SecReT4
SecReT4 contains data from 925 references related to type IV secretion systems (T4SSs). Last Update: Aug 11, 2012

Categories (Literatures contain following contents are categorized)
reviews experimental studies bioinformatics genome sequencing T4SS component T4SS effectors
conjugation DNA uptake and release effector translocation structural study protein interaction other
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Number of references found for the 'pro_interaction' category : 97

References
(1) Vincent CD et al (2012). Identification of the DotL coupling protein subcomplex of the Legionella Dot/Icm type IV secretion system. Mol Microbiol. . [PudMed:22694730]
(2) Villamil Giraldo AM et al (2012). Type IV Secretion System Core Component VirB8 from Brucella Binds to the Globular Domain of VirB5 and to a Periplasmic Domain of VirB6. Biochemistry. 51(18):3881-90. [PudMed:22515661]
(3) Pham KT et al (2012). CagI is an essential component of the Helicobacter pylori Cag type IV secretion system and forms a complex with CagL. PLoS One. 7(4):e35341. [PudMed:22493745]
(4) Morse K et al (2012). Association and evidence for linked recognition of type IV secretion system proteins VirB9-1, VirB9-2, and VirB10 in Anaplasma marginale. Infect Immun. 80(1):215-27. [PudMed:22038917]
(5) Conradi J et al (2012). Cyclic RGD peptides interfere with binding of the Helicobacter pylori protein CagL to integrins alpha(V)beta (3) and alpha (5)beta (1). Amino Acids. 43(1):219-32. [PudMed:21915696]
(6) Dubreuil R et al (2011). Bringing host-cell takeover by pathogenic bacteria to center stage. Cell Logist. 1(4):120-124. [PudMed:22279609]
(7) Lang S et al (2011). An activation domain of plasmid R1 TraI protein delineates stages of gene transfer initiation. Mol Microbiol. 82(5):1071-85. [PudMed:22066957]
(8) Backert S et al (2011). Molecular mechanisms of gastric epithelial cell adhesion and injection of CagA by Helicobacter pylori. Cell Commun Signal. 9:28. [PudMed:22044679]
(9) Wessler S et al (2011). Regulation of the actin cytoskeleton in Helicobacter pylori-induced migration and invasive growth of gastric epithelial cells. Cell Commun Signal. 9(1):27. [PudMed:22044652]
(10) Truttmann MC et al (2011). BID-F1 and BID-F2 domains of Bartonella henselae effector protein BepF trigger together with BepC the formation of invasome structures. PLoS One. 6(10):e25106. [PudMed:22043280]
(11) Berry TM et al (2011). Caught in the act: the dialogue between bacteriophage R17 and the type IV secretion machine of plasmid R1. Mol Microbiol. 82(5):1039-43. [PudMed:22023392]
(12) Jain S et al (2011). Processing and maturation of the pilin of the type IV secretion system encoded within the gonococcal genetic island. J Biol Chem. 286(51):43601-10. [PudMed:22006923]
(13) Fernandez-Gonzalez E et al (2011). Transfer of R388 derivatives by a pathogenesis-associated type IV secretion system into both bacteria and human cells. J Bacteriol. 193(22):6257-65. [PudMed:21908662]
(14) Backert S et al (2011). Pathogenesis of Helicobacter pylori infection. Helicobacter. 16 Suppl 1:19-25. [PudMed:21896081]
(15) Hilbi H et al (2011). Anchors for effectors: subversion of phosphoinositide lipids by legionella. Front Microbiol. 2:91. [PudMed:21833330]
(16) Andrieux L et al (2011). A single amino acid change in the transmembrane domain of the VirB8 protein affects dimerization, interaction with VirB10 and Brucella suis virulence. FEBS Lett. 585(15):2431-6. [PudMed:21763312]
(17) de Barsy M et al (2011). Identification of a Brucella spp. secreted effector specifically interacting with human small GTPase Rab2. Cell Microbiol. 13(7):1044-58. [PudMed:21501366]
(18) Sivanesan D et al (2011). The dimer interface of Agrobacterium tumefaciens VirB8 is important for type IV secretion system function, stability, and association of VirB2 with the core complex. J Bacteriol. 193(9):2097-106. [PudMed:21398549]
