Global profiling of coxsackievirus- and cytokine-induced gene expression in human pancreatic islets.

AIMS/HYPOTHESIS: It is thought that enterovirus infections initiate or facilitate the pathogenetic processes leading to type 1 diabetes. Exposure of cultured human islets to cytolytic enterovirus strains kills beta cells after a protracted period, suggesting a role for secondary virus-induced factors such as cytokines. METHODS: To clarify the molecular mechanisms involved in virus-induced beta cell destruction, we analysed the global pattern of gene expression in human islets. After 48 h, RNA was extracted from three independent human islet preparations infected with coxsackievirus B5 or exposed to interleukin 1beta (50 U/ml) plus interferon gamma (1,000 U/ml), and gene expression profiles were analysed using Affymetrix HG-U133A gene chips, which enable simultaneous analysis of 22,000 probe sets. RESULTS: As many as 13,077 genes were detected in control human islets, and 945 and 1293 single genes were found to be modified by exposure to viral infection and the indicated cytokines, respectively. Four hundred and eighty-four genes were similarly modified by the cytokines and viral infection. CONCLUSIONS/INTERPRETATION: The large number of modified genes observed emphasises the complex responses of human islet cells to agents potentially involved in insulitis. Notably, both cytokines and viral infection significantly (p<0.02) increased the expression of several chemokines, the cytokine IL-15 and the intercellular adhesion molecule ICAM-1, which might contribute to the homing and activation of mononuclear cells in the islets during infection and/or an early autoimmune response. The present results provide novel insights into the molecular mechanisms involved in viral- and cytokine-induced human beta cell dysfunction and death.

Comparative genomic hybridization and karyotyping of human embryonic stem cells reveals the occurrence of an isodicentric X chromosome after long-term cultivation.

Human embryonic stem (hES) cells are important research tools in studies of the physiology of early tissue differentiation. In addition, prospects are high regarding the use of these cells for successful cell transplantation. However, one concern has been that cultivation of these cells over many passages might induce chromosomal changes. It is thus important to investigate these cell lines, and check that a normal chromosomal content is retained even during long-term in vitro culture. Comparative genomic hybridization (CGH) was used to analyse three hES cell lines derived in our laboratory and cultured continuously for 30-42 weeks, comprising 35-39 cell passages. CGH could be successfully performed in 48 out of a total of 50 isolated single cells (96%). All three lines (HS181, HS235 and HS237) were shown to have a normal chromosomal content when analysed by both single cell CGH and by karyotyping up to passages 39, 39 and 35 respectively. No aneuploidies or larger deletions or amplifications were detected, and they were female (46,XX). However, HS237 was reanalysed at passage 61, and at that point an aberrant X chromosome was detected by karyotyping. The aberration was confirmed and characterized by single cell CGH and fluorescence in situ hybridization analysis, 46,X,idic(X)(q21). Thus, chromosomal aberrations may occur over time in stem cell lines, and continuous analysis of these cells during cultivation is crucial. Single cell CGH is a method that can be used for continuous analysis of the hES cell lines during cultivation, in order to detect chromosome imbalance.

Rainbow trout glucose transporter (OnmyGLUT1): functional assessment in Xenopus laevis oocytes and expression in fish embryos.

Recently, we reported the cloning of a putative glucose transporter (OnmyGLUT1) from rainbow trout embryos. In this paper, we describe the functional characteristics of OnmyGLUT1 and its expression during embryonic development of rainbow trout. Transport of D-glucose was analysed in Xenopus laevis oocytes following microinjection of mRNA transcribed in vitro. These experiments confirmed that OnmyGLUT1 is a facilitative Na(+)-independent transporter. Assessment of substrate selectivity, sensitivity to cytochalasin B and phloretin and kinetic parameters showed that the rainbow trout glucose transporter was similar to a carp transporter and to mammalian GLUT1. Embryonic expression of OnmyGLUT1 was studied using whole-mount in situ hybridization. Ubiquitous distribution of transcripts was observed until the early phase of somitogenesis. During the course of organogenesis, somitic expression decreased along the rostro-caudal axis, finally ceasing in the mature somites. The OnmyGLUT1 transcripts were detected in the neural crest during the whole study period. Transcripts were also found in structures that are likely to originate from the neural crest cells (gill arches, pectoral fins, upper jaw, olfactory organs and primordia of mouth lips). Hexose transport activity was detected at all developmental stages after blastulation. Cytochalasin B blocked the accumulation of phosphorylated 2-deoxy-D-glucose by dissociated embryonic cells, suggesting an important role for transport in glucose metabolism.

