Mugdha V. Joglekar

Expression of islet-specific microRNAs during human pancreatic development

During pancreatic islet development, sequential changes in gene expression are known to be necessary for efficient differentiation and function of the endocrine pancreas. Several studies till now have demonstrated that microRNAs (miRNAs), which regulate translation of gene transcripts, influence gene expression cascades involved in pancreas development. Some of these miRNAs; miR-7 and miR-375 have been known to be expressed at high levels in pancreas and are also known to be involved in Zebrafish pancreas development as well as insulin secretion in mice. We demonstrate here that 4 different islet-specific microRNAs (miR-7, miR-9, miR-375 and miR-376) are expressed at high levels during human pancreatic islet development. Of these, miR-375, is seen to be differentially expressed in human islet beta- as well as non-beta-cells. Though no significant difference in abundance of miR-375 was noted in either cell type, analysis of islet-specific miRNA and mRNA in single cells show that non-beta cells contain higher levels of miR-375. Our data demonstrate that miRNAs that are known to be regulated during Zebrafish pancreatic development may play similar role in human pancreatic islet development.

The miR-30 family microRNAs confer epithelial phenotype to human pancreatic cells

Epithelial-to-mesenchymal transition is a phenomenon necessary for embryonic development and also seen during certain pathological conditions. We show here for the first time that reduction in miR-30 family microRNAs, is responsible for mesenchymal transition of primary cultures of human pancreatic epithelial cells. We found that miR-30 family microRNAs target mesenchymal gene transcripts and maintain them in a translationally inactive state. Forced depletion using miR-30 family specific anti-miRs leads to mesenchymal transition while ectopic overexpression maintains the epithelial phenotype. We also show that miR-30 family microRNAs increase in abundance during differentiation of pancreatic islet-derived mesenchymal cells into hormone-producing islet-like cell aggregates. Our studies in human adult diseased pancreas also demonstrate that miR-30 family microRNAs are expressed at lower abundance in fibrotic lesions during pancreatitis. Together, our data confirm that miR-30 family microRNAs form a part of the regulatory signaling events involved in cellular response of pancreatic epithelial cells during mesenchymal transition.

Human bone marrow-derived mesenchymal cells differentiate and mature into endocrine pancreatic lineage in vivo

BACKGROUND AIMS The scarcity of human islets for transplantation remains a major limitation of cell replacement therapy for diabetes. Bone marrow-derived progenitor cells are of interest because they can be isolated, expanded and offered for such therapy under autologous/allogeneic settings. METHODS We characterized and compared human bone marrow-derived mesenchymal cells (hBMC) obtained from (second trimester), young (1-24 years) and adult (34-81 years) donors. We propose a novel protocol that involves assessment of paracrine factors from regenerating pancreas in differentiation and maturation of hBMC into endocrine pancreatic lineage in vivo. RESULTS We observed that donor age was inversely related to growth potential of hBMC. Following in vitro expansion and exposure to specific growth factors involved in pancreatic development, hBMC migrated and formed islet-like cell aggregates (ICA). ICA show increased abundance of pancreatic transcription factors (Ngn3, Brn4, Nkx6.1, Pax6 and Isl1). Although efficient differentiation was not achieved in vitro, we observed significant maturation and secretion of human c-peptide (insulin) upon transplantation into pancreactomized and Streptozotocin (STZ)-induced diabetic mice. Transplanted ICA responded to glucose and maintained normoglycemia in diabetic mice. CONCLUSIONS Our data demonstrate that hBMC have tremendous in vitro expansion potential and can be differentiated into multiple lineages, including the endocrine pancreatic lineage. Paracrine factors secreted from regenerating pancreas help in efficient differentiation and maturation of hBMC, possibly via recruiting chromatin modulators, to generate glucose-responsive insulin-secreting cells.

Multigenerational Undernutrition Increases Susceptibility to Obesity and Diabetes that Is Not Reversed after Dietary Recuperation

People in developing countries have faced multigenerational undernutrition and are currently undergoing major lifestyle changes, contributing to an epidemic of metabolic diseases, though the underlying mechanisms remain unclear. Using a Wistar rat model of undernutrition over 50 generations, we show that Undernourished rats exhibit low birth-weight, high visceral adiposity (DXA/MRI), and insulin resistance (hyperinsulinemic-euglycemic clamps), compared to age-/gender-matched control rats. Undernourished rats also have higher circulating insulin, homocysteine, endotoxin and leptin levels, lower adiponectin, vitamin B12 and folate levels, and an 8-fold increased susceptibility to Streptozotocin-induced diabetes compared to control rats. Importantly, these metabolic abnormalities are not reversed after two generations of unrestricted access to commercial chow (nutrient recuperation). Altered epigenetic signatures in insulin-2 gene promoter region of Undernourished rats are not reversed by nutrient recuperation, and may contribute to the persistent detrimental metabolic profiles in similar multigenerational undernourished human populations.

