Requirement of PDZ-containing proteins for cell cycle regulation and differentiation in the mouse lens epithelium

The roles of PDZ domain-containing proteins such as Dlg and Scrib have been well described for Drosophila; however, their requirement for mammalian development is poorly understood. Here we show that Dlg, Scrib, MAGI1, MAGI3, and MPDZ are expressed in the mouse ocular lens. We demonstrate that the increase in proliferation and defects in cellular adhesion and differentiation observed in epithelia of lenses that express E6, a viral oncoprotein that can bind to several PDZ proteins, including the human homologs of Dlg and Scrib, is dependent on E6's ability to bind these proteins via their PDZ domains. Analyses of lenses from mice carrying an insertional mutation in Dlg (dlg(gt)) show increased proliferation and proliferation in spatially inappropriate regions of the lens, a phenotype similar to that of lenses expressing E6. The results from this study indicate that multiple PDZ domain-containing proteins, including Dlg and Scrib, may be required for maintaining the normal pattern of growth and differentiation in the lens. Furthermore, the phenotypic similarities among the Drosophila dlg mutant, the lenses of dlg(gt) mice, and the lenses of E6 transgenic mice suggest that Dlg may have a conserved function in regulating epithelial cell growth and differentiation across species.     

Mechanism of insolubilization by a single-point mutation in alphaA-crystallin linked with hereditary human cataracts

AlphaA-crystallin is a small heat shock protein that functions as a molecular chaperone and a lens structural protein. The R49C single-point mutation in alphaA-crystallin causes hereditary human cataracts. We have previously investigated the in vivo properties of this mutant in a gene knock-in mouse model. Remarkably, homozygous mice carrying the alphaA-R49C mutant exhibit nearly complete lens opacity concurrent with small lenses and small eyes. Here we have investigated the 90 degrees light scattering, viscosity, refractive index, and bis-ANS fluorescence of lens proteins isolated from the alphaA-R49C mouse lenses and found that the concentration of total water-soluble proteins showed a pronounced decrease in alphaA-R49C homozygous lenses. Light scattering measurements on proteins separated by gel permeation chromatography showed a small amount of high-molecular mass aggregated material in the void volume which still remains soluble in alphaA-R49C homozygous lens homogenates. An increased level of binding of beta- and gamma-crystallin to the alpha-crystallin fraction was observed in alphaA-R49C heterozygous and homozygous lenses but not in wild-type lenses. Quantitative analysis with the hydrophobic fluorescence probe bis-ANS showed a pronounced increase in fluorescence yield upon binding to alpha-crystallin from mutant as compared with the wild-type lenses. These results suggest that the decrease in the solubility of the alphaA-R49C mutant protein was due to an increase in its hydrophobicity and supra-aggregation of alphaA-crystallin that leads to cataract formation. Our study further shows that analysis of mutant proteins from the mouse model is an effective way to understand the mechanism of protein insolubilization in hereditary cataracts.     

Uptake of75Se in cataractous rat lens proteins

The purpose of the present study was to measure the pattern of uptake of⁷⁵Se into proteins in normal rat lenses and into the proteins of lenses with selenite-induced cataract. Ten-day-old suckling rats received a single injection of⁷⁵Se with or without a cataractous dose of cold carrier sodium selenite. Four days after injection, the proteins from excised lenses were counted for⁷⁵Se radioactivity and subjected to gel permeation chromatography, amino acid analyses, and mass spectrometry. All three soluble crystallin lens proteins took up⁷⁵Se in both normal and cataractous lenses. However, cataractous lenses did not take up⁷⁵Se into a soluble protein in which major quantities of⁷⁵Se were taken up in normal rats. Futhermore,⁷⁵Se in the gamma-crystallins was associated with an unusual acidic amino acid. It was concluded that selenium metabolism by lens proteins may be unusual compared to other soft tissues.     

Thermosensitive omsA mutation of Escherichia coli that causes thermoregulated release of periplasmic proteins.

