Interaction of alpha-crystallin with lens plasma membranes. Affinity for MP26

The binding of the major water-soluble lens protein alpha-crystallin to the lens plasma membrane has been investigated by reassociating purified alpha-crystallin with alpha-crystallin-depleted membranes and with phospholipid vesicles in which the lens membrane protein MP26 had been reconstituted. alpha-Crystallin reassociates at high affinity (Kd = 13 X 10(-8)M) with alkali-washed lens plasma membranes but not with lens plasma membranes treated with guanidine/HCl, nor with phospholipid vesicles or erythrocyte membranes. Binding to lens plasma membranes is dependent on salt, temperature and pH and occurs in a saturable manner. Reconstitution of MP26 into phospholipid vesicles and subsequent analysis of alpha-crystallin binding suggests the involvement of this transmembrane protein. Binding ist not influenced by pretreatment of membranes with proteases, suggesting that the 4-kDa cytoplasmic fragment of MP26 is not necessary for alpha-crystallin binding. Labeling experiments using (trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine as a probe for intrinsic membrane proteins further showed that alpha-crystallin contains hydrophobic regions on its surface which might enable this protein to make contact with the lipid bilayer. Newly synthesized alpha-crystallin, in lens culture, is not associated with the plasma membrane, suggesting that the assembly of alpha-crystallin aggregates does not take place in a membrane-bound mode.     

MP26 in the bovine lens: a post-embedding immunocytochemical study

Gold immunolabeling of bovine lens tissue embedded in Lowicryl K4M, using a polyclonal antibody specific for a major component of lens fiber plasma membrane of 26 K molecular weight, shows that this constituent is absent from the epithelial cell plasma membrane and associated only with the junctional and non-junctional domains of the lens fiber plasma membrane.     

Arrangement of MP26 in lens junctional membranes: Analysis with proteases and antibodies

Summary The major membrane protein of the bovine lens fiber cell is a 26-kilodalton (kD) protein (MP26), which appears to be a component of the extensive junctional specializations found in these cells. To examine the arrangement of MP26 within the junctional membranes, various proteases were incubated with fiber cell membranes that had been isolated with or without urea and/or detergents. These membranes were analyzed with electron microscopy and SDS-PAGE to determine whether the junctional specializations or the proteins were altered by proteolysis. Microscopy revealed no obvious structural changes. Electrophoresis showed that chymotrypsin, papain, and trypsin degraded MP26 to 21–22 kD species. A variety of protease treatments, including overnight digestions, failed to generate additional proteolysis. Regions on MP26 which were sensitive to these three proteases overlapped. Smaller peptides were cleaved from MP26 with V8 protease and carboxypptidases A and B. Protein domains cleaved by these proteases also overlapped with regions sensitive to chymotrypsin, papain, and trypsin. Specific inhibition of the carboxypeptidases suggested that cleavage obtained with these preparations was not likely due to contaminating endoproteases. Since antibodies are not thought to readily penetrate the 2–3 nm extracellular gap in the fiber cell junctions, antibodies to MP26 were used to analyze the location of the protease-sensitive domains. Antisera were applied to control (26 kD) and proteolyzed (22 kD) membranes, with binding being evaluated by means of ELISA reactions on intact membranes. Antibody labeling was also done following SDS-PAGE and transfer to derivatized paper. Both assays showed a significant decrease in binding following proteolysis, with the 22 kD product showing no reaction with the anti-MP26 sera. These investigations suggest that MP26 is arranged with approximately fourfifths of the primary sequence “protected” by the lipid bilayer and the narrow extracellular gap. One-fifth of the molecule, including the C-terminus, appears to be exposed on the cytoplasmic side of the membrane.     

Glycation of lens MIP26 affects the permeability in reconstituted liposomes.