Human fetal pancreatic insulin-producing cells proliferate in vitro

There have been considerable efforts towards understanding the potential of human pancreatic endocrine cells to proliferate and transition into mesenchymal cell populations. Since rodent studies have demonstrated that mouse insulin-producing cells do not proliferate in vitro, a similar possibility has been considered for human islet endocrine cells. Considering the inherent differences in mouse and human pancreatic islets, we decided to assess the potential of human fetal pancreatic insulin-producing cells to proliferate in vitro. We studied the proliferative potential of human fetal pancreatic islet-derived populations from second or third trimester fetal pancreas and characterized the cells that grow out during their expansion. We have used seven different approaches including in situ hybridization and immunostaining, quantitative estimation of multiple gene transcripts in populations as well as in single cells, clonal analysis of islet cells, assessment of heritable marks of active insulin promoter, and thymidine analog-based lineage tracing. Our studies demonstrate that human fetal pancreatic insulin-producing cells proliferate in vitro to generate mesenchymal cell populations. Interestingly, epigenetic modifications that mark open chromatin conformation of insulin promoter regions are retained even after a million fold expansion/proliferation in vitro. These findings demonstrate that hormone-producing cells in pancreatic islets proliferate in vitro and retain epigenetic marks that characterize an active insulin promoter. Such in vitro-derived mesenchymal cells may be of potential use in cell-replacement therapy for diabetes.

HUMAN UMBILICAL CORD BLOOD SERUM PROMOTES GROWTH, PROLIFERATION, AS WELL AS DIFFERENTIATION OF HUMAN BONE MARROW–DERIVED PROGENITOR CELLS

SummaryFelal calf serum (FCS) is conventionally used for animal cell cultures due to its inherent growth-promoting activities. However animal welfare issues and stringent requirements for human transplantation studies demand a suitable alternative for FCS. With this view, we studied the effect of FCS, human AB serum (ABS), and human umbilical cord blood serum (UCBS) on murine islets of Langerhans and human bone marrow-derived mesenchymal-like cells (hBMCs). We found that there was no difference in morphology and functionality of mouse islets cultured in any of these three different serum supplements as indicated by insulin immunostaining. A comparative analysis of hBMCs maintained in each of these three different serum supplements demonstrated that UCBS supplemented media better supported proliferation of hBMCs. Moreover, a modification of adipogenic differentiation protocol using UCBS indicates that it can be used as a supplement to support differentiation of hBMCs into adipocytes. Our results demonstrate that UCBS not only is suitable for maintenance of murine pancreatic islets, but also supports attachment, propagation, and differentiation of hBMCs in vitro. We conclude that UCBS can serve as a better serum supplement for growth, maintenance, and differentiation of hBMCs, making it a more suitable supplement in cell systems that have therapeutic potential in human transplantation programs.

Circulating microRNAs: Understanding the Limits for Quantitative Measurement by Real-Time PCR

Ever since the discovery of small, non-coding RNAs in circulation, microRNAs have gained significant attention as biomarkers or, in some instances, regulators of disease and/or associated complications. Until now, most articles published use real-time quantitative PCR (qPCR) for assessment of

A comparative analysis of high-throughput platforms for validation of a circulating microRNA signature in diabetic retinopathy

MicroRNAs are now increasingly recognized as biomarkers of disease progression. Several quantitative real-time PCR (qPCR) platforms have been developed to determine the relative levels of microRNAs in biological fluids. We systematically compared the detection of cellular and circulating microRNA using a standard 96-well platform, a high-content microfluidics platform and two ultra-high content platforms. We used extensive analytical tools to compute inter- and intra-run variability and concordance measured using fidelity scoring, coefficient of variation and cluster analysis. We carried out unprejudiced next generation sequencing to identify a microRNA signature for Diabetic Retinopathy (DR) and systematically assessed the validation of this signature on clinical samples using each of the above four qPCR platforms. The results indicate that sensitivity to measure low copy number microRNAs is inversely related to qPCR reaction volume and that the choice of platform for microRNA biomarker validation should be made based on the abundance of miRNAs of interest.

Effect of alginate encapsulation on the cellular transcriptome of human islets

Encapsulation of human islets may prevent their immune rejection when transplanted into diabetic recipients. To assist in understanding why clinical outcomes with encapsulated islets were not ideal, we examined the effect of encapsulation on their global gene (mRNA) and selected miRNAs (non-coding (nc)RNA) expression. For functional studies, encapsulated islets were transplanted into peritoneal cavity of diabetic NOD-SCID mice. Genomics analysis and transplantation studies demonstrate that islet origin and isolation centres are a major source of variation in islet quality. In contrast, tissue culture and the encapsulation process had only a minimal effect, and did not affect islet viability. Microarray analysis showed that as few as 29 genes were up-regulated and 2 genes down-regulated (cut-off threshold 0.1) by encapsulation. Ingenuity analysis showed that up-regulated genes were involved mostly in inflammation, especially chemotaxis, and vascularisation. However, protein expression of these factors was not altered by encapsulation, raising doubts about the biosignificance of the gene changes. Encapsulation had no effect on levels of islet miRNAs. In vivo studies indicate differences among the centres in the quality of the islets isolated. We conclude that microencapsulation of human islets with barium alginate has little effect on their transcriptome.

Endothelial cells in pancreatic islet development and function

Endothelial cells represent one of the most abundant and widely found cell types in the mammalian embryo. These cells arise in close proximity with and often as an integral part of several organs such as the kidneys, lungs, liver and pancreas. In most of these organs, they play an instructive role to determine the fate of progenitor cells in the developing embryo. Studies carried out until now by Eckhard Lammert, Douglas Melton, Ken Zaret and colleagues have convincingly demonstrated the importance of endothelial cells in normal development of the pancreas. This article reviews the literature in development of endothelial and endodermal cells. Understanding these endothelium-derived signaling mechanisms that allow differentiation of endodermal cells to endocrine pancreatic lineage will help us develop strategies for making insulin-producing cells in vitro.