publication . Article . Preprint . Other literature type . 2018

4-Hydroxyphenylpyruvate Dioxygenase Thermolability Is Responsible for Temperature-Dependent Melanogenesis in Aeromonas salmonicida subsp. salmonicida

Qiao, Yunqian; Wang, Jiao; Wang, He; Chai, Baozhong; Rao, Chufeng; Chen, Xiangdong; Du, Shishen;
Open Access
  • Published: 17 May 2018 Journal: Applied and Environmental Microbiology, volume 85 (issn: 0099-2240, eissn: 1098-5336, Copyright policy)
  • Publisher: American Society for Microbiology
Abstract
<jats:title>ABSTRACT</jats:title> <jats:p><jats:named-content content-type="genus-species">Aeromonas salmonicida</jats:named-content> subsp. <jats:italic>salmonicida</jats:italic> is a major pathogen affecting fisheries worldwide and is a well-known pigmented member of the <jats:italic>Aeromonas</jats:italic> genus. This subspecies produces melanin at ≤22°C. However, melanogenesis decreases as the culture temperature increases and is completely suppressed at 30°C to 35°C, while bacterial growth is unaffected. The mechanism and biological significance of this temperature-dependent melanogenesis remain unclear. Heterologous expression of an <jats:named-content con...
Subjects
Medical Subject Headings: animal diseases
free text keywords: Pathogen, Biology, Microbiology, Aeromonas salmonicida, biology.organism_classification, Escherichia coli, medicine.disease_cause, medicine, 4-Hydroxyphenylpyruvate dioxygenase, Homogentisic acid, chemistry.chemical_compound, chemistry, Thermolabile, Aeromonas media, Aeromonas, Enzyme, chemistry.chemical_classification, Dioxygenase, Heterologous expression, Genetics, Genetics and Molecular Biology
Related Organizations

1. Singh S, Malhotra AG, Pandey A, Pandey KM. 2013. Computational model for 2. Nosanchuk JD, Casadevall A. 2006. Impact of melanin on microbial virulence and 3. Kwon-Chung KJ, Rhodes JC. 1986. Encapsulation and melanin formation as indicators 4. Dixon DM, Migliozzi J, Cooper CR, Jr., Solis O, Breslin B, Szaniszlo PJ. 1992.

6. Chai B, Qiao Y, Wang H, Zhang X, Wang J, Wang C, Zhou P, Chen X. 2017.

7. Wang H, Qiao Y, Chai B, Qiu C, Chen X. 2015. Identification and molecular 8. Janda JM, Abbott SL. 2010. The genus Aeromonas: taxonomy, pathogenicity, and 9. Abbott SL, Cheung WK, Janda JM. 2003. The genus Aeromonas: biochemical 10. Martin-Carnahan A, Joseph SW. 2005. Family I. Aeromonadaceae Colwell, 11. McIntosh D, Austin B. 1991. Atypical characteristics of the salmonid pathogen 12. Griffin PJ, Snieszko SF, Friddle SB. 1953. Pigment formation by Bacterium salmonicida. J Bacteriol 65:652-659.

13. Griffin PJ, Snieszko SF, Friddle SB. 1953. A more comprehensive description of Bacterium salmonicida. Trans Am Fish Soc 82:129-138.

14. Daher RK, Filion G, Tan SG, Dallaire-Dufresne S, Paquet VE, Charette SJ. 2011.

15. Stuber K, Burr SE, Braun M, Wahli T, Frey J. 2003. Type III secretion genes in 17. Moki ST, Nomura T, Yoshimizu M. 1995. Effect of incubation temperature for 18. Anbar M, Gul O, Lamed R, Sezerman UO, Bayer EA. 2012. Improved 19. Vázquez-Figueroa E, Chaparro-Riggers J, Bommarius AS. 2007. Development of a 20. Amin N, Liu AD, Ramer S, Aehle W, Meijer D, Metin M, Wong S, Gualfetti P, 21. Chou PY, Fasman GD. 1974. Conformational parameters for amino acids in helical, 22. Munoz V, Serrano L. 1994. Intrinsic secondary structure propensities of the amino 23. Kim CA, Berg JM. 1993. Thermodynamic β-sheet propensities measured using a 24. Koh E, Kim T, Cho HS. 2006. Mean curvature as a major determinant of β-sheet 33. Watanabe K, Hata Y, Kizaki H, Katsube Y, Suzuki Y. 1997. The refined crystal 25. Robson B, Suzuki E. 1976. Conformational properties of amino acid residues in globular proteins. J Mol Biol 107:327-356. [OpenAIRE]

26. O'Neil KT, DeGrado WF. 1990. A thermodynamic scale for the helix-forming 27. von Heijne G. 1991. Proline kinks in transmembrane α-helices. J Mol Biol 28. Sankararamakrishnan R, Vishveshwara S. 1992. Geometry of proline-containing 29. Schimmel PR, Flory PJ. 1968. Conformational energies and configurational statistics 30. Matthews BW, Nicholson H, Becktel WJ. 1987. Enhanced protein thermostability 31. Zhou C, Xue Y, Ma Y. 2010. Enhancing the thermostability of α-glucosidase from 34. De Vendittis E, Castellano I, Cotugno R, Ruocco MR, Raimo G, Masullo M. 2008. [OpenAIRE]

