Sentrin is a ubiquitin-like molecule that has been shown to interact with the death domains of Fas and tumor necrosis factor receptor 1 (TNFR1), PML, Rad51, Rad52, and RanGAP1. We have reported previously that sentrin can be conjugated to other proteins in a manner analogous to protein ubiquitination (Kamitani, T., Nguyen, H. P., and Yeh, E. T. H. (1997) J. Biol. Chem. 272, 14001-14004). Furthermore, the conserved C-terminal Gly-Gly residues are required for sentrinization to occur. To identify enzymes which play a role in sentrinization, the yeast two-hybrid system was used to screen a human placenta cDNA library using sentrin as bait. A strong positive interacting clone was found to contain a cDNA insert encoding the ubiquitin-conjugating enzyme, Ubc9. The interaction between sentrin and Ubc9 required the ubiquitin domain and the C-terminal GlyGly residues of sentrin. This interaction appears to be specific because sentrin could only interact weakly with UbcH5B, but could not interact with HHR6B, UbcH6 nor E2-EPF. In vitro translated sentrin could be precipitated by a GST-Ubc9 fusion protein, but not by glutathione S-transferase. A -mercaptoethanol-sensitive Ubc9-sentrin conjugate could also be identified in the in vitro binding assay. Substitution of the conserved cysteine residue of Ubc9 by serine abolished the formation of the Ubc9-sentrin conjugate. Taken together, Ubc9 is a strong candidate to be the key conjugating enzyme in the sentrinization pathway.Sentrin is a 101-amino acid ubiquitin-like protein that interacts with the death domains of Fas and TNFR1 1 (1), with PML, a tumor suppressor implicated in the pathogenesis of promyelocytic leukemia (2), with Rad51 and Rad52, proteins that are involved in repairing double-stranded DNA breaks (3), and with RanGAP1, a GTPase-activating protein that is critically involved in nuclear protein transport (4,5). Using the COS cell expression system, we have shown that sentrin can be conjugated to other proteins in a manner analogous to protein ubiquitination (6). Moreover, sentrinized proteins appear to reside in the nucleus. We have also shown that the C-terminal four amino acids of sentrin, His-Ser-Thr-Val, were efficiently cleaved to allow the conjugation of sentrin to other proteins via the conserved Gly 97 residue. Thus, the biochemistry of sentrinization pathway appears to be remarkably similar to that of the ubiquitination pathway.Conjugation of ubiquitin to its target protein requires the initial activation of the conserved C-terminal Gly residue catalyzed by a specific ubiquitin-activating enzyme, E1 (7-11). An intermediate, ubiquitin adenylate, is formed by displacement of PP i from ATP and ubiquitin adenylate is then transferred to a thiol site in E1 with release of AMP. Through transacylation, ubiquitin is transferred to a ubiquitin-conjugating enzyme, E2, to form another thiol ester bond. Finally, ubiquitin is transferred from E2 to its target protein through an isopeptide linkage with the ⑀-amino group of the Lys residue of the target protein. The tr...
Physical and Functional Interaction between Myeloid Cell Leukemia 1 Protein (MCL1) and Fortilin
Myeloid cell leukemia 1 protein (MCL1) is an antiapoptotic protein that is structurally related to Bcl-2. Unlike other Bcl-2 family proteins that are constitutively expressed, MCL1 is inducibly expressed in cells that are recently exposed to growth and differentiation stimuli. Here, we report the identification of fortilin as a novel MCL1-interacting protein by screening of a yeast two-hybrid library with MCL1 as bait. Fortilin specifically interacted with MCL1 both in vitro and in vivo. The intracellular localization of fortilin was predominantly nuclear and identical to that of MCL1, as shown by immunostaining and confocal microscopy analysis. Fortilin, like MCL1, was rapidly inducible in serum-stimulated human aortic vascular smooth muscle cells. Although the depletion of intracellular fortilin by small interfering RNA (siRNA) against fortilin (siRNAfortilin) did not affect intracellular MCL1 level, the depletion of intracellular MCL1 by siRNA-MCL1 was associated with the significant reduction of the fortilin protein level, without affecting the fortilin transcript numbers. In addition, a pulse-chase experiment showed that the depletion of MCL1 by siRNA-MCL1 was associated with the rapid degradation of fortilin protein, which was found quite stable in the presence of MCL1. Furthermore, the half-life of fortilin R21A , a point mutant of fortilin lacking the binding to MCL1, was significantly shorter than that of wild-type fortilin as shown by a pulse-chase experiment. These data suggest that MCL1, in addition to being an anti-apoptotic molecule, serves as a chaperone of fortilin, binding and stabilizing fortilin in vivo. Taken together with our previous observation that fortilin overexpression prevents cells from undergoing apoptosis (Li, F., Zhang, D., and Fujise, K. (2001) J. Biol. Chem. 276, 47542-47549), it is likely that MCL1, an anti-apoptotic protein inducible by growth and differentiation stimuli, stabilizes another anti-apoptotic protein fortilin maximizing the prosurvival environment in cells.
