IDENTIFICATION OF A NEW GENE, MOLR, ESSENTIAL FOR UTILIZATION OF MOLYBDATE BY ESCHERICHIA-COLI

被引：50

作者：

LEE, JH ^{[1
]}

WENDT, JC ^{[1
]}

SHANMUGAM, KT ^{[1
]}

机构：

[1] UNIV FLORIDA,DEPT MICROBIOL & CELL SCI,GAINESVILLE,FL 32611

来源：

JOURNAL OF BACTERIOLOGY | 1990年 / 172卷 / 04期

关键词：

D O I：

10.1128/jb.172.4.2079-2087.1990

中图分类号：

Q93 [微生物学];

学科分类号：

071005 ; 100705 ;

摘要：

A mutation in a new gene, molR, prevented the synthesis in Escherichia coli of molybdoenzymes, including the two formate dehydrogenase isoenzymes, nitrate reductase and trimethylamine-N-oxide reductase. This phenotype was suppressed by supplementing the media with molybdate. Thus, the molR mutant was phenotypically similar to previously described chlD mutants, thought to be defective in molybdate transport. The molR is located at 65.3 min in the E. coli chromosome, in contrast to the chlD gene, which maps at 17 min and thus can be readily distinguished. The molR gene is also cotransducible with a hitherto unidentified gene essential for the production of 2-oxoglutarate from isocitrate, designated icdB (located at 66 min). The molR mutant strain SE1100 also failed to produce the hydrogenase component of formate hydrogenylase (HYD3) in molybdate-unsupplemented media. The amount of molybdate required by strain SE1100 for the production of parental levels of formate hydrogenlyase activity was dependent on the growth medium. In Luria-Bertani medium, this value was about 100 μM, and in glucose-minimal medium, 1.0 μM was sufficient. In low-sulfur medium, this value decreased to about 50 nM. The addition of sulfate or selenite increased the amount of molybdate needed for the production of formate hydrogenlyase activity. These data suggest that in the absence of the high-affinity molybdate transport system, E. coli utilizes sulfate and selenite transport systems for transporting molybdate, preferring sulfate transport over the selenite transport system.

引用

页码：2079 / 2087

页数：9

共 45 条

[1] BACTERIAL PERIPLASMIC TRANSPORT-SYSTEMS - STRUCTURE, MECHANISM, AND EVOLUTION [J].

AMES, GFL .

ANNUAL REVIEW OF BIOCHEMISTRY, 1986, 55 :397-425

[2] LINKAGE MAP OF ESCHERICHIA-COLI-K-12, EDITION-7 [J].

BACHMANN, BJ .

MICROBIOLOGICAL REVIEWS, 1983, 47 (02) :180-230

[3] ISOLATION AND CHARACTERIZATION OF A SOLUBLE ACTIVE FRAGMENT OF HYDROGENASE ISOENZYME-2 FROM THE MEMBRANES OF ANAEROBICALLY GROWN ESCHERICHIA-COLI [J].

BALLANTINE, SP ;

BOXER, DH .

EUROPEAN JOURNAL OF BIOCHEMISTRY, 1986, 156 (02) :277-284

[4] NICKEL-CONTAINING HYDROGENASE ISOENZYMES FROM ANAEROBICALLY GROWN ESCHERICHIA-COLI K-12 [J].

BALLANTINE, SP ;

BOXER, DH .

JOURNAL OF BACTERIOLOGY, 1985, 163 (02) :454-459

[5] LAMBDA-PLACMU - A TRANSPOSABLE DERIVATIVE OF BACTERIOPHAGE-LAMBDA FOR CREATING LACZ PROTEIN FUSIONS IN A SINGLE STEP [J].

BREMER, E ;

SILHAVY, TJ ;

WEISEMANN, JM ;

WEINSTOCK, GM .

JOURNAL OF BACTERIOLOGY, 1984, 158 (03) :1084-1093

[6] MOLYBDATE REDUCTION BY ESCHERICHIA-COLI K-12 AND ITS CHL MUTANTS [J].

CAMPBELL, AM ;

DELCAMPILLOCAMPBELL, A ;

VILLARET, DB .

PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA, 1985, 82 (01) :227-231

[7]

CHUMLEY FG, 1979, GENETICS, V91, P639

[8] RESOLUTION OF DISTINCT SELENIUM-CONTAINING FORMATE DEHYDROGENASES FROM ESCHERICHIA-COLI [J].

COX, JC ;

EDWARDS, ES ;

DEMOSS, JA .

JOURNAL OF BACTERIOLOGY, 1981, 145 (03) :1317-1324

[9] THE USE OF TRANSPOSON TN5 MUTAGENESIS IN THE RAPID GENERATION OF CORRELATED PHYSICAL AND GENETIC MAPS OF DNA SEGMENTS CLONED INTO MULTICOPY PLASMIDS - A REVIEW [J].

DEBRUIJN, FJ ;

LUPSKI, JR .

GENE, 1984, 27 (02) :131-149

[10] REGULATION OF SULFATE TRANSPORT IN SALMONELLA TYPHIMURIUM [J].

DREYFUSS, J ;

PARDEE, AB .

JOURNAL OF BACTERIOLOGY, 1966, 91 (06) :2275-&

← 1 2 3 4 5 →