RNA-binding protein PCBP2 regulates pancreatic ß cell function and adaptation to glucose.

Glucose plays a key role in shaping pancreatic ß cell function. Thus, deciphering the mechanisms by which this nutrient stimulates ß cells holds therapeutic promise for combating ß cell failure in type 2 diabetes (T2D). ß Cells respond to hyperglycemia in part by rewiring their mRNA metabolism, yet the mechanisms governing these changes remain poorly understood. Here, we identify a requirement for the RNA-binding protein PCBP2 in maintaining ß cell function basally and during sustained hyperglycemic challenge. PCBP2 was induced in primary mouse islets incubated with elevated glucose and was required to adapt insulin secretion. Transcriptomic analysis of primary Pcbp2-deficient ß cells revealed impacts on basal and glucose-regulated mRNAs encoding core components of the insulin secretory pathway. Accordingly, Pcbp2-deficient ß cells exhibited defects in calcium flux, insulin granule ultrastructure and exocytosis, and the amplification pathway of insulin secretion. Further, PCBP2 was induced by glucose in primary human islets, was downregulated in islets from T2D donors, and impacted genes commonly altered in islets from donors with T2D and linked to single-nucleotide polymorphisms associated with T2D. Thus, these findings establish a paradigm for PCBP2 in governing basal and glucose-adaptive gene programs critical for shaping the functional state of ß cells.

Zebrafish Paralogs brd2a and brd2b Are Needed for Proper Circulatory, Excretory and Central Nervous System Formation and Act as Genetic Antagonists during Development.

Brd2 belongs to the BET family of epigenetic transcriptional co-regulators that act as adaptor-scaffolds for the assembly of chromatin-modifying complexes and other factors at target gene promoters. Brd2 is a protooncogene and candidate gene for juvenile myoclonic epilepsy in humans, a homeobox gene regulator in Drosophila, and a maternal-zygotic factor and cell death modulator that is necessary for normal development of the vertebrate central nervous system (CNS). As two copies of Brd2 exist in zebrafish, we use antisense morpholino knockdown to probe the role of paralog Brd2b, as a comparative study to Brd2a, the ortholog of human Brd2. A deficiency in either paralog results in excess cell death and dysmorphology of the CNS, whereas only Brd2b deficiency leads to loss of circulation and occlusion of the pronephric duct. Co-knockdown of both paralogs suppresses single morphant defects, while co-injection of morpholinos with paralogous RNA enhances them, suggesting novel genetic interaction with functional antagonism. Brd2 diversification includes paralog-specific RNA variants, a distinct localization of maternal factors, and shared and unique spatiotemporal expression, providing unique insight into the evolution and potential functions of this gene.

Ins1-Cre and Ins1-CreER Gene Replacement Alleles Are Susceptible To Silencing By DNA Hypermethylation.

Targeted gene ablation studies of the endocrine pancreas have long suffered from suboptimal Cre deleter strains. In many cases, Cre lines purportedly specific for beta cells also displayed expression in other islet endocrine cells or in a subset of neurons in the brain. Several pancreas and endocrine Cre lines have experienced silencing or mosaicism over time. In addition, many Cre transgenic constructs were designed to include the hGH mini-gene, which by itself increases beta-cell replication and decreases beta-cell function. More recently, driver lines with Cre or CreER inserted into the Ins1 locus were generated, with the intent of producing ß cell-specific Cre lines with faithful recapitulation of insulin expression. These lines were bred in multiple labs to several different mouse lines harboring various lox alleles. In our hands, the ability of the Ins1-Cre and Ins1-CreER lines to delete target genes varied from that originally reported, with both alleles displaying low levels of expression, increased levels of methylation compared to the wild-type allele, and ultimately inefficient or absent target deletion. Thus, caution is warranted in the interpretation of results obtained with these genetic tools, and Cre expression and activity should be monitored regularly when using these lines.

Metabolic stress activates an ERK/hnRNPK/DDX3X pathway in pancreatic ß cells.

OBJECTIVE: Pancreatic ß cell failure plays a central role in the development of type 2 diabetes (T2D). While the transcription factors shaping the ß cell gene expression program have received much attention, the post-transcriptional controls that are activated in ß cells during stress are largely unknown. We recently identified JUND as a pro-oxidant transcription factor that is post-transcriptionally upregulated in ß cells during metabolic stress. Here we seek to uncover the mechanisms underlying this maladaptive response to metabolic stress. METHODS: RNA-protein and protein-protein interactions were measured using RNA immunoprecipitation and co-immunoprecipitation, respectively, in Min6 cells and mouse islets. Phos-tag analyses were used to assess hnRNPK phosphorylation in primary mouse and human islets and Min6 cells. Translating ribosome affinity purification (TRAP) followed by RT-qPCR was used to identify changes in the ribosome occupancy of mRNAs in Min6 cells. Gene depletion studies used lentiviral delivery of CRISPR-Cas9 to Min6 cells. Apoptosis was measured in primary islets using a cell-permeable dye with a fluorescence readout of activated cleaved caspase-3 and-7. RESULTS: A de novo motif analysis was performed on a subset of genes previously found to be regulated at the level of ribosome binding during PDX1-deficiency, which identified a poly-cytosine (polyC) motif in the 3'UTR of the transcript encoding JUND. The polyC-binding protein hnRNPK bound to the mRNA encoding JUND, leading us to hypothesize that hnRNPK regulates JUND expression during glucolipotoxicity. Indeed, loss of hnRNPK blocked the post-transcriptional upregulation of JUND during metabolic stress. hnRNPK was phosphorylated in mouse and human islets during glucolipotoxicity and in islets of diabetic db/db mice. The MEK/ERK signaling pathway was both necessary and sufficient for the phosphorylation of hnRNPK, upregulation of JUND levels, and induction of pro-oxidant and pro-inflammatory genes. Further, we identified the RNA helicase DDX3X as a new binding partner for hnRNPK that is required for efficient translation of JUND mRNA. Loss of hnRNPK reduced DDX3X binding to translation machinery, suggesting that these factors cooperate to regulate translation in ß cells. CONCLUSIONS: Our results identify a novel ERK/hnRNPK/DDX3X pathway that influences ß cell survival and is activated under conditions associated with T2D.

