A lens intercellular junction protein, MP26, is a phosphoprotein

Aquaporin-0 targets interlocking domains to control the integrity and transparency of the eye lens

PURPOSE

Lens fiber cell membranes contain aquaporin-0 (AQP0), which constitutes approximately 50% of the total fiber cell membrane proteins and has a dual function as a water channel protein and an adhesion molecule. Fiber cell membranes also develop an elaborate interlocking system that is required for maintaining structural order, stability, and lens transparency. Herein, we used an AQP0-deficient mouse model to investigate an unconventional adhesion role of AQP0 in maintaining a normal structure of lens interlocking protrusions.

METHODS

The loss of AQP0 in AQP0(-/-) lens fibers was verified by Western blot and immunofluorescence analyses. Changes in membrane surface structures of wild-type and AQP0(-/-) lenses at age 3 to 12 weeks were examined with scanning electron microscopy. Preferential distribution of AQP0 in wild-type fiber cell membranes was analyzed with immunofluorescence and immunogold labeling using freeze-fracturing transmission electron microscopy.

RESULTS

Interlocking protrusions in young differentiating fiber cells developed normally but showed minor abnormalities at approximately 50 μm deep in the absence of AQP0 in all ages studied. Strikingly, protrusions in maturing fiber cells specifically underwent uncontrolled elongation, deformation, and fragmentation, while cells still retained their overall shape. Later in the process, these changes eventually resulted in fiber cell separation, breakdown, and cataract formation in the lens core. Immunolabeling at the light microscopy and transmission electron microscopy levels demonstrated that AQP0 was particularly enriched in interlocking protrusions in wild-type lenses.

CONCLUSIONS

This study suggests that AQP0 exerts its primary adhesion or suppression role specifically to maintain the normal structure of interlocking protrusions that is critical to the integrity and transparency of the lens.

Phosphorylation determines the calmodulin-mediated Ca2+ response and water permeability of AQP0

In Xenopus oocytes, the water permeability of AQP0 (P(f)) increases with removal of external calcium, an effect that is mediated by cytoplasmic calmodulin (CaM) bound to the C terminus of AQP0. To investigate the effects of serine phosphorylation on CaM-mediated Ca(2+) regulation of P(f), we tested the effects of kinase activation, CaM inhibition, and a series of mutations in the C terminus CaM binding site. Calcium regulation of AQP0 P(f) manifests four distinct phenotypes: Group 1, with high P(f) upon removal of external Ca(2+) (wild-type, S229N, R233A, S235A, S235K, K238A, and R241E); Group 2, with high P(f) in elevated (5 mm) external Ca(2+) (S235D and R241A); Group 3, with high P(f) and no Ca(2+) regulation (S229D, S231N, S231D, S235N, and S235N/I236S); and Group 4, with low P(f) and no Ca(2+) regulation (protein kinase A and protein kinase C activators, S229D/S235D and S235N/I236S). Within each group, we tested whether CaM binding mediates the phenotype, as shown previously for wild-type AQP0. In the presence of calmidazolium, a CaM inhibitor, S235D showed high P(f) and no Ca(2+) regulation, suggesting that S235D still binds CaM. Contrarily, S229D showed a decrease in recruitment of CaM, suggesting that S229D is unable to bind CaM. Taken together, our results suggest a model in which CaM acts as an inhibitor of AQP0 P(f). CaM binding is associated with a low P(f) state, and a lack of CaM binding is associated with a high P(f) state. Pathological conditions of inappropriate phosphorylation or calcium/CaM regulation could induce P(f) changes contributing to the development of a cataract.

Aquaporin 0-calmodulin interaction and the effect of aquaporin 0 phosphorylation

Aquaporin 0 (AQP0), also known as major intrinsic protein of lens, is the most abundant membrane protein in the lens and it undergoes a host of C-terminally directed posttranslational modifications. The C-terminal region containing the major phosphorylation sites is a putative calmodulin-binding site, and calmodulin has been shown to regulate AQP0 water permeability. The purpose of the present study was to elucidate the role of AQP0 phosphorylation on calmodulin binding. AQP0 C-terminal peptides were synthesized with and without serine phosphorylation on S231 and S235, and the ability of these peptides to bind dansyl-labeled calmodulin and the calcium dependence of the interaction was assessed using a fluorescence binding assay. The AQP0 C-terminal phosphorylated peptides were found to have 20-50-fold lower affinities for calmodulin than the unphosphorylated peptide. Chemical cross-linking studies revealed specific sites of AQP0-calmodulin interaction that are significantly reduced by AQP0 phosphorylation. These data suggest that AQP0 C-terminal phosphorylation affects calmodulin binding in vivo and has a role in regulation of AQP0 function.