We studied the role of glycation of lens putative gap junctional protein, MIP26, on the permeability as well as on calmodulin mediated gating activity in reconstituted liposomes. Calf lens membranes were incubated with 0-100 mM glucose for 3 days and MIP26 was isolated. There was a glucose concentration dependent increase in the glycation of MIP26 which reached to 2.48 moles/mole of protein with 100 mM glucose. Gel electrophoresis showed that there was no degradation of MIP26 to MIP22 during incubation. Channel permeability was determined by reconstituting MIP26 into asolectin liposomes. There was a MIP26 glycation dependent decrease in the permeability to sucrose. Furthermore, proteoliposomes containing nonglycated MIP26 showed complete uncoupling of the channels with calmodulin whereas the channels containing glycated MIP26 were only partially uncoupled. These results suggest that glycation of MIP26 does interfere with the gating activity in reconstituted liposomes.     

Sequence analysis of peptide fragments from the intrinsic membrane protein of calf lens fibers MP26 and its natural maturation product MP22

Calf lens fiber plasma membranes, containing only the intrinsic membrane protein MP26 and its maturation product MP22 were treated with proteolytic enzymes such as trypsin, protease V8 from S. aureus or with chemical agents as CNBr in formic acid. The cleavage products, purified by electrophoresis, were analysed for their amino acid composition and N-terminal sequences. Proteolysis gave rise to peptides which were mainly shortened at the C-terminal end of the molecules. While the V8 protease produced a fragment with a similar N-terminal sequence as the maturation product MP22, trypsin yielded another cleavage product. Chemical hydrolysis yielded large fragments (11-15 kDa) with hydrophobic N-terminal sequences. Our results suggest that MP26 is characterised by an N-terminal signal sequence and possesses other hydrophobic domains which could function as untranslocated insertion sequences.     

In vitro synthesis and membrane insertion of bovine MP26, an integral protein from lens fiber plasma membrane

Synthesis of MP26, the principal protein of lens fiber plasma membranes, was directed in the reticulocyte lysate system by poly A mRNA enriched from whole bovine lens RNA using oligo (dt)-cellulose chromatography. Synthesized MP26 was enriched by immune precipitation. The in vitro-synthesized MP26 had an electrophoretic mobility indistinguishable from that of the native molecule. MP26 showed a cotranslational requirement for dog pancreas microsomes in order for membrane association to occur. Microsome-associated in vitro- synthesized MP26 showed a sensitivity to digestion with chymotrypsin which was similar to the sensitivity of native MP26 in isolated lens fiber plasma membranes, indicating correct insertion of the MP26 into the microsome. Synthesis and membrane insertion of MP26 using N-formyl- [35S]methionyl tRNA as label demonstrated that no proteolytic processing or significant glycosylation accompanied membrane insertion. Chymotryptic cleavage of membrane-inserted, N-formyl-[35S]methionine- labeled MP26 resulted in loss of label, suggesting that the N-terminal of the in vitro-synthesized MP26 faces the cytoplasm.     

Fatty acid acylation of lens fiber plasma membrane proteins. MP26 and alpha-crystallin are palmitoylated

We describe in this report the fatty acylation of some of the main polypeptides from the eye lens fibers. MP26, the major lens fiber plasma membrane protein, and probably MP22, its natural degradation product, are palmitoylated in a post-translational process. This is also the case for alpha-crystallin, a major cytoplasmic structural protein shown to interact directly with the plasma membrane. Furthermore, a 65 kDa non-identified polypeptide and a high molecular weight component are also modified in the same way.     

