THE INTERACTION OF TRITON-X-100 WITH PURPLE MEMBRANES - DETERGENT BINDING, SPECTRAL CHANGES AND MEMBRANE SOLUBILIZATION

被引：18

作者：

GONZALEZMANAS, JM ^{[1
]}

VIRTO, MD ^{[1
]}

GURTUBAY, JIG ^{[1
]}

GONI, FM ^{[1
]}

机构：

[1] UNIV BASQUE COUNTRY,DEPT BIOCHEM,POB 644,E-48080 BILBAO,SPAIN

来源：

EUROPEAN JOURNAL OF BIOCHEMISTRY | 1990年 / 188卷 / 03期

关键词：

D O I：

10.1111/j.1432-1033.1990.tb15449.x

中图分类号：

Q5 [生物化学]; Q7 [分子生物学];

学科分类号：

071010 ; 081704 ;

摘要：

The interaction of the non‐ionic surfactant Triton X‐100 with Halobacterium purple membranes has been examined at sublytic and lytic surfactant concentrations. These membranes present a number of important peculiarities in their behaviour towards the surfactant. Although solubilization is a very slow process, with a half‐time of the order of hours, detergent binding appears to occur at the same fast rate as that found in other membranes. Lipids are solubilized more easily than proteins, so that hardly any protein is solubilized at surfactant concentrations at which about 75% of the lipid is in the form of detergent‐mixed micelles; once started, protein solubilization takes place within a narrow range of surfactant concentrations. Retinal provides a built‐in probe to monitor detergent‐induced conformational changes by spectroscopy in the visible range. No spectral variation is detected at the prelytic stage, i.e. when detergent is incorporated into the membrane in monomeric form. Membrane disruption is accompanied by a blue shift in the absorption maximum, retinal isomerization (from all‐trans to 13‐cis), and a decrease in specific absorbance (bleaching). Increasing detergent concentrations after solubilization is completed do not produce further shifts in the spectral maximum, but the specific absorbance is progressively decreased. It is shown that Triton X‐100 has a complex effect on the retinal chromophore, modifying its configuration and microenvironment (changes in maximum wavelength) and promoting hydrolysis of the retinal‐bacterioopsin Schiff's base (bleaching). Copyright © 1990, Wiley Blackwell. All rights reserved

引用

页码：673 / 678

页数：6

共 29 条

[1] KINETIC-STUDIES ON THE INTERACTION OF PHOSPHATIDYLCHOLINE LIPOSOMES WITH TRITON X-100 [J].

ALONSO, A ;

URBANEJA, MA ;

GONI, FM ;

CARMONA, FG ;

CANOVAS, FG ;

GOMEZFERNANDEZ, JC .

BIOCHIMICA ET BIOPHYSICA ACTA, 1987, 902 (02) :237-246

[2] IS THE PURPLE COLOR OF BACTERIORHODOPSIN MAINTAINED BY LIPID PROTEIN INTERACTIONS [J].

BARIBEAU, J ;

BOUCHER, F .

BIOCHIMICA ET BIOPHYSICA ACTA, 1987, 890 (02) :275-278

[3]

BARTLETT GR, 1959, J BIOL CHEM, V234, P466

[4] SOLUBILIZATION OF SEMLIKI FOREST VIRUS MEMBRANE WITH SODIUM DODECYL-SULFATE [J].

BECKER, R ;

HELENIUS, A ;

SIMONS, K .

BIOCHEMISTRY, 1975, 14 (09) :1835-1841

[5] PHOTOPHYSICAL AND PHOTOCHEMICAL BEHAVIOR OF 11-CIS-RETINAL AND ITS SCHIFF-BASE IN A MICELLE [J].

BECKER, RS ;

FREEDMAN, K ;

LENOBLE, C .

JOURNAL OF PHYSICAL CHEMISTRY, 1986, 90 (18) :4334-4336

[6] LIGHT-DARK ADAPTATION OF BACTERIORHODOPSIN IN TRITON-TREATED PURPLE MEMBRANE [J].

CASADIO, R ;

GUTOWITZ, H ;

MOWERY, P ;

TAYLOR, M ;

STOECKENIUS, W .

BIOCHIMICA ET BIOPHYSICA ACTA, 1980, 590 (01) :13-23

[7] FORMATION AND PROPERTIES OF BACTERIORHODOPSIN MONOMERS IN NONIONIC DETERGENTS OCTYL-BETA-GLUCOSIDE AND TRITON X-100 [J].

DENCHER, NA ;

HEYN, MP .

FEBS LETTERS, 1978, 96 (02) :322-326

[8] INTERACTION OF PURPLE MEMBRANE WITH SOLVENTS .2. MODE OF INTERACTION [J].

EISENBACH, M ;

CAPLAN, SR .

BIOCHIMICA ET BIOPHYSICA ACTA, 1979, 554 (02) :281-292

[9] THE INTERACTION OF PHOSPHATIDYLCHOLINE BILAYERS WITH TRITON X-100 [J].

GONI, FM ;

URBANEJA, MA ;

ARRONDO, JLR ;

ALONSO, A ;

DURRANI, AA ;

CHAPMAN, D .

EUROPEAN JOURNAL OF BIOCHEMISTRY, 1986, 160 (03) :659-665

[10] TRITON X-100 SOLUBILIZATION OF MITOCHONDRIAL INNER AND OUTER MEMBRANES [J].

GURTUBAY, JIG ;

GONI, FM ;

GOMEZFERNANDEZ, JC ;

OTAMENDI, JJ ;

MACARULLA, JM .

JOURNAL OF BIOENERGETICS AND BIOMEMBRANES, 1980, 12 (1-2) :47-70

← 1 2 3 →