Ellis M V, James S R, Perisic O, Downes C P, Williams R L, Katan M
Cancer Research Campaign Centre for Cell and Molecular Biology, Chester Beatty Laboratories, Fulham Road, London SW3 6JB, United Kingdom.
J Biol Chem. 1998 May 8;273(19):11650-9. doi: 10.1074/jbc.273.19.11650.
Structural studies of phospholipase C delta1 (PLCdelta1) in complexes with the inositol-lipid headgroup and calcium identified residues within the catalytic domain that could be involved in substrate recognition, calcium binding, and catalysis. In addition, the structure of the PLCdelta1 catalytic domain revealed a cluster of hydrophobic residues at the rim of the active site opening (hydrophobic ridge). To assess a role of each of these residues, we have expressed, purified, and characterized enzymes with the point mutations of putative active site residues (His311, Asn312, Glu341, Asp343, His356, Glu390, Lys438, Lys440, Ser522, Arg549, and Tyr551) and residues from the hydrophobic ridge (Leu320, Phe360, and Trp555). The replacements of most active site residues by alanine resulted in a great reduction (1,000-200,000-fold) of PLC activity analyzed in an inositol lipid/sodium cholate mixed micelle assay. Measurements of the enzyme activity toward phosphatidylinositol, phosphatidylinositol 4-monophosphate, and phosphatidylinositol 4, 5-bis-phosphate (PIP2) identified Ser522, Lys438, and Arg549 as important for preferential hydrolysis of polyphosphoinositides, whereas replacement of Lys440 selectively affected only hydrolysis of PIP2. When PLC activity was analyzed at different calcium concentrations, substitutions of Asn312, Glu390, Glu341, and Asp343 resulted in a shift toward higher calcium concentrations required for PIP2 hydrolysis, suggesting that all these residues contribute toward Ca2+ binding. Mutational analysis also confirmed the importance of His311 ( approximately 20,000-fold reduction) and His356 ( approximately 6,000-fold reduction) for the catalysis. Mutations within the hydrophobic ridge, which had little effect on PIP2 hydrolysis in the mixed-micelles, resulted in an enzyme that was less dependent on the surface pressure when analyzed in a monolayer. This systematic mutational analysis provides further insights into the structural basis for the substrate specificity, requirement for Ca2+ ion, catalysis, and surface pressure/activity dependence, with general implications for eukaryotic phosphoinositide-specific PLCs.
对磷脂酶Cδ1(PLCδ1)与肌醇脂质头部基团及钙形成的复合物进行的结构研究,确定了催化结构域内可能参与底物识别、钙结合及催化作用的残基。此外,PLCδ1催化结构域的结构揭示了活性位点开口边缘(疏水脊)处存在一簇疏水残基。为评估这些残基各自的作用,我们表达、纯化并表征了具有假定活性位点残基(His311、Asn312、Glu341、Asp343、His356、Glu390、Lys438、Lys440、Ser522、Arg549和Tyr551)以及来自疏水脊的残基(Leu320、Phe360和Trp555)点突变的酶。在肌醇脂质/胆酸钠混合胶束测定中,大多数活性位点残基被丙氨酸取代导致PLC活性大幅降低(1000 - 200,000倍)。对酶针对磷脂酰肌醇、磷脂酰肌醇4 - 单磷酸和磷脂酰肌醇4,5 - 二磷酸(PIP2)的活性测量表明,Ser522、Lys438和Arg549对多磷酸肌醇的优先水解很重要,而Lys440的取代仅选择性地影响PIP2的水解。当在不同钙浓度下分析PLC活性时,Asn312、Glu390、Glu341和Asp343的取代导致PIP2水解所需的钙浓度向更高值偏移,表明所有这些残基都有助于Ca2 +结合。突变分析还证实了His311(降低约20,000倍)和His356(降低约6,000倍)对催化作用的重要性。疏水脊内的突变在混合胶束中对PIP2水解影响不大,但在单层分析时导致酶对表面压力的依赖性降低。这种系统性的突变分析为底物特异性、对Ca2 +离子的需求、催化作用以及表面压力/活性依赖性的结构基础提供了进一步的见解,对真核磷酸肌醇特异性PLC具有普遍意义。