Shiga toxin
From Proteopedia
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==Introduction== | ==Introduction== | ||
'''Shiga Toxins''' are a family of [http://en.wikipedia.org/wiki/AB5_toxin AB5] toxins (Stx1 and Stx2) which cause dysentery, hemolytic-uremic syndrome, and potentially renal failure in humans. They are primarily secreted by Shiga toxin-encoding Escherichia coli (STEC), notably by the 0157:H7 strain<ref name=Wagner>PMID: 12010491</ref> and shigella dysentarie. STECs are one of the major foodborne pathogens, affecting both developed and third-world countries. The stx gene is not endogenous to these strains, but is introduced through horizontal gene transfer from environmental prophages of the lambdoid bacteriophage family and incorporated into the E. Coli genome.<ref name=Wagner>PMID: 12010491</ref> Shiga Toxins are closely related to [[ricin]], which is structurally and mechanistically similar. Shiga toxin acts to inhibit protein synthesis in eukaryotic cells and is the main virulence factor of STEC. | '''Shiga Toxins''' are a family of [http://en.wikipedia.org/wiki/AB5_toxin AB5] toxins (Stx1 and Stx2) which cause dysentery, hemolytic-uremic syndrome, and potentially renal failure in humans. They are primarily secreted by Shiga toxin-encoding Escherichia coli (STEC), notably by the 0157:H7 strain<ref name=Wagner>PMID: 12010491</ref> and shigella dysentarie. STECs are one of the major foodborne pathogens, affecting both developed and third-world countries. The stx gene is not endogenous to these strains, but is introduced through horizontal gene transfer from environmental prophages of the lambdoid bacteriophage family and incorporated into the E. Coli genome.<ref name=Wagner>PMID: 12010491</ref> Shiga Toxins are closely related to [[ricin]], which is structurally and mechanistically similar. Shiga toxin acts to inhibit protein synthesis in eukaryotic cells and is the main virulence factor of STEC. | ||
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| - | {{STRUCTURE_2ga4| PDB=2ga4 | SCENE= }} | ||
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| - | {{STRUCTURE_1dm0| PDB=1dm0 | SCENE= }} | ||
==Human Interaction== | ==Human Interaction== | ||
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Treatment with antibiotics is contraindicated as antibiotic treatment has been demonstrated to increase Stx production up to one hundred fold.<ref name=Herold>PMID: 15493821</ref> This results from the link between Stx production (and phage induction) to the [http://en.wikipedia.org/wiki/SOS_response SOS response pathway].<ref name=Herold>PMID: 15493821</ref> In the event of renal failure kidney dialysis may be employed. A number of potential treatments are under development including B subunit inhibitors, polysaccharides that promote macrophage uptake of Stx, blocking of the GB3 membrane receptor, and inhibition of [http://en.wikipedia.org/wiki/Retrograde_transport#Retrograde_transport retrograde transport].<ref name=Nishikiwa>PMID: 21644029</ref> | Treatment with antibiotics is contraindicated as antibiotic treatment has been demonstrated to increase Stx production up to one hundred fold.<ref name=Herold>PMID: 15493821</ref> This results from the link between Stx production (and phage induction) to the [http://en.wikipedia.org/wiki/SOS_response SOS response pathway].<ref name=Herold>PMID: 15493821</ref> In the event of renal failure kidney dialysis may be employed. A number of potential treatments are under development including B subunit inhibitors, polysaccharides that promote macrophage uptake of Stx, blocking of the GB3 membrane receptor, and inhibition of [http://en.wikipedia.org/wiki/Retrograde_transport#Retrograde_transport retrograde transport].<ref name=Nishikiwa>PMID: 21644029</ref> | ||
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==Structure== | ==Structure== | ||
