Diabetes mellitus due to viruses — some recent developments (original) (raw)
- Harris HF (1899) A case of diabetes mellitus quickly following mumps. Boston Med Surg J 140: 465–469
Google Scholar - Todd JA (1991) A protective role of the environment in the development of Type 1 diabetes. Diabetic Med 8: 906–910
Google Scholar - Drash AL, Lipton RB, Dorman JS et al. (1991) The interface between epidemiology and molecular biology in the search for the causes of insulin-dependent diabetes mellitus. Ann Med 23: 463–471
Google Scholar - Gamble DR, Taylor KW (1969) Seasonal incidence of diabetes mellitus. BMJ 3: 631–633
Google Scholar - Gamble DR, Kinsley ML, Fitzgerald MG, Bolton R, Taylor KW (1969) Viral antibodies in diabetes mellitus. BMJ 3: 627–630
Google Scholar - King ML, Shaikh A, Bidwell D, Voller A, Banatvala JE (1983) Coxsackie-virus-specific IgM responses in children with insulin-dependent diabetes mellitus. Lancet I: 1397–1399
Google Scholar - Diabetes Epidemiology Research International (1987) Preventing insulin-dependent diabetes mellitus: the environmental challenge. BMJ 295: 479–481
Google Scholar - Diabetes Epidemiology Research International (1990) Secular trends in the incidence of childhood IDDM in 10 countries. Diabetes 39: 858–864
Google Scholar - Gladisch R, Hofmann W, Waldherr R (1976) Myocarditis and insulitis in Coxsackie virus infection. Z Kardiol 65: 873–881
Google Scholar - Yoon J-W, Austin M, Onodera T, Notkins AL (1979) Virus-induced diabetes mellitus. Isolation of a virus from a child with diabetic ketoacidosis. New Engl J Med 300: 1173–1178
Google Scholar - Champsaur H, Dussaix E, Samolyk D, Fabre M, Bach C, Assan R (1980) Diabetes and Coxsackie virus B5 infection. Lancet I: 251
Google Scholar - Uriarte A, Cabrera E, Ventura R, Vargas J (1987) Islet cell antibodies and echo 4 virus infection. Diabetologia 30: A 590 (Abstract)
Google Scholar - Wagenknecht LE, Roseman JM, Herman WH (1991) Increased incidence of insulin dependent diabetes mellitus following an epidemic of Coxsackie B5. Am J Epidemiol 133: 1024–1031
Google Scholar - Rewers M, LaPorte RE, Walczak M, Dmochowski K, Bogaczynska E (1987) Apparent epidemic of insulin-dependent diabetes mellitus in Midwestern Poland. Diabetes 36: 106–113
Google Scholar - Bae Y-S, Eun H-M, Pon RT, Giron GW, Yoon J-W (1990) Two amino acids, Phe-16 and Ala-776, on the polyprotein are most likely to be responsible for the diabetogenicity of EMC virus. J Gen Virol 71: 639–645
Google Scholar - Titchener PA (1991) Genetic studies on coxsackievirus B4 tissue tropism. Ph. D Thesis, University of Reading, Reading, UK
Google Scholar - Ramsingh A, Araki H, Bryant S, Hixson A (1992) Identification of candidate sequences that determine virulence in Coxsackie B4. Virus Res 23: 281–292
Google Scholar - Menser MA, Forrest JM, Bransby RD (1978) Rubella infection and diabetes mellitus. Lancet I: 57–60
Google Scholar - Ward KP, Galloway WH, Auchterlonie IA (1979) Congenital cytomegalovirus and diabetes. Lancet I: 497
Google Scholar - Pak C-Y, McArthur RG, Eun H-M, Yoon J-W (1988) Cytomegalovirus infection with autoimmune type I diabetes. Lancet I: 1–14
Google Scholar - Pak CY, Cha CY, Rajotte RV, McArthur RG, Yoon J-W (1990) Human pancreatic islet cell specific 38kD autoantigen identified by cytomegalovirus-induced monoclonal islet cell autoantibody. Diabetologia 33: 569–572
Google Scholar - Suenaga K, Yoon J-W (1988) Association of beta cell specific expression of endogenous retrovirus with the development of insulitis and diabetes in NOD mice. Diabetes 37: 1719–1726
Google Scholar - Like AA, Chick WL (1970) Studies on the diabetic mutant mouse. II. Electron microscopy of pancreatic islets. Diabetologia 6: 216–242
Google Scholar - Like AA, Rossini AA (1976) Streptozotocin-induced pancreatic insulitis: a new model of diabetes mellitus. Science 193: 415–417
