role in initiating transcription-complex formation upon binding to the TATA box, the general transcription factor TFIID, which includes the TATA-binding protein (TBP) and several TBP-associated factors, has been implicated as a target for activators. Consistent with this idea, an increasing number of activators have been reported to bind directly to TBP. To assess the functional importance of these in vitro interactions for transcriptional regulation in vivo, we made use of a novel strategy in yeast to show that a physical interaction with TBP is sufficient for a sequence-specific DNA-binding protein to increase initiation of transcription by RNA polymerase II. These results imply that binding of TFIID to promoter elements is a limiting step in transcription complex assembly in vivo.
Lentiviral vectors open exciting perspectives for the genetic treatment of a wide array of inherited and acquired diseases, owing to their ability to govern the efficient delivery, integration, and long-term expression of transgenes into nondividing cells both in vitro and in vivo. The genomic complexity of HIV, where a whole set of genes encode virulence factors essential for pathogenesis but not required for gene transfer, allowed a major step toward clinical acceptability through the creation of multiply attenuated packaging systems. Until now, however, vector particles could only be produced by transient transfection because no high-output, stable packaging cell line was available that produced the latest generation of HIV-based vectors. Here we describe such a line, based on the doxycycline-repressible expression of HIV-1 Rev/Gag/Pol and of the vesicular stomatitis virus G envelope (VSV G) in 293 human embryonic kidney cells. Upon induction, the LVG clones can produce 1 to 20 HeLa-transducing units per cell per day for about a week, a yield that compares favorably with that of transiently transfected 293T cells. These virions exhibit functional properties similar to those of viruses produced transiently, in particular the ability to transduce nonmitotic targets. This system will facilitate the further development of lentiviral vectors for gene therapy.
The human RNA polymerase II and III snRNA promoters have similar enhancers, the distal sequence elements (DSEs), and similar basal promoter elements, the proximal sequence elements (PSEs). The DSE, which contains an octamer motif, binds broadly expressed activator Oct-1. The PSE binds a multiprotein complex referred to as SNAP c or PTF. On DNAs containing both an octamer site and a PSE, Oct-1 and SNAP c bind cooperatively. SNAP c consists of at least four stably associated subunits, SNAP43, SNAP45, SNAP50, and SNAP190. None of the three small subunits, which have all been cloned, can bind to the PSE on their own. Here we report the isolation of cDNAs corresponding to the largest subunit of SNAP c , SNAP190. SNAP190 contains an unusual Myb DNA binding domain consisting of four complete repeats (Ra to Rd) and a half repeat (Rh). A truncated protein consisting of the last two SNAP190 Myb repeats, Rc and Rd, can bind to the PSE, suggesting that the SNAP190 Myb domain contributes to recognition of the PSE by the SNAP complex. SNAP190 is required for snRNA gene transcription by both RNA polymerases II and III and interacts with SNAP45. In addition, SNAP190 interacts with Oct-1. Together, these results suggest that the largest subunit of the SNAP complex is involved in direct recognition of the PSE and is a target for the Oct-1 activator. They also provide an example of a basal transcription factor containing a Myb DNA binding domain.The regulation of transcription initiation is mediated by the interplay between two classes of promoter elements: the basal promoter elements, which can be defined as those promoter elements sufficient to direct basal levels of transcription in vitro, and the regulatory elements, which modulate the levels of transcription. The basal elements are recognized by basal transcription factors, whereas the regulatory elements are recognized by either transcriptional activators or repressors. Eucaryotic activators are often modular, consisting of a DNA binding domain, which targets the activator to the correct promoter, and of activation domains, whose role is to enhance transcription (see references 21-23, 32, and 33 for reviews).The human snRNA gene family contains both RNA polymerase II and RNA polymerase III genes. The RNA polymerase II snRNA promoters consist of a proximal sequence element (PSE), which is sufficient to direct basal levels of transcription in vitro, and a distal sequence element, which activates basal transcription. The RNA polymerase III snRNA promoters are similar, except that basal transcription is directed by the combination of a PSE and a TATA box (reviewed in reference 9). The PSE is recognized by a multisubunit complex called the SNAP complex (SNAP c ) (7) or PTF (34). Since SNAP c can bind to the PSE on its own, it corresponds to a sequence-specific DNA binding basal transcription factor. SNAP c contains at least four subunits, SNAP43, SNAP45, SNAP50, and SNAP190, and cDNAs encoding the SNAP43 (7) or PTF ␥ (35), SNAP45 (24) or PTF ␦ (35), and SNAP50 (6) or PTF  (2) su...
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