Non-secretion of mutant proteins of the glaucoma gene myocilin in cultured trabecular meshwork cells and in aqueous humor.

Until recently, very little was known about the molecular mechanisms responsible for the development of glaucoma, a leading cause of blindness worldwide. Mutations in the glaucoma gene myocilin (MYOC, GLC1A) are associated with elevated intraocular pressure and the development of autosomal dominant juvenile glaucoma and a subset of adult-onset glaucoma. MYOC is expressed in the trabecular meshwork (TM), a tissue responsible for drainage of aqueous humor from the eye, and the tissue involved in elevated intraocular pressure associated with glaucoma. To better understand the role of MYOC in glaucoma pathogenesis, we examined the expression of normal and mutant myocilin in cultured ocular (TM) and non-ocular cells as well as in the aqueous humor of patients with and without MYOC glaucoma. Normal myocilin was secreted from cultured cells, but very little to no myocilin was secreted from cells expressing five different mutant forms of MYOC. In addition, no mutant myocilin was detected in the aqueous humor of patients harboring a nonsense MYOC mutation (Q368X). Co-transfection of cultured cells with normal and mutant myocilin led to suppression of normal myocilin secretion. These studies suggest that MYOC glaucoma is due either to insufficient levels of secreted myocilin or to compromised TM cell function caused by congestion of the TM secretory pathway.

Inwardly rectifying potassium channels in lens epithelium are from the IRK1 (Kir 2.1) family.

Lens epithelial cells from many species contain inwardly rectifying K+ channels. The channels are highly selective for K+ over Na+. They have a conductance of 27-30 pS in symmetrical 150 mM K+ solutions. The conductance to inwardly flowing current depends on the external [K+], being 1/2 maximal at about 50 mM and maximal by 110-150 mM. The amino acid sequences from lens epithelium (eight different species) show at least 98% sequence homology to each other and to the potassium channel known as IRK1 (Kir 2.1). Cloned channels from chick, rabbit, and human lens epithelium all make functional channels when their cDNA is transfected into HEK-293 or tsA-201 cells. Human lens inward rectifiers when engineered as fusion proteins with green fluorescent protein (GFP) also make functional channels. In addition, their localization in the membrane and in intracellular organelles can be demonstrated by fluorescence microscopy.

An initiator element is required for maximal human chorionic somatomammotropin gene promoter and enhancer function.

Previous studies have indicated that cell-specific expression of the human chorionic somatomammotropin (hCS) gene may be mediated by a placental-specific enhancer (CSEn). In the current studies, we have analyzed the promoter elements that are required for enhancer and promoter function in choriocarcinoma cells (BeWo). Mutation of both hCS GHF1 sites had no effect on promoter or enhancer activity. In contrast, mutation of the Sp1 site diminished basal and CSEn-stimulated transcription by approximately 75% and approximately 56%, respectively, indicating that Sp1 was necessary but not sufficient for maximal basal and enhancer-mediated transcription. Deletion and site-specific mutation of the proximal promoter region indicated that the TATA box and an initiator site (InrE) located between nucleotides -15/+1 of the hCS promoter were required for maximal promoter and enhancer function. Mutations of the InrE were associated with reduced basal and enhancer-stimulated activities and altered transcription initiation sites. A protein of 70-kDa mass, that was preferentially expressed in human choriocarcinoma cells (BeWo and JEG-3), bound specifically to the InrE. The data suggest that an initiator present in high concentrations in placental cells contributes to the control of cell-specific hCS gene expression at the promoter level and is required for maximal enhancer function.

Two CGTCA motifs and a GHF1/Pit1 binding site mediate cAMP-dependent protein kinase A regulation of human growth hormone gene expression in rat anterior pituitary GC cells.