Google Scholar - Leiter EH, Bedigian HG (1979) Intracisternal type A particles in genetically diabetic mice: identification in pancreas and induction in cultured B-cells. Diabetologia 17: 175–185
Google Scholar - Gamble DR (1980) The epidemiology of insulin-dependent diabetes with particular reference to the relationship of virus infection to its etiology. Epidemiol Rev 2: 49–70
Google Scholar - Barrett-Connor E (1985) Is insulin-dependent diabetes mellitus caused by coxsackievirus B infection? A review of epidemiologic evidence. Rev Infect Dis 7: 207–215
Google Scholar - Palmer JP, Cooney MK, Ward RH et al. (1982) Reduced coxsackie antibody titres in type 1 (insulin-dependent) diabetic patients during an outbreak of Coxsackie B3 and B4 infection. Diabetologia 22: 426–429
Google Scholar - Hyoty H, Huupponen T, Kotola L, Leinikki P (1986) Humoral immunity against viral antigens in type I diabetes: altered IgA class immune response against Coxsackie B4 virus. Acta Path Microbiol Immunol Scand 94: 83–88
Google Scholar - Yoon J-W, McClintock PR, Onodera T, Notkins AL (1980) Virus induced diabetes mellitus. XVIII. Inhibition by a nondiabetogenic variant of encephalomyocarditis virus. J Exp Med 152: 878–892
Google Scholar - Burch GE, Tsui C-Y, Harb JM, Colcolough HL (1971) Pathologic findings in the pancreas of mice infected with coxsackievirus B4. Arch Intern Med 128: 40–47
Google Scholar - Tsui C-Y, Burch GE, Harb JM (1972) Pancreatitis in mice infected with coxsackievirus B. Arch Path 93: 379–389
Google Scholar - Coleman TJ, Taylor KW, Gamble DR (1974) The development of diabetes following Coxsackie B virus infection in mice. Diabetologia 10: 753–759
Google Scholar - Kuno S, Itagaki A, Yamazaki I, Katsumoto T, Kurimura T (1984) Pathogenicity of newly isolated Coxsackievirus B4 for mouse pancreas. Acta Virol 28: 433–436
Google Scholar - Jordan GW, Bolton V, Schmidt N (1985) Diabetogenic potential of Coxsackie B viruses in nature. Arch Virol 86: 213–221
Google Scholar - Szopa TM, Ward T, Dronfield DM, Portwood ND, Taylor KW (1990) Coxsackie B4 viruses with the potential to damage beta cells of the islets are present in clinical isolates. Diabetologia 33: 325–328
Google Scholar - Yoon J-W, Onodera T, Notkins AL (1978) Virus-induced diabetes mellitus: beta cell damage and insulin-dependent hyperglycaemia in mice infected with coxsackievirus B4. J Exp Med 148: 1068–1080
Google Scholar - Toniolo A, Onodera T, Jordan G, Yoon J-W, Notkins AL (1982) Virus-induced diabetes mellitus: glucose abnormalities produced in mice by the six members of the Coxsackie B virus group. Diabetologia 31: 496–499
Google Scholar - Wyatt HV (1973) Poliomyelitis in hypogammaglobulinemics. J Infect Dis 128: 802–806
Google Scholar - Wilfert CM, Buckley RH, Mohanakamur T et al. (1977) Persistent and fatal nervous system echo virus infection in patients with agammaglobulinemia. New Eng J Med 296: 1485–1489
Google Scholar - Bowles NE, Richardson PJ, Olsen EGJ, Archard LC (1986) Detection of Coxsackie-B-virus-specific RNA sequences in myocardial biopsy samples from patients with myocarditis and dilated cardiomyopathy. Lancet I: 1120–1123
Google Scholar - Schnurr DP, Cao Y, Schmidt NJ (1984) Coxsackie B3 virus persistence and myocarditis in N:NIH(s) II nu/nu and + /nu mice. J Gen Virol 65: 1197–1201
Google Scholar - Bocharov EV, Shalaurova BV (1984) Persistence of Coxsackie B1 virus in BALB/c mice. Acta Virol 28: 345
Google Scholar - Matteuci D, Paglianti M, Giangregorio AM, Capobianchi MR, Dianzani F, Bendinelli M (1985) Group B Coxsackieviruses readily establish persistent infections in human lymphoid cell lines. J Virol 56: 651–654
Google Scholar - Schnurr DP, Schmidt NJ (1984) Persistent infection of mouse fibroblasts with coxsackievirus. Arch Virol 81: 91–101
Google Scholar - Frank JA Jr, Schmidt EV, Smith RE, Wilfert CM (1986) Persistent infections of rat insulinoma cells with Coxsackie B4 virus. Arch Virol 87: 143–150
