FLUORESCENCE ENERGY-TRANSFER ANALYSIS OF CALMODULIN.PEPTIDE COMPLEXES

被引:56
|
作者
CHAPMAN, ER
ALEXANDER, K
VORHERR, T
CARAFOLI, E
STORM, DR
机构
[1] UNIV WASHINGTON, DEPT PHARMACOL SJ-30, SEATTLE, WA 98195 USA
[2] SWISS FED INST TECHNOL, BIOCHEM LAB, CH-8092 ZURICH, SWITZERLAND
来源
BIOCHEMISTRY | 1992年 / 31卷 / 51期
关键词
D O I
10.1021/bi00166a016
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 interactions between calmodulin and the tryptophan residues of synthetic peptides corresponding to the calmodulin binding domains of skeletal muscle myosin light-chain kinase and the plasma membrane calcium pump were examined. The single tryptophan residue contained in each peptide became relatively immobilized and inaccessible to iodide ion upon binding to calmodulin, indicating that the indole side chain was inserted into a hydrophobic cleft in the surface of calmodulin. Fluorescence energy transfer from peptidyl tryptophan residues to an AEDANS moiety attached to cysteine-26 of spinach calmodulin was measured. Included in these analyses was a tryptophan-containing peptide analog of the calmodulin binding domain of neuromodulin. These data indicated that the indole ring of each peptide inserted 32-35 angstrom away from cysteine-26 and may therefore interact with the carboxyl-terminal lobe of CaM in its ''bent' conformation [Persechini & Kretsinger (1988a) J. Cardiovasc. Pharmacol. 12 (Suppl 5), S1-S12; Ikura et al. (1992) Science 256, 632-638; Vorherr et al. (1992) Eur. J. Biochem. 204, 931-937]. The interchange of tryptophan-3 and phenylalanine-21 of the calcium pump peptide increased the efficiency of energy transfer to the AEDANS-moiety approximately 12-fold, reducing the calculated distance to 20 angstrom. These data suggest that phenylalanine-21 of the calcium pump peptide interacts with the hydrophobic cleft in the amino-terminal lobe of CaM.
引用
收藏
页码:12819 / 12825
页数:7
相关论文
共 50 条
  • [21] MOLECULAR ENERGY-TRANSFER STUDIES BY INFRARED FLUORESCENCE
    SUTTON, DG
    ABSTRACTS OF PAPERS OF THE AMERICAN CHEMICAL SOCIETY, 1972, 164 (AUG-S): : 23 - &
  • [22] ENERGY-TRANSFER AND FLUORESCENCE MECHANISMS IN PHOTOSYNTHETIC MEMBRANES
    GEACINTOV, NE
    BRETON, J
    CRC CRITICAL REVIEWS IN PLANT SCIENCES, 1987, 5 (01): : 1 - 44
  • [23] DETECTION OF ACTIN ASSEMBLY BY FLUORESCENCE ENERGY-TRANSFER
    TAYLOR, DL
    REIDLER, J
    SPUDICH, JA
    STRYER, L
    JOURNAL OF CELL BIOLOGY, 1981, 89 (02): : 362 - 367
  • [24] DIFFUSION-ENHANCED FLUORESCENCE ENERGY-TRANSFER
    STRYER, L
    THOMAS, DD
    MEARES, CF
    ANNUAL REVIEW OF BIOPHYSICS AND BIOENGINEERING, 1982, 11 : 203 - 222
  • [25] AMYLASE SUBSTRATE BASED ON FLUORESCENCE ENERGY-TRANSFER
    ZHANG, ZJ
    SEITZ, WR
    OCONNELL, K
    ANALYTICA CHIMICA ACTA, 1990, 236 (02) : 251 - 256
  • [26] FLUORESCENCE QUENCHING AND NONRADIATIVE ENERGY-TRANSFER IN SOLUTIONS
    KAWSKI, A
    KUTEN, E
    KAMINSKI, J
    JOURNAL OF PHYSICS B-ATOMIC MOLECULAR AND OPTICAL PHYSICS, 1973, 6 (09) : 1907 - 1916
  • [27] DESCRIPTION OF FLUORESCENCE AT ENERGY-TRANSFER BY PIGMENT MATRIX
    MELICHOVA, EM
    KUKUSHKIN, AK
    BIOFIZIKA, 1985, 30 (05): : 807 - 810
  • [28] FLUORESCENCE AND ENERGY-TRANSFER OF TRYPTOPHANS IN APLYSIA MYOGLOBIN
    JANES, SM
    HOLTOM, G
    ASCENZI, P
    BRUNORI, M
    HOCHSTRASSER, RM
    BIOPHYSICAL JOURNAL, 1987, 51 (04) : 653 - 660
  • [29] 2 DIMENSIONAL ENERGY-TRANSFER AND FLUORESCENCE POLARIZATION
    HUDSON, B
    WOLBER, P
    BIOPHYSICAL JOURNAL, 1981, 33 (02) : A131 - A131
  • [30] TIME-RESOLVED FLUORESCENCE ENERGY-TRANSFER
    VANDERMEER, BW
    CHEN, SY
    BIOPHYSICAL JOURNAL, 1993, 64 (02) : A242 - A242
12345