Rainbow trout (Onchorhynchus mykiss) hepatic glucose transporter.

We report identification of a rainbow trout hepatic glucose transporter sharing 58% and 52% amino acid identity with avian and mammalian GLUT2 sequences, respectively. The functionality of OnmyGLUT2 was assessed by expression in rainbow trout embryos. We also measured the transport of hexose in isolated rainbow trout hepatocytes. Inhibition of 3-O-methylglucose uptake by cytochalasin B, phloretin and 2-deoxy-D-glucose suggested the existence of a functional facilitative transporter in these cells. Expression of OnmyGLUT2 was found in the liver, kidney and intestine.

Monosaccharide uptake in common carp (Cyprinus carpio) EPC cells is mediated by a facilitative glucose carrier.

In most animal cells, transport of monosaccharides across the plasma membrane is mediated by glucose transporters (GLUT). Mammals express at least five distinct transporters (GLUTs 1--5), which are well characterised both functionally and genetically. In contrast, the glucose transport system of fish remains poorly studied. Here we report studies of hexose uptake in carp EPC cells and cloning of a glucose transporter cDNA from these cells. Transport of radio-labelled methylglucose (3-OMG) followed Michaelis--Menten kinetics with a K(m) value (8.5 mM) similar to that of mammalian cells. The inhibition of transport by cytochalasin B and phloretin, but not by phloridzin or cyanide, strongly suggested the existence of a facilitative carrier. D-Glucose, 2-deoxyglucose, 3-OMG, D-mannose and D-xylose were competitive inhibitors of 3-OMG uptake, while L-glucose, mannitol, D-fructose, D-ribose and sucrose did not compete with 3-OMG. We cloned a carp glucose transporter (CyiGLUT1), using RT-PCR and RACE strategies. CyiGLUT1 was different from known carp and zebrafish EST sequences. The complete cDNA (3060 bp) contained one open reading frame encoding a predicted protein of 478 amino acids. The deduced amino acid sequence shared 78% identity with mammalian and avian GLUT1 proteins. Key amino acids involved in substrate selection and catalysis of mammalian GLUTs were conserved in the carp transporter.

Cloning and characterization of glucose transporter in teleost fish rainbow trout (Oncorhynchus mykiss).

The facilitated diffusion of monosaccharides across the plasma membrane is mediated by glucose transporters (GLUTs). In contrast to mammals, the glucose transport system of lower vertebrates remains unexplored. We detected glucose transport activity in rainbow trout embryos. Two GLUTs sharing 83% amino acid identity were cloned from juvenile fish, these have been denoted OnmyGLUT1A and OnmyGLUT1B. In adult trout OnmyGLUT1A is predominantly expressed in the heart with low expression in other tissues. An inverse terminal repeat of a Tc1-like transposable element was found in the 3'-untranslated region of OnmyGLUT1B. Phylogenetic analysis suggested that rainbow trout genes share a common ancestor with higher vertebrate GLUT1. We also found GLUT genes in several salmonid species.

Transfer of growth hormone (GH) transgenes into Arctic charr. (Salvelinus alpinus L.) I. Growth response to various GH constructs.

Four constructs containing salmonid growth hormone (GH) genes were transferred to Arctic charr (Salvelinus alpinus L.). Cytomegalovirus (CMV) and piscine metallothionein B (OnMT) and histone 3 (OnH3) promoters connected to sockeye salmon growth hormone 1 gene (OnGH1) were used for ectopic expression, and Atlantic salmon growth hormone 2 gene with 5'flanking region (SsGH2) was tested for pituitary-specific expression. Charr carrying the OnGH1 constructs showed a dramatic increase in growth rate. The 10-month old transformed fish were 14-fold heavier than control siblings. The ability of the CMVGH1 construct to promote growth was greater than that obtained in fish with piscine promoters. Analysis of individual growth curves of charr carrying the OnH3GH1 transgene indicated a stable ratio of specific growth rates in transformed and control fish regardless of fish size. No alteration in growth performance was found in fish carrying the SsGH2 transgene. There was evidence that the transformed rainbow trout (Oncorhynchus mykiss) were unable to produce SsGH2 mRNA in their pituitary glands. The presence of the transgene in various tissues was examined in trout to evaluate the reliability of one-tissue sampling.