The permeability of reconstituted liposomes containing the purified lens fiber cell integral membrane proteins MP20, MP26 and MP70

Summary A number of lens fiber cell integral membrane proteins have been localized to junctional regions where they have been proposed to play a role in either mediating or controlling cell-to-cell communication. We have examined the effect of three lens fiber cell membrane proteins, MP20, MP26 and MP70, on the permeability properties of unilamellar phospholipid liposomes. This approach has been previously used to examine the channel-forming properties of MP26. Liposome permeability was determined by measuring the effect of Co²⁺ on the quenching of the fluorescence of N-4-nitrobenzo-2-oxa-1,3 diazole phosphatidyl ethanolamine (NBD-PE)-containing liposomes as described previously by Scaglione and Rintoul (Invest. Ophthalmol. Vis. Sci. 30:961–966, 1989). The effect of all three proteins on liposome permeability was similar. Permeability was dependent on the protein/phospholipid ratio and was not significantly affected by agents known to modify gap junctional permeability in vivo. Glycophorin A, a non-channel-forming integral membrane protein derived from erythrocytes, was also shown to increase the permeability of unilamellar phospholipid liposomes. The ability of a non-channel membrane protein to increase Co²⁺ quenching of NBD-PE-containing liposomes (presumably in a nonspecific manner) indicates that reports describing the permeability of lens membrane protein-containing liposomes should be interpreted with caution in terms of their relationship to cell-to-cell communication.We would like to thank Dr. Rita Meyer for technical assistance with the freeze-fracture electron microscopy, Drs. Wolfgang Baumann and Barbara Malewicz for the purification of bovine lens lipids, and Dr. Gary Nelsestuen for the use of both the fluorescence and photon correlation spectrophotometers as well as for many helpful discussions. This research was supported by NIH grant EY 05684.     

Preparation, characterization, and localization of antisera against bovine MP26, an integral protein from lens fiber plasma membrane

Polyclonal antisera were prepared in rabbits using both native and chymotrypsin-digested bovine lens fiber plasma membranes. MP26, the principal protein of lens fiber plasma membranes, and CT20, a chymotryptic fragment of MP26, were isolated electrophoretically and used to purify anti-MP26 and anti-CT20 activity from the respective antisera by affinity chromatography. These affinity-purified antisera were characterized by immunoreplica. Immunofluorescence microscopy localized MP26 on sections of methacrylate-embedded lenses in the lens fiber plasma membranes, but not the lens epithelium. Immunocytochemistry of isolated native or chymotrypsin-digested lens fiber plasma membranes localized both the MP26 and the CT20 only in the nonjunctional plasma membranes, with no detectable activity in the lens fiber junctions themselves. Electron microscopy revealed a second set of pentalaminar profiles, thinner by 4 nm than the lens fiber junctions, which contained demonstrable anti-MP26 and anti-CT20 activity following immunocytochemistry. These results indicate either that MP26 is not a component of the lens fiber junctions, or that significant conformational changes accompany assembly of MP26 into lens fiber junctions, resulting in the masking of MP26 antigenic determinants.     

Bi-ionic potentials of bovine lens capsules and collodion membranes

Concentration dependencies of bi-ionic potentials of well-cleaned bovine lens capsules in vitro, of collodion and of modified collodion membranes were studied. The lens capsules have positively fixed charges, and collodion membranes have negatively fixed charges. As these membranes are partially selectively permeable, both co-ions and counter-ions exist in the membrane. However, many studies on bi-ionic potentials have been limited to systems in which the membrane has extreme ionic selectivity and co-ions are completely excluded from the membrane. Experimental results agreed with theoretical values obtained by assuming the common ion concentration to be constant throughout the membrane for systems such as KCl(C)-membrane (θ>0, or θ<0)-NaCl(C), NaNO₃(C)-membrane (θ>0)-NaCl(C) and CaCl₂(C₁)-membrane (θ>0)-NaCl(C₂) (C₂/C₁ = 2), where C is the bulk concentration. The theoretical reliability of this assumption was checked. When both electrolytes in solution were uni-univalent, the ratio of ionic mobilities of two counter-ions (or two co-ions) in all of these membranes was almost the same as the ratio obtained in bulk solution, while the ratio of ionic mobilities of the counter-ion and the co-ion was almost the same as the ratio obtained in bulk solution for the lens capsule, but different in the case of the collodion and modified collodion membranes.     