(19) Terradot L et al (2011). Architecture of the Helicobacter pylori Cag-type IV secretion system. FEBS J. 278(8):1213-22. [PudMed:21352491]
(20) Tegtmeyer N et al (2011). Role of Abl and Src family kinases in actin-cytoskeletal rearrangements induced by the Helicobacter pylori CagA protein. Eur J Cell Biol. 90(11):880-90. [PudMed:21247656]
(21) Paschos A et al (2011). An in vivo high-throughput screening approach targeting the type IV secretion system component VirB8 identified inhibitors of Brucella abortus 2308 proliferation. Infect Immun. 79(3):1033-43. [PudMed:21173315]
(22) Jurik A et al (2010). The coupling protein Cagbeta and its interaction partner CagZ are required for type IV secretion of the Helicobacter pylori CagA protein. Infect Immun. 78(12):5244-51. [PudMed:20876293]
(23) Olbermann P et al (2010). A global overview of the genetic and functional diversity in the Helicobacter pylori cag pathogenicity island. PLoS Genet. 6(8):e1001069. [PudMed:20808891]
(24) Hutton ML et al (2010). Helicobacter pylori exploits cholesterol-rich microdomains for induction of NF-kappaB-dependent responses and peptidoglycan delivery in epithelial cells. Infect Immun. 78(11):4523-31. [PudMed:20713621]
(25) Kerr JE et al (2010). Evidence for VirB4-mediated dislocation of membrane-integrated VirB2 pilin during biogenesis of the Agrobacterium VirB/VirD4 type IV secretion system. J Bacteriol. 192(19):4923-34. [PudMed:20656905]
(26) Wallden K et al (2010). Type IV secretion systems: versatility and diversity in function. Cell Microbiol. 12(9):1203-12. [PudMed:20642798]
(27) Waksman G et al (2010). Molecular architecture of bacterial type IV secretion systems. Trends Biochem Sci. 35(12):691-8. [PudMed:20621482]
(28) Murata-Kamiya N et al (2010). Helicobacter pylori exploits host membrane phosphatidylserine for delivery, localization, and pathophysiological action of the CagA oncoprotein. Cell Host Microbe. 7(5):399-411. [PudMed:20478541]
(29) Tsai YL et al (2010). The small heat-shock protein HspL is a VirB8 chaperone promoting type IV secretion-mediated DNA transfer. J Biol Chem. 285(26):19757-66. [PudMed:20427270]
(30) Sivanesan D et al (2010). Quantitative analysis of VirB8-VirB9-VirB10 interactions provides a dynamic model of type IV secretion system core complex assembly. Biochemistry. 49(21):4483-93. [PudMed:20426418]
(31) de Paz HD et al (2010). Functional dissection of the conjugative coupling protein TrwB. J Bacteriol. 192(11):2655-69. [PudMed:20363945]
(32) Mossey P et al (2010). Agrobacterium tumefaciens type IV secretion protein VirB3 is an inner membrane protein and requires VirB4, VirB7, and VirB8 for stabilization. J Bacteriol. 192(11):2830-8. [PudMed:20348257]
(33) Xu L et al (2010). Inhibition of host vacuolar H+-ATPase activity by a Legionella pneumophila effector. PLoS Pathog. 6(3):e1000822. [PudMed:20333253]
(34) Zhu Y et al (2010). Structural mechanism of host Rab1 activation by the bifunctional Legionella type IV effector SidM/DrrA. Proc Natl Acad Sci U S A. 107(10):4699-704. [PudMed:20176951]
(35) Niu H et al (2010). Anaplasma phagocytophilum Ats-1 is imported into host cell mitochondria and interferes with apoptosis induction. PLoS Pathog. 6(2):e1000774. [PudMed:20174550]
(36) Rego AT et al (2010). Two-step and one-step secretion mechanisms in Gram-negative bacteria: contrasting the type IV secretion system and the chaperone-usher pathway of pilus biogenesis. Biochem J. 425(3):475-88. [PudMed:20070257]
(37) Jimenez-Soto LF et al (2009). Helicobacter pylori type IV secretion apparatus exploits beta1 integrin in a novel RGD-independent manner. PLoS Pathog. 5(12):e1000684. [PudMed:19997503]
(38) Mihajlovic S et al (2009). Plasmid r1 conjugative DNA processing is regulated at the coupling protein interface. J Bacteriol. 191(22):6877-87. [PudMed:19767437]