We established the cis-acting elements which mediate cAMP responsiveness of the human growth hormone (hGH) gene in transiently transfected rat anterior pituitary tumor GC cells. Analysis of the intact hGH gene or hGH 5'-flanking DNA (5'-FR) coupled to the hGh cDNA or chloramphenicol acetyltransferase or luciferase genes, indicated that cAMP primarily stimulated hGH promoter activity. Cotransfection of a protein kinase A inhibitory protein cDNA demonstrated that the cAMP response was mediated by protein kinase A. Mutational analysis of the hGH promoter identified two core cAMP response element motifs (CGTCA) located at nucleotides -187/-183 (distal cAMP response element; dCRE) and -99/-95 (proximal cAMP response element; pCRE) and a pituitary-specific transcription factor (GHF1/Pit1) binding site at nucleotides -123/-112 (dGHF1) which were required for cAMP responsiveness. GHF1 was not a limiting factor, since overexpression of GHF1 in cotransfections increased basal but not forskolin induction levels. Gel shift analyses indicated that similar, ubiquitous, thermostable protein(s) specifically bound the pCRE and dCRE motifs. The CGTCA motif-binding factors were cAMP response element binding protein (CREB)/activating transcription factor-1 (ATF-1)-related, since the DNA-protein complex was competed by unlabeled CREB consensus oligonucleotide, specifically supershifted by antisera to CREB and ATF-1 but not ATF-2, and was bound by purified CREB with the same relative binding affinity (pCRE < dCRE < CREB) and mobility as the GC nuclear extract. UV cross-linking and Southwestern blot analyses revealed multiple DNA-protein interactions of which approximately 100- and approximately 45-kDa proteins were predominant; the approximately 45-kDa protein may represent CREB. These results indicate that CREB/ATF-1-related factors act coordinately with the cell-specific factor GHF1 to mediate cAMP-dependent regulation of hGH-1 gene transcription in anterior pituitary somatotrophs.

Molecular cloning of cDNA for the B beta subunit of Xenopus fibrinogen, the product of a coordinately-regulated gene family.

Fibrinogen, the principal blood-clotting protein, is made up of three different subunits synthesized in the liver. In vitro administration of glucocorticoids to liver cells from the frog Xenopus laevis causes a dramatic increase in fibrinogen synthesis. Investigations of molecular mechanisms underlying this hormonal stimulation at the mRNA level require cDNA clones complementary to the mRNAs coding for the three fibrinogen subunits, called A alpha, B beta, and gamma. We describe here the isolation and characterization of cDNA clones for the B beta subunit of Xenopus fibrinogen. cDNA libraries in both plasmid (pBR322) and phage (lambda gt10) cloning vectors were constructed from frog liver mRNA and screened with a rat B beta cDNA. Clones thus isolated hybridized to two Xenopus liver mRNAs 2500 and 1800 bases long, the previously-determined sizes for B beta mRNAs. The identity of the plasmid clone B beta-27 was confirmed by hybridization-selection of complementary mRNA which translated in vitro into the B beta polypeptide, as determined by size and susceptibility to thrombin cleavage. lambda/B beta 10, a clone representing nearly all of the 2500-base B beta mRNA, was isolated from the phage cDNA library. The 3'-end of this clone includes a polyadenylation signal about 20 residues upstream of a stretch of 34 adenosine residues, which probably represents the 3'-poly(A) tail of the messenger RNA. lambda/B beta 10 lacks only 20 nucleotides of full-length B beta mRNA at the 5'-end and there is one major start site of transcription. The 2500-base B beta mRNA has a 700-base extension at the 3'-end that is not present in the 1800-base mRNA. The Xenopus laevis genome contains two or three genes for the B beta fibrinogen subunit. Using the cDNA clone as a probe, B beta mRNA was shown to be induced at least 20-fold by glucocorticoid treatment of purified parenchymal cells of Xenopus liver maintained in primary culture.

Isolation and characterization of cDNA clones for the gamma subunit of Xenopus fibrinogen, the product of a coordinately regulated gene family.

Fibrinogen, the major structural protein involved in blood coagulation, is synthesized and secreted by the liver. In the frog Xenopus laevis, fibrinogen production is dramatically induced by glucocorticoids. The hormonal stimulation requires synthesis of three separate subunits, designated A alpha, B beta, and gamma. For investigation of the molecular mechanisms underlying this coordinate induction, we have isolated cDNA clones for the subunits of Xenopus fibrinogen. In this communication we describe the identification of clones for the gamma chain. Initially, a Xenopus liver cDNA library in pBR322 was screened with a rat gamma chain cDNA and a clone representing half of the 1600-base frog gamma mRNA was identified. This clone was shown to be complementary to gamma mRNA by hybrid selection of mRNA that translated in vitro into the gamma polypeptide. A clone about 1460 base pairs in length was then isolated from a Xenopus liver lambda gt10 cDNA library and subcloned into Bluescript SK-. This clone, designated X1 gamma 3, contains the entire 3'-end and lacks 38 bases at the 5'-end of gamma mRNA. The deduced amino acid sequence at the N-terminal is compatible with a signal peptide of 20-23 amino acids, in agreement with the calculated size of the frog gamma chain signal peptide. Following the signal sequence is a region of highly conserved amino acids that participate in disulfide bond formation critical for the maintenance of tertiary structure in mammalian fibrinogen. The gamma cDNA clone was used to measure gamma mRNA in purified Xenopus liver cells treated with glucocorticoids in primary culture.(ABSTRACT TRUNCATED AT 250 WORDS)