Umbilical cord mesenchymal stromal cells transplantation delays the onset of hyperglycemia in the RIP-B7.1 mouse model of experimental autoimmune diabetes through multiple immunosuppressive and anti-inflammatory responses.

Type 1 diabetes mellitus (T1DM) is an autoimmune disorder specifically targeting pancreatic islet beta cells. Despite many efforts focused on identifying new therapies able to counteract this autoimmune attack and/or stimulate beta cells regeneration, TD1M remains without effective clinical treatments providing no clear advantages over the conventional treatment with insulin. We previously postulated that both the inflammatory and immune responses and beta cell survival/regeneration must be simultaneously targeted to blunt the progression of disease. Umbilical cord-derived mesenchymal stromal cells (UC-MSC) exhibit anti-inflammatory, trophic, immunomodulatory and regenerative properties and have shown some beneficial yet controversial effects in clinical trials for T1DM. In order to clarify conflicting results, we herein dissected the cellular and molecular events derived from UC-MSC intraperitoneal administration (i.p.) in the RIP-B7.1 mouse model of experimental autoimmune diabetes. Intraperitoneal (i.p.) transplantation of heterologous mouse UC-MSC delayed the onset of diabetes in RIP-B7.1 mice. Importantly, UC-MSC i. p. transplantation led to a strong peritoneal recruitment of myeloid-derived suppressor cells (MDSC) followed by multiple T-, B- and myeloid cells immunosuppressive responses in peritoneal fluid cells, spleen, pancreatic lymph nodes and the pancreas, which displayed significantly reduced insulitis and pancreatic infiltration of T and B Cells and pro-inflammatory macrophages. Altogether, these results suggest that UC-MSC i. p. transplantation can block or delay the development of hyperglycemia through suppression of inflammation and the immune attack.

Diagnostic difficulties in glucokinase hyperinsulinism.

Glucokinase hyperinsulinism is a rare variant of congenital hyperinsulinism caused by activating mutations in the glucokinase gene and has been reported so far to be a result of overactivity of glucokinase within the pancreatic beta-cell. Here we report on a new patient with difficulties to diagnose persistent hyperinsulinism and discuss diagnostic procedures of this as well as the other reported individuals. After neonatal hypoglycemia, the patient was reevaluated at the age of 3 years for developmental delay. Morning glucose after overnight fast was 2.5-3.6 mmol/l. Fasting tests revealed supressed insulin secretion at the end of fasting (1.4-14.5 pmol/l). In addition, diagnostic data of the patients reported so far were reviewed. A novel heterozygous missense mutation in exon 10 c.1354G>C (p.Val452Leu) was found and functional studies confirmed the activating mutation. There was no single consistent diagnostic criterion found for our patient and glucokinase hyperinsulinism individuals in general. Often at the time of hypoglycemia low insulin levels were found. Therefore insulin concentrations at hypoglycemia, or during fasting test as well as reactive hypoglycemia after an oral glucose tolerance test were not conclusive for all patients. A glucose lowering effect in extra-pancreatic tissues independent from hyperinsulinism that results in diagnostic difficulties may contribute to underestimation of glucokinase hyperinsulinism. Mutational analysis of the GCK-gene should be performed in all individuals with unclear episodes of hypoglycemia even without documented hyperinsulinism during hypoglycemia. Delay of diagnosis might result in mental handicap of the affected individuals.

Hiperinsulinismo monogénico / Monogenic hyperinsulinism

El término hiperinsulinismo monogénico se refiere a casos de hiperinsulinemia causados por mutaciones en un solo gen. Los pacientes presentan hipoglucemias de ayuno recurrentes, niveles inadecuados de insulina e incremento de la glucemia tras la administración de glucagón endovenoso. Además, no existe cetonemia, cetonuria ni acidosis. La principal causa de este cuadro clínico son las canelopatías, en las que el hiperinsulinismo está producido por alteraciones estructurales de los canales de potasio dependientes del ATP como consecuencia de mutaciones en el receptor de la sulfonilurea 1 (SUR1) o en el rectifi cador interno de los canales de potasio (Kir6.2). La segunda causa más común es el síndrome de hiperinsulinismo-hiperamonemia, originado por mutaciones activadoras de la enzima glutamato deshidrogenasa (GDH). Este síndrome se caracteriza por cuadros de hipoglucemia hiperinsulinémica con niveles elevados de amonio, que pueden ser provocados por la ingestión de una comida rica en proteínas. Otra causa de hiperinsulinismo monogénico es el hiperinsulinismo inducido por mutaciones activadoras en el gen de la glucocinasa (GGK). Finalmente, debe incluirse también la mutación en la enzima mitocondrial 3-hidroxiacil-CoA deshidrogenasa de cadena corta (SCHAD), que cataliza el tercero de los cuatro pasos de la oxidación de los ácidos grasos en la mitocondria

The term monogenic hyperinsulinism refers to cases of hyperinsulinism caused by mutations in a single gene. The affected patients show recurrent fasting hypoglycemia, inadequate serum insulin levels, and an increase in plasma glucose levels following the administration of intravenous glucagon. In addition, there is an absence of ketonemia, ketonuria and acidosis. The main causes of these syndromes are channelopathies, in which hyperinsulinism is caused by structural changes in the ATP-sensitive potassium channels due to mutations in sulfonylurea receptor 1 (SUR1) or in Kir6.2, the pre-forming subunit of this channel. The second most frequent cause is the hyperinsulinism/hyperammonemia syndrome, caused by activating mutations of the glutamate dehydrogenase (GDH) enzyme. This syndrome is characterized by episodes of hypoglycemia with hyperinsulinism and elevated levels of ammonium, which can be triggered by the ingestion of a protein- rich meal. Monogenic hyperinsulinism can also be induced by activating mutations of the glucokinase gene. Finally, mutations of mitochondrial short-chain 3-hydroxyacyl-coenzyme A dehydrogenase (SCHAD), which catalyses the third of the four steps in mitochondrial fatty acid oxidation, should also be included