(39) Fronzes R et al (2009). The structural biology of type IV secretion systems. Nat Rev Microbiol. 7(10):703-14. [PudMed:19756009]
(40) Urwyler S et al (2009). Endosomal and secretory markers of the Legionella-containing vacuole. Commun Integr Biol. 2(2):107-9. [PudMed:19704903]
(41) Ge J et al (2009). A Legionella type IV effector activates the NF-kappaB pathway by phosphorylating the IkappaB family of inhibitors. Proc Natl Acad Sci U S A. 106(33):13725-30. [PudMed:19666608]
(42) Oliveira MJ et al (2009). CagA associates with c-Met, E-cadherin, and p120-catenin in a multiproteic complex that suppresses Helicobacter pylori-induced cell-invasive phenotype. J Infect Dis. 200(5):745-55. [PudMed:19604117]
(43) Rasis M et al (2009). The LetA-RsmYZ-CsrA regulatory cascade, together with RpoS and PmrA, post-transcriptionally regulates stationary phase activation of Legionella pneumophila Icm/Dot effectors. Mol Microbiol. 72(4):995-1010. [PudMed:19400807]
(44) Bourg G et al (2009). Interactions between Brucella suis VirB8 and its homolog TraJ from the plasmid pSB102 underline the dynamic nature of type IV secretion systems. J Bacteriol. 191(9):2985-92. [PudMed:19251859]
(45) Hatakeyama M (2008). Linking epithelial polarity and carcinogenesis by multitasking Helicobacter pylori virulence factor CagA. Oncogene. 27(55):7047-54. [PudMed:19029944]
(46) Delahay RM et al (2008). The highly repetitive region of the Helicobacter pylori CagY protein comprises tandem arrays of an alpha-helical repeat module. J Mol Biol. 377(3):956-71. [PudMed:18295231]
(47) Hatakeyama M (2008). SagA of CagA in Helicobacter pylori pathogenesis. Curr Opin Microbiol. 11(1):30-7. [PudMed:18243773]
(48) Kutter S et al (2008). Protein subassemblies of the Helicobacter pylori Cag type IV secretion system revealed by localization and interaction studies. J Bacteriol. 190(6):2161-71. [PudMed:18178731]
(49) Aly KA et al (2008). The type IV secretion system component VirB5 binds to the trans-zeatin biosynthetic enzyme Tzs and enables its translocation to the cell surface of Agrobacterium tumefaciens. J Bacteriol. 190(5):1595-604. [PudMed:18165307]
(50) Rolan HG et al (2008). VirB12 is a serological marker of Brucella infection in experimental and natural hosts. Clin Vaccine Immunol. 15(2):208-14. [PudMed:18077620]
(51) Cambronne ED et al (2007). The Legionella pneumophila IcmSW complex interacts with multiple Dot/Icm effectors to facilitate type IV translocation. PLoS Pathog. 3(12):e188. [PudMed:18069892]
(52) Aly KA et al (2007). The VirB5 protein localizes to the T-pilus tips in Agrobacterium tumefaciens. Microbiology. 153(Pt 11):3766-75. [PudMed:17975085]
(53) Hare S et al (2007). Identification, structure and mode of action of a new regulator of the Helicobacter pylori HP0525 ATPase. EMBO J. 26(23):4926-34. [PudMed:17972918]
(54) Pattis I et al (2007). The Helicobacter pylori CagF protein is a type IV secretion chaperone-like molecule that binds close to the C-terminal secretion signal of the CagA effector protein. Microbiology. 153(Pt 9):2896-909. [PudMed:17768234]
(55) Zupan J et al (2007). VirB1* promotes T-pilus formation in the vir-Type IV secretion system of Agrobacterium tumefaciens. J Bacteriol. 189(18):6551-63. [PudMed:17631630]
(56) Baek HY et al (2007). Interaction between the Helicobacter pylori CagA and alpha-Pix in gastric epithelial AGS cells. Ann N Y Acad Sci. 1096:18-23. [PudMed:17405911]
(57) Bayliss R et al (2007). NMR structure of a complex between the VirB9/VirB7 interaction domains of the pKM101 type IV secretion system. Proc Natl Acad Sci U S A. 104(5):1673-8. [PudMed:17244707]
(58) Baron C (2006). VirB8: a conserved type IV secretion system assembly factor and drug target. Biochem Cell Biol. 84(6):890-9. [PudMed:17215876]