A lens intercellular junction protein, MP26, is a phosphoprotein

The major protein present in the plasma membrane of the bovine lens fiber cell (MP26), thought to be a component of intercellular junctions, was phosphorylated in an in vivo labeling procedure. After fragments of decapsulated fetal bovine lenses were incubated with [32P]orthophosphate, membranes were isolated and analyzed by SDS PAGE and autoradiography. A number of lens membrane proteins were routinely phosphorylated under these conditions. These proteins included species at Mr 17,000 and 26,000 as well as a series at both 34,000 and 55,000. The label at Mr 26,000 appeared to be associated with MP26, since (a) boiling the membrane sample in SDS led to both an aggregation of MP26 and a loss of label at Mr 26,000, (b) the label at 26,000 was resistant to both urea and nonionic detergents, and (c) two-dimensional gels showed that a phosphorylated Mr 24,000 fragment was derived from MP26 with V8 protease. Studies with proteases also provided for a localization of most label within approximately 20 to 40 residues from the COOH-terminus of MP26. Published work indicates that the phosphorylated portion of MP26 resides on the cytoplasmic side of the membrane, and that this region of MP26 contains a number of serine residues. The same region of MP26 was labeled when isolated lens membranes were reacted with a cAMP-dependent protein kinase prepared from the bovine lens. After the in vivo labeling of lens fragments, phosphoamino acid analysis of MP26 demonstrated primarily labeled serines, with 5-10% threonines and no tyrosines. Treatments that lowered the intracellular calcium levels in the in vivo system led to a selective reduction of MP26 phosphorylation. In addition, forskolin and cAMP stimulated the phosphorylation of MP26 and other proteins in concentrated lens homogenates. These findings are of interest because MP26 appears to serve as a protein of cell-to-cell channels in the lens, perhaps as a lens gap junction protein.     

Structural studies of lens fiber junction protein MP26 by cyanogen bromide cleavage

The lens fiber-cell plasma membrane MP26 from chick, bovine, and human lenses yielded identical cyanogen bromide peptide maps, confirming the essential conservation of structure in the junction protein of vertebrate lens fiber cells. Immunoblot analyses of the cyanogen bromide peptide maps of human lens MP26 and of its age-dependent proteolytic product MP22 confirmed that MP22 is a derivative of MP26. The findings in this study are the first consistent with the positioning of the methionine residues in lens MP26 as predicted by its cDNA-derived sequence.     

Identification of the calmodulin-binding components in bovine lens plasma membranes

Lens membranes, purified from calf lenses, have been labeled by covalent cross-linking to membrane-bound 125I-calmodulin with dithiobis(succinimidyl propionate). Electrophoretic analysis in sodium dodecyl sulfate demonstrated two major 125I-containing products of Mr = 49 000 and 36 000. That the formation of these two components was specifically inhibited by unlabeled calmodulin, or calmodulin antagonists, would indicate that the formation of these components was calmodulin-specific. The size of these two 125I-labeled components was unchanged over a range of 125I-calmodulin or dithiobis(succinimidyl propionate) concentrations indicating that they represent 1:1 complexes between 125I-calmodulin (Mr = 17 000) and Mr-32 000 and Mr-19 000 lens membrane components respectively. Although formation of both cross-linked components exhibited an absolute dependence on Mg2+, the autoradiographic intensity of these components was enhanced when Ca2+ was included with Mg2+ during the cross-linking reaction. Labeling was maximal in 10 mM MgCl2 and approximately 1 microM Ca2+. Treatment of lens membranes with chymotrypsin resulted in the cleavage of MP26 (the major lens membrane protein), with the appearance of a major proteolytic fragment of Mr = 22 000. This proteolysis was not associated with any significant change in either the size or amount of the 125I-calmodulin-labeled membrane components. These results suggest that calmodulin interacts with two membrane proteins, but not significantly with MP26, in the intact lens cell membrane. Our results indicate the need to maintain caution in interpreting direct calcium plus calmodulin effects on MP26 and lens cell junctions.     

