Rozsa F W, Shimizu S, Lichter P R, Johnson A T, Othman M I, Scott K, Downs C A, Nguyen T D, Polansky J, Richards J E
Department of Ophthalmology, The University of Michigan Medical School, Ann Arbor, MI 48105, USA.
Mol Vis. 1998 Oct 6;4:20.
The aim of this study was to screen affected members of glaucoma families for mutations in the Trabecular Meshwork Inducible Glucocorticoid Response (TIGR) gene also known by the name myocilin (MYOC) or by combined names such as TIGR/MYOC. Our primary objectives were (1) to identify mutations responsible for glaucoma in members of three families for which we have shown linkage between chromosome 1 GLC1A-region markers and the primary open angle glaucoma (POAG) phenotype, and (2) to determine the relationship of these and other mutations to key points of predicted function and structure of the TIGR/MYOC protein.
DNA sequence determination was used to identify sequence changes in sections of the TIGR/MYOC gene that were PCR-amplified from genomic DNA from the probands of three previously-reported GLC1A juvenile-onset POAG families, UM:JG1, UM:JG3, UM:GL57, and unmapped family UM:JG5. Allele-specific oligonucleotide hybridization was used to screen for the identified mutations in PCR-amplified DNA from individual members of each pedigree and from a panel of 11 additional juvenile glaucoma family probands, 42 adult POAG family probands, and 43 normal individuals. Computerized algorithms were used to identify functional motifs and predict structures of normal and mutant forms of the protein.
Sequence changes were found that alter amino acids in the olfactomedin-like domain near the carboxy terminal end of the TIGR protein in affected members of families UM:JG1 (Pro370Leu), UM:JG3 (Val426Phe), UM:GL57 (Glu323Lys) and UM:JG5 (Gly252Arg). Co-segregation of glaucoma and Pro370Leu, Val426Phe, and Gly252Arg in known GLC1A families suggests that these are mutations. Although the Gly252Arg substitution observed in UM:JG5 is non-conservative, it was not possible to distinguish whether it is a mutation or a polymorphism. None of the sequence changes described in these families were observed in other juvenile glaucoma cases in this study, nor in any of the POAG or phenotypically normal individuals tested here. Analysis of amino acid sequence changes resulting from mutations described in this and other works demonstrate localization of many mutations in the vicinity of predicted functional motifs in the olfactomedin-like domain. Identification of rat latrophilin (LPH1/CIRL) as a new member of the olfactomedin-like protein family to which TIGR/MYOC belongs suggests that the region of olfactomedin homology is a protein domain that can occur in different protein contexts.
Location of mutations described in this and previous work suggests that some specific predicted protein motifs in the olfactomedin-like domain may be important to TIGR/MYOC function. In some cases, the role of TIGR/MYOC in the etiology of glaucoma may result from alteration of the sequences recognized by modifying enzymes such as casein kinase II. In other cases altered protein folding may affect access of enzymes to their target sequences on TIGR/MYOC. Although modifications and structures discussed here are predicted rather than proven, they provide a useful theoretical framework for design of subsequent experiments. Alterations to protein folding and predicted modification motifs cannot explain the pathogenic mechanisms of all of the known TIGR/MYOC glaucoma mutations.
本研究旨在筛查青光眼家族中的患病成员,以寻找小梁网诱导糖皮质激素反应(TIGR)基因(也称为肌纤蛋白(MYOC)或TIGR/MYOC等组合名称)中的突变。我们的主要目标是:(1)在三个家族的成员中鉴定导致青光眼的突变,我们已经证明1号染色体GLC1A区域标记与原发性开角型青光眼(POAG)表型之间存在连锁关系;(2)确定这些突变及其他突变与TIGR/MYOC蛋白预测功能和结构关键点的关系。
采用DNA序列测定法,从先前报道的三个GLC1A青少年型POAG家族(UM:JG1、UM:JG3、UM:GL57)和未定位家族UM:JG5的先证者的基因组DNA中PCR扩增TIGR/MYOC基因片段,以鉴定序列变化。采用等位基因特异性寡核苷酸杂交法,对每个家系个体成员以及另外11个青少年青光眼家族先证者、42个成年POAG家族先证者和43个正常个体的PCR扩增DNA进行筛选,以寻找已鉴定的突变。使用计算机算法识别功能基序,并预测正常和突变形式蛋白质的结构。
在UM:JG1家族(Pro370Leu)、UM:JG3家族(Val426Phe)、UM:GL57家族(Glu323Lys)和UM:JG5家族(Gly252Arg)的患病成员中发现了序列变化,这些变化改变了TIGR蛋白羧基末端附近嗅觉介质样结构域中的氨基酸。在已知的GLC1A家族中,青光眼与Pro370Leu、Val426Phe和Gly252Arg的共分离表明这些是突变。尽管在UM:JG5中观察到的Gly252Arg替代是非保守的,但无法区分它是突变还是多态性。在本研究的其他青少年青光眼病例中,以及在此测试的任何POAG或表型正常个体中,均未观察到这些家族中描述的序列变化。对本研究及其他研究中描述的突变导致的氨基酸序列变化的分析表明,许多突变位于嗅觉介质样结构域中预测的功能基序附近。大鼠latrophilin(LPH1/CIRL)被鉴定为TIGR/MYOC所属的嗅觉介质样蛋白家族的新成员,这表明嗅觉介质同源区域是一个可以出现在不同蛋白质背景中的蛋白质结构域。
本研究及先前研究中描述的突变位置表明,嗅觉介质样结构域中的一些特定预测蛋白质基序可能对TIGR/MYOC功能很重要。在某些情况下,TIGR/MYOC在青光眼病因学中的作用可能是由于修饰酶(如酪蛋白激酶II)识别的序列发生改变。在其他情况下,蛋白质折叠的改变可能会影响酶对TIGR/MYOC上其靶序列的作用。尽管这里讨论的修饰和结构是预测性的而非已证实的,但它们为后续实验的设计提供了有用的理论框架。蛋白质折叠和预测修饰基序的改变不能解释所有已知的TIGR/MYOC青光眼突变的致病机制。