(59) Vincent CD et al (2006). The Legionella pneumophila IcmS-LvgA protein complex is important for Dot/Icm-dependent intracellular growth. Mol Microbiol. 61(3):596-613. [PudMed:16803597]
(60) Busler VJ et al (2006). Protein-protein interactions among Helicobacter pylori cag proteins. J Bacteriol. 188(13):4787-800. [PudMed:16788188]
(61) Weber SS et al (2006). Legionella pneumophila exploits PI(4)P to anchor secreted effector proteins to the replicative vacuole. PLoS Pathog. 2(5):e46. [PudMed:16710455]
(62) Paschos A et al (2006). Dimerization and interactions of Brucella suis VirB8 with VirB4 and VirB10 are required for its biological activity. Proc Natl Acad Sci U S A. 103(19):7252-7. [PudMed:16648257]
(63) Bailey S et al (2006). Agrobacterium tumefaciens VirB8 structure reveals potential protein-protein interaction sites. Proc Natl Acad Sci U S A. 103(8):2582-7. [PudMed:16481621]
(64) Couturier MR et al (2006). Interaction with CagF is required for translocation of CagA into the host via the Helicobacter pylori type IV secretion system. Infect Immun. 74(1):273-81. [PudMed:16368981]
(65) Carle A et al (2006). The Brucella suis type IV secretion system assembles in the cell envelope of the heterologous host Agrobacterium tumefaciens and increases IncQ plasmid pLS1 recipient competence. Infect Immun. 74(1):108-17. [PudMed:16368963]
(66) Walker DH et al (2005). Progress in rickettsial genome analysis from pioneering of Rickettsia prowazekii to the recent Rickettsia typhi. Ann N Y Acad Sci. 1063:13-25. [PudMed:16481486]
(67) de Paz HD et al (2005). Functional interactions between type IV secretion systems involved in DNA transfer and virulence. Microbiology. 151(Pt 11):3505-16. [PudMed:16272374]
(68) Hoppner C et al (2005). The putative lytic transglycosylase VirB1 from Brucella suis interacts with the type IV secretion system core components VirB8, VirB9 and VirB11. Microbiology. 151(Pt 11):3469-82. [PudMed:16272371]
(69) Cascales E et al (2005). Agrobacterium tumefaciens oncogenic suppressors inhibit T-DNA and VirE2 protein substrate binding to the VirD4 coupling protein. Mol Microbiol. 58(2):565-79. [PudMed:16194240]
(70) Christie PJ et al (2005). Biogenesis, architecture, and function of bacterial type IV secretion systems. Annu Rev Microbiol. 59:451-85. [PudMed:16153176]
(71) Yuan Q et al (2005). Identification of the VirB4-VirB8-VirB5-VirB2 pilus assembly sequence of type IV secretion systems. J Biol Chem. 280(28):26349-59. [PudMed:15901731]
(72) Alegria MC et al (2005). Identification of new protein-protein interactions involving the products of the chromosome- and plasmid-encoded type IV secretion loci of the phytopathogen Xanthomonas axonopodis pv. citri. J Bacteriol. 187(7):2315-25. [PudMed:15774874]
(73) Cascales E et al (2004). Agrobacterium VirB10, an ATP energy sensor required for type IV secretion. Proc Natl Acad Sci U S A. 101(49):17228-33. [PudMed:15569944]
(74) Atmakuri K et al (2004). Energetic components VirD4, VirB11 and VirB4 mediate early DNA transfer reactions required for bacterial type IV secretion. Mol Microbiol. 54(5):1199-211. [PudMed:15554962]
(75) Hwang HH et al (2004). Plant proteins that interact with VirB2, the Agrobacterium tumefaciens pilin protein, mediate plant transformation. Plant Cell. 16(11):3148-67. [PudMed:15494553]
(76) Beranek A et al (2004). Thirty-eight C-terminal amino acids of the coupling protein TraD of the F-like conjugative resistance plasmid R1 are required and sufficient to confer binding to the substrate selector protein TraM. J Bacteriol. 186(20):6999-7006. [PudMed:15466052]
(77) Noirot P et al (2004). Protein interaction networks in bacteria. Curr Opin Microbiol. 7(5):505-12. [PudMed:15451506]
(78) Hatakeyama M (2004). Oncogenic mechanisms of the Helicobacter pylori CagA protein. Nat Rev Cancer. 4(9):688-94. [PudMed:15343275]