Post-translational Modifications of Aquaporin 0 (AQP0) in the Normal Human Lens: Spatial and Temporal Occurrence†

Because of the lack of protein turnover in fiber cells of the ocular lens, Aquaporin 0 (AQP0), the most abundant membrane protein in the lens, undergoes extensive post-translational modification with fiber cell age. To map the distribution of modified forms of AQP0 within the lens, normal human lenses ranging in age from 34 to 38 were concentrically dissected into several cortical and nuclear sections. Membrane proteins still embedded in the membranes were digested with trypsin, and the resulting C-terminal peptides of AQP0 were analyzed by HPLC tandem mass spectrometry, permitting the identification of modifications and estimation of their abundance. Consistent with earlier reports, the major phosphorylation site was Ser 235, and the major sites of backbone cleavage occurred at residues 246 and 259. New findings suggest that cleavage at these sites may be a result of nonenzymatic truncation at asparagine residues. In addition, this approach revealed previously undetected sites of truncation at residues 249, 260, 261, and 262; phosphorylation at Ser 231 and to a lower extent at Ser 229; and racemization/isomerization of l-Asp 243 to d-Asp and d-iso-Asp. The spatial distribution of C-terminally modified AQP0 within the lens indicated an increase in truncation and racemization/isomerization with fiber cell age, whereas the level of Ser 235 phosphorylation increased from the outer to inner cortex but decreased in the nucleus. Furthermore, the remarkably similar pattern and distribution of truncation products from lenses from three donors suggest specific temporal mechanisms for the modification of AQP0.

The major integral proteins of spinach leaf plasma membranes are putative aquaporins and are phosphorylated in response to Ca2+ and apoplastic water potential

We show that homologs of the major intrinsic protein (MIP) family are major integral proteins of the spinach leaf plasma membrane and constitute approximately 20% of integral plasma membrane protein. By using oligonucleotide primers based on partial amino acid sequences for polymerase chain reaction and screening of a spinach leaf cDNA library, we obtained two full-length clones of MIP homologs (pm28a and pm28b). One of these clones, pm28a, was sequenced, and it encodes a protein (PM28A) of 281 amino acids with a molecular mass of 29.9 kD. DNA gel blots indicated that PM28A is the product of a single gene, and RNA gel blots showed that pm28a is ubiquitously expressed in the plant. In vivo phosphorylation of the 28-kD polypeptide(s), corresponding to PM28A and PM28B, was dependent on apoplastic water potential, suggesting a role in regulation of cell turgor for these putative aquaporins. In vitro, only one of the homologs, PM28A, was phosphorylated. Phosphorylation of PM28A occurred on Ser-274, seven amino acids from the C terminus of the protein, within a consensus phosphorylation site (Ser-X-Arg) for vertebrate protein kinase C. In vitro phosphorylation of PM28A was due to a plasma membrane-associated protein kinase and was strictly dependent on submicromolar concentrations of Ca2+.

Identification and characterization of presenilin I-467, I-463 and I-374

We cloned a novel isoform of presenilin I (presenilin I-374) besides previously published presenilin I-467 and I-463 in human lymphocytes. Presenilin I-463 was identical to presenilin I-467 except a 12 bp nucleotides deletion in its amino terminal region. Another isoform, presenilin I-374 was produced by an alternative splicing with an additional exon consisting of 92 bp nucleotides (exon 11), which resulted in the frame shift with a stop codon to generate a truncated presenilin consisting of 374 amino acids. The transcripts for presenilin I-467/463 was ubiquitously detected while that for presenilin I-374 was selectively detected in liver, spleen, kidney. Abnormal behavior of presenilin I on gel electrophoresis was found with affinity-purified antibodies against presenilin I.

