DESIGN OF A MEMBRANE-TRANSPORT PROTEIN FOR FLUORESCENCE SPECTROSCOPY

被引：48

作者：

MENEZES, ME

ROEPE, PD

KABACK, HR

机构：

[1] UNIV CALIF LOS ANGELES, INST MOLEC BIOL, HOWARD HUGHES MED INST, DEPT PHYSIOL, LOS ANGELES, CA 90024 USA

[2] ROCHE INST MOLEC BIOL, ROCHE RES CTR, NUTLEY, NJ 07110 USA

来源：

PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA | 1990年 / 87卷 / 05期

关键词：

D O I：

10.1073/pnas.87.5.1638

中图分类号：

O [数理科学和化学]; P [天文学、地球科学]; Q [生物科学]; N [自然科学总论];

学科分类号：

07 ; 0710 ; 09 ;

摘要：

To modify the lac permease of Escherichia coli for fluorescence spectroscopy, six tryptophan residues at positions 10, 33, 78, 151, 171, and 223 were first replaced individually with phenylalanine by using oligonucleotide-directed site-specific mutagenesis. None of the tryptophan residues is critical for activity, as evidenced by the finding that the mutant permease molecules catalyze lactose/H+ symport almost as well as wild-type permease. Subsequently, a permease molecule was designed in which all of the tryptophan residues were replaced with phenylalanine. Remarkably, the lac permease harboring all six mutations catalyzes active lactose transport about 75% as well as wild-type permease. The fluorescence emission spectrum of purified wild-type permease solubilized in octyl β-D-glucopyranoside and phospholipid exhibits a broad maximum centered at 350 nm, and the peak is almost completely absent from the spectrum of permease devoid of tryptophan. Furthermore, a new maximum centered at about 306 nm is apparent in the spectrum of the modified permease, suggesting that tyrosine fluorescence in the native protein is quenched by internal energy transfer to tryptophan residues. By using site-directed mutagenesis to replace specified residues in the molecule without tryptophan, it should now be possible to utilize tryptophan fluorescence spectroscopy to study static and dynamic aspects of permease structure and function.

引用

页码：1638 / 1642

页数：5

共 38 条

[1] A COMPLEMENTATION ANALYSIS OF RESTRICTION AND MODIFICATION OF DNA IN ESCHERICHIA COLI
BOYER, HW
ROULLAND.D
[J]. JOURNAL OF MOLECULAR BIOLOGY, 1969, 41 (03) : 459 - &
[2] SEQUENCE OF THE LACTOSE PERMEASE GENE
BUCHEL, DE
GRONENBORN, B
MULLERHILL, B
[J]. NATURE, 1980, 283 (5747) : 541 - 545
[3] CHARACTERIZATION OF SITE-DIRECTED MUTANTS IN THE LAC PERMEASE OF ESCHERICHIA-COLI .2. GLUTAMATE-325 REPLACEMENTS
CARRASCO, N
PUTTNER, IB
ANTES, LM
LEE, JA
LARIGAN, JD
LOLKEMA, JS
ROEPE, PD
KABACK, HR
[J]. BIOCHEMISTRY, 1989, 28 (06) : 2533 - 2539
[4] MONOCLONAL-ANTIBODIES AGAINST THE LAC CARRIER PROTEIN FROM ESCHERICHIA-COLI .1. FUNCTIONAL-STUDIES
CARRASCO, N
VIITANEN, P
HERZLINGER, D
KABACK, HR
[J]. BIOCHEMISTRY, 1984, 23 (16) : 3681 - 3687
[5] PREPARATION, CHARACTERIZATION, AND PROPERTIES OF MONOCLONAL-ANTIBODIES AGAINST THE LAC CARRIER PROTEIN FROM ESCHERICHIA-COLI
CARRASCO, N
TAHARA, SM
PATEL, L
GOLDKORN, T
KABACK, HR
[J]. PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA-BIOLOGICAL SCIENCES, 1982, 79 (22): : 6894 - 6898
[6] INTRAMOLECULAR DISLOCATION OF THE COOH TERMINUS OF THE LAC CARRIER PROTEIN IN RECONSTITUTED PROTEOLIPOSOMES
CARRASCO, N
HERZLINGER, D
MITCHELL, R
DECHIARA, S
DANHO, W
GABRIEL, TF
KABACK, HR
[J]. PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA-BIOLOGICAL SCIENCES, 1984, 81 (15): : 4672 - 4676
[7] COLLINS JC, 1989, J BIOL CHEM, V264, P14698
[8] COSTELLO MJ, 1987, J BIOL CHEM, V262, P17072
[9] FOSTER DL, 1983, J BIOL CHEM, V258, P31
[10] TOPOLOGY OF THE LAC CARRIER PROTEIN IN THE MEMBRANE OF ESCHERICHIA-COLI
GOLDKORN, T
RIMON, G
KABACK, HR
[J]. PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA-BIOLOGICAL SCIENCES, 1983, 80 (11): : 3322 - 3326

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