Vincenzo Flati

TRIM8/GERP RING finger protein interacts with SOCS-1.

Members of the suppressor of cytokine signaling (SOCS) family of signaling molecules regulate the activation of cytokine signaling. Experimental evidence indicates that SOCS expression is induced by cytokines and pro-inflammatory stimuli and is controlled at both the transcriptional and post-transcriptional levels. SOCS proteins are unstable and seem to be rapidly degraded by proteasomal pathways. However, the mechanisms by which SOCS protein levels are regulated remain unclear. Here, we show that TRIM8/GERP, a RING finger protein, interacts with SOCS-1 in vitro andin vivo. TRIM8/GERP, previously identified as a new member of the family of proteins containing a tripartite motif (TRIM), is a 551-amino acid RING finger protein conserved across species. TRIM8/GERP expression can be induced by interferon-γ in epithelial and lymphoid cells. Coexpression of TRIM8/GERP with SOCS-1 decreases SOCS-1 protein stability and levels. Functionally, expression of TRIM8/GERP decreases the repression of interferon-γ signaling mediated by SOCS-1. These data suggest that TRIM8/GERP may be a regulator of SOCS-1 function.

Morphometric changes induced by amino acid supplementation in skeletal and cardiac muscles of old mice.

Aging is associated with progressive structural disorganization of muscular and cardiac fibers, decreasing functional capacity, and increased rates of disease and death. Aging is also characterized by disturbances in protein synthesis with impaired cellular organelle functions, particularly in the mitochondria. The availability of amino acids is a key factor for the overall metabolism of mammals and exogenous supplements of amino acid mixtures (AAm) could be a valid therapeutic strategy to improve quality of life, avoiding malnutrition and muscle wasting in the elderly. We investigated the morphoquantitative effects of long-term AAm supplementation on the mitochondria and sarcomeres (by electron microscope) and on collagen matrix deposition (by histologic techniques) in both skeletal and cardiac muscles of young and aged mice. Our data showed that old animals have fewer mitochondria and massive fibrosis in both muscles. Long-term AAm supplementation increased the number and volume of mitochondria and sarcomeres and decreased fibrosis in both skeletal muscle and hearts in old rats. These findings indicate that AAm restored muscular morphologic parameters and probably improved the mechanical performance of these organs.

Mechanisms of initiation and progression of intestinal fibrosis in IBD

Abstract Intestinal fibrosis is a common complication of the inflammatory bowel diseases (IBDs). It becomes clinically apparent in >30% of patients with Crohn’s disease (CD) and in about 5% with ulcerative colitis (UC). Fibrosis is a consequence of local chronic inflammation and is characterized by excessive extracellular matrix (ECM) protein deposition. ECM is produced by activated myofibroblasts, which are modulated by both, profibrotic and antifibrotic factors. Fibrosis depends on the balance between the production and degradation of ECM proteins. This equilibrium can be impacted by a complex and dynamic interaction between profibrotic and antifibrotic mediators. Despite the major therapeutic advances in the treatment of active inflammation in IBD over the past two decades, the incidence of intestinal strictures in CD has not significantly changed as the current anti-inflammatory therapies neither prevent nor reverse the established fibrosis and strictures. This implies that control of intestinal inflammation does not necessarily affect the associated fibrotic process. The conventional view that intestinal fibrosis is an inevitable and irreversible process in patients with IBD is also gradually changing in light of an improved understanding of the cellular and molecular mechanisms that underline the pathogenesis of fibrosis. Comprehension of the mechanisms of intestinal fibrosis is thus vital and may pave the way for the developments of antifibrotic agents and new therapeutic approaches in IBD.

Intracellular Mechanisms of Metabolism Regulation: The Role of Signaling via the Mammalian Target of Rapamycin Pathway and Other Routes

The development of diabetes mellitus is the consequence of defects in the action of insulin in skeletal muscles and adipose tissue other than pancreas and liver defects. Insulin action defects are mostly the results of defects of the insulin intracellular signaling transduction pathway. This review summarizes the main mechanisms involved in insulin signaling and possible intracellular defects that lead to insulin resistance. We also report preliminary experimental data that suggest the existence of intracellular alternatives to insulin metabolic pathways stimulated by nutrients such as amino acids (AAs). Indeed, we found that oral supplements with AAs stimulated both glucose transporter-4 and protein synthesis through independent insulin signals in rat hearts. Evidence suggests that the mammalian target of rapamycin and/or other molecules could be involved in this insulin-independent metabolic pathway. This hypothesis suggests the presence of an ancestral metabolic pathway in eukaryotic cells that is not active when insulin intracellular signaling is efficient but can be activated by alternative stimuli, such as AAs, when insulin signaling is impaired. Our observations provide molecular evidence that supports the use of anabolic nutrients such as AAs, together with standard therapies, to overcome insulin resistance syndrome.