(79) Jakubowski SJ et al (2004). Agrobacterium tumefaciens VirB6 domains direct the ordered export of a DNA substrate through a type IV secretion System. J Mol Biol. 341(4):961-77. [PudMed:15328612]
(80) Harris RL et al (2004). Tra proteins characteristic of F-like type IV secretion systems constitute an interaction group by yeast two-hybrid analysis. J Bacteriol. 186(16):5480-5. [PudMed:15292150]
(81) Shamaei-Tousi A et al (2004). Interaction between protein subunits of the type IV secretion system of Bartonella henselae. J Bacteriol. 186(14):4796-801. [PudMed:15231811]
(82) Llosa M et al (2004). Euroconference on the Biology of Type IV Secretion Processes: bacterial gates into the outer world. Mol Microbiol. 53(1):1-8. [PudMed:15225298]
(83) Terradot L et al (2004). Biochemical characterization of protein complexes from the Helicobacter pylori protein interaction map: strategies for complex formation and evidence for novel interactions within type IV secretion systems. Mol Cell Proteomics. 3(8):809-19. [PudMed:15133060]
(84) Malek JA et al (2004). Protein interaction mapping on a functional shotgun sequence of Rickettsia sibirica. Nucleic Acids Res. 32(3):1059-64. [PudMed:14872061]
(85) Cascales E et al (2003). The versatile bacterial type IV secretion systems. Nat Rev Microbiol. 1(2):137-49. [PudMed:15035043]
(86) Atmakuri K et al (2003). VirE2, a type IV secretion substrate, interacts with the VirD4 transfer protein at cell poles of Agrobacterium tumefaciens. Mol Microbiol. 49(6):1699-713. [PudMed:12950931]
(87) Llosa M et al (2003). Conjugative coupling proteins interact with cognate and heterologous VirB10-like proteins while exhibiting specificity for cognate relaxosomes. Proc Natl Acad Sci U S A. 100(18):10465-70. [PudMed:12925737]
(88) Gilmour MW et al (2003). Interaction between the IncHI1 plasmid R27 coupling protein and type IV secretion system: TraG associates with the coiled-coil mating pair formation protein TrhB. Mol Microbiol. 49(1):105-16. [PudMed:12823814]
(89) Jakubowski SJ et al (2003). Agrobacterium tumefaciens VirB6 protein participates in formation of VirB7 and VirB9 complexes required for type IV secretion. J Bacteriol. 185(9):2867-78. [PudMed:12700266]
(90) Ding Z et al (2002). A novel cytology-based, two-hybrid screen for bacteria applied to protein-protein interaction studies of a type IV secretion system. J Bacteriol. 184(20):5572-82. [PudMed:12270814]
(91) Krall L et al (2002). Detergent extraction identifies different VirB protein subassemblies of the type IV secretion machinery in the membranes of Agrobacterium tumefaciens. Proc Natl Acad Sci U S A. 99(17):11405-10. [PudMed:12177443]
(92) Ward DV et al (2002). Peptide linkage mapping of the Agrobacterium tumefaciens vir-encoded type IV secretion system reveals protein subassemblies. Proc Natl Acad Sci U S A. 99(17):11493-500. [PudMed:12177441]
(93) Schroder G et al (2002). TraG-like proteins of DNA transfer systems and of the Helicobacter pylori type IV secretion system: inner membrane gate for exported substrates. J Bacteriol. 184(10):2767-79. [PudMed:11976307]
(94) Dumenil G et al (2001). The Legionella pneumophila IcmR protein exhibits chaperone activity for IcmQ by preventing its participation in high-molecular-weight complexes. Mol Microbiol. 40(5):1113-27. [PudMed:11401716]
(95) Zhao Z et al (2001). Activities of virE1 and the VirE1 secretion chaperone in export of the multifunctional VirE2 effector via an Agrobacterium type IV secretion pathway. J Bacteriol. 183(13):3855-65. [PudMed:11395448]
(96) Hapfelmeier S et al (2000). VirB6 is required for stabilization of VirB5 and VirB3 and formation of VirB7 homodimers in Agrobacterium tumefaciens. J Bacteriol. 182(16):4505-11. [PudMed:10913084]
(97) Deng W et al (1999). VirE1 is a specific molecular chaperone for the exported single-stranded-DNA-binding protein VirE2 in Agrobacterium. Mol Microbiol. 31(6):1795-807. [PudMed:10209751]