Your search keyword '"Rebecca Callingham"' showing total 3 results

1. Roles for the long non-coding RNA Pax6os1/PAX6-AS1 in pancreatic beta cell function

Author

Livia Lopez-Noriega, Rebecca Callingham, Aida Martinez-Sánchez, Sameena Nawaz, Grazia Pizza, Nejc Haberman, Nevena Cvetesic, Marie-Sophie Nguyen-Tu, Boris Lenhard, Piero Marchetti, Lorenzo Piemonti, Eelco de Koning, A.M. James Shapiro, Paul R. Johnson, Isabelle Leclerc, Benoit Hastoy, Benoit R. Gauthier, Timothy J. Pullen, and Guy A. Rutter

Subjects

Cell biology, Cellular physiology, Molecular biology, Science

Abstract

Summary: Long non-coding RNAs (lncRNAs) are emerging as crucial regulators of beta cell function. Here, we show that an lncRNA-transcribed antisense to Pax6, annotated as Pax6os1/PAX6-AS1, was upregulated by high glucose concentrations in human as well as murine beta cell lines and islets. Elevated expression was also observed in islets from mice on a high-fat diet and patients with type 2 diabetes. Silencing Pax6os1/PAX6-AS1 in MIN6 or EndoC-βH1 cells increased several beta cell signature genes’ expression. Pax6os1/PAX6-AS1 was shown to bind to EIF3D, indicating a role in translation of specific mRNAs, as well as histones H3 and H4, suggesting a role in histone modifications. Important interspecies differences were found, with a stronger phenotype in humans. Only female Pax6os1 null mice fed a high-fat diet showed slightly enhanced glucose clearance. In contrast, silencing PAX6-AS1 in human islets enhanced glucose-stimulated insulin secretion and increased calcium dynamics, whereas overexpression of the lncRNA resulted in the opposite phenotype.

Published

2025

2. Nicotinamide riboside kinases display redundancy in mediating nicotinamide mononucleotide and nicotinamide riboside metabolism in skeletal muscle cells

Author

Rachel S. Fletcher, Joanna Ratajczak, Craig L. Doig, Lucy A. Oakey, Rebecca Callingham, Gabriella Da Silva Xavier, Antje Garten, Yasir S. Elhassan, Philip Redpath, Marie E. Migaud, Andrew Philp, Charles Brenner, Carles Canto, and Gareth G. Lavery

Subjects

Skeletal muscle, NAD+, Energy metabolism, Nicotinamide riboside, Internal medicine, RC31-1245

Abstract

Objective: Augmenting nicotinamide adenine dinucleotide (NAD+) availability may protect skeletal muscle from age-related metabolic decline. Dietary supplementation of NAD+ precursors nicotinamide mononucleotide (NMN) and nicotinamide riboside (NR) appear efficacious in elevating muscle NAD+. Here we sought to identify the pathways skeletal muscle cells utilize to synthesize NAD+ from NMN and NR and provide insight into mechanisms of muscle metabolic homeostasis. Methods: We exploited expression profiling of muscle NAD+ biosynthetic pathways, single and double nicotinamide riboside kinase 1/2 (NRK1/2) loss-of-function mice, and pharmacological inhibition of muscle NAD+ recycling to evaluate NMN and NR utilization. Results: Skeletal muscle cells primarily rely on nicotinamide phosphoribosyltransferase (NAMPT), NRK1, and NRK2 for salvage biosynthesis of NAD+. NAMPT inhibition depletes muscle NAD+ availability and can be rescued by NR and NMN as the preferred precursors for elevating muscle cell NAD+ in a pathway that depends on NRK1 and NRK2. Nrk2 knockout mice develop normally and show subtle alterations to their NAD+ metabolome and expression of related genes. NRK1, NRK2, and double KO myotubes revealed redundancy in the NRK dependent metabolism of NR to NAD+. Significantly, these models revealed that NMN supplementation is also dependent upon NRK activity to enhance NAD+ availability. Conclusions: These results identify skeletal muscle cells as requiring NAMPT to maintain NAD+ availability and reveal that NRK1 and 2 display overlapping function in salvage of exogenous NR and NMN to augment intracellular NAD+ availability.

Published

2017

3. The long non-coding RNA Pax6os1/PAX6-AS1 modulates pancreatic β-cell identity and function

Author

Lorenzo Piemonti, A. M. James Shapiro, Boris Lenhard, Isabelle Leclerc, Guy A. Rutter, Livia Lopez-Noriega, Nevena Cvetesic, Rebecca Callingham, Aida Martinez-Sanchez, Eelco J.P. de Koning, Timothy J. Pullen, Marie-Sophie Nguyen-Tu, Nejc Haberman, Grazia Pizza, Piero Marchetti, and Paul Johnson

Subjects

endocrine system, medicine.medical_specialty, Chemistry, Insulin, medicine.medical_treatment, Pancreatic islets, Type 2 diabetes, medicine.disease, Endocrinology, medicine.anatomical_structure, Downregulation and upregulation, Internal medicine, medicine, Gene silencing, Glucose homeostasis, PAX6, Transcription factor

Abstract

Long non-coding RNAs (lncRNAs) are emerging as crucial regulators of {beta}-cell development and function. Consequently, the mis-expression of members of this group may contribute to the risk of type 2 diabetes (T2D). Here, we investigate roles for an antisense lncRNA expressed from the Pax6 locus (annotated as Pax6os1 in mice and PAX6-AS1 in humans) in {beta}-cell function. The transcription factor Pax6 is required for the development of pancreatic islets and maintenance of a fully differentiated {beta}-cell phenotype. Pax6os1/PAX6-AS1 expression was increased in pancreatic islets and {beta}-cell lines at high glucose concentrations, in islets from mice fed a high fat diet, and in those from patients with type 2 diabetes. Silencing or deletion of Pax6os1/PAX6-AS1 in MIN6 cells and EndoC-{beta}H1cells, respectively, upregulated {beta}-cell signature genes, including insulin. Moreover, shRNA-mediated silencing of PAX6-AS1 in human islets not only increased insulin mRNA, but also enhanced glucose-stimulated insulin secretion and calcium dynamics. In contrast, inactivation of Pax6os1 in mice was largely without effect on glucose homeostasis, though female Pax6os1 null mice on high fat diet (HFD) showed a tendency towards enhanced glucose clearance. Together, our results suggest that increased expression of PAX6-AS1 at high glucose levels may contribute to {beta}-cell dedifferentiation and failure in some forms of type 2 diabetes. Thus, targeting PAX6-AS1 may provide a promising strategy to enhance insulin secretion and improve glucose homeostasis in type 2 diabetes.

Published

2020