Intracellular sequestration of hetero-oligomers formed by wild-type and glaucoma-causing myocilin mutants.

PURPOSE: To investigate mechanism(s) by which mutations in the olfactomedin domain of myocilin (MYOC), also known as the trabecular meshwork-induced glucocorticoid response (TIGR) gene, cause autosomal dominant open-angle glaucoma, the structure and properties of wild-type (WT) MYOC protein were examined, when expressed alone or simultaneously with the Q368X or K423E disease-associated polypeptides. METHODS: Myocilin was analyzed in human aqueous humor and human trabecular meshwork (HTM) tissues. COS-7 and immortalized human trabecular meshwork (iHTM) cell lines were transfected with expression vectors encoding WT MYOC, mutated, and/or epitope-tagged cDNAs. MYOC proteins were characterized by double-epitope tagging procedures and/or Western blot analysis. RESULTS: MYOC polypeptides formed highly similar oligomers in aqueous humor, HTM tissues, transfected COS-7, and iHTM cell lines. These complexes ranged in size from 116 kDa to more than 200 kDa. The smallest complex, approximately 116 kDa, resulted from dimerization between two MYOC monomers. Expression of a 150-kDa complex was strongest in aqueous humor. Cotransfections of the WT construct with either the Q368X or K423E cDNA produced MYOC(WT)/MYOC(mutant) heterodimers and higher molecular weight hetero-oligomeric complexes. WT homo-oligomeric complexes were secreted in the extracellular media of both cell lines whereas the Q368X and K423E mutant/mutant homomultimers and heteromeric WT/mutant oligomers remained sequestered intracellularly. CONCLUSIONS: Formation of heteromeric WT/mutant complexes may provide a critical mechanism by which mutant myocilin polypeptides produce autosomal dominant open-angle glaucoma. The intracellular sequestration of abnormal WT/mutant complexes could lead to the malfunction of MYOC-expressing cells and to POAG potentially involving a dominant negative effect.

Signal sequences initiate the pathway of maturation in the endoplasmic reticulum lumen.

An interaction between an N-terminal signal sequence and the translocon leads to the initiation of protein translocation into the endoplasmic reticulum lumen. Subsequently, folding and modification of the substrate rapidly ensue. The close temporal coordination of these processes suggests that they may be structurally and functionally coordinated as well. Here we show that information encoded in the hydrophobic domain of a signal sequence influences the timing and efficiency of at least two steps in maturation, namely N-linked glycosylation and signal sequence cleavage. We demonstrate that these consequences correlate with and likely stem from the nature of the initial association made between the signal sequence and the translocon during the initiation of translocation. We propose a model by which these maturational events are controlled by the signal sequence-translocon interaction. Our work demonstrates that the pathway taken by a nascent chain through post-translational maturation depends on information encoded in its signal sequence.

Current perspectives on the TIGR/MYOC gene (Myocilin) and glaucoma.

Over the past several years, many groups worldwide have confirmed the presence of probable disease-causing mutations in the coding region of the (TIGR/MYOC) gene associated with glaucoma. Disease-associated point mutations are often found in the third exon of TIGR/MYOC and are predicted to exert a substantial influence on protein structure. Although there has been speculation as to the mechanisms involved in the pathogenic effects for a number of the mutations, the processes leading to the development of glaucoma involving TIGR/MYOC remain to be elucidated. In addition to ongoing mutation studies, efforts are underway to follow up on TIGR/MYOC gene regulation studies in human trabecular meshwork cells and other possibly relevant cell types. Potentially by altering gene regulation, a major variant (-1000 G/C), present in 15-20% of individuals, appears to be associated with a more rapid progression of glaucomatous disease. This article addresses several of these areas of research on the TIGR/MYOC gene and glaucoma, briefly presenting currently available evidence and considering or updating information presented previously.

In vitro localization of TIGR/MYOC in trabecular meshwork extracellular matrix and binding to fibronectin.

PURPOSE: To determine whether trabecular meshwork-inducible glucocorticoid response/myocilin (TIGR/MYOC) protein associates with the extracellular matrix (ECM) of human trabecular meshwork (HTM) cells. METHODS: The extracellular localization of TIGR/MYOC was examined by immunofluorescence microscopy in HTM cultures treated with and without dexamethasone and ascorbate and in a transformed HTM cell line, TM-1, transiently transfected with TIGR/MYOC cDNA. Antibodies to TIGR/MYOC, fibronectin, laminin, type IV collagen, or thrombospondin were used to determine the extracellular localization of TIGR/MYOC. Solid phase binding assays using 125I-recombinant TIGR/MYOC and types I and IV collagens, fibronectin, and laminin were done to examine the association of TIGR/MYOC with these proteins and to identify a specific TIGR/MYOC binding site within fibronectin. The domains of fibronectin tested were the fibrin/collagen binding domain, the RGD domain, and the Heparin II (Hep II) domain. RESULTS: TIGR/MYOC colocalized with fibronectin, laminin, and type IV collagen, but not thrombospondin in both dexamethasone and dexamethasone/ascorbate-treated HTM cultures and in TM-1 cultures transfected with TIGR/MYOC cDNA. In solid phase binding assays, 125I-TIGR/MYOC bound fibronectin but not laminin or type IV collagen. Binding to fibronectin could be competed with excess TIGR/MYOC or fibronectin. Specific binding was found for the Hep II domain of fibronectin. CONCLUSIONS: TIGR/MYOC can associate with components of the ECM via interactions with the Hep II domain of fibronectin. The interactions with the Hep II domain of fibronectin could alter cell-matrix interactions in the TM and provides an interesting lead to explore the role(s) of TIGR/MYOC in both steroid-induced and primary open angle glaucoma.

Transformation of human trabecular meshwork cells with SV40 TAg alters promoter utilization.

PURPOSE: To compare promoter usage in primary differentiated and SV40 TAg transformed human trabecular meshwork cells (HTM and TM1 cells). METHODS: Cultured HTM and TM1 cells were transfected with vectors expressing MYOC/TIGR from the CMV-IE, IE4/5 (HSV immediate early 4/5), ICP6 (early gene ICP6 of HSV), EF-1 alpha (human elongation factor 1 alpha-subunit), or the UB6 (human ubiquitin) promoters, respectively. Immunoblotting was used to measure MYOC/TIGR protein expression. MYOC/TIGR expression at the RNA level was detected by Northern blotting. RESULTS: In primary HTM cells, CMV was the only promoter displaying substantial activity. In TM1 cells, several promoters were functional with the order in decreasing activity being EF-1 alpha > or = CMV > or = UB6 >> IE4/5. CONCLUSIONS: The difference between the normal and transformed HTM cells suggests that the latter cell type has alterations that influence cellular promoter function. The type of cell used is likely to be a crucial factor in evaluating the functions of promoter elements for genes expressed in the trabecular meshwork and in screening promoters for use in gene delivery studies, especially for evaluations of the MYOC/TIGR gene in relation to glaucoma mechanisms.