Truncated form of VACM-1/cul-5 with an extended 3' untranslated region stimulates cell growth via a MAPK-dependent pathway

New insights into the mechanism for VACM-1/cul5 expression in vascular tissue in vivo

Vasopressin-activated calcium-mobilizing (VACM-1)/cul5 is the least conserved member of a cullin protein family involved in the formation of E3-specific ligase complexes that are responsible for delivering the ubiquitin protein to their target substrate proteins selected for ubiquitin-dependent degradation. This chapter summarizes work to date that has focused on VACM-1/cul5's tissue-specific expression in vivo and on its potential role in the control of specific cellular signaling pathways in those structures. As mammalian cells may contain hundreds of E3 ligases, identification VACM-1/cul5 as a specific subunit of the system that is expressed in the endothelium and in collecting tubules, structures known for their control of cellular permeability, may have significant implications when designing studies to elucidate the mechanism of water conservation. For example, VACM-1/cul5 expression is affected by water deprivation in some tissues and there is a potential relationship between neddylated VACM-1/cul5 and aquaporins.

VACM-1/cul5 expression in vascular tissue in vivo is induced by water deprivation and its expression in vitro regulates aquaporin-1 concentrations

VACM-1, a cul5 gene product, when overexpressed in vitro, has an antiproliferative effect. In vivo, VACM-1/cul5 is present in tissues involved in the regulation of water balance. Neither proteins targeted for VACM-1/cul5-specific degradation nor factors that may regulate its expression in those tissues have been studied. To identify genes that may be misregulated by VACM-1 cDNA, we performed microarray analysis. Our results indicate that in cos-1 cells transfected with VACM-1 cDNA, mRNA levels for several genes, including AQP1, were decreased when compared to the control group. Our results also indicate that in cos-1 cells transfected with VACM-1 cDNA, endogenous AQP1 protein was decreased about 6-fold when compared to the controls. To test the hypothesis that VACM-1/cul5 may be regulated by conditions that compromise water homeostasis in vivo, we determined if 24 h of water deprivation affects VACM-1/cul5 levels or the effect of VACM-1/cul5 on AQP1. VACM-1 mRNA and protein levels were significantly higher in rat mesenteric arteries, skeletal muscle and the heart ventricle but not in the heart atrium from 24-h water-deprived rats when compared to the controls. Interestingly, 24 h of water deprivation increased modification of VACM-1 by an ubiquitin-like protein, Nedd8, essential for cullin-dependent E3 ligase activity. Although water deprivation did not significantly change AQP1 levels in the mesenteric arteries, AQP1 protein concentrations were inversely correlated with the ratio of the VACM-1 to Nedd8-modified VACM-1. These results suggest that VACM-1/cul5 may regulate endothelial AQP1 concentration both in vivo and in vitro.

Cullin 5 gene expression in the rat cerebral cortex and hippocampus following traumatic brain injury (TBI)

Cullin-5 (Cul-5), a member of the cullin gene family of scaffold proteins of E3 ubiquitin-ligase complexes, has a role in proteolysis and cell cycle regulation. We recently demonstrated that cul-5 mRNA is ubiquitously expressed in the central nervous system. The present study used quantitative real time polymerase chain reaction and western blotting to measure changes in cul-5 mRNA and Cul-5 protein expression, respectively, in the injured CNS in response to traumatic brain injury (TBI). cul-5 mRNA levels were significantly decreased in the ipsilateral rat cerebral cortex on Days 1 and 7, but not on Day 3 following TBI. In the ipsilateral hippocampus, cul-5 mRNA was significantly reduced on Day 1 after TBI. Cul-5 protein levels were significantly decreased in the ipsilateral rat cerebral cortex on Days 1-7 post-TBI while levels were significantly lower in the ipsilateral hippocampus on Days 3-7 post-TBI. Since Cul-5 is ubiquitously expressed in eukaryotic cells and is linked to proteasome-mediated protein degradation, it may have a role in CNS cell fate determination under conditions of traumatic stress.