Role of quinolinate phosphoribosyl transferase in degradation of phthalate by Burkholderia cepacia DBO1

被引:17
作者
Chang, HK [1 ]
Zylstra, GJ [1 ]
机构
[1] Rutgers State Univ, Cook Coll, Biotechnol Ctr Agr & Environm, New Brunswick, NJ 08901 USA
来源
JOURNAL OF BACTERIOLOGY | 1999年 / 181卷 / 10期
关键词
D O I
10.1128/JB.181.10.3069-3075.1999
中图分类号
Q93 [微生物学];
学科分类号
071005 ; 100705 ;
摘要
Two distinct regions of DNA encode the enzymes needed for phthalate degradation by Burkholderia cepacia DBO1. A gene coding for an enzyme (quinolinate phosphoribosyl transferase) involved in the biosynthesis of NAD(+) was identified between these two regions by sequence analysis and functional assays. Southern hybridization experiments indicate that DBO1 and other phthalate-degrading B. cepacia strains have two dissimilar genes for this enzyme, while non-phthalate-degrading B. cepacia strains have only a single gene. The sequenced gene was labeled ophE, due to the fact that it is specifically induced by phthalate as shown by lacZ gene fusions. Insertional knockout mutants lacking ophE grow noticeably slower on phthalate while exhibiting normal rates of growth on other substrates. The fact that elevated levels of quinolinate phosphoribosyl transferase enhance growth on phthalate stems from the structural similarities between phthalate and quinolinate: phthalate is a competitive inhibitor of this enzyme and the phthalate catabolic pathway cometabolizes quinolinate. The recruitment of this gene for growth on phthalate thus gives B. cepacia an advantage over other phthalate-degrading bacteria in the environment.
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页码:3069 / 3075
页数:7
相关论文
共 74 条
  • [41] ANALYSIS OF THE NUCLEOTIDE-SEQUENCE OF CHROMOSOME-VI FROM SACCHAROMYCES-CEREVISIAE
    MURAKAMI, Y
    NAITOU, M
    HAGIWARA, H
    SHIBATA, T
    OZAWA, M
    SASANUMA, S
    SASANUMA, M
    TSUCHIYA, Y
    SOEDA, E
    YOKOYAMA, K
    YAMAZAKI, M
    TASHIRO, H
    EKI, T
    [J]. NATURE GENETICS, 1995, 10 (03) : 261 - 268
  • [42] GENES IN PHT PLASMID ENCODING THE INITIAL DEGRADATION PATHWAY OF PHTHALATE IN PSEUDOMONAS-PUTIDA
    NOMURA, Y
    NAKAGAWA, M
    OGAWA, N
    HARASHIMA, S
    OSHIMA, Y
    [J]. JOURNAL OF FERMENTATION AND BIOENGINEERING, 1992, 74 (06): : 333 - 344
  • [43] A SIMPLE METHOD FOR DETECTION OF ENZYME-ACTIVITIES INVOLVED IN THE INITIAL STEP OF PHTHALATE DEGRADATION IN MICROORGANISMS
    NOMURA, Y
    HARASHIMA, S
    OSHIMA, Y
    [J]. JOURNAL OF FERMENTATION AND BIOENGINEERING, 1989, 67 (04): : 291 - 296
  • [44] ISOLATION AND IDENTIFICATION OF PHTHALATE-UTILIZING BACTERIA
    NOMURA, Y
    TAKADA, N
    OSHIMA, Y
    [J]. JOURNAL OF FERMENTATION AND BIOENGINEERING, 1989, 67 (04): : 297 - 299
  • [45] DEVELOPMENT OF BROAD-HOST-RANGE VECTORS AND GENE BANKS - SELF-CLONING OF THE PSEUDOMONAS-AERUGINOSA PAO CHROMOSOME
    OLSEN, RH
    DEBUSSCHER, G
    MCCOMBIE, WR
    [J]. JOURNAL OF BACTERIOLOGY, 1982, 150 (01) : 60 - 69
  • [46] CONSTRUCTION OF MOBILIZABLE VECTORS DERIVED FROM PLASMIDS RP4, PUC18 AND PUC19
    PARKE, D
    [J]. GENE, 1990, 93 (01) : 135 - 137
  • [47] PEAKALL D B, 1975, Residue Reviews, V54, P1
  • [48] PHTHALATE METABOLISM IN PSEUDOMONAS-FLUORESCENS PHK - PURIFICATION AND PROPERTIES OF 4,5-DIHYDROXYPHTHALATE DECARBOXYLASE
    PUJAR, BG
    RIBBONS, DW
    [J]. APPLIED AND ENVIRONMENTAL MICROBIOLOGY, 1985, 49 (02) : 374 - 376
  • [49] Diverse reactions catalyzed by naphthalene dioxygenase from Pseudomonas sp strain NCIB 9816
    Resnick, SM
    Lee, K
    Gibson, DT
    [J]. JOURNAL OF INDUSTRIAL MICROBIOLOGY & BIOTECHNOLOGY, 1996, 17 (5-6) : 438 - 457
  • [50] Ribbons D. W., 1984, MICROBIAL DEGRADATIO, P371
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