Juxiang Yang

Pdx1 (MODY4) regulates pancreatic beta cell susceptibility to ER stress

Type 2 diabetes mellitus (T2DM) results from pancreatic β cell failure in the setting of insulin resistance. Heterozygous mutations in the gene encoding the β cell transcription factor pancreatic duodenal homeobox 1 (Pdx1) are associated with both T2DM and maturity onset diabetes of the young (MODY4), and low levels of Pdx1 accompany β cell dysfunction in experimental models of glucotoxicity and diabetes. Here, we find that Pdx1 is required for compensatory β cell mass expansion in response to diet-induced insulin resistance through its roles in promoting β cell survival and compensatory hypertrophy. Pdx1-deficient β cells show evidence of endoplasmic reticulum (ER) stress both in the complex metabolic milieu of high-fat feeding as well as in the setting of acutely reduced Pdx1 expression in the Min6 mouse insulinoma cell line. Further, Pdx1 deficiency enhances β cell susceptibility to ER stress-associated apoptosis. The results of high throughput expression microarray and chromatin occupancy analyses reveal that Pdx1 regulates a broad array of genes involved in diverse functions of the ER, including proper disulfide bond formation, protein folding, and the unfolded protein response. These findings suggest that Pdx1 deficiency leads to a failure of β cell compensation for insulin resistance at least in part by impairing critical functions of the ER.

The diabetes gene Pdx1 regulates the transcriptional network of pancreatic endocrine progenitor cells in mice

Heterozygous mutations in the gene encoding the pancreatic homeodomain transcription factor pancreatic duodenal homeobox 1 (PDX1) are associated with maturity onset diabetes of the young, type 4 (MODY4) and type 2 diabetes. Pdx1 governs the early embryonic development of the pancreas and the later differentiation of the insulin-producing islet beta cells of the endocrine compartment. We derived a Pdx1 hypomorphic allele that reveals a role for Pdx1 in the specification of endocrine progenitors. Mice homozygous for this allele displayed a selective reduction in endocrine lineages associated with decreased numbers of endocrine progenitors and a marked reduction in levels of mRNA encoding the proendocrine transcription factor neurogenin 3 (Ngn3). During development, Pdx1 occupies an evolutionarily conserved enhancer region of Ngn3 and interacts with the transcription factor one cut homeobox 1 (Hnf6) to activate this enhancer. Furthermore, mRNA levels of all 4 members of the transcription factor network that regulates Ngn3 expression, SRY-box containing gene 9 (Sox9), Hnf6, Hnf1b, and forkhead box A2 (Foxa2), were decreased in homozygous mice. Pdx1 also occupied regulatory sequences in Foxa2 and Hnf1b. Thus, Pdx1 contributes to specification of endocrine progenitors both by regulating expression of Ngn3 directly and by participating in a cross-regulatory transcription factor network during early pancreas development. These results provide insights that may be applicable to beta cell replacement strategies involving the guided differentiation of ES cells or other progenitor cell types into the beta cell lineage, and they suggest a molecular mechanism whereby human PDX1 mutations cause diabetes.

Mouse preimplantation embryos developed from oocytes injected with round spermatids or spermatozoa have similar but distinct patterns of early messenger RNA expression.

Abstract Quantitative real-time polymerase chain reaction assay was used to compare the temporal transcriptional activation and mRNA removal for a number of genes in mouse embryos derived by round spermatid injection (ROSI) or intracytoplasmic sperm injection. A number of marker genes with widely different cellular functions were analyzed. Similar patterns of activation were found for the transcription factor Oct 4, the translation initiation factor eukaryotic initiation factor 1A, the L1 ribosomal protein, the chromatin modifying protein histone deacetylase 1, the enzyme hypoxanthine phosphoribosyl transferase, the murine endogenous retrovirus-like element, and the repetitive DNA LINE retrotransposons. Expression of the retrovirus-like mobile element intracisternal A particle, however, was markedly elevated from the two-cell to the blastocyst stages in ROSI embryos. Analyses performed for various paternal mRNAs introduced into the oocyte by the round spermatid, including protamines 1 and 2, transition protein 2, ropporin, and glyceraldehydes 3-phosphate dehydrogenase, revealed all were removed from the preimplantation embryos, albeit with distinct temporal patterns.

