Therapeutic implications of novel mutations of the RFX6 gene associated with early-onset diabetes.

Identification of the genetic defect underlying early-onset diabetes is important for determining the specific diabetes subtype, which would then permit appropriate treatment and accurate assessment of recurrence risk in offspring. Given the extensive genetic and clinical heterogeneity of the disease, high-throughput sequencing might provide additional diagnostic potential when Sanger sequencing is ineffective. Our aim was to develop a targeted next-generation assay able to detect mutations in several genes involved in glucose metabolism. All 13 known MODY genes, genes identified from a genome-wide linkage study or genome-wide association studies as increasing the risk of type 2 diabetes and genes causing diabetes in animal models, were included in the custom panel. We selected a total of 102 genes by performing a targeting re-sequencing in 30 patients negative for mutations in the GCK, HNF1α, HNF4α, HNF1ß and IPF1 genes at the Sanger sequencing analysis. Previously unidentified variants in the RFX6 gene were found in three patients and in two of them we also detected rare variants in WFS1 and ABCC8 genes. All patients showed a good therapeutic response to dipeptidyl peptidase-4 (DPP4) inhibitors. Our study reveals that next-generation sequencing provides a highly sensitive method for identification of variants in new causative genes of diabetes. This approach may help in understanding the molecular etiology of diabetes and in providing more personalized treatment for each genetic subtype.

[The role of podocyte damage in the pathogenesis of glomerulosclerosis and possible repair mechanisms]. / Ruolo del danno podocitario nella patogenesi della glomerulosclerosi e possibili meccanismi di riparazione.

Converging evidence suggests that damage to podocytes plays a key role in progression towards glomerulosclerosis, in particular as the primary cause of all forms of focal segmental glomerulosclerosis (FSGS), the most common glomerular disease leading to end-stage renal disease. Any damage occurring to the complex architecture of specialized proteins that constitute the podocyte foot processes, essential to the highly specialized functions of podocytes, leads inevitably to loss of function in the glomerular filtration barrier, and ultimately to proteinuria. Recent studies have also highlighted that a reduction of the podocyte number in a damaged glomerulus is a critical factor for the development of proteinuria and glomerulosclerosis. As long as the podocyte loss is limited, restitution or repair is possible, which shows that the glomerular architecture can be remodeled. However, mature podocytes have limited capacity to divide and display all the phenotypic and functional features of highly specialized, terminally differentiated cells. A potential mechanism for podocyte replacement might be stem-cell-based regeneration, since it has been established that the developmental source of podocytes are resident renal progenitors. Podocyte damage could then be potentially repaired by a stem cell population resident in the kidney.

[The role of endothelial progenitor cells in renal disease]. / Ruolo dei progenitori endoteliali nelle malattie renali.

Recent evidence suggests that injury to the renal vasculature may play an important role in the pathogenesis of both chronic and acute ischemic kidney injury. Early alterations in peritubular capillary blood flow during reperfusion have been documented and associated with loss of normal endothelial cell function. In addition, ischemia induces alterations in endothelial cells that may promote inflammation and procoagulant activity, thus contributing to vascular congestion. Reduction of the microvasculature density increases hypoxia-mediated fibrosis and alters proper hemodynamics, which may lead to hypertension. This may play a critical role in the progression of chronic kidney disease following initial recovery from ischemia/reperfusion-induced acute kidney injury. The turnover and replacement of endothelial cells is therefore an important mechanism in the maintenance of vascular integrity also in the kidney. It is becoming clear that impaired vascular repair mechanisms as a result of a reduced number and/or impaired function of endothelial progenitor cells may contribute to renal disease. Moreover, investigators have begun to identify potential mechanisms responsible for the loss of function of endothelial progenitors in renal disease. In allografts, persistent injury results in excessive turnover of graft vascular endothelial cells. Moreover, chronic damage elicits a response that is associated with the recruitment of both leukocytes and endothelial progenitors, facilitating an overlapping process of inflammation and angiogenesis. In conclusion, angiogenesis and endothelial cell turnover play a pivotal role in renal disease and allograft rejection. Manipulation of these processes might have important implications for the development of novel therapeutic strategies in the near future.

Methimazole inhibits CXC chemokine ligand 10 secretion in human thyrocytes.

