Synthalin: a lost lesson for glucagon suppression in diabetes therapeutics.

OBJECTIVES: Within mammalian pancreatic islets, there are two major endocrine cell types, beta-cells which secrete insulin and alpha-cells which secrete glucagon. Whereas, insulin acts to lower circulating glucose, glucagon counters this by increasing circulating glucose via the mobilisation of glycogen. Synthalin A (Syn A) was the subject of much research in the 1920s and 1930s as a potential pancreatic alpha-cell toxin to block glucagon secretion. However, with the discovery of insulin and its lifesaving use in patients with diabetes, research on Syn-A was discontinued. KEY FINDINGS: This short review looks back on early studies performed with Syn A in animals and humans with diabetes. These are relevant today because both type 1 and type 2 diabetes are now recognised as states of not only insulin deficiency but also glucagon excess. SUMMARY: Lessons learned from this largely forgotten portfolio of work and therapeutic strategy aimed at limiting the number or function of islet alpha-cells might be worthy of reconsideration.

Vasopressin receptors in islets enhance glucose tolerance, pancreatic beta-cell secretory function, proliferation and survival.

Arginine vasopressin (AVP), a peptide secreted from the posterior pituitary, is chiefly regarded as a hormone involved in the regulation of body fluid balance and osmolality. However, recent evidence has revealed that posterior pituitary hormones can exert important actions on endocrine pancreatic function. In the present study, the presence of AVP receptors, namely Avpr1a (V1a), Avpr1b (V1b) and Avpr2 (V2) was demonstrated in murine islets as well as rodent BRIN BD11 and human 1.1B4 beta-cells. Further to this, AVP was shown to induce significant concentration-dependent (10-12 - 10-6 M) increases of insulin release from both rodent and human beta-cells, as well as mouse islets. Insulinotropic actions of AVP were completely annulled by specific V1a or V1b receptor antagonists, and partially abolished by an oxytocin receptor antagonist. In addition, beta-cell insulin secretory actions of AVP were augmented by both IBMX (200 µM) and KCl (30 mM) and linked to significantly increased cAMP production and [Ca2+]i. AVP substantially increased proliferation of rodent and human beta-cells. Moreover, AVP fully protected against cytokine-induced beta-cell apoptosis. AVP had no effect on glucagon secretion. Immunohistochemical examination of beta- and alpha-cells revealed co-expression of AVP with glucagon, and particularly insulin. Finally, administration of AVP in combination with glucose to mice significantly reduced blood glucose, which was associated with increased plasma insulin. These data indicate that AVP possesses novel and potentially important effects on pancreatic endocrine function. Understanding disturbances in islet AVP receptor signalling could reveal insight into the beta-cell defects associated with diabetes.

The Genetic Links to Anxiety and Depression (GLAD) Study: Online recruitment into the largest recontactable study of depression and anxiety.

BACKGROUND: Anxiety and depression are common, debilitating and costly. These disorders are influenced by multiple risk factors, from genes to psychological vulnerabilities and environmental stressors, but research is hampered by a lack of sufficiently large comprehensive studies. We are recruiting 40,000 individuals with lifetime depression or anxiety and broad assessment of risks to facilitate future research. METHODS: The Genetic Links to Anxiety and Depression (GLAD) Study (www.gladstudy.org.uk) recruits individuals with depression or anxiety into the NIHR Mental Health BioResource. Participants invited to join the study (via media campaigns) provide demographic, environmental and genetic data, and consent for medical record linkage and recontact. RESULTS: Online recruitment was effective; 42,531 participants consented and 27,776 completed the questionnaire by end of July 2019. Participants' questionnaire data identified very high rates of recurrent depression, severe anxiety, and comorbidity. Participants reported high rates of treatment receipt. The age profile of the sample is biased toward young adults, with higher recruitment of females and the more educated, especially at younger ages. DISCUSSION: This paper describes the study methodology and descriptive data for GLAD, which represents a large, recontactable resource that will enable future research into risks, outcomes, and treatment for anxiety and depression.

Tel/PDGFRbeta induces stem cell differentiation via the Ras/ERK and STAT5 signaling pathways.

OBJECTIVE: Fusion genes involving the platelet-derived growth factor receptor-beta (PDGFRbeta) are found in a subgroup of myeloproliferative neoplasms, with one such fusion, Tel/PDGFRbeta found in a subset of chronic myelomonocytic leukemia patients. Tel/PDGFRbeta results in constitutive activation of several signaling pathways and induces a myeloproliferative disease in mice, with signals via tyrosines 579/581 identified as being important for this phenotype. In this study, we have used a tetracycline-regulated system to express wild-type and the mutated F2 Tel/PDGFRbeta to identify the key signaling pathways, which drive Tel/PDGFRbeta-induced differentiation of embryonic stem (ES) cells. MATERIALS AND METHODS: The leukemic oncogene Tel/PDGFRbeta and Tel/PDGFRbeta-F2 were inducibly expressed in ES cells and their effects on self-renewal, signal transduction, and gene expression patterns analyzed. RESULTS: Tel/PDGFRbeta activated several major signal transduction pathways (signal transducers and activators of transcription [STAT] 3, STAT5, mitogen-activated protein kinases, phosphatidylinositol-3 kinase) in ES cells, but only specific inhibition of the mitogen-activated protein kinase kinase/extracellular regulated kinase (MEK/ERK) or STAT5 pathways was able to significantly prevent Tel/PDGFRbeta-induced differentiation and restore ES-cell self-renewal. Inhibiting the tyrosine kinase activity of the oncogene using Gleevec or PDGFRbeta inhibitor III also substantially prevented Tel/PDGFRbeta-induced differentiation and its ability to upregulate key genes involved in myelopoiesis. Tyrosines 579/581 played a critical role in mediating signals via the Ras/ERK and STAT5 pathways, with dual targeting of the tyrosine kinase activity of Tel/PDGFRbeta and the MEK/ERK pathway completely preventing Tel/PDGFRbeta-induced differentiation. CONCLUSION: These findings suggest that targeted disruption of key signaling pathways in combination with the tyrosine kinase activity of leukemic oncogenes, such as Tel/PDGFRbeta, may result in more efficacious therapies for suppressing leukemic progression in the clinical setting.