Immunotherapy targeting the C-terminal domain of TDP-43 decreases neuropathology and confers neuroprotection in mouse models of ALS/FTD.

Effective therapies are urgently needed to safely target TDP-43 pathology as it is closely associated with the onset and development of devastating diseases such as frontotemporal lobar degeneration with TDP-43 pathology (FTLD-TDP) and amyotrophic lateral sclerosis (ALS). In addition, TDP-43 pathology is present as a co-pathology in other neurodegenerative diseases such as Alzheimer's disease and Parkinson's disease. Our approach is to develop a TDP-43-specific immunotherapy that exploits Fc gamma-mediated removal mechanisms to limit neuronal damage while maintaining physiological TDP-43 function. Thus, using both in vitro mechanistic studies in conjunction with the rNLS8 and CamKIIa inoculation mouse models of TDP-43 proteinopathy, we identified the key targeting domain in TDP-43 to accomplish these therapeutic objectives. Targeting the C-terminal domain of TDP-43 but not the RNA recognition motifs (RRM) reduces TDP-43 pathology and avoids neuronal loss in vivo. We demonstrate that this rescue is dependent on Fc receptor-mediated immune complex uptake by microglia. Furthermore, monoclonal antibody (mAb) treatment enhances phagocytic capacity of ALS patient-derived microglia, providing a mechanism to restore the compromised phagocytic function in ALS and FTD patients. Importantly, these beneficial effects are achieved while preserving physiological TDP-43 activity. Our findings demonstrate that a mAb targeting the C-terminal domain of TDP-43 limits pathology and neurotoxicity, enabling clearance of misfolded TDP-43 through microglia engagement, and supporting the clinical strategy to target TDP-43 by immunotherapy. SIGNIFICANCE STATEMENT: TDP-43 pathology is associated with various devastating neurodegenerative disorders with high unmet medical needs such as frontotemporal dementia (FTD), amyotrophic lateral sclerosis (ALS) and Alzheimer's disease. Thus, safely and effectively targeting pathological TDP-43 represents a key paradigm for biotechnical research as currently there is little in clinical development. After years of research, we have determined that targeting the C-terminal domain of TDP-43 rescues multiple patho-mechanisms involved in disease progression in two animal models of FTD/ALS. In parallel, importantly, our studies establish that this approach does not alter the physiological functions of this ubiquitously expressed and indispensable protein. Together, our findings substantially contribute to the understanding of TDP-43 pathobiology and support the prioritization for clinical testing of immunotherapy approaches targeting TDP-43.

Klf6 protects ß-cells against insulin resistance-induced dedifferentiation.

OBJECTIVES: In the pathogenesis of type 2 diabetes, development of insulin resistance triggers an increase in pancreatic ß-cell insulin secretion capacity and ß-cell number. Failure of this compensatory mechanism is caused by a dedifferentiation of ß-cells, which leads to insufficient insulin secretion and diabetic hyperglycemia. The ß-cell factors that normally protect against dedifferentiation remain poorly defined. Here, through a systems biology approach, we identify the transcription factor Klf6 as a regulator of ß-cell adaptation to metabolic stress. METHODS: We used a ß-cell specific Klf6 knockout mouse model to investigate whether Klf6 may be a potential regulator of ß-cell adaptation to a metabolic stress. RESULTS: We show that inactivation of Klf6 in ß-cells blunts their proliferation induced by the insulin resistance of pregnancy, high-fat high-sucrose feeding, and insulin receptor antagonism. Transcriptomic analysis showed that Klf6 controls the expression of ß-cell proliferation genes and, in the presence of insulin resistance, it prevents the down-expression of genes controlling mature ß-cell identity and the induction of disallowed genes that impair insulin secretion. Its expression also limits the transdifferentiation of ß-cells into α-cells. CONCLUSION: Our study identifies a new transcription factor that protects ß-cells against dedifferentiation, and which may be targeted to prevent diabetes development.

Mechanism of insulin resistance in a rat model of kidney disease and the risk of developing type 2 diabetes.