A mutant of Escherichia coli with a thermosensitive defect, possibly in the outer membrane (omsA mutant), was isolated from E. coli K-12 by mutagenization and selection for thermosensitivity and beta-lactam supersensitivity of growth. The mutant also showed very high sensitivity to other antibiotics, such as macarbomycin, midecamycin, rifampin, and bacitracin. The mutation was recessive to the wild type and was mapped at about 4 min on the E. coli chromosome between fhuA and metD. The mutation caused rapid release into the medium of periplasmic enzymes such as RTEM penicillinase but practically no cytoplasmic enzyme when cells grown at 30 degrees C were transferred to 37 or 42 degrees C. Electron microscopic observations showed many large double-layered vesicles attached to the surface of cells incubated at 42 degrees C. We conclude that the mutant had a mutation that caused a temperature-dependent defect in the outer membrane structure or its assembly (named an oms mutation). The omsA mutant may be useful for production of periplasmic proteins, which it releases into the culture medium on shift up of temperature.     

Interaction between membrane proteins PBP3 and rodA is required for normal cell shape and division in Escherichia coli.

In Escherichia coli, the products of several genes are required for septation, and the products of several others are required for the maintenance of the rod shape of the cells. We show here that the combination of certain mutations in a division gene (ftsI) with a specific mutation in one of the shape genes (rodA) could produce cells with normal shape and division, although separately these mutations led to a loss of the capacity to divide (ftsI) or to form normal rod-shaped cells (rodA). In contrast, combinations between other mutant alleles of these genes produced double mutants which had lost the capacity both to divide and to form rod-shaped cells. The mutual phenotypic correction observed within particular pairs of mutant genes suggests that the normal morphogenetic cycle of growth and division may require direct interaction between the two membrane proteins which are the products of these genes.     

Loss of a homologous group of proteins in a dominantly inherited ectodermal malformation.

Hair from mice bearing the dominantly inherited Naked trait (NN) and from normal (NN) mice of the same inbred strain was separated into its major protein components by standard techniques. The relative amounts of proteins in these components were then determined by a regression method from the amino acid composition of the hair samples and of the fractions into which they had been separated. The results indicated that the amount of soluble fibril in Naked-mouse hair is decreased. Polyacrylamide-gel electrophoresis of this fraction prepared from the hair of both normal and Naked mice revealed that all protein bands present in the normal are also present in the Naked mice. However, a densitometric scan of the gels at 280 nm showed that the soluble fibril fraction from Naked-mouse hair is deficient in several proteins which, on amino acid analysis, were found to contain 31% glycine and 10% tyrosine. Gel filtration of S-carboxymethylkerateine prepared from normal and mutant hair showed that the mutant hair is deficient in a heterogeneous, low-molecular-weight fraction also rich in glycine and tyrosine. Our present data do not reveal the mechanism whereby a single gene locus modulates the production of several different proteins.     

Ca(2+)-binding proteins in the retina: from discovery to etiology of human disease(1)

Examination of the role of Ca(2+)-binding proteins (CaBPs) in mammalian retinal neurons has yielded new insights into the function of these proteins in normal and pathological states. In the last 8 years, studies on guanylate cyclase (GC) regulation by three GC-activating proteins (GCAP1-3) led to several breakthroughs, among them the recent biochemical analysis of GCAP1(Y99) mutants associated with autosomal dominant cone dystrophy. Perturbation of Ca(2+) homeostasis controlled by mutant GCAP1 in photoreceptor cells may result ultimately in degeneration of these cells. Here, detailed analysis of biochemical properties of GCAP1(P50L), which causes a milder form of autosomal dominant cone dystrophy than constitutive active Y99C mutation, showed that the P50L mutation resulted in a decrease of Ca(2+)-binding, without changes in the GC activity profile of the mutant GCAP1. In contrast to this biochemically well-defined regulatory mechanism that involves GCAPs, understanding of other processes in the retina that are regulated by Ca(2+) is at a rudimentary stage. Recently, we have identified five homologous genes encoding CaBPs that are expressed in the mammalian retina. Several members of this subfamily are also present in other tissues. In contrast to GCAPs, the function of this subfamily of calmodulin (CaM)-like CaBPs is poorly understood. CaBPs are closely related to CaM and in biochemical assays CaBPs substitute for CaM in stimulation of CaM-dependent kinase II, and calcineurin, a protein phosphatase. These results suggest that CaM-like CaBPs have evolved into diverse subfamilies that control fundamental processes in cells where they are expressed.     