Characterization of the ovine-lens plasma-membrane protein-kinase substrates

The cAMP-dependent protein-kinase-catalyzed phosphorylation of the two major intrinsic lens fiber cell plasma membrane proteins, MP20 and MP26, is likely restricted to the inner cortical and nuclear regions of the lens in vivo. The ovine-lens-specific connexin, MP70, that has been identified as Cx50 in mice and Cx45.6 in the chick, is also a protein kinase substrate although it does not appear to be phosphorylated by a number of protein kinases including cAMP-dependent protein kinase, calmodulin-dependent protein kinase or protein kinase C. Rather, an extrinsic lens membrane fraction was isolated which contained protein kinase activity that catalyzed the phosphorylation of MP70; this protein kinase activity was cAMP-independent, Ca(2+)-independent, Mg(2+)-dependent, phosphorylated MP70 on a serine residue(s) and migrated with a molecular mass of 35 kDa on a gel filtration column. Both MP70 phosphorylation and the endogenous protein kinase activity were restricted to the lens outer cortical region. This membrane-associated protein kinase activity represents the first reported partial characterization of an endogenous lens fiber cell protein kinase activity that catalyzes the phosphorylation of a lens connexin protein. The phosphatase-induced shift in the electrophoretic mobility of MP70 is not reversed by this protein kinase, indicating that MP70 is likely phosphorylated on different residues by two or more protein kinases.

Phosphorylation of nodulin 26 on serine 262 affects its voltage-sensitive channel activity in planar lipid bilayers

Nodulin 26 is an symbiosome membrane protein of soybean nodules that shows ion channel activity in planar lipid bilayers. Serine 262 of nodulin 26 is phosphorylated by calmodulin-like domain protein kinase. To study the effects of phosphorylation, nodulin 26 with Ser, Ala, or Asp at position 262 were expressed in Escherichia coli. The expressed protein possessed a histidine-rich leader sequence for purification by Ni2+ chelate fast protein liquid chromatography. Upon reconstitution into planar lipid bilayers, the recombinant proteins showed a large single channel conductance (3.1 nanosiemens (nS) in cis0.2M/trans1.0 M KCl and 1.6 nS in cis 0.2M/trans0.2 M KCl) and weak anion selectivity, similar to native soybean nodulin 26. Nodulin 26 with Ser- or Ala-262 occupied the maximal open conductance state greater than 97% of the time (3.1 nS in cis0.2M/trans1.0 M KCl) regardless of applied voltage. However, nodulin 26 with Asp-262 showed increased gating and preferential occupancy of lower subconductance states (1.8 and 0.6 nS in cis0.2M/trans1.0 M KCl) at high applied voltages (e.g. 70 mV). In situ phosphorylation of Ser-262 of nodulin 26 by calmodulin-like domain protein kinase also resulted in increased voltage-dependent gating and preferential occupancy of lower subconductance states. These results suggest that phosphorylation of serine 262 of nodulin 26 modulates channel activity by conferring voltage sensitivity.

Biochemical evidence for adhesion-promoting role of major intrinsic protein isolated from both normal and cataractous human lenses

In this study, we tested the adhesion-promoting role of major intrinsic protein from both normal human (cadaver) and senile cataractous lenses. Junctional membrane solubilized proteins and pure major intrinsic protein obtained from both type of lenses were reconstituted in neutral phosphatidylcholine liposomes. The interaction of these liposomes with phosphatidylserine vesicles was studied by resonance energy transfer. Our results show that normal human lens junction solubilized proteins and pure major intrinsic protein isolated from them promote adhesion. No quenching effect was observed when major intrinsic protein was omitted in the vesicle reconstitution, no other intrinsic protein of normal human junctional membrane provoked the adhesive effect. In contrast, major intrinsic protein isolated from human senile cataractous lens fails to induce adhesion. The proteolytic cleavages that in vitro originate major intrinsic protein 22,000 Da did not blunt its adhesive capability, suggesting that the proteolytic modifications that major intrinsic protein undergoes in senile cataract were not related with the incompetence of cataractous lens junctions to induce adhesion. Cataractous lens junctional membranes showed protein aggregates. These membranes were treated with sodium hydroxide and reconstituted into liposomes. The sodium hydroxide treatment removed the protein aggregates and restored the adhesive capability. Furthermore, the supernatant obtained after the sodium hydroxide treatment of cataractous junctional membranes, inhibited the adhesive effect of vesicles reconstituted with bovine solubilized proteins. These experiments prove that the failure to induce adhesion of human senile cataractous lens junction proteins is due to the interaction with protein aggregates, which can be removed by sodium hydroxide.

