BackgroundPancreatic islets are exposed to strong pro-apoptotic stimuli: inflammation and hyperglycemia, during the progression of the autoimmune diabetes (T1D). We found that the Cdk11(Cyclin Dependent Kinase 11) is downregulated by inflammation in the T1D prone NOD (non-obese diabetic) mouse model. The aim of this study is to determine the role of CDK11 in the pathogenesis of T1D and to assess the hierarchical relationship between CDK11 and Cyclin D3 in beta cell viability, since Cyclin D3, a natural ligand for CDK11, promotes beta cell viability and fitness in front of glucose.MethodsWe studied T1D pathogenesis in NOD mice hemideficient for CDK11 (N-HTZ), and, in N-HTZ deficient for Cyclin D3 (K11HTZ-D3KO), in comparison to their respective controls (N-WT and K11WT-D3KO). Moreover, we exposed pancreatic islets to either pro-inflammatory cytokines in the presence of increasing glucose concentrations, or Thapsigargin, an Endoplasmic Reticulum (ER)-stress inducing agent, and assessed apoptotic events. The expression of key ER-stress markers (Chop, Atf4 and Bip) was also determined.ResultsN-HTZ mice were significantly protected against T1D, and NS-HTZ pancreatic islets exhibited an impaired sensitivity to cytokine-induced apoptosis, regardless of glucose concentration. However, thapsigargin-induced apoptosis was not altered. Furthermore, CDK11 hemideficiency did not attenuate the exacerbation of T1D caused by Cyclin D3 deficiency.ConclusionsThis study is the first to report that CDK11 is repressed in T1D as a protection mechanism against inflammation-induced apoptosis and suggests that CDK11 lies upstream Cyclin D3 signaling. We unveil the CDK11/Cyclin D3 tandem as a new potential intervention target in T1D.
Autoimmune diabetes (T1D) is caused by the immune-mediated destruction of insulin-producing beta cells in the pancreas leading to hyperglycemia. Apoptosis is the main mechanism responsible for beta cell demise, including Fas-receptor engagement and Perforin release as essential death executers. However, the chronic inflammatory milieu pervading pancreatic islets prior to diabetes onset, alters beta cells function and primes beta cells for apoptosis long before the debut of the disease. To identify those genes that are targeted by inflammation and are causally related to beta cell fitness and viability we have used the microarray technology. We have identified several candidate genes being downregulated by inflammation, one of this genes is Cdk11, a cyclin-dependent kinase which is involved in transcription (CDK11p130), mitosis and apoptosis (CDK11p58). L-type cyclins are the partners for Cdk11p130, and Cyclin D3 is the partner of CDK11p58. The Cdk11 gene, when is transcribed, generates a single mRNA form, that can be translated either into CDK11p130 or CDK11p58 by a differential IRES (Internal Ribosome Entry Site) usage, being CDK11p58 only expressed during mitosis, while CDK11p130is expressed during all cell cycle phases. We have addressed the role of CDK11 in autoimmune diabetes using the T1D-prone NOD mouse model hemideficient in CDK11, since the CDK11 null mutation is embryonically lethal. First of all, we have confirmed the effect of inflammation on Cdk11 mRNA expression in islet cells by submitting NODSCID mice to adoptive transfer of increasing amounts of diabetogenic NOD splenocytes, and, observed that Cdk11 expression in islet endocrine cells is downregulated by inflammation in a dose-response dependent manner.
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