Chronic kidney disease is associated with homeostatic imbalances such as insulin resistance. However, the underlying mechanisms leading to these imbalances and whether they promote the development of type 2 diabetes is unknown. The effect of chronic kidney disease on insulin resistance was studied on two different rat strains. First, in a 5/6th nephrectomised Sprague-Dawley rat model of chronic kidney disease, we observed a correlation between the severity of chronic kidney disease and hyperglycemia as evaluated by serum fructosamine levels (p<0.0001). Further, glucose tolerance tests indicated an increase of 25% in glycemia in chronic kidney disease rats (p<0.0001) as compared to controls whereas insulin levels remained unchanged. We also observed modulation of glucose transporters expression in several tissues such as the liver (decrease of ≈40%, p≤0.01) and muscles (decrease of ≈29%, p≤0.05). Despite a significant reduction of ≈37% in insulin-dependent glucose uptake in the muscles of chronic kidney disease rats (p<0.0001), the development of type 2 diabetes was never observed. Second, in a rat model of metabolic syndrome (Zucker Leprfa/fa), chronic kidney disease caused a 50% increased fasting hyperglycemia (p<0.0001) and an exacerbated glycemic response (p<0.0001) during glucose challenge. Similar modulations of glucose transporters expression and glucose uptake were observed in the two models. However, 30% (p<0.05) of chronic kidney disease Zucker rats developed characteristics of type 2 diabetes. Thus, our results suggest that downregulation of GLUT4 in skeletal muscle may be associated with insulin resistance in chronic kidney disease and could lead to type 2 diabetes in predisposed animals.

MAP17 Is a Necessary Activator of Renal Na+/Glucose Cotransporter SGLT2.

The renal proximal tubule reabsorbs 90% of the filtered glucose load through the Na+-coupled glucose transporter SGLT2, and specific inhibitors of SGLT2 are now available to patients with diabetes to increase urinary glucose excretion. Using expression cloning, we identified an accessory protein, 17 kDa membrane-associated protein (MAP17), that increased SGLT2 activity in RNA-injected Xenopus oocytes by two orders of magnitude. Significant stimulation of SGLT2 activity also occurred in opossum kidney cells cotransfected with SGLT2 and MAP17. Notably, transfection with MAP17 did not change the quantity of SGLT2 protein at the cell surface in either cell type. To confirm the physiologic relevance of the MAP17-SGLT2 interaction, we studied a cohort of 60 individuals with familial renal glucosuria. One patient without any identifiable mutation in the SGLT2 coding gene (SLC5A2) displayed homozygosity for a splicing mutation (c.176+1G>A) in the MAP17 coding gene (PDZK1IP1). In the proximal tubule and in other tissues, MAP17 is known to interact with PDZK1, a scaffolding protein linked to other transporters, including Na+/H+ exchanger 3, and to signaling pathways, such as the A-kinase anchor protein 2/protein kinase A pathway. Thus, these results provide the basis for a more thorough characterization of SGLT2 which would include the possible effects of its inhibition on colocalized renal transporters.

[Drug pharmacokinetics in renal failure: What's new?]. / Pharmacocinétique des médicaments en insuffisance rénale : nouveautés.

The prevalence and incidence of chronic kidney disease (CKD) has steadily increased over the past two decades attributed to an important raise of cases of diabetes, hypertension and obesity, leading risk factors of renal failure. CKD is known to impair drug disposition of non-renally eliminated medications that may lead to unintended toxicity or lower therapeutic effect despite dose adjustment according to glomerular filtration rate (GFR). Modulation of metabolism enzymes (cytochrome P450, phase II) and drug transporters in various organs (intestines, liver, kidneys and brain) are being held responsible for altered pharmacokinetics where uremic toxins, inflammatory cytokines and parathyroid hormone, common factors present in CKD, may be considered possible culprits. This review gives a thorough summary of the recent preclinical, clinical studies and Food and Drug Administration (FDA) guidelines and allows a current understanding of drug absorption, distribution, metabolism and excretion in CKD.