Similarity of the yellow chromophores isolated from human cataracts with those from ascorbic acid-modified calf lens proteins: evidence for ascorbic acid glycation during cataract formation

Chromatographic evidence supporting the similarity of the yellow chromophores isolated from aged human and brunescent cataract lenses and calf lens proteins ascorbylated in vitro is presented. The water-insoluble fraction from early stage brunescent cataract lenses was solubilized by sonication (WISS) and digested with a battery of proteolytic enzymes under argon to prevent oxidation. Also, calf lens proteins were incubated with ascorbic acid for 4 weeks in air and submitted to the same digestion. The percent hydrolysis of the proteins to amino acids was approximately 90% in every case. The content of yellow chromophores was 90, 130 and 250 A(330) units/g protein for normal human WISS, cataract WISS and ascorbate-modified bovine lens proteins respectively. Aliquots equivalent to 2.0 g of digested protein were subjected to size-exclusion chromatography on a Bio-Gel P-2 column. Six peaks were obtained for both preparations and pooled. Side by side thin-layer chromatography (TLC) of each peak showed very similar R(f) values for the long wavelength-absorbing fluorophores. Glycation with [U-(14)C]ascorbic acid, followed by digestion and Bio-Gel P-2 chromatography, showed that the incorporated radioactivity co-eluted with the A(330)-absorbing peaks, and that most of the fluorescent bands were labeled after TLC. Peaks 2 and 3 from the P-2 were further fractionated by preparative Prodigy C-18 reversed-phase high-performance liquid chromatography. Two major A(330)-absorbing peaks were seen in peak 2 isolated from human cataract lenses and 5 peaks in fraction 3, all of which eluted at the same retention times as those from ascorbic acid glycated calf lens proteins. HPLC fractionation of P-2 peaks 4, 5 and 6 showed many A(330)-absorbing peaks from the cataract WISS, only some of which were identical to the asorbylated proteins. The major fluorophores, however, were present in both preparations. These data provide new evidence to support the hypothesis that the yellow chromophores in brunescent lenses represent advanced glycation endproducts (AGEs) probably due to ascorbic acid glycation in vivo.     

Comparison of cytoplasmic ribosomal proteins of gateway barley and its mutant

The proteins of the cytoplasmic ribosomes isolated from dry embryos of Gateway barley and its virescens mutant were compared by two-dimensional polyacrylamide gel electrophoresis (2D-PAGE). The monosomes of both the lines gave similar patterns with 60 basic proteins. Upon dissociation of the monosomes, for the mutant, the basic proteins of the large subunits migrated more slowly than those of the normal and lacked three proteins but had three additional spots. Also, the proteins of the small subunits differed. The mutant lacked three of the proteins present in the normal but had three additional spots. Therefore, the large and small subunits contained a total of 34 and 41 basic proteins, respectively, in both the lines. There were several spots with identical electrophoretic mobilities in the small and large subunits of these two lines.     

Studies of muscle proteins in embryonic myocardial cells of cardiac lethal mutant mexican axolotls (Ambystoma mexicanum) by use of heavy meromyosin binding and sodium dodecyl sulfate polyacrylamide gel electrophoresis