Google Scholar - Gibson JP, Righthand F (1985) Persistence of echovirus 6 in cloned human cell lines. J Virol 54: 219–223
Google Scholar - Montgomery L, Gordon D, George K, Maratos-Flier E (1991) Coxsackie infection of insulinoma cells leads to viral latency and altered insulin and class I MHC expression. Diabetes 40: 150 A. (Abstract)
Google Scholar - Vella C (1990) Coxsackie B4 infection of the pancreas — a murine model. Ph. D Thesis, University of London, London, UK
Google Scholar - Rabinowe SL, George KL, Laughlin R, Soeldner JS, Eisenbarth GS (1986) Congenital rubella: monoclonal antibody defined T-cell abnormalities in young children. Am J Med 81: 779–782
Google Scholar - Holland J, Spindler K, Horodyski F, Grabau B, Nichol S, Vandepol S (1987) Rapid evolution of RNA genomes. Science 215: 1577–1585
Google Scholar - Prabhakar BJ, Haspel MV, McClintock PR, Notkins AL (1985) Detection of conserved and nonconserved epitopes on Coxsackie virus B: frequency of antigenic change. Virology 146: 302–306
Google Scholar - Szopa TM, Dronfield DM, Ward T, Taylor KW (1989) In vivo infection of mice with Coxsackie B4 virus induces long-term functional changes in pancreatic islets with minimal alteration in blood glucose. Diabetic Med 6: 314–319
Google Scholar - Oldstone MBA, Southern P, Rodriguez M, Lampeter P (1984) Virus persists in the beta cells of islets of Langerhans and is associated with chemical manifestations of diabetes. Science 224: 1440–1443
Google Scholar - Cohen SR, Naviaux RK, Vanden Brinck KM, Jordan GW (1988) Comparison of the nucleotide sequences of diabetogenic and nondiabetogenic encephalomyocarditis virus. Virology 166: 603–607
Google Scholar - Bae Y-S, Eun H-M, Yoon J-W (1989) Genomic differences between the diabetogenic and nondiabetogenic variants of encephalomyocarditis virus. Virology 170: 282–287
Google Scholar - Jenkins O, Booth JD, Minor PD, Almond JW (1987) The complete nucleotide sequence of Coxsackie virus B4 and its comparison to other members of the Picornaviridae. J Gen Virol 68: 1835–1848
Google Scholar - Rivera VM, Welsh JD, Maizel JV (1988) Comparitive sequence analysis of the 5′ noncoding region of enteroviruses and rhinoviruses. Virology 165: 42–50
Google Scholar - Pelletier J, Sonenberg N (1988) Internal initiation of translation of eukaryotic mRNA directed by a sequence derived from poliovirus RNA. Nature 334: 320–325
Google Scholar - Pelletier J, Sonenberg N (1989) Internal binding of eukaryotic ribosomes on poliovirus mRNA: translation in HeLa cell extracts. J Virol 63: 441–444
Google Scholar - Trono D, Andino R, Baltimore D (1988) An RNA sequence of hundreds of nucleotides at the 5′ end of poliovirus RNA is involved in allowing viral protein synthesis. J Virol 62: 2291–2299
Google Scholar - Trono D, Pelletier J, Sonenberg N, Baltimore D (1988) Translation in mammalian cells of a gene linked to the poliovirus 5′ noncoding region. Science 241: 445–448
Google Scholar - Craighead JE, McLane MF (1968) Diabetes mellitus: induction in mice by encephalomyocarditis virus. Science 162: 913–914
Google Scholar - Yoon J-W, London WT, Curfman BL, Brown RL, Notkins AL (1986) Coxsackievirus B4 produces transient diabetes in nonhuman primates. Diabetes 35: 712–716
Google Scholar - Hellqvist LNB, Taylor KW, Zaluzny S (1981) Selective disorganisation of biochemical function in B cells of islets of Langerhans infected by EMC-M virus in tissue culture. FEBS Lett 132: 215–218
Google Scholar - Szopa TM, Gamble DR, Taylor KW (1986) Coxsackie B4 virus induces short-term changes in the metabolic functions of mouse pancreatic islets in vitro. Cell Biochem Funct 4: 181–189
Google Scholar - Szopa TM, Ward T, Taylor KW (1986) Impaired metabolic function in human pancreatic islets following infection with Coxsackie B4 virus in vitro. Diabetologia 30: 587 (Abstract)
