A GENERAL ROLE FOR THE LUX AUTOINDUCER IN BACTERIAL-CELL SIGNALING - CONTROL OF ANTIBIOTIC BIOSYNTHESIS IN ERWINIA

被引：208

作者：

BAINTON, NJ

BYCROFT, BW

CHHABRA, SR

STEAD, P

GLEDHILL, L

HILL, PJ

REES, CED

WINSON, MK

SALMOND, GPC

STEWART, GSAB

WILLIAMS, P

机构：

[1] UNIV NOTTINGHAM,FAC AGR & FOOD SCI,DEPT APPL BIOCHEM & FOOD SCI,SUTTON LE12 5RD,LEICS,ENGLAND

[2] UNIV NOTTINGHAM,DEPT PHARMACEUT SCI,NOTTINGHAM NG7 2RD,ENGLAND

[3] UNIV WARWICK,DEPT BIOL SCI,COVENTRY CV4 7AL,W MIDLANDS,ENGLAND

来源：

GENE | 1992年 / 116卷 / 01期

关键词：

LUXR; GENE REGULATION; CELL DENSITY; N-BETA-KETOCAPROYL)HOMOSERINE LACTONE; CARBAPENEM; RECOMBINANT DNA;

D O I：

10.1016/0378-1119(92)90633-Z

中图分类号：

Q3 [遗传学];

学科分类号：

071007 ; 090102 ;

摘要：

Micro-organisms have evolved complex and diverse mechanisms to sense environmental changes. Activation of a sensory mechanism typically leads to alterations in gene expression facilitating an adaptive response. This may take several forms, but many are mediated by response-regulator proteins. The luxR-encoded protein (LuxR) has previously been characterised as a member of the response-regulator superfamily and is known to respond to the small diffusible autoinducer signal molecule N-(beta-ketocaproyl) homoserine lactone (KHL). Observed previously in only a few marine bacteria, we now report that KHL is in fact produced by a diverse group of terrestrial bacteria. In one of these (Erwinia carotovora), we show that it acts as a molecular control signal for the expression of genes controlling carbapenem antibiotic biosynthesis. This represents the first substantive evidence to support the previous postulate that the lux autoinducer, KHL, is widely involved in bacterial signalling.

引用

页码：87 / 91

页数：5

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