Effects of treadmill exercise and training frequency on anabolic signaling pathways in the skeletal muscle of aged rats

Physical exercise is the most effective intervention against sarcopenia of aging; however, the cellular and molecular mechanisms mediating training-induced adaptations are not yet completely understood. Furthermore, it is unclear whether exercise training initiated late in life affects myocyte anabolic signaling in a dose-dependent manner. Hence, we sought to investigate the effects of treadmill exercise and training frequency on anabolic pathways, including insulin signaling, in the skeletal muscle of old rats. Aged (14-16-month-old) male Wistar rats were trained on a treadmill for 3 (EX3) or 5 days/week (EX5) during 8 weeks and compared with age-matched sedentary controls (SED). Four-month-old rats were used as young controls (YC). Protein expression levels of insulin receptor (IR), insulin receptor substrate 1 (IRS-1), activated (phosphorylated) mammalian target of rapamycin (p-mTOR) and glucose transporter GLUT4 were determined in quadriceps muscle extracts via immunoblotting. Mitochondrial cytochrome c oxidase (COX) activity was assessed by histochemical staining, while electron microscopy was employed to quantify the sarcomere volume (V(src)). Body weight (BW) increased, whereas muscle weight (MW) and V(src) decreased with age. EX5, but not EX3 increased MW and V(src), without affecting BW. The expression of IR and GLUT4 was higher in SED rats relative to the YC group. Conversely, protein levels of IRS-1 and p-mTOR as well as COX activity were reduced in advanced age. Compared with SED rats, EX3 animals displayed reduced IR expression and increased IRS-1 levels and COX activity. The expression of GLUT 4 and p-mTOR was unaffected by EX3. EX5 up-regulated IRS-1 and p-mTOR expression and COX activity, while decreasing GLUT4 levels, with no effect on IR expression. In summary, substantial impairments in muscle anabolic pathways, including insulin signaling, were detected in aged sedentary rats. These changes were ameliorated by exercise training, concomitant with improvements in muscle trophism. Benefits were more evident in rats trained for 5 days/week, suggesting that physical exercise initiated late in life affects anabolic signaling in a dose-dependent manner.

Oral Amino Acid Supplementation Counteracts Age-Induced Sarcopenia in Elderly Rats

We investigated the effects of a specific mixture of amino acid (AA) supplements on the adaptation changes induced by aging in the soleus muscle of rats. Male Wistar rats were divided into 3 groups (n = 5 each): young control (YO), 3 months of age; elderly control (EL), 18 months of age; and elderly orally supplemented with an AA mixture (EL-AA), 18 months of age, given as 0.1 g/kg per day in drinking water for 8 weeks. Myosin heavy chain (MHC) composition was analyzed in all muscles. The total fiber number and fiber cross-sectional area of types 1 and 2A fibers were also measured in immunostained sections of the soleus muscle. The ratios between the sarcomere volume (Vsar) and the total volume (Vtot) and single muscle fibers were studied by electron microscopy. The expression of total and phosphorylated serine/threonine protein kinase mammalian target of rapamycin (mTOR), a potent regulator of messenger RNA translation initiation, was also determined in all groups. Aging was associated with an overall shift toward the expression of a slower MHC phenotype, atrophy of fast and slow fibers, a significant decrease in Vtot/Vsar, and no changes in total fiber number. AA supplementation antagonized the effects of aging. A shift toward the expression of faster MHC isoforms was observed. Fiber atrophy appeared to be partly counteracted by the AA supplements; we noted an increase in cross-sectional area fibers and Vtot/Vsar in EL-AAs. Total and phosphorylated mTOR expression appeared to decrease in EL and was restored by the AA supplements. Collectively, these results suggest that aging-induced muscle adaptations can be partly restored by AA supplementation. An mTOR signal pathway may mediate the effects on fiber trophism.

Angiotensin receptor blockers improve insulin signaling and prevent microvascular rarefaction in the skeletal muscle of spontaneously hypertensive rats

Objective Spontaneously hypertensive rats are an example of an animal model of genetic hypertension with insulin resistance. The aim of this study was to investigate insulin signaling in the heart and in the skeletal muscle of spontaneously hypertensive rats, as well as to evaluate the effects of renin–angiotensin system blockade. Design and Methods We investigated eight untreated spontaneously hypertensive rats of 12 weeks of age and eight age-matched normotensive Wistar–Kyoto controls. In addition, eight spontaneously hypertensive rats were treated for 8 weeks with the angiotensin receptor blocker olmesartan, and eight spontaneously hypertensive rats with the angiotensin-converting enzyme inhibitor enalapril. The heart and a skeletal muscle (quadriceps femoris) were promptly dissected and frozen. Insulin signaling was evaluated by Western blot analysis of involved proteins; in addition, microvessel density was indirectly evaluated by immunohistochemistry. Results Blood pressure values were normalized by both olmesartan and enalapril. In the heart, no statistically significant difference in the expression of proteins involved in insulin signaling was observed between untreated spontaneously hypertensive rats and Wistar–Kyoto controls. On the contrary, in the skeletal muscle of untreated spontaneously hypertensive rats, we noted a significant reduction of insulin receptors, of insulin-receptor substrate-1, and of phosphorylated-mammalian target of rapamycin. The treatment with olmesartan normalized insulin signaling, including expression of glucose transporter-4, whereas the treatment with enalapril was ineffective for the insulin receptor and less effective than olmesartan on the insulin-receptor substrate-1, phosphorylated-mammalian target of rapamycin and glucose transporter-4. There was a significant reduction in microvessel density in the skeletal muscle of spontaneously hypertensive rats compared with Wistar–Kyoto controls, and this was completely prevented by both olmesartan and enalapril. Conclusion These results suggest that changes in insulin signaling occur in the skeletal muscle but not in the heart of untreated spontaneously hypertensive rats. In the skeletal muscle, insulin signaling was restored by olmesartan, whereas enalapril was less effective. Effective antihypertensive treatment with olmesartan or enalapril was associated with prevention of microvascular rarefaction.