JUND regulates pancreatic ß cell survival during metabolic stress.

OBJECTIVE: In type 2 diabetes (T2D), oxidative stress contributes to the dysfunction and loss of pancreatic ß cells. A highly conserved feature of the cellular response to stress is the regulation of mRNA translation; however, the genes regulated at the level of translation are often overlooked due to the convenience of RNA sequencing technologies. Our goal is to investigate translational regulation in ß cells as a means to uncover novel factors and pathways pertinent to cellular adaptation and survival during T2D-associated conditions. METHODS: Translating ribosome affinity purification (TRAP) followed by RNA-seq or RT-qPCR was used to identify changes in the ribosome occupancy of mRNAs in Min6 cells. Gene depletion studies used lentiviral delivery of shRNAs to primary mouse islets or CRISPR-Cas9 to Min6 cells. Oxidative stress and apoptosis were measured in primary islets using cell-permeable dyes with fluorescence readouts of oxidation and activated cleaved caspase-3 and-7, respectively. Gene expression was assessed by RNA-seq, RT-qPCR, and western blot. ChIP-qPCR was used to determine chromatin enrichment. RESULTS: TRAP-seq in a PDX1-deficiency model of ß cell dysfunction uncovered a cohort of genes regulated at the level of mRNA translation, including the transcription factor JUND. Using a panel of diabetes-associated stressors, JUND was found to be upregulated in mouse islets cultured with high concentrations of glucose and free fatty acid, but not after treatment with hydrogen peroxide or thapsigargin. This induction of JUND could be attributed to increased mRNA translation. JUND was also upregulated in islets from diabetic db/db mice and in human islets treated with high glucose and free fatty acid. Depletion of JUND in primary islets reduced oxidative stress and apoptosis in ß cells during metabolic stress. Transcriptome assessment identified a cohort of genes, including pro-oxidant and pro-inflammatory genes, regulated by JUND that are commonly dysregulated in models of ß cell dysfunction, consistent with a maladaptive role for JUND in islets. CONCLUSIONS: A translation-centric approach uncovered JUND as a stress-responsive factor in ß cells that contributes to redox imbalance and apoptosis during pathophysiologically relevant stress.

A PDX1-ATF transcriptional complex governs ß cell survival during stress.

OBJECTIVE: Loss of insulin secretion due to failure or death of the insulin secreting ß cells is the central cause of diabetes. The cellular response to stress (endoplasmic reticulum (ER), oxidative, inflammatory) is essential to sustain normal ß cell function and survival. Pancreatic and duodenal homeobox 1 (PDX1), Activating transcription factor 4 (ATF4), and Activating transcription factor 5 (ATF5) are transcription factors implicated in ß cell survival and susceptibility to stress. Our goal was to determine if a PDX1-ATF transcriptional complex or complexes regulate ß cell survival in response to stress and to identify direct transcriptional targets. METHODS: Pdx1, Atf4 and Atf5 were silenced by viral delivery of gRNAs or shRNAs to Min6 insulinoma cells or primary murine islets. Gene expression was assessed by qPCR, RNAseq analysis, and Western blot analysis. Chromatin enrichment was measured in the Min6 ß cell line and primary isolated mouse islets by ChIPseq and ChIP PCR. Immunoprecipitation was used to assess interactions among transcription factors in Min6 cells and isolated mouse islets. Activation of caspase 3 by immunoblotting or by irreversible binding to a fluorescent inhibitor was taken as an indication of commitment to an apoptotic fate. RESULTS: RNASeq identified a set of PDX1, ATF4 and ATF5 co-regulated genes enriched in stress and apoptosis functions. We further identified stress induced interactions among PDX1, ATF4, and ATF5. PDX1 chromatin occupancy peaks were identified over composite C/EBP-ATF (CARE) motifs of 26 genes; assessment of a subset of these genes revealed co-enrichment for ATF4 and ATF5. PDX1 occupancy over CARE motifs was conserved in the human orthologs of 9 of these genes. Of these, Glutamate Pyruvate Transaminase 2 (Gpt2), Cation transport regulator 1 (Chac1), and Solute Carrier Family 7 Member 1 (Slc7a1) induction by stress was conserved in human islets and abrogated by deficiency of Pdx1, Atf4, and Atf5 in Min6 cells. Deficiency of Gpt2 reduced ß cell susceptibility to stress induced apoptosis in both Min6 cells and primary islets. CONCLUSIONS: Our results identify a novel PDX1 stress inducible complex (es) that regulates expression of stress and apoptosis genes to govern ß cell survival.