Google Scholar - Yoon J-W, Onodera T, Notkins AL (1978) Virus-induced diabetes mellitus. XI. Replication of Coxsackie virus B3 in human pancreatic beta cell culture. Diabetes 27: 778–781
Google Scholar - Chatterjee NK, Haley TM, Nejman C (1986) Functional alterations in pancreatic β cells as a factor in virus-induced hyperglycaemia. J Biol Chem 260: 12786–12791
Google Scholar - Szopa TM, Ward T, Taylor KW (1992) Disturbance of mouse pancreatic _β_-cell function following echo 4 virus infection. Biochem Soc Trans 20: 3155
Google Scholar - Petersen K-G, Heilmeyer P, Kerp L (1975) Synthesis of proinsulin and large glucagon immunoreactivity in isolated islets of Langerhans from EMC virus infected mice. Diabetologia 11: 21–25
Google Scholar - Ward T, Clemens J, Taylor KW (1990) Effects of a diabetogenic strain of encephalomyocarditis virus on protein synthesis in mouse islets of Langerhans. Biochem J 270: 777–781
Google Scholar - Portwood ND, Taylor KW (1990) Coxsackie B4 virus-induced changes in mouse pancreatic _β_-cell mRNAs. Biochem Soc Trans 18: 1264
Google Scholar - Portwood ND, Clemens MJ, Taylor KW (1991) Differential effects of Coxsackie B4 virus on murine pancreatic preproinsulin mRNA. Biochem Soc Trans 19: 398
Google Scholar - Krausslich HG, Niclin MHJ, Toyoda H, Etchison D, Wimmer E (1987) Poliovirus proteinase 2A induces cleavage of eucaryotic initiation factor 4F polypeptide p220. J Virol 61: 2711–2718
Google Scholar - Jordan GW, Bolton V (1986) Interferon-sensitive coxsackievirus variants in nature. J Interf Res 5: 289–296
Google Scholar - Rhodes CJ, Taylor KW (1985) Effect of interferon and double-stranded RNA on B-cell function in mouse islets of Langerhans. Biochem J 228: 87–94
Google Scholar - Campbell IL, Harrison LC, Ashcroft RG, Jack I (1988) Reovirus infection enhances expression of class I proteins on human B-cells and rat RIN m5B cells. Diabetes 37: 362–365
Google Scholar - Cavallo MG, Baroni MG, Toto A et al. (1992) Viral infection induces cytokine release by islet beta cells. Immunology 75: 664–668
Google Scholar - Parkkonen P, Hyoty H, Koskinen L, Leinikki P (1992) Mumps virus infects beta cells in human fetal islet cell cultures upregulating the expression of HLA class I molecules. Diabetologia 35: 63–69
Google Scholar - Dobersen MJ, Scharf JE, Ginsberg-Fellner F, Notkins AL (1980) Cytotoxic autoantibodies to _β_-cells in the serum of patients with insulin dependent diabetes mellitus. New Engl J Med 303: 1493–1498
Google Scholar - Kanatsuna T, Lernmark A, Rubenstein AH, Steiner DF (1981) Block in insulin release from column perifused pancreatic β cells induced by islet cell surface antibodies and complement. Diabetes 30: 231–234
Google Scholar - Dronfield DM (1992) Viruses, islet cell antibodies, and pancreatic B-cell function. Ph. D Thesis, University of London, London, UK
Google Scholar - Rubinstein P, Walker ME, Fedun B, Witt ME, Cooper LZ, Ginsberg-Fellner F (1982) The HLA system in congenital rubella patients with and without diabetes. Diabetes 31: 1088–1091
Google Scholar - Ginsberg-Fellner F, Witt ME, Yagihashi S et al. (1984) Congenital rubella syndrome as a model for type 1 (insulin-dependent) diabetes mellitus: increased prevalence of islet cell surface antibodies. Diabetologia 27: 87–89
Google Scholar - Drash AL, Lipton RB, Dorman JS et al. (1991) The interface between epidemiology and molecular biology in the search for causes of insulin-dependent diabetes mellitus. Ann Med 23: 463–471
Google Scholar - Nigro G, Pacella ME, Patane E, Midulla M (1986) Multi-system Coxsackie B-6 infection with findings suggestive of diabetes mellitus, Eur J Paediatr 145: 557–559
Google Scholar - Schernthaner G, Ludwig H, Mayr WR (1978) Coxsackie B4 viral infection, anti-islet immunity and immunogenetics in insulin-dependent diabetes mellitus. Acta Diabet Lat 15: 184–191