Channel reconstitution in liposomes and planar bilayers with HPLC-purified MIP26 of bovine lens

Summary The major intrinsic protein (MIP26) of bovine lens membranes, purified by HPLC, was incorporated into liposomes and planar bilayers. Permeability of MIP26 channels was studied in liposomes by a spectrophotometric osmotic-swelling assay, and channel electrical properties were monitored in planar bilayers following liposome fusion. Particle formation in liposomes was determined by freeze fracture. MIP26 channels were permeable to KCl and sucrose. In planar bilayers, channel-conductance transitions were observed only after addition of liposomes to both chambers and with voltages greater than ±20 mV. Channel open probability decreased progressively as voltage increased, and an open probability of 50% was at 60–80 mV, indicating that the channels are voltage dependent. Histograms of single-channel current amplitudes at 80 mV showed a Gaussian distribution that peaked at 10 pA (120 pS), after subtraction of 1 pA baseline current. Frequency distributions of open and closed times at 80 mV were single exponential functions with time constants of 0.13 and 1.9 sec, respectively. Open time constants ranged from 0.1 to 0.3 sec, and closed time constants ranged from 1 to 7 sec. Cs⁺ did not decrease conductance, but reduced mean open time from 0.2 to 0.038 sec and mean closed time from 1.5 to 0.38 sec. The increase in channel flickering with Cs⁺ occurred in bursts. TEA affected neither conductance nor kinetics. Channel events were also observed in Na⁺ solutions (zero K⁺). These data indicate that MIP26 channels are not K⁺-selective channels. Channel characteristics such as: permeability to molecules larger than small ions, conductance greater than 100 pS, long open and closed time constants, etc., are similar to those of gap junction channels.     

Phosphorylation of lens membranes with a cyclic AMP-dependent protein kinase purified from the bovine lens

We report the phosphorylation of lens membranes with a cAMP-dependent protein kinase isolated from bovine lenses. The holoenzyme was eluted from DEAE agarose at less than 100 mM NaCl and from gel filtration columns with a relative molecular weight of 180 000. The regulatory subunit was identified with the affinity label 8-azido-[32P]cAMP. Four focusing variants with relative molecular weights of 49 000 were seen on two-dimensional gels. The catalytic subunit was purified approx. 5000-fold and migrated at 42 000 Mr on SDS gels. Based on these observations, the enzyme is classified as a Type I cAMP-dependent protein kinase. Purified lens plasma membranes were incubated with the holoenzyme or its catalytic subunit in the presence of 32P-labeled ATP. Several membrane proteins, including the major lens membrane polypeptide, MP26, were shown to be substrates for the kinase in this reaction. MP26 appears to be the major component of intercellular junctions in the lens. Studies with protease treatments on labeled membranes appeared to localize the phosphorylation sites to the cytoplasmic side of the membrane.     

Phosphorylation of MP26, a lens junction protein,is enhanced by activators of protein kinase C

Summary MP26, a protein thought to form gap junctional channels in the lens, and other lens proteins were phosphorylated under conditions that activate protein kinase C. Phosphorylation was detected both in lens fiber cell fragments in an in vivo labeling procedure with³²P-phosphate and in cell homogenates with³²P-ATP. In these experiments, both calcium and 12-O-tetradecanoylphorbol 13-acetate (TPA) were necessary for maximal phosphorylation of MP26. Calcium stimulated the phosphorylation of MP26 approximately fourfold and TPA with calcium led to a sevenfold increase. If TPA was present, 1 m calcium was sufficient for maximal labeling. Phosphoamino acid analysis demonstrated approximately 85% phosphoserine, 15% phosphothreonine, and no phosphotyrosine when MP26 was phosphorylated in lens homogenates in the presence of TPA and calcium and then electrophoretically purified. Phosphorylation occurred near the cytoplasmic, C-terminal of MP26. The possible involvement of other kinases was also examined. The Walsh inhibitor, which affects cAMP-dependent protein kinases, had no influence on the TPA-mediated increase in phosphorylation. In studies with isolated membranes and added kinases, MP26 was also found to not be a substrate for calcium/calmodulindependent protein kinase II. Thus, protein kinase C may have phosphorylated MP26 in a direct manner.     