Morelloflavone, a biflavonoid extracted from Garcinia dulcis, has shown antioxidative, antiviral, and anti-inflammatory properties. However, the function and the mechanism of this compound in cancer treatment and tumor angiogenesis have not been elucidated to date. In this study, we postulated that morelloflavone might have the ability to inhibit angiogenesis, the pivotal step in tumor growth, invasiveness, and metastasis. We showed that morelloflavone could inhibit vascular endothelial growth factor (VEGF)-induced cell proliferation, migration, invasion, and capillary-like tube formation of primary cultured human umbilical vascular endothelial cells in a dose-dependent manner. Morelloflavone effectively inhibited microvessel sprouting of endothelial cells in the mouse aortic ring assay and the formation of new blood microvessels induced by VEGF in the mouse Matrigel plug assay. Furthermore, morelloflavone inhibited tumor growth and tumor angiogenesis of prostate cancer cells (PC-3) in xenograft mouse tumor model in vivo, suggesting that morelloflavone inhibited tumorigenesis by targeting angiogenesis. To understand the underlying mechanism of morelloflavone on the inhibitory effect of tumor growth and angiogenesis, we showed that morelloflavone could inhibit the activation of both RhoA and Rac1 GTPases but have little effect on the activation of Cdc42 GTPase. Additionally, morelloflavone inhibited the phosphorylation and activation of Raf/mitogen-activated protein kinase/extracellular signalregulated kinase (ERK) kinase/ERK pathway kinases without affecting VEGF receptor 2 activity. Together, our results indicate that morelloflavone exerts antiangiogenic action by targeting the activation of Rho-GTPases and ERK signaling pathways. These findings are the first to reveal the novel functions of morelloflavone in tumor angiogenesis and its molecular basis for the anticancer action. [Cancer Res 2009;69(2):518-25]
Fortilin, a 172-amino-acid polypeptide present both in the cytosol and nucleus, possesses potent anti-apoptotic activity. Although fortilin is known to bind Ca2+, the biochemistry and biological significance of such an interaction remains unknown. In the present study we report that fortilin must bind Ca2+ in order to protect cells against Ca2+-dependent apoptosis. Using a standard Ca2+-overlay assay, we first validated that full-length fortilin binds Ca2+ and showed that the N-terminus (amino acids 1-72) is required for its Ca2+-binding. We then used flow dialysis and CD spectropolarimetry assays to demonstrate that fortilin binds Ca2+ with a dissociation constant (Kd) of approx. 10 mM and that the binding of fortilin to Ca2+ induces a significant change in the secondary structure of fortilin. In order to evaluate the impact of the binding of fortilin to Ca2+ in vivo, we measured intracellular Ca2+ levels upon thapsigargin challenge and found that the lack of fortilin in the cell results in the exaggerated elevation of intracellular Ca2+ in the cell. We then tested various point mutants of fortilin for their Ca2+ binding and identified fortilin(E58A/E60A) to be a double-point mutant of fortilin lacking the ability of Ca2+-binding. We then found that wild-type fortilin, but not fortilin(E58A/E60A), protected cells against thapsigargin-induced apoptosis, suggesting that the binding of fortilin to Ca2+ is required for fortilin to protect cells against Ca2+-dependent apoptosis. Together, these results suggest that fortilin is an intracellular Ca2+ scavenger, protecting cells against Ca2+-dependent apoptosis by binding and sequestering Ca2+ from the downstream Ca2+-dependent apoptotic pathways.
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