Google Scholar - Scherbaum WA, Hampl W, Muir P et al. (1991) No association between islet cell antibodies and Coxsackie B, mumps, rubella and cytomegalovirus antibodies in non-diabetic individuals aged 7–19 years. Diabetologia 34: 835–838
Google Scholar - Ujevich MM, Jaffe R (1980) Pancreatic islet cell damage in children with fatal viral infections. Arch Path Lab Med 104: 438–441
Google Scholar - Jenson AB, Rosenberg HS, Notkins AL (1980) Pancreatic damage in children with fatal viral infections. Lancet II: 354–358
Google Scholar - Buschard K, Rygaard J, Ropke C, Lund E (1986) Circulating islet cell antibodies in virus induced diabetes antecede clinical disease. Diabetes 35: 185 (Abstract)
Google Scholar - Gerling I, Chatterjee NK, Nejman C (1991) Coxsackie B4-induced development of antibodies to 64,000-Mr islet autoantigen and hyperglycaemia in mice. Autoimmunity 10: 49–56
Google Scholar - Notkins AL (1984) On the track of viruses. Nature 311: 209–210
Google Scholar - Oldstone MBA (1987) Molecular mimicry and autoimmune disease. Cell 50: 819–820
Google Scholar - Baekkeskov S, Aanstoot H-J, Christgau S et al. (1990) Identification of the 64,000 K autoantigen in insulin dependent diabetes as the GABA synthesizing enzyme glutamic acid decarboxylase. Nature 347: 151–153
Google Scholar - Kaufman DL, Erlander MG, Clare-Salzler M, Atkinson MA, Maclaren MA, Tobin AJ (1992) Autoimmunity to two forms of glutamate decarboxylase in insulin-dependent diabetes mellitus. J Clin Invest 89: 283–292
Google Scholar - Bu D-F, Erlander MG, Hitz BC et al. (1992) Two human glutamate decarboxylases 65-kDa GAD and 67-kDa GAD, are encoded by a single gene. Proc Natl Acad Sci USA 89: 2115–2119
Google Scholar - Jones DB, McLaughlin PJ, Armstrong N, Yeung M, Coulson A (1992) Does Coxsackie B4 virus infection induce GAD and HSP65 autoreactivity in type 1 diabetes? Diabetic Med 9 [Suppl 2]: 524 (Abstract)
Google Scholar - Oldstone MBA, Nerenberg M, Southern P, Price J, Lewicki H (1991) Virus infection triggers insulin-dependent diabetes mellitus in a transgenic model: role of anti-self (virus) immune response. Cell 65: 319–331
Google Scholar - Barboni E, Mannochio I, Asdurbali G (1966) Observations on diabetes mellitus associated with experimental foot and mouth disease in cattle. Vet Ital 17: 362–368
Google Scholar - Yoon J-W, Morishima T, McClintock PR, Austin M, Notkins AL (1984) Virus-induced diabetes mellitus: mengovirus infects pancreatic beta cells in strains of mice resistant to the diabetogenic effects of encephalomyocarditis virus. J Virol 50: 684–690
Google Scholar - John HJ (1934) The diabetic child. Etiologic factors. Ann Intern Med 8: 198–213
Google Scholar - Frisk G, Nilsson E, Tuvemo T, Friman G, Diderholm H (1992) The possible role of coxsackie A and echo virus in the pathogenesis of type 1 diabetes mellitus studied by IgM analysis. J Infect 24: 13–22
Google Scholar - Sussman ML, Strauss L, Hodes HL (1959) Fatal Coxsackie group B virus infection in the newborn. Am J Dis Child 97: 483–492
Google Scholar - Nelson PG, Arthur LJH, Gurling KJ, Gamble DR, Taylor KW (1977) Familial juvenile-onset diabetes. BMJ 2: 1126–1127
Google Scholar - Kaplan MH, Klein SW, McPhee J, Harper RG (1983) Coxsackie virus infections in infants younger than 3 months of age: a serious childhood illness. Rev Infect Dis 5: 1019–1032
Google Scholar - Wilson C, Connolly JM, Thomson D (1977) Coxsackie B2 virus infection and acute onset diabetes in a child. BMJ 1: 1008
Google Scholar - Asplin CM, Cooney MK, Crossley JR, Dornan TL, Raghu P, Palmer JP (1982) Coxsackie B4 infection and islet cell antibodies three years before overt diabetes. J Pediatr 101: 398–400
Google Scholar - Nihalani KD, Pethani RR, Menon PS, Mehtalia SD (1982) Coxsackie B4 virus causing insulin dependent diabetes mellitus, myopericarditis and encephalitis — a case report. JAPI 30: 107–109
Google Scholar - Ahmad N, Abraham AA (1982) Pancreatic isleitis with Coxsackie virus B5 infection. Hum Path 13: 661–662
Google Scholar