35. Metpally RP, Reddy BV. 2009. Comparative proteome analysis of psychrophilic 36. O'HIci B, Olivier G, Powell R. 2000. Genetic diversity of the fish pathogen 37. Colston SM, Fullmer MS, Beka L, Lamy B, Gogarten JP, Graf J. 2014. Bioinformatic 39. Wiklund T, Dalsgaard I. 1998. Occurrence and significance of atypical Aeromonas 42. Pavan ME, Pavan EE, López NI, Levin L, Pettinari MJ. 2015. Living in an extremely 44. Belland RJ, Trust TJ. 1988. DNA:DNA reassociation analysis of Aeromonas 45. Hänninen ML, Hirvelä-Koski V. 1997. Molecular and phenotypic methods for the 46. Høie S, Dalsgaard I, Aase IL, Heum M, Thornton JM, Powell R. 1999. Polymerase 47. Sørum H, Holstad G, Lunder T, Håstein T. 2000. Grouping by plasmid profiles of 48. Umelo E, Trust TJ. 1998. Physical map of the chromosome of Aeromonas 49. Lund V, Jenssen LM, Wesmajervi MS. 2002. Assessment of genetic variability and 50. Studer N, Frey J, Vanden Bergh P. 2013. Clustering subspecies of Aeromonas 51. Martinez-Murcia AJ, Benlloch S, Collins MD. 1992. Phylogenetic interrelationships 52. Gulla S, Lund V, Kristoffersen AB, Sorum H, Colquhoun DJ. 2016. vapA (A-layer) 53. Rodriguez-Rojas A, Mena A, Martin S, Borrell N, Oliver A, Blazquez J. 2009.

Microbiology 155:1050-1057.

54. Wang R, Wang H, Zhou H, Wang Y, Yue J, Diao B, Kan B. 2011. Characters of 55. Han H, Iakovenko L, Wilson AC. 2015. Loss of homogentisate 1,2-dioxygenase 57. Dehio C, Meyer M. 1997. Maintenance of broad-host-range incompatibility group P 60. Serre L, Sailland A, Sy D, Boudec P, Rolland A, Pebay-Peyroula E, Cohen-Addad C.

1999. Crystal structure of Pseudomonas fluorescens 4-hydroxyphenylpyruvate

Abstract
<jats:title>ABSTRACT</jats:title> <jats:p><jats:named-content content-type="genus-species">Aeromonas salmonicida</jats:named-content> subsp. <jats:italic>salmonicida</jats:italic> is a major pathogen affecting fisheries worldwide and is a well-known pigmented member of the <jats:italic>Aeromonas</jats:italic> genus. This subspecies produces melanin at ≤22°C. However, melanogenesis decreases as the culture temperature increases and is completely suppressed at 30°C to 35°C, while bacterial growth is unaffected. The mechanism and biological significance of this temperature-dependent melanogenesis remain unclear. Heterologous expression of an <jats:named-content con...
Subjects
Medical Subject Headings: animal diseases
free text keywords: Pathogen, Biology, Microbiology, Aeromonas salmonicida, biology.organism_classification, Escherichia coli, medicine.disease_cause, medicine, 4-Hydroxyphenylpyruvate dioxygenase, Homogentisic acid, chemistry.chemical_compound, chemistry, Thermolabile, Aeromonas media, Aeromonas, Enzyme, chemistry.chemical_classification, Dioxygenase, Heterologous expression, Genetics, Genetics and Molecular Biology
Related Organizations

1. Singh S, Malhotra AG, Pandey A, Pandey KM. 2013. Computational model for 2. Nosanchuk JD, Casadevall A. 2006. Impact of melanin on microbial virulence and 3. Kwon-Chung KJ, Rhodes JC. 1986. Encapsulation and melanin formation as indicators 4. Dixon DM, Migliozzi J, Cooper CR, Jr., Solis O, Breslin B, Szaniszlo PJ. 1992.

6. Chai B, Qiao Y, Wang H, Zhang X, Wang J, Wang C, Zhou P, Chen X. 2017.

7. Wang H, Qiao Y, Chai B, Qiu C, Chen X. 2015. Identification and molecular 8. Janda JM, Abbott SL. 2010. The genus Aeromonas: taxonomy, pathogenicity, and 9. Abbott SL, Cheung WK, Janda JM. 2003. The genus Aeromonas: biochemical 10. Martin-Carnahan A, Joseph SW. 2005. Family I. Aeromonadaceae Colwell, 11. McIntosh D, Austin B. 1991. Atypical characteristics of the salmonid pathogen 12. Griffin PJ, Snieszko SF, Friddle SB. 1953. Pigment formation by Bacterium salmonicida. J Bacteriol 65:652-659.