In the Absence of the Mouse DNA/RNA-Binding Protein MSY2, Messenger RNA Instability Leads to Spermatogenic Arrest

Abstract MSY2 is a member of the Y-box family of proteins solely expressed in male and female germ cells. In the male, MSY2 serves as a coactivator of transcription by binding to a consensus promoter element present in many germ cell-specific genes. In the nucleus, MSY2 marks specific mRNAs for cytoplasmic storage, stabilization, and suppression of translation. The inactivation of MSY2 by gene targeting leads to spermatogenic arrest and infertility. In testes of mice lacking MSY2, incomplete nuclear condensation is prominent in later-stage spermatids at the time of massive spermatid loss. Because MSY2 interacts with DNA and mRNAs, there are several distinct sites of action, which could be disrupted in mice that lack MSY2, resulting in the arrest of spermatogenesis. To define the molecular cause(s) of the spermatogenic arrest in mice lacking MSY2, transcriptional and posttranscriptional processes were assayed. Transcription, mRNA processing, and mRNA intracellular transport appear normal in the absence of MSY2. However, a redistribution of mRNAs from ribonucleoprotein particles to polysomes and marked decreases were detected for many meiotic and postmeiotic germ cell mRNAs, including the mRNAs encoding the transition proteins and protamines. This suggests that increased mRNA instability is a likely cause of the male infertility in Msy2-null mice.

Mouse testis brain RNA-binding protein/translin selectively binds to the messenger RNA of the fibrous sheath protein glyceraldehyde 3-phosphate dehydrogenase-S and suppresses its translation in vitro

Abstract The testis brain RNA-binding protein (TB-RBP/translin) is a DNA- and RNA-binding protein with multiple functions. As an RNA-binding protein, TB-RBP binds to conserved sequence elements often present in the 3′ untranslated regions (UTRs) of specific mRNAs modulating their translation and transport. To identify additional mRNA targets of TB-RBP, immunoprecipitation and reverse transcription-polymerase chain reaction (RT-PCR) assays were carried out using an affinity-purified antibody to TB-RBP with testicular extracts. Gapds mRNA was found to be selectively precipitated in a TB-RBP-mRNA complex. Consistent with the delayed translation of GAPDS and the subcellular ribonucleoprotein location of TB-RBP, polysomal gradient analysis showed that most of the Gapds mRNA in adult testis extracts was present in the nonpolysomal fractions. In vitro translation assays revealed that Gapds mRNA translation was inhibited by recombinant TB-RBP or by a TB-RBP mutant protein, Nb, capable of binding RNA. No inhibition was seen with mutant forms of TB-RBP lacking domains required for RNA binding, including the TB-RBP Cb mutant and the C-terminal-truncated form of TB-RBP that disrupts the leucine zipper. As an additional indicator of the specificity of TB-RBP inhibition of Gapds mRNA translation, a putative TB-RBP binding H-element was deleted from the 5′ UTR of the Gapds mRNA. No translational inhibition by recombinant TB-RBP was seen with Gapds mRNA lacking the H element. These data suggest that TB-RBP is involved in the posttranscriptional regulation of Gapds gene expression during spermiogenesis. Moreover, the Gapds mRNA is the first mRNA shown to have a functional TB-RBP binding site in its 5′ UTR.

Research Resource: The Pdx1 Cistrome of Pancreatic Islets

The homeodomain transcription factor pancreas duodenal homeobox 1 (Pdx1, also known as insulin promoter factor 1) is a master regulator of pancreas development, as mice or humans lacking Pdx1 function are a pancreatic. Importantly, heterozygous mutations in Pdx1 cause early and late onset forms of diabetes in humans. Despite these central roles in development and adult β-cell function, we have only rudimentary knowledge of the transcriptome targets of Pdx1 that mediate these phenotypes. Therefore, we performed global location analysis of Pdx1 occupancy in pancreatic islets. We used evolutionary conservation of target genes to identify the most relevant Pdx1 targets by performing chromatin immunoprecipitation sequencing on both human and mouse islets. Remarkably, the conserved target set is highly enriched for genes annotated to function in endocrine system and metabolic disorders, various signaling pathways, and cell survival, providing a molecular explanation for many of the phenotypes resulting from Pdx1 deficiency.

CDC2A (CDK1)-mediated phosphorylation of MSY2 triggers maternal mRNA degradation during mouse oocyte maturation.

Degradation of maternal mRNA is thought to be essential to undergo the maternal-to-embryonic transition. Messenger RNA is extremely stable during oocyte growth in mouse and MSY2, an abundant germ cell-specific RNA-binding protein, likely serves as a mediator of global mRNA stability. Oocyte maturation, however, triggers an abrupt transition in which most mRNAs are significantly degraded. We report that CDC2A (CDK1)-mediated phosphorylation of MSY2 triggers this transition. Injecting Cdc2a mRNA, which activates CDC2A, overcomes milrinone-mediated inhibition of oocyte maturation, induces MSY2 phosphorylation and the maturation-associated degradation of mRNAs. Inhibiting CDC2A following its activation with roscovitine inhibits MSY2 phosphorylation and prevents mRNA degradation. Expressing non-phosphorylatable dominant-negative forms of MSY2 inhibits the maturation-associated decrease in mRNAs, whereas expressing constitutively active forms induces mRNA degradation in the absence of maturation and phosphorylation of endogenous MSY2. A positive-feedback loop of CDK1-mediated phosphorylation of MSY2 that leads to degradation of Msy2 mRNA that in turn leads to a decrease in MSY2 protein may ensure that the transition is irreversible.