Morphological alterations of gap junctions in phalloidin-treated rat livers

Morphological alterations in the pattern of liver cell gap junctions were examined in phalloidin-treated rats to assess the role of gap junctions in experimental intrahepatic cholestasis. Double-labelled fluorescent staining of gap junctions and F-actin were performed using a monoclonal antibody against rat hepatocyte connexin 32 and rhodamine-phalloidin. Immunoelectron microscopy, using the anti-connexin 32 antibody, freeze-fracture replica electron microscopy, and conventional electron microscopy were also performed. In phalloidin-treated rat livers, the specific immunofluorescent staining of connexin 32 was markedly decreased in the pericentral area after 1 day of phalloidin treatment and, after 5 days of phalloidin treatment, there was a decrease in connexin 32 staining in the entire hepatic lobule. On the other hand, F-actin staining at the cell periphery and at the bile canaliculi was markedly increased in the pericentral area of the hepatic lobule after 1 day of phalloidin treatment and in the entire lobule after 5 days of treatment. Immunoelectron microscopy showed that both sides of the cytoplasmic domains of gap junctions were stained with anti-connexin 32 antibody in controls, whereas, in cholestatic rats, only one side of the cytoplasmic domain of some gap junctions was stained with anti-connexin 32 antibody after 1 or 3 days of phalloidin treatment. No gap junctions were observed after 5 days of phalloidin treatment either by freeze-fracture replica electron microscopy or by conventional electron microscopy. These results indicate that with phalloidin treatment, hepatocyte gap junctions decrease, first in the pericentral area, and finally throughout the entire lobule.

Cloning, characterization, and chromosomal mapping of human aquaporin of collecting duct

We recently cloned a cDNA of the collecting duct apical membrane water channel of rat kidney, which is important for the formation of concentrated urine (Fushima, K., S. Uchida, Y. Hara, Y. Hirata, F. Marumo, and S. Sasaki. 1993. Nature [Lond.]. 361:549-552). Since urine concentrating ability varies among mammalian species, we examined whether an homologous protein is present in human kidney. By screening a human kidney cDNA library, we isolated a cDNA clone, designated human aquaporin of collecting duct (hAQP-CD), that encodes a 271-amino acid protein with 91% identity to rat AQP-CD. mRNA expression of hAQP-CD was predominant in the kidney medulla compared with the cortex, immunohistochemical staining of hAQP-CD was observed only in the collecting duct cells, and the staining was dominant in the apical domain. Functional expression study in Xenopus oocytes confirmed that hAQP-CD worked as a water channel. Western blot analysis of human kidney medulla indicated that the molecular mass of hAQP-CD is 29 kD, which is the same mass expected from the amino acid sequence. Chromosomal mapping of the hAQP-CD gene assigned its location to chromosome 12q13. These results could be important for future studies of the pathophysiology of human urinary concentration mechanisms in normal and abnormal states.

The human lens fiber-cell intrinsic membrane protein MP19 gene: isolation and sequence analysis

DNA sequence analysis of overlapping shotgun and restriction fragments have revealed the entire sequence of the human lens fiber cell intrinsic membrane protein MP19 gene (also termed MP17, MP18, and MP20). The 8,056 bp MP19 gene contains 5 exons encoding a mature protein of 173 amino acids, which displayed a very high degree of identity (91%) with that of bovine MP19, deduced from a bovine cDNA sequence. The exon range in size from 52 bases (exon 1) to about 340 bases (exon 5). The introns consist of two large segments (introns B and C) of about 4,700 bases and 1,800 bases, respectively, and two small segments (intron A and D) of about 450 and 250 bases each. Seven Alu family DNA repeats are found within the human MP19 gene. The sequenced gene includes 100 bases of 5' flanking sequence.