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Shiga Toxin acts as an N-glycosidase, removing an adenine from the 60S ribosomal rRNA of a target cell leading to reduced protein synthesis.<ref name=Di>PMID: 21184769</ref> The B subunit is necessary for binding to globo series glycolipid globotriaosylceramide (Gb3), a eukaryotic membrane receptor, where it is then endocytosed and proteolytically cleaved into two active A subunits and a B subunit.<ref name=Lenz>PMID: 2170899</ref> Once the A subunit is transported to the cytosol it acts by depurinating the 28S ribosomal RNA which leads to inhibition of protein elongation and ultimately cellular apoptosis. On the A subunit <scene name='Shiga_toxin_1/Active_site_zoomed_in/1'>Tyr77, Tyr114, Glu167, Arg170, and Trp203</scene> are all essential in glycosidic activity.<ref name=Di>PMID: 21184769</ref> | Shiga Toxin acts as an N-glycosidase, removing an adenine from the 60S ribosomal rRNA of a target cell leading to reduced protein synthesis.<ref name=Di>PMID: 21184769</ref> The B subunit is necessary for binding to globo series glycolipid globotriaosylceramide (Gb3), a eukaryotic membrane receptor, where it is then endocytosed and proteolytically cleaved into two active A subunits and a B subunit.<ref name=Lenz>PMID: 2170899</ref> Once the A subunit is transported to the cytosol it acts by depurinating the 28S ribosomal RNA which leads to inhibition of protein elongation and ultimately cellular apoptosis. On the A subunit <scene name='Shiga_toxin_1/Active_site_zoomed_in/1'>Tyr77, Tyr114, Glu167, Arg170, and Trp203</scene> are all essential in glycosidic activity.<ref name=Di>PMID: 21184769</ref> | ||
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==3D structures== | ==3D structures== | ||
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| + | {{STRUCTURE_2ga4| PDB=2ga4 | SCENE= }} | ||
[[1dm0]] - Stx1<br /> | [[1dm0]] - Stx1<br /> | ||
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[[1r4p]] - Stx2 bound to ligand<br /> | [[1r4p]] - Stx2 bound to ligand<br /> | ||
[[2ga4]] - Stx2 with adenine<br /> | [[2ga4]] - Stx2 with adenine<br /> | ||
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'''Mutants''' | '''Mutants''' | ||
Revision as of 17:40, 7 November 2011
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3D structures
1dm0 - Stx1
1r4q - Stx2
1r4p - Stx2 bound to ligand
2ga4 - Stx2 with adenine
Mutants
1c48 - Shiga-like toxin B subunit
1cqf - Shiga-like toxin B subunit bound to trisaccharide
1bos - Shiga-like toxin bound to receptor
References
- ↑ 1.0 1.1 Wagner PL, Livny J, Neely MN, Acheson DW, Friedman DI, Waldor MK. Bacteriophage control of Shiga toxin 1 production and release by Escherichia coli. Mol Microbiol. 2002 May;44(4):957-70. PMID:12010491
- ↑ 2.0 2.1 2.2 Herold S, Karch H, Schmidt H. Shiga toxin-encoding bacteriophages--genomes in motion. Int J Med Microbiol. 2004 Sep;294(2-3):115-21. PMID:15493821
- ↑ Russell JB, Jarvis GN. Practical mechanisms for interrupting the oral-fecal lifecycle of Escherichia coli. J Mol Microbiol Biotechnol. 2001 Apr;3(2):265-72. PMID:11321582
- ↑ Nishikawa K. Recent progress of Shiga toxin neutralizer for treatment of infections by Shiga toxin-producing Escherichia coli. Arch Immunol Ther Exp (Warsz). 2011 Aug;59(4):239-47. Epub 2011 Jun 5. PMID:21644029 doi:10.1007/s00005-011-0130-5
- ↑ 5.0 5.1 5.2 Fraser ME, Chernaia MM, Kozlov YV, James MN. Crystal structure of the holotoxin from Shigella dysenteriae at 2.5 A resolution. Nat Struct Biol. 1994 Jan;1(1):59-64. PMID:7656009
- ↑ 6.0 6.1 Di R, Kyu E, Shete V, Saidasan H, Kahn PC, Tumer NE. Identification of amino acids critical for the cytotoxicity of Shiga toxin 1 and 2 in Saccharomyces cerevisiae. Toxicon. 2011 Mar 15;57(4):525-39. Epub 2010 Dec 22. PMID:21184769 doi:10.1016/j.toxicon.2010.12.006
- ↑ Roman F, Santa A, Rimanoczky A, Toldi Z, Pataki L. [Isotope study of in vitro K(+) uptake and release of erythrocytes in juvenile diabetes with 86Rb]. Padiatr Grenzgeb. 1990;29(4):339-45. PMID:2170899
