Calcium, calcium-sensing receptor and colon cancer |
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Authors: | Whitfield James F |
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Affiliation: | Institute for Biological Sciences, National Research Council of Canada, Building M-54, Montreal Road Campus, Ottawa, Ont. Canada K1A 0R6. pthosteo@rogers.com |
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Abstract: | There is much evidence that dietary Ca(2+) loading reduces colon cell proliferation and carcinogenesis in humans and rodents, but during carcinogenesis it becomes ineffective or even tumor-promoting. We are beginning to see how Ca(2+) balances the continuous massive cell production in colon crypts by driving the terminal differentiation and eventually the apoptosis of the cells mainly on the mucosal surface, and how this Ca(2+) control is lost during colon carcinogenesis. The rapid proliferation of the transit-amplifying (TA) progeny of the colon stem cells is driven by the so-called "Wnt" signaling mechanism, which involves the stimulation of proliferogenic genes such as those for c-Myc and cyclin D1 and the silencing of the gene for the cell cycle-stopping p21(Cip1/WAF1) protein by nuclear beta-catenin*Tcf-4 complexes. TA cells avoid mitotic damage and premature apoptosis by expressing the protein survivin. It appears that TA cell cycling stops and terminal differentiation starts when the cells reach a higher level in the crypt where there is enough lumenal Ca(2+) to stimulate the expression and activation of CaSRs (Ca(2+)-sensing receptors), the signals from which stimulate the expression of E-cadherin. Along with this, the APC (adenomatous polyposis coli) protein appears and some of it enters the nucleus. There it makes the TA cells susceptible to the eventual apoptotic balancing by stopping survivin expression and the beta-catenin*Tcf-4 complex from driving further cell cycling by releasing beta-catenin from the nucleus, and delivering it to cytoplasmic APC*axin*GSK-3beta complexes for ultimate proteasomal destruction. Cytoplasmic beta-catenin is then prevented from returning to the nucleus by either being intercepted and destroyed by APC*axin*GSK-3beta complexes or locked by the emerging E-cadherin into membrane adherens junctions which tie the cell into the sheet of proliferatively shut-down cells with APC-dependent cytoskeletons moving to the mouth of the crypt and onto the flat mucosal surface. A common first step in sporadic colon carcinogenesis is the loss of functional APC which disorients upwardly directed migration and causes the retention of nuclear beta-catenin and proliferogenic beta-catenin*Tcf-4 complexes as well as genomic instability. Eventually the balance between cell proliferation and terminal differentiation and death is radically tipped in favour of proliferation by the appearance of apoptosis-resistant, survivin-expressing clones of Ca(2+)-insensitive cells which are locked into the proliferative, mutation-prone mode because of CaSR-disabling gene mutations which prevent the stimulation of E-cadherin expression and terminal differentiation. |
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Keywords: | APC, adenomatous polyposis coli AOM, azoxymethane β-TrCP-E3 ligase, β-transducin repeat-containing protein-E3 ubiquitin ligase CaMK II and IV, Ca2+ • calmodulin-activated protein kinases II and IV CaSR, Ca2+-sensing receptor cdk, cyclin-dependent protein kinases CKI, casein kinase I CpG island, genomic islands with 300–30,000 CG dinucleotides Fzp, Wnt protein’s frizzled receptor GSK-3β, glycogen synthase kinase-3β LRP, low-density lipoprotein receptor-related protein p21Cip1/WAF1p27Kip1, 21 kDa protein inhibitors of cyclin-dependent protein kinases TA cell, transit-amplifying cell Tcf-4, T-cell factor-4 TP53, 53 kDa tumor-suppressor protein TRPV6, transit receptor potential cation channel V subfamily 6 Wnt, wingless-int mammalian signal proteins |
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