Junctions between lens fiber cells are labeled with a monoclonal antibody shown to be specific for MP26

A monoclonal antibody (mcAb) that recognizes an intracellular domain of the major lens membrane protein in both chicken and bovine lenses is described. Mice were immunized with chicken lens fiber cell membranes that had been washed with 7 M urea. Hybridomas were screened by means of enzyme-linked immunosorbent assays and the molecular specificities of the mcAbs were determined using electrophoretic transfer procedures, "Westerns." One of these mcAbs, an IgG designated B2, reacted with a single band of 28,000 Mr from the chicken embryo lens (MP28) and the analogous 26,000 Mr protein in the bovine lens (MP26). Monoclonal B2 was shown to be specific for these proteins, since (a) heating in SDS caused MP26 to aggregate and reduced B2 binding to the protein band at an Mr of 26,000 in Western transfer analysis; (b) apparent dimers were bound by B2 in Western transfers; (c) soluble protein fractions from the lens contained no detectable B2 antigens; and (d) a cyanogen bromide fragment of MP26 was bound by B2. Studies with several proteases indicated that the antigenic site for B2 resides on a 2-kd, protease-sensitive region at the C-terminal end of MP26 and MP28. Evidence for B2 binding on the cytoplasmic side of the membrane comes from labeling studies done at the ultrastructural level. These studies, utilizing indirect methods with peroxidase and colloidal gold markers, clearly demonstrated that B2 labels two types of junctional profiles. In our calf lens membrane preparations after tannic acid staining, the predominant type (80%) measured 16-18 nn thick, with the second type measuring only 12-14 nm. Chick embryo lens cells that had differentiated in vitro and formed groups of lens fiber-like cells (termed lentoids), fluoresced brightly only when they had been permeabilized before labeling with B2 and a fluorochrome-conjugated antibody. This binding was concentrated at the plasma membranes of cells within the lentoids, even outside areas of cell-cell contact. Surrounding epithelioid cells were not stained. Solubilized lens cultures, examined by Westerns, displayed a single immunoreactive band, which co-migrated with MP28.     

Isolation and physical characterization of bovine lens crystallins.

The soluble proteins from bovine lens homogenate were separated on Sepharose CL-6B (2 X 200 cm) in 0.05 M tris-NaHSO3 pH 8.2 buffer containing 20 mM EDTA. Five sharp and defined fractions (HM alpha, alpha, beta H, beta L, gamma) were obtained. Each crystallin fraction was further purified by rechromatography on the same column. Each protein fraction was pure as judged by ultracentrifugation and SDS-gel electrophoresis. The molecular weights of the five fractions were 3.04 x 10(6), 5.83 x 10(5), 1.58 x 10(5) , 4.59 x 10(4), 2.14 x 10(4) as determined from sedimentation coefficient and intrinsic viscosity data by Scheraga-Mandelkern equation, which was in close agreement with that obtained by gel filtration. The polypeptide composition of crystallins as determined by SDS-gel electrophoresis revealed one band for high molecular weight alpha (HM alpha) and alpha, three for beta H, two for beta L and one for gamma. The gross CD patterns of crystallins were about the same in the peptide region (200 nm similar to or approximately 250 nm) with a minimum centered at about 217 nm, indicative of a beta-sheet structure in all crystallins. The [theta] values at 217 nm ranged from --1700 to --3700 degrees cm2 per decimole. The CD spectra of these crystallins in the aromatic region (250 nm similar to or approximately 300 nm) were different, reflecting the different contributions of aromatic amino acids to the tertiary structure of crystallins.