In the Mexican axolotl Ambystoma mexicanum recessive mutant gene c, by way of abnormal inductive processes from surrounding tissues, results in an absence of embryonic heart function. The lack of contractions in mutant heart cells apparently results from their inability to form normally organized myofibrils, even though a few actin-like (60-A) and myosin-like (150-A) filaments are present. Amorphous "proteinaceous" collections are often visible. In the present study, heavy meromyosin (HMM) treatment of mutant heart tissue greatly increases the number of thin filaments and decorates them in the usual fashion, confirming that they are actin. The amorphous collections disappear with the addition of HMM. In addition, an analysis of the constituent proteins of normal and mutant embryonic hearts and other tissues is made by sodium dodecyl sulfate (SDS) gel electrophoresis. These experiments are in full agreement with the morphological and HMM binding studies. The gels show distinct 42,000-dalton bands for both normal and mutant hearts, supporting the presence of normal actin. During early developmental stages (Harrison's stage 34) the cardiac tissues in normal and mutant siblings have indistinguishable banding patterns, but with increasing development several differences appear. Myosin heavy chain (200,000 daltons) increases substantially in normal hearts during development but very little in mutants. Even so the quantity of 200,000-dalton protein in mutant hearts is significantly more than in any of the nonmuscle tissues studied (i.e. gut, liver, brain). Unlike normal hearts, the mutant hearts lack a prominent 34,000-dalton band, indicating that if mutants contain muscle tropomyosin at all, it is present in drastically reduced amounts. Also, mutant hearts retain large amounts of yolk proteins at stages when the platelets have virtually disappeared from normal hearts. The morphologies and electrophoresis patterns of skeletal muscle from normal and mutant siblings are identical, confirming that gene c affects only heart muscle differentiation and not skeletal muscle. The results of the study suggest that the precardiac mesoderm in cardiac lethal mutant axolotl embryos initiates but then fails to complete its differentiation into functional muscle tissue. It appears that this single gene mutation, by way of abnormal inductive processes, affects the accumulation and organization of several different muscle proteins, including actin, myosin, and tropomyosin.     

Transmembrane region of wild-type and mutant M13 coat proteins. Conformational role of beta-branched residues.

Although transmembrane (TM) segments of integral membrane proteins are putatively alpha-helical in conformation, beta-sheet promoters (Val, Ile, Thr) often account for approximately 40% of TM residue composition. We are examining the conformational role(s) of these residues, using as a model system the major coat protein of the filamentous bacteriophage M13. This 50-residue protein, which is located at the Escherichia coli host membrane during phage reproduction, contains a prototypic 19-residue hydrophobic midregion (residues 21-39: YIGYAWAMVVVIVGATIGI). Using "Eckstein" site-directed mutagenesis, we have generated several viable M13 coat protein mutants with beta-branched amino acid substitutions within their TM region. Mutant coat proteins, including Ile32----Val (I32V) and Ala27----Thr (A27T), were obtained in milligram quantities by growing M13 mutant phages in liter preparations, confirming that these coat proteins are capable of assuming their normal biological function(s) in phage reproduction. Circular dichroism spectroscopy performed in the membrane-mimetic medium of deoxycholate micelles indicated comparable alpha-helical contents of mutants I32V and A27T to wild-type protein. 13C nuclear magnetic resonance experiments with mutant A27T demonstrated that the combination of additional beta-branched content and introduction of an -OH substituent induced chemical shift and temperature-dependent changes and influenced the local protein environment at sites up to 12 residues remote from the mutation site. In contrast, mutant I32V (of which a salient feature is a mid-TM pentavaline segment) behaved very similarly to wild-type coat. These findings are interpreted in terms of the range of TM secondary structure and stability which can be accommodated by viable M13 coat protein mutants.     

Phospholipase C regulatory mutation of Pseudomonas aeruginosa that results in constitutive synthesis of several phosphate-repressible proteins

We describe here a new mutant of Pseudomonas aeruginosa PAO, strain D10C (genotype plcB), which produces phospholipase C and alkaline phosphatase constitutively. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the extracellular proteins produced by this mutant in high- and low-Pi media revealed that the mutation resulted in a marked deficiency of one major Pi-regulated protein of 41,000 molecular weight and constitutive synthesis of all other major extracellular Pi-regulated proteins. Furthermore, the plcB mutant was deficient in phosphate transport. A plcA mutation, which also led to a loss of the 41,000-molecular-weight protein, was similarly deficient in Pi transport. The genetic loci, plcA and plcB, located at 22 to 23 min on the PAO chromosome, were indistinguishable by conjugational and transductional mapping, and may therefore be in the same gene or in a cluster of genes which regulate the synthesis of Pi-repressible proteins.     