Amino Acid Supplementation Counteracts Metabolic and Functional Damage in the Diabetic Rat Heart

We aimed to assess whether a specific mixture of amino acid (AA) supplements counteracts the metabolic and functional changes in the streptozotocin (STZ)-induced diabetic rat heart model. Adult male Wistar rats were divided into 6 groups (n = 10 each) and treated for 43 days: nondiabetic controls, nondiabetic rats given an AA mixture (0.1 g/kg per day), diabetic rats (induced with 65 mg/kg STZ given intraperitoneally), diabetic rats given AAs, diabetic rats given insulin (5 IU/day given subcutaneously), and diabetic rats given insulin plus AAs. During treatment, glycemia and insulinemia levels were measured in all groups. Changes in enzyme (reduced nicotinamide adenine dinucleotide-dehydrogenase, cytochrome c oxidase) activities and myosin heavy chain (MHC) composition were measured in the left ventricle. In 5 rats contractile function was assessed by measuring maximal shortening velocity of skinned ventricular trabeculae and the expression of translational regulator mammalian target of rapamycin (mTOR) was also found. STZ-induced diabetes was associated with reduced myocardial contractility, overall loss of oxidative capacity, a shift toward a slower MHC phenotype, and decreased mTOR tissue content. All of these changes appeared to be reversible with insulin. AA supplements partially restored the myocardial and oxidative dysfunction and also increased mTOR tissue content. The combination of insulin and AAs did not have a synergistic effect on either enzymatic or functional profiles. We conclude that AA supplements may contribute to restoring the oxidative and contractile dysfunction of diabetic rat hearts, probably through an mTOR-insulin independent mechanism.

Intracellular molecular effects of insulin resistance in patients with metabolic syndrome

Aim of the studyPatients with metabolic syndrome (MetS) have an increased risk of cardiovascular disease. Data obtained from muscle biopsies have demonstrated altered insulin signaling (IS) in patients with MetS. The IS regulates critical cell functions including molecular-regulated cellular metabolite fluxes, protein and energetic metabolism, cell proliferation and apoptosis with consequent regulation of cell life including endothelial homeostasis and blood coagulation. However, little is known about blood cell IS in MetS patients. The aim of this study was to develop a method to evaluate IS in peripheral lymphocytes to identify altered intracellular molecules in patients with MetS to use as risk biomarkers of vascular thrombosis.Patients and MethodsWe investigated 40 patients with MetS and 20 controls. MetS was defined according to guidelines from the US National Cholesterol Education Program Adult Treatment Panel III. Blood samples were taken from all participants. Total mononuclear cells were isolated from peripheral blood using density gradient centrifugation. IS molecules were evaluated using Western blot analysis followed by computer-assisted densitometer evaluation.ResultsLymphocytes of MetS patients showed a reduced mTOR expression (the mammalian target of rapamycin) which is a fundamental molecule of IS. Major impairment of IS was confirmed by reduced upstream and downstream mTOR molecules which regulate fundamental cells metabolic functions.ConclusionsIn patients with MetS, we found a reduction of mTOR and other mTOR-related molecules involved in insulin resistance, cell repair, coagulation and vasculogenesis. A reduced expression of mTOR may reflect an increased risk of vascular thrombosis.

New mutations and protein variants of NBS1 are identified in cancer cell lines

Alterations of the NBS1 gene are responsible for Nijmegen breakage syndrome (NBS), which is characterized by chromosomal instability, radiosensitivity, and cancer predisposition. NBS1 protein (Nibrin) is part of a molecular complex (NBS1– MRE11A–RAD50) that is functionally involved in DNA double‐strand–break repair. Defects in recombination or in repair mechanisms at the level of DNA breakage can lead to chromosomal aberrations, genetic instability, as well as cancer predisposition syndromes (i.e., NBS, ataxia‐telangiectasia, Bloom syndrome). In this study, we examined 20 cancer cell lines to evaluate the potential involvement of NBS1 in tumoral pathogenesis. Three different mutations, generating truncated or aberrant NBS1 transcripts, were identified at the level of NBS1 mRNA. In addition, two shorter NBS1 protein variants were detected in two cell lines. These data suggest a possible involvement of NBS1 in tumor development.