Vaults are ribonucleoprotein particles found in the cytoplasm of eucaryotic cells. The 13 MDa particles are composed of multiple copies of three proteins: an M(r) 100 000 major vault protein (MVP) and two minor vault proteins of M(r) 193 000 (vault poly-(ADP-ribose) polymerase) and M(r) 240 000 (telomerase-associated protein 1), as well as small untranslated RNA molecules of approximately 100 bases. Although the existence of vaults was first reported in the mid-1980s no function has yet been attributed to this organelle. The notion that vaults might play a role in drug resistance was suggested by the molecular identification of the lung resistance-related (LRP) protein as the human MVP. MVP/LRP was found to be overexpressed in many chemoresistant cancer cell lines and primary tumor samples of different histogenetic origin. Several, but not all, clinico-pathological studies showed that MVP expression at diagnosis was an independent adverse prognostic factor for response to chemotherapy. The hollow barrel-shaped structure of the vault complex and its subcellular localization indicate a function in intracellular transport. It was therefore postulated that vaults contributed to drug resistance by transporting drugs away from their intracellular targets and/or the sequestration of drugs. Here, we review the current knowledge on the vault complex and critically discuss the evidence that links vaults to drug resistance.
The catalytic activity of the Src homology 2 (SH2) domain-containing tyrosine phosphatase, SHP-2, is required for virtually all of its signaling effects. Elucidating the molecular mechanisms of SHP-2 signaling, therefore, rests upon the identification of its target substrates. In this report, we have used SHP-2 substratetrapping mutants to identify the major vault protein (MVP) as a putative SHP-2 substrate. MVP is the predominant component of vaults that are cytoplasmic ribonucleoprotein complexes of unknown function. We show that MVP is dephosphorylated by SHP-2 in vitro and it forms an enzyme-substrate complex with SHP-2 in vivo. In response to epidermal growth factor (EGF), SHP-2 associates via its SH2 domains with tyrosyl-phosphorylated MVP. MVP also interacts with the activated form of the extracellular-regulated kinases (Erks) in response to EGF and a constitutive complex between tyrosyl-phosphorylated MVP, SHP-2, and the Erks was detected in MCF-7 breast cancer cells. Using MVP-deficient fibroblasts, we demonstrate that MVP cooperates with Ras for optimal EGF-induced Elk-1 activation and is required for cell survival. We propose that MVP functions as a novel scaffold protein for both SHP-2 and Erk. The regulation of MVP tyrosyl phosphorylation by SHP-2 may play an important role in cell survival signaling.Tyrosyl phosphorylation is a dynamic and reversible posttranslational modification catalyzed by the opposing actions of PTKs 1 and PTPs. The coordinated actions of PTKs and PTPs are crucial for the regulation of a multitude of physiological processes such as cell growth, differentiation, migration, adhesion, immune response, cell survival, and apoptosis. Although there is overwhelming evidence to demonstrate a critical role for PTPs in the regulation of cellular physiology, a detailed molecular understanding of the actions of many of these enzymes remains to be determined. In large part, the lack of a precise molecular basis for how PTPs function has stemmed from the difficult task of identifying their substrates. The SH2 domain-containing PTP, SHP-2, is an ubiquitously expressed PTP that has two SH2 domains at the NH 2 terminus, a PTP domain, and a COOH-terminal tail (1-3). Much evidence derived from genetic studies demonstrates that SHP-2 plays a positive role in transducing signals from receptor PTKs (4). Further evidence in mammalian systems for a positive signaling role for SHP-2 has been obtained from mice containing a targeted deletion within exon 3 of murine SHP-2 that deletes the NH 2 terminus SH2 domain (5). SHP-2 exon 3-deleted mice exhibit embryonic lethality (5). Fibroblasts derived from them are defective for the activation of the MAPKs such as the Erks in response to a number of polypeptide growth factors (5-8). These data, as well as those derived from others (9, 10), place SHP-2 upstream of the Erks, and in some cases upstream of either Ras (11), phosphatidylinositol 3-kinase (8, 12, 13) or the Src family kinases (6,14,15).The ability of SHP-2 to transduce downstream signals in such a d...
Vaults are large ribonucleoprotein particles found in eukaryotic cells. They are composed of multiple copies of a Mr 100,000 major vault protein and two minor vault proteins of Mr 193,000 and 240,000, as well as small untranslated RNAs of 86-141 bases. The vault components are arranged into a highly characteristic hollow barrel-like structure of 35 x 65 nm in size. Vaults are predominantly localized in the cytoplasm where they may associate with cytoskeletal elements. A small fraction of vaults are found to be associated with the nucleus. As of yet, the precise cellular function of the vault complex is unknown. However, their distinct morphology and intracellular distribution suggest a role in intracellular transport processes. Here we review the current knowledge on the vault complex, its structure, components and possible functions.
Human vaults are intracellular ribonucleoprotein particles believed to be involved in multidrug resistance. The complex consists of a major vault protein (MVP), two minor vault proteins (VPARP and TEP1), and several small untranslated RNA molecules. Three human vault RNA genes (HVG1-3) have been described, and a fourth was found in a homology search (HVG4). In the literature only the association of hvg1 with vaults was shown in vivo. However, in a yeast three-hybrid screen the association of hvg1, hvg2, and hvg4 with TEP1 was demonstrated. In this study we investigated the expression and vault association of different vault RNAs in a variety of cell lines, including pairs of drugsensitive and drug-resistant cells. HVG1-3 are expressed in all cell lines examined, however, none of the cell lines expressed HVG4. This probably is a consequence of the absence of essential external polymerase III promoter elements. The bulk of the vault RNA associated with vaults was hvg1. Interestingly, an increased amount of hvg3 was bound to vaults isolated from multidrug-resistant cell lines. Our findings suggest that vaults bind the RNA molecules with different affinities in different situations. The ratio in which the vault RNAs are associated with vaults might be of functional importance.
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