Meiotic Messenger RNA and Noncoding RNA Targets of the RNA-Binding Protein Translin (TSN) in Mouse Testis

Abstract In postmeiotic male germ cells, TSN, formerly known as testis brain-RNA binding protein, is found in the cytoplasm and functions as a posttranscriptional regulator of a group of genes transcribed by the transcription factor CREM-tau. In contrast, in pachytene spermatocytes, TSN is found predominantly in nuclei. Tsn-null males show a reduced sperm count and high levels of apoptosis in meiotic cells, suggesting a critical function for TSN during meiosis. To identify meiotic target RNAs that associate in vivo with TSN, we reversibly cross-linked TSN to RNA in testis extracts from 17-day-old and adult mice and immunoprecipitated the complexes with an affinity-purified TSN antibody. Extracts from Tsn-null mice were used as controls. Cloning and sequencing the immunoprecipitated RNAs, we identified four new TSN target mRNAs, encoding diazepam-binding inhibitor-like 5, arylsulfatase A, a tetratricopeptide repeat structure-containing protein, and ring finger protein 139. In contrast to the population of postmeiotic translationally delayed mRNAs that bind TSN, these four mRNAs are initially expressed in pachytene spermatocytes. In addition, anti-TSN also precipitated a nonprotein-coding RNA (ncRNA), which is abundant in nuclei of pachytene spermatocytes and has a putative polyadenylation signal, but no open reading frame. A second similar ncRNA is adjacent to a GGA repeat, a motif frequently associated with recombination hot spots. RNA gel-shift assays confirm that the four new target mRNAs and the ncRNA specifically bind to TSN in testis extracts. These studies have, for the first time, identified both mRNAs and a ncRNA as TSN targets expressed during meiosis.

Deletion of the DNA/RNA-binding protein MSY2 leads to post-meiotic arrest

Y-box proteins are a well-characterized family of nucleic acid binding proteins that are expressed from bacteria to human. This review will focus on MSY2, a member of the Y-box gene family that is exclusively expressed in male and female germ cells. MSY2 is the mouse ortholog of FRGY2, the Xenopus germ cell-specific protein and the human germ cell protein, Contrin. MSY2 functions as a co-activator of transcription in male germ cells and plays an important role in the translational repression and storage of both paternal and maternal mRNAs in spermatocytes, spermatids and oocytes. Following gene targeting, matings of heterozygotes produce a normal Mendelian ratio with equal numbers of phenotypically normal males and females. However, males and females lacking Msy2 are infertile. In Msy2-null males, spermatogenesis is disrupted in post-meiotic germ cells with many misshapen and multinucleated spermatids. No spermatozoa are found in the epididymis. The germ cell specificity and the critical functions played by this multifunctional DNA- and RNA-binding protein during spermatogenesis make Contrin, the human ortholog of MSY2, an attractive and novel target for male contraception.

Endoplasmic Reticulum Oxidoreductin-1-Like β (ERO1lβ) Regulates Susceptibility to Endoplasmic Reticulum Stress and Is Induced by Insulin Flux in β-Cells

Hyperglycemia increases insulin flux through the endoplasmic reticulum (ER) of pancreatic β-cells, and the unfolded protein response pathway is required to enhance insulin processing. Pancreatic and duodenal homeobox 1 (PDX1), a key pancreatic transcription factor, regulates insulin along with targets involved in insulin processing and secretion. Here we find that PDX1 is a direct transcriptional regulator of ER oxidoreductin-1-like β (Ero1lβ), which maintains the oxidative environment of the ER to facilitate disulfide bond formation. PDX1 deficiency reduced Ero1lβ transcript levels in mouse islets and mouse insulinoma (MIN6) cells; moreover, PDX1 occupied the Ero1lβ promoter in β-cells. ERO1lβ levels were induced by high glucose concentrations and by the reducing agent dithiothreitol, indicating potential roles in adaptation to increased oxidative protein folding load in the β-cell ER. In MIN6 cells, small interfering RNA-mediated silencing of Ero1lβ decreased insulin content and increased susceptibility to ER stress-induced apoptosis. These findings demonstrate roles for the PDX1 target ERO1lβ in maintaining insulin content and regulating cell survival during ER stress.