Cataracts and Microphthalmia Caused by a Gja8 Mutation in Extracellular Loop 2

The mouse semi-dominant Nm2249 mutation displays variable cataracts in heterozygous mice and smaller lenses with severe cataracts in homozygous mice. This mutation is caused by a Gja8^R205G point mutation in the second extracellular loop of the Cx50 (or α8 connexin) protein. Immunohistological data reveal that Cx50-R205G mutant proteins and endogenous wild-type Cx46 (or α3 connexin) proteins form diffuse tiny spots rather than typical punctate signals of normal gap junctions in the lens. The level of phosphorylated Cx46 proteins is decreased in Gja8^R205G/R205G mutant lenses. Genetic analysis reveals that the Cx50-R205G mutation needs the presence of wild-type Cx46 to disrupt lens peripheral fibers and epithelial cells. Electrophysiological data in Xenopus oocytes reveal that Cx50-R205G mutant proteins block channel function of gap junctions composed of wild-type Cx50, but only affect the gating of wild-type Cx46 channels. Both genetic and electrophysiological results suggest that Cx50-R205G mutant proteins alone are unable to form functional channels. These findings imply that the Gja8^R205G mutation differentially impairs the functions of Cx50 and Cx46 to cause cataracts, small lenses and microphthalmia. The Gja8^R205G mutation occurs at the same conserved residue as the human GJA8^R198W mutation. This work provides molecular insights to understand the cataract and microphthalmia/microcornea phenotype caused by Gja8 mutations in mice and humans.     

Purification and characterization of recombinant forms of murine Tcl1 proteins

The TCL1 gene, which is located on chromosome 14, plays a major role in human hematopoietic malignancies and encodes a 14-kDa protein whose function has not been determined. This gene is expressed in pre-B cells, in immature thymocytes, and, at low levels, in activated T cells but not in peripheral mature B cells and in normal cells. The Tcl1 protein is similar in its primary structure to a protein encoded by the mature T-cell proliferation gene (MTCP1). The MTCP1 gene is located on the X chromosome and has been shown to be involved in rare chromosomal translocations in T-cell proliferative diseases. The murine TCL1 gene resides on mouse chromosome 12 and is homologous to the human TCL1 and MTCP1 genes. Murine Tcl1 protein has 116 amino acid residues and shares 50% sequence identity with human Tcl1, while the human and mouse Mtcp1 are nearly identical, with conservative differences in only six residues. The TCL1 and MTCP1 genes appear to be members of a family of genes involved in lymphoid proliferation and T-cell malignancies. Our laboratory has undertaken the study of the Tcl1 and Mtcp1 proteins to determine the structure and the function of these related proteins. In the present report, we have produced, using a bacterial expression system, the purified murine Tcl1 protein and a mutant form of murine Tcl1 protein containing a cysteine to alanine mutation at amino acid position 85. The recombinant proteins were purified by chromatography on a Ni-NTA resin followed by reverse-phase FPLC using a buffer system at pH 7.9 and a polymer-based reverse-phase column. The murine Tcl1 recombinant protein displays limited solubility and forms disulfide-linked dimers and oligomers, while the mutant murine Tcl1 C86A protein has increased solubility and does not form higher order oligomers. The purified recombinant murine proteins were characterized by N-terminal sequence analysis, mass spectrometry, and circular dichroism spectroscopy. Initial results indicate that the mutant murine Tcl1 C86A protein is suitable for both NMR and X-ray crystallographic methods of structure determination.     

A heat shock-resistant mutant of Saccharomyces cerevisiae shows constitutive synthesis of two heat shock proteins and altered growth

A heat shock-resistant mutant of the budding yeast Saccharomyces cerevisiae was isolated at the mutation frequency of 10(-7) from a culture treated with ethyl methane sulfonate. Cells of the mutant are approximately 1,000-fold more resistant to lethal heat shock than those of the parental strain. Tetrad analysis indicates that phenotypes revealed by this mutant segregated together in the ratio 2+:2- from heterozygotes constructed with the wild-type strain of the opposite mating type, and are, therefore, attributed to a single nuclear mutation. The mutated gene in the mutant was herein designated hsr1 (heat shock response). The hsr1 allele is recessive to the HSR1+ allele of the wild-type strain. Exponentially growing cells of hsr1 mutant were found to constitutively synthesize six proteins that are not synthesized or are synthesized at reduced rates in HSR1+ cells unless appropriately induced. These proteins include one hsp/G0-protein (hsp48A), one hsp (hsp48B), and two G0-proteins (p73, p56). Heterozygous diploid (hsr1/HSR1+) cells do not synthesize the proteins constitutively induced in hsr1 cells, which suggests that the product of the HSR1 gene might negatively regulate the synthesis of these proteins. The hsr1 mutation also led to altered growth of the mutant cells. The mutation elongated the duration of G1 period in the cell cycle and affected both growth arrest by sulfur starvation and growth recovery from it. We discuss the problem of which protein(s) among those constitutively expressed in growing cells of the hsr1 mutant is responsible for heat shock resistance and alterations in the growth control.     