13. Griffin PJ, Snieszko SF, Friddle SB. 1953. A more comprehensive description of Bacterium salmonicida. Trans Am Fish Soc 82:129-138.

14. Daher RK, Filion G, Tan SG, Dallaire-Dufresne S, Paquet VE, Charette SJ. 2011.

15. Stuber K, Burr SE, Braun M, Wahli T, Frey J. 2003. Type III secretion genes in 17. Moki ST, Nomura T, Yoshimizu M. 1995. Effect of incubation temperature for 18. Anbar M, Gul O, Lamed R, Sezerman UO, Bayer EA. 2012. Improved 19. Vázquez-Figueroa E, Chaparro-Riggers J, Bommarius AS. 2007. Development of a 20. Amin N, Liu AD, Ramer S, Aehle W, Meijer D, Metin M, Wong S, Gualfetti P, 21. Chou PY, Fasman GD. 1974. Conformational parameters for amino acids in helical, 22. Munoz V, Serrano L. 1994. Intrinsic secondary structure propensities of the amino 23. Kim CA, Berg JM. 1993. Thermodynamic β-sheet propensities measured using a 24. Koh E, Kim T, Cho HS. 2006. Mean curvature as a major determinant of β-sheet 33. Watanabe K, Hata Y, Kizaki H, Katsube Y, Suzuki Y. 1997. The refined crystal 25. Robson B, Suzuki E. 1976. Conformational properties of amino acid residues in globular proteins. J Mol Biol 107:327-356. [OpenAIRE]

26. O'Neil KT, DeGrado WF. 1990. A thermodynamic scale for the helix-forming 27. von Heijne G. 1991. Proline kinks in transmembrane α-helices. J Mol Biol 28. Sankararamakrishnan R, Vishveshwara S. 1992. Geometry of proline-containing 29. Schimmel PR, Flory PJ. 1968. Conformational energies and configurational statistics 30. Matthews BW, Nicholson H, Becktel WJ. 1987. Enhanced protein thermostability 31. Zhou C, Xue Y, Ma Y. 2010. Enhancing the thermostability of α-glucosidase from 34. De Vendittis E, Castellano I, Cotugno R, Ruocco MR, Raimo G, Masullo M. 2008. [OpenAIRE]

35. Metpally RP, Reddy BV. 2009. Comparative proteome analysis of psychrophilic 36. O'HIci B, Olivier G, Powell R. 2000. Genetic diversity of the fish pathogen 37. Colston SM, Fullmer MS, Beka L, Lamy B, Gogarten JP, Graf J. 2014. Bioinformatic 39. Wiklund T, Dalsgaard I. 1998. Occurrence and significance of atypical Aeromonas 42. Pavan ME, Pavan EE, López NI, Levin L, Pettinari MJ. 2015. Living in an extremely 44. Belland RJ, Trust TJ. 1988. DNA:DNA reassociation analysis of Aeromonas 45. Hänninen ML, Hirvelä-Koski V. 1997. Molecular and phenotypic methods for the 46. Høie S, Dalsgaard I, Aase IL, Heum M, Thornton JM, Powell R. 1999. Polymerase 47. Sørum H, Holstad G, Lunder T, Håstein T. 2000. Grouping by plasmid profiles of 48. Umelo E, Trust TJ. 1998. Physical map of the chromosome of Aeromonas 49. Lund V, Jenssen LM, Wesmajervi MS. 2002. Assessment of genetic variability and 50. Studer N, Frey J, Vanden Bergh P. 2013. Clustering subspecies of Aeromonas 51. Martinez-Murcia AJ, Benlloch S, Collins MD. 1992. Phylogenetic interrelationships 52. Gulla S, Lund V, Kristoffersen AB, Sorum H, Colquhoun DJ. 2016. vapA (A-layer) 53. Rodriguez-Rojas A, Mena A, Martin S, Borrell N, Oliver A, Blazquez J. 2009.

Microbiology 155:1050-1057.

54. Wang R, Wang H, Zhou H, Wang Y, Yue J, Diao B, Kan B. 2011. Characters of 55. Han H, Iakovenko L, Wilson AC. 2015. Loss of homogentisate 1,2-dioxygenase 57. Dehio C, Meyer M. 1997. Maintenance of broad-host-range incompatibility group P 60. Serre L, Sailland A, Sy D, Boudec P, Rolland A, Pebay-Peyroula E, Cohen-Addad C.

1999. Crystal structure of Pseudomonas fluorescens 4-hydroxyphenylpyruvate

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publication . Article . Preprint . Other literature type . 2018

4-Hydroxyphenylpyruvate Dioxygenase Thermolability Is Responsible for Temperature-Dependent Melanogenesis in Aeromonas salmonicida subsp. salmonicida

Qiao, Yunqian; Wang, Jiao; Wang, He; Chai, Baozhong; Rao, Chufeng; Chen, Xiangdong; Du, Shishen;