Reverey H, Veit M, Ponimaskin E, Schmidt M F
Institut für Immunologie und Molekularbiologie, Freie Universität Berlin, Fachbereich Veterinärmedizin, Luisenstrasse 56, 10117 Berlin, Germany.
J Biol Chem. 1996 Sep 27;271(39):23607-10. doi: 10.1074/jbc.271.39.23607.
The transmembrane glycoprotein HEF and its acylation deficient mutant M1 were expressed in Sf9 insect cells infected with recombinant baculovirus and in CV1 mammalian cells using the vaccinia T7 system. In insect cells (Sf9), both wild type HEF and HEF(M1) are synthesized in their precursor form HEF0, which appears as a double band in SDS gels. Digestion with glycopeptidase F and endoglycosidase H reveals that the larger 84-kDa form is modified by the attachment of unprocessed carbohydrates of the high mannose type whereas the smaller 76-kDa form is non-glycosylated. As revealed by in vitro labeling experiments with palmitic acid another modification of HEF is the attachment of a long chain fatty acid to cysteine residue Cys-652 which is located at the internal border of the cytoplasmic membrane. After labeling with [3H]palmitic acid in both systems only HEF(WT) is acylated, whereas HEF(M1) is not. High performance liquid chromatography analysis of the fatty acids bound to HEF(WT) expressed in Sf9 insect cells reveals nearly 80% of palmitic acid. In contrast to this finding, the acylation pattern of HEF expressed in CV1 cells shows nearly the same amounts of stearic and palmitic acid (40%). Since the interconversion of the input [3H]palmitic acid to stearic acid is even lower in CV1 cells than in insect cells, it follows that only HEF expressed in mammalian, but not in insect cells selects for stearic acid during its biosynthetic acylation. We extended our study to acylation of endogenous proteins in Sf9 cells. In finding only palmitate linked to protein we present evidence that, in contrast to mammalian cells, insect cells (Sf9) cannot transfer stearic acid to polypeptide. This finding favors the hypothesis of enzymatic acylation over non-enzymatic mechanisms of acyl transfer to protein.
跨膜糖蛋白HEF及其酰化缺陷突变体M1在感染重组杆状病毒的Sf9昆虫细胞和使用痘苗T7系统的CV1哺乳动物细胞中表达。在昆虫细胞(Sf9)中,野生型HEF和HEF(M1)均以前体形式HEF0合成,在SDS凝胶中呈现为两条带。用糖肽酶F和内切糖苷酶H消化后发现,较大的84 kDa形式通过连接未加工的高甘露糖型碳水化合物而被修饰,而较小的76 kDa形式则未被糖基化。如用棕榈酸进行的体外标记实验所示,HEF的另一种修饰是将长链脂肪酸连接到位于细胞质膜内边界的半胱氨酸残基Cys-652上。在两个系统中用[3H]棕榈酸标记后,只有HEF(WT)被酰化,而HEF(M1)未被酰化。对Sf9昆虫细胞中表达的与HEF(WT)结合的脂肪酸进行高效液相色谱分析,结果显示近80%为棕榈酸。与这一发现相反,CV1细胞中表达的HEF的酰化模式显示硬脂酸和棕榈酸的含量几乎相同(40%)。由于CV1细胞中输入的[3H]棕榈酸向硬脂酸的相互转化甚至比昆虫细胞中的更低,因此可以得出结论,只有在哺乳动物细胞而非昆虫细胞中表达的HEF在其生物合成酰化过程中选择硬脂酸。我们将研究扩展到Sf9细胞中内源性蛋白质的酰化。在仅发现与蛋白质相连的棕榈酸盐的研究中,我们提供了证据表明,与哺乳动物细胞不同,昆虫细胞(Sf9)不能将硬脂酸转移到多肽上。这一发现支持了酰基转移到蛋白质的酶促酰化假说,而非非酶促机制。