CXC chemokine ligand 10 (CXCL10) plays a pivotal role in the self-perpetuation of the inflammatory processes in patients with autoimmune thyroid disease. Treatment with methimazole (MMI) reduces serum CXCL10 in patients with Graves' disease. In isolated human thyrocytes, tumor necrosis factor (TNF)alpha demonstrates a potent synergistic effect on interferon (IFN)gamma-induced CXCL10 secretion. We investigated the mechanism underlying the synergism between IFNgamma and TNFalpha and the effect of MMI on CXCL10 secretion in human thyrocytes. A peroxisome proliferator-activated receptor gamma agonist, rosiglitazone (RGZ), a known inhibitor of T helper 1 (Th1)-mediated responses, was also studied for comparison. Experiments were carried out in human thyrocytes isolated from internodular parenchyma of thyroid tissues derived from patients who had undergone surgery for multinodular goiter. ELISA was used to measure CXCL10 levels in culture supernatant. Flow cytometry was used to assess IFNgamma membrane receptor expression. Specific mRNA analysis was performed by Taqman real-time PCR. Immunofluorescence was performed to detect nuclear translocation of nuclear factor-kappaB (NF-kappaB). In human thyrocytes, the synergistic effect of TNFalpha with IFNgamma on CXCL10 secretion is due to the upregulation of IFNgamma receptor expression. MMI decreased cytokine-induced CXCL10 secretion by reducing TNFalpha-induced upregulation of the IFNgamma receptor. RGZ decreased the cytokine-induced CXCL10 secretion by impairing NF-kappaB translocation, without affecting IFNgamma receptor. MMI and RGZ targeted thyrocytes with the same pharmacological potency, likely acting throughout different mechanisms. Targeting T helper 1-mediated autoimmune thyroid disease with drugs that impair different intracellular pathways could be a novel pharmacological tool.

[Chemokines: possible therapeutic targets and useful clinical parameters in renal transplantation]. / Le chemochine nel trapianto renale: possibili bersagli terapeutici e nuovi parametri clinici.

Chemokines are a family of small, structurally related cytokines that regulate trafficking of different subsets of leukocytes, thus critically regulating inflammation. The chemokine system influences allograft biology at 3 main levels: 1) the process of ischemia-reperfusion injury, 2) the induction of transplant tolerance, and 3) the pathogenesis of acute rejection and chronic allograft nephropathy. Accordingly, following ischemia/reperfusion in a rat model, CXCR2 produced at the graft level attracts and activates granulocytes, which in turn promotes graft damage. Moreover, in some experimental models CCR4 recruits T regulatory cells and mediates transplant tolerance. Furthermore, the discovery of the involvement of CXCR3 in the induction of the alloresponse to transplant suggests that this chemokine receptor might represent an important target for treatment of both acute rejection and chronic allograft nephropathy. Indeed, CXCR3 ligands play a pivotal role in the initiation and amplification of host alloresponses and also alter vascular cell functions, which explains their critical role not only in the development of acute rejection, but also in the pathogenesis of chronic allograft nephropathy, where both immune- and nonimmune- mediated mechanisms are involved. Finally, we have recently demonstrated that the pretransplant serum level of the CXCR3 ligand IP-10/CXCL10 is a clinically useful parameter for the identification of subjects with a high risk of acute rejection, chronic allograft nephropathy, and graft failure. This simple test could contribute to the prevention of acute rejections and the individualization of immunosuppressive therapies.

Pharmacological modulation of stem cell function.

The discovery of stem cells (SC) has shed new light on the understanding of mechanisms responsible for ischemic and degenerative disorders, and opened a new field for regenerative medicine. Furthermore, dysregulation of SC self-renewal and their transformation seem to be involved also in the development of cancer, suggesting that pharmacological treatment devoted to regulate SC genomic and phenotypic functions might represent a potential new strategy even for the treatment of neoplastic disorders. SC display a promiscuous set of transcription factors and an open chromatin structure which are required to maintain their multipotentiality, while they are progressively quenched during differentiation into specific multiple lineages. The mechanisms that govern stem cell fate decisions are under tight control but remain potentially alterable. Recent studies have shown that several currently used drugs such as colony stimulating factors, statins, angiotensin-II receptor antagonists/ACE-inhibitors, Erythropoietin, nitric oxide donors, estrogens and glitazones, have modulatory activity on SC functions. These drugs mostly enhance SC survival and mobilization. Furthermore, a series of new pharmacological agents such as the chemokine receptor antagonist AMD3100, glycogen synthase kinase-3 (GSK-3) inhibitors and histone deacetylase inhibitors (HDACi), that modulate the growth, differentiation and mobilization of SC, have been recently discovered and are currently under evaluation in both in vivo experimental models and preliminary clinical trials. Thus, modulation of SC properties through pharmacological treatment represents a new field of investigation which may lead to the development of novel strategies for the treatment not only of ischemic and degenerative disorders, but also of cancer.

Some protein tyrosine phosphatases target in part to lipid rafts and interact with caveolin-1.

A profile-based search of the SWISS-PROT database reveals that most protein tyrosine phosphatases (PTPs) contain at least one caveolin-1-binding motif. To ascertain if the presence of caveolin-binding motif(s) in PTPs corresponds to their actual localization in caveolin-1-enriched membrane fractions, we performed subcellular fractionating experiments. We found that all tested PTPs (PTP1B, PTP1C, SHPTP2, PTEN, and LAR) are actually localized in caveolin-enriched membrane fractions, despite their distribution in other subcellular sites, too. More than 1/2 of LAR and about 1/4 of SHPTP2 and PTP-1C are localized in caveolin-enriched membrane fractions whereas, in these fractions, PTP-1B and PTEN are poorly concentrated. Co-immunoprecipitation experiments with antibodies specific for each tested PTP demonstrated that all five phosphatases form molecular complexes with caveolin-1 in vivo. Collectively, our findings propose that particular PTPs could perform some of their cellular actions or are regulated by recruitment into caveolin-enriched membrane fractions.