In vivo functional analyses of the type II acyl carrier proteins of fatty acid biosynthesis

Acyl carrier protein (ACP) is a key component of the fatty acid synthesis pathways of both type I and type II synthesis systems. A large number of structure-function studies of various type II ACPs have been reported, but all are in vitro studies that assayed function or interaction of mutant ACPs with various enzymes of fatty acid synthesis or transfer. Hence in these studies functional properties of various mutant ACPs were assayed with only a subset of the many ACP-interacting proteins, which may not give an accurate overall view of the function of these proteins in vivo. This is especially so because Escherichia coli ACP has been reported to interact with several proteins that have no known roles in lipid metabolism. We therefore tested a large number of mutant derivatives of E. coli ACP carrying single amino acid substitutions for their abilities to restore growth to an E. coli strain carrying a temperature-sensitive mutation in acpP, the gene that encodes ACP. Many of these mutant proteins had previously been tested in vitro thus providing data for comparison with our results. We found that several mutant ACPs containing substitutions of ACP residues reported previously to be required for ACP function in vitro support normal growth of the acpP mutant strain. However, several mutant proteins reported to be severely defective in vitro failed to support growth of the acpP strain in vivo (or supported only weak growth). A collection of ACPs from diverse bacteria and from three eukaryotic organelles was also tested. All of the bacterial ACPs tested restored growth to the E. coli acpP mutant strain except those from two related bacteria, Enterococcus faecalis and Lactococcus lactis. Only one of the three eukaryotic organellar ACPs allowed growth. Strikingly the ACP is that of the apicoplast of Plasmodium falciparum (the protozoan that causes malaria). The fact that an ACP from a such diverse organism can replace AcpP function in E. coli suggests that some of the protein-protein interactions detected for AcpP may be not be essential for growth of E. coli.     

Synchronous scan fluorescence spectroscopy of proteins and human eye lenses

Scanning both the excitation and emission monochromators synchronously while recording the fluorescence spectrum results in a considerable decrease in the apparent band width and shift in the peak position. We demonstrate the potential of this approach in the studies on proteins and their interactions as well as fluorophores in condensed media. We have chosen crystallins, eye lens proteins and human lenses. Synchronous scan spectra of alpha-, beta- and gamma-crystallins are clearly distinguishable and appear to provide specific signatures. The spectrum of the mixed solution could be simulated by the linear combination of components indicating that these proteins might not have any specific interaction in the dilute solutions. Synchronous spectra of the human lenses, both normal and cataractous, show several distinguishable features.     

Yeast mutants affecting possible quality control of plasma membrane proteins

Mutations gef1, stp22, STP26, and STP27 in Saccharomyces cerevisiae were identified as suppressors of the temperature-sensitive alpha-factor receptor (mutation ste2-3) and arginine permease (mutation can1(ts)). These suppressors inhibited the elimination of misfolded receptors (synthesized at 34 degrees C) as well as damaged surface receptors (shifted from 22 to 34 degrees C). The stp22 mutation (allelic to vps23 [M. Babst and S. Emr, personal communication] and the STP26 mutation also caused missorting of carboxypeptidase Y, and ste2-3 was suppressed by mutations vps1, vps8, vps10, and vps28 but not by mutation vps3. In the stp22 mutant, both the mutant and the wild-type receptors (tagged with green fluorescent protein [GFP]) accumulated within an endosome-like compartment and were excluded from the vacuole. GFP-tagged Stp22p also accumulated in this compartment. Upon reaching the vacuole, cytoplasmic domains of both mutant and wild-type receptors appeared within the vacuolar lumen. Stp22p and Gef1p are similar to tumor susceptibility protein TSG101 and voltage-gated chloride channel, respectively. These results identify potential elements of plasma membrane quality control and indicate that cytoplasmic domains of membrane proteins are translocated into the vacuolar lumen.