Eileen M. Kasperek scite author profile

A necessary step in ubiquitin-dependent proteolysis is the addition of a polyubiquitin chain to the target protein. This ubiquitinated protein is degraded by a multisubunit complex known as the 26S proteasome. The polyubiquitin chain is probably not released until a late stage in the proteolysis by the proteasome. It is subsequently disassembled to yield functional ubiquitin monomers. Here we present evidence that a 93 kDa protein, isopeptidase T, has the properties expected for the enzyme which disassembles these branched polyubiquitin chains. Protein and cDNA sequencing revealed that isopeptidase T is a member of the ubiquitin specific protease family (UBP). Isopeptidase T disassembles branched polyubiquitin chains (linked by the G76-K48 isopeptide bond) by a sequential exo mechanism, starting at the proximal end of the chain (the proximal ubiquitin contains a free carboxyl-terminus). Isopeptidase T prefers to disassemble chains in which there is an intact and unblocked RGG sequence at the C-terminus of the proximal subunit. Rates of disassembly are reduced when G76 of the proximal ubiquitin is modified, for example, by ligation to substrate protein, by esterification, by replacement of the proximal glycine with alanine (G76A), or by truncation. Linear proubiquitin is only a poor substrate. Observed rates and specificity are consistent with isopeptidase T playing a major role in disassembly of polyubiquitin chains. The high discrimination against chains that are blocked or modified at the proximal end indicates that the enzyme acts after release of the chains from conjugated proteins or degradation intermediates. Thus, the proteolytic degradation signal is not disassembled by isopeptidase T before the ubiquitinated protein is degraded. These (and earlier) results suggest that UBP isozymes may exhibit significant substrate specificity, consistent with a role in the regulated catabolism of the polymeric ubiquitin, including the polyubiquitin protein degradation signal.

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Dissection of the Molecular Basis of pp60v-src Induced Gating of Connexin 43 Gap Junction Channels

Zhou

1999

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Suppression of gap-junctional communication by various protein kinases, growth factors, and oncogenes frequently correlates with enhanced mitogenesis. The oncogene v-src appears to cause acute closure of gap junction channels. Tyr265 in the COOH-terminal tail of connexin 43 (Cx43) has been implicated as a potential target of v-src, although v-src action has also been associated with changes in serine phosphorylation. We have investigated the mechanism of this acute regulation through mutagenesis of Cx43 expressed in Xenopus laevis oocyte pairs. Truncations of the COOH-terminal domain led to an almost complete loss of response of Cx43 to v-src, but this was restored by coexpression of the independent COOH-terminal polypeptide. This suggests a ball and chain gating mechanism, similar to the mechanism proposed for pH gating of Cx43, and K+ channel inactivation. Surprisingly, we found that v-src mediated gating of Cx43 did not require the tyrosine site, but did seem to depend on the presence of two potential SH3 binding domains and the mitogen-activated protein (MAP) kinase phosphorylation sites within them. Further point mutagenesis and pharmacological studies in normal rat kidney (NRK) cells implicated MAP kinase in the gating response to v-src, while the stable binding of v-src to Cx43 (in part mediated by SH3 domains) did not correlate with its ability to mediate channel closure. This suggests a common link between closure of gap junctions by v-src and other mitogens, such as EGF and lysophosphatidic acid (LPA).

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Structure and Function of Ubiquitin Conjugating Enzyme E2-25K: The Tail Is a Core-Dependent Activity Element

et al. 1997

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Individual members of the conserved family of ubiquitin conjugating enzymes (E2s) mediate the ubiquitination and turnover of specific substrates of the ubiquitin-dependent degradation pathway. E2 proteins have a highly conserved core domain of approximately 150 amino acids which contains the active-site Cys. Certain E2s have unique terminal extensions, which are thought to contribute to selective E2 function by interacting either with substrates or with trans-acting factors such as ubiquitin-protein ligases (E3s). We used the mammalian ubiquitin conjugating enzyme E2-25K in a biochemical test of this hypothesis. The properties of two truncated derivatives show that the 47-residue tail of E2-25K is necessary for three of the enzyme's characteristic properties: high activity in the synthesis of unanchored K48-linked polyubiquitin chains; resistance of the active-site Cys residue to alkylation; and an unusual discrimination against noncognate (nonmammalian) ubiquitin activating (E1) enzymes. However, the tail is not sufficient to generate these properties, as shown by the characteristics of a chimeric enzyme in which the tail of E2-25K was fused to the core domain of yeast UBC4. These and other results indicate that the specific biochemical function of the tail is strongly dependent upon unique features of the E2-25K core domain. Thus, divergent regions within the conserved core domains of E2 proteins may be highly significant for function. Expression of truncated E2-25K as a glutathione S-transferase (GST) fusion protein resulted in the apparent recovery of E2-25K-specific properties, including activity in chain synthesis. However, the catalytic mechanism utilized by the truncated fusion protein proved to be distinct from the mechanism utilized by the wild-type enzyme. The unexpected properties of the fusion protein were due to GST-induced dimerization. These results indicate the potential for self-association to modulate the polyubiquitin chain synthesis activities of E2 proteins, and indicate that caution should be applied in interpreting the activities of GST fusion proteins.

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Structure of Tetraubiquitin Shows How Multiubiquitin Chains Can Be Formed

Cook

Jeffrey

Kasperek

et al. 1994

Journal of Molecular Biology

144

146

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