Protein kinases with calmodulin-like domains: novel targets of calcium signals in plants

Recently, a novel calcium-dependent protein kinase has been identified that is structurally distinguished by the localization of a calcium-binding regulatory domain fused to a serine/threonine catalytic domain. The regulatory domain is homologous to calmodulin and contains four helix-loop-helix calcium-binding sites. As a result, the kinase is directly activated by calcium without a requirement for other effector molecules.

The MIP family of integral membrane channel proteins: sequence comparisons, evolutionary relationships, reconstructed pathway of evolution, and proposed functional differentiation of the two repeated halves of the proteins

The major intrinsic protein (MIP) of the bovine lens fiber cell membrane was the first member of the MIP family of proteins to be sequenced and characterized. It is probably a homotetramer with transmembrane channel activity that plays a role in lens biogenesis or maintenance. The polypeptide chain of each subunit may span the membrane six times, and both the N- and C-termini face the cell cytoplasm. Eighteen sequenced or partially sequenced proteins from bacteria, yeast, plants, and animals have now been shown to be members of the MIP family. These proteins appear to function in (1) metazoan development and neurogenesis (MIP and BIB), (2) water transport across the human erythrocyte membrane (ChIP), (3) communication between host plant cells and symbiotic nitrogen-fixing bacteria (NOD), (4) transport across the tonoplast membrane during plant seed development (alpha-TIP), (5) water stress-induced resistance to desiccation in plants (Wsi-TIP), (6) suppression of a genetic growth defect on fermentable sugars in yeast (FPS1), and (7) transport of glycerol across bacterial cell membranes (GlpF). One other sequenced member of the MIP family (ORF1 of Lactococcus lactis) has no known physiological function. The biochemical functions of the eukaryotic proteins are not well established. Computer analyses have revealed that the first and second halves of all MIP family proteins probably arose by a tandem, intragenic, duplication event. Thus, the primary structure of putative transmembrane helices 1 to 3 is similar to that of putative transmembrane helices 4 to 6 even though they are of opposite orientation in the membrane. Among the most conserved residues in these two repeated halves are a membrane-embedded glutamate (E) in helices 1 and 4, an asparagine-proline-alanine (NPA) sequence in the loops between helices 2 and 3 (cytoplasmically localized) and helices 5 and 6 (extracellularly localized), and a glycine within helices 3 and 6. Statistical analyses suggest that the two halves of these proteins have evolved to serve distinct functions: the first half is more important for the generalized or common functions of these proteins, while the second half of these proteins is more differentiated to provide specific or dissimilar functions of the proteins. The apparent origin of MIP family proteins by duplication of a three-spanner precursor protein suggests an evolutionary origin distinct from other transport proteins with six transmembrane spanners.(ABSTRACT TRUNCATED AT 400 WORDS)

Tonoplast-bound protein kinase phosphorylates tonoplast intrinsic protein

Tonoplast intrinsic protein (TIP) is a member of a family of putative membrane channels found in bacteria, animals, and plants. Plants have seed-specific, vegetative/reproductive organ-specific, and water-stress-induced forms of TIP. Here, we report that the seed-specific TIP is a phosphoprotein whose phosphorylation can be monitored in vivo by allowing bean cotyledons to take up [(32)P]orthophosphate and in vitro by incubating purified tonoplasts with gamma-labeled [(32)P]ATP. Characterization of the in vitro phosphorylation of TIP indicates that a membrane-bound protein kinase phosphorylates TIP in a Ca(2+)-dependent manner. The capacity of the isolated tonoplast membranes to phosphorylate TIP declined markedly during seed germination, and this decline occurred well before the development-mediated decrease in TIP occurs. Phosphoamino acid analysis of purified, radiolabeled TIP showed that serine is the major, if not only, phosphorylated residue, and cyanogen bromide cleavage yielded a single radioactive peptide peak on a reverse-phase high-performance liquid chromatogram. Estimation of the molecular mass of the cyanogen bromide phosphopeptide by laser desorption mass spectroscopy led to its identification as the hydrophilic N-terminal domain of TIP. The putative phosphate-accepting serine residue occurs in a consensus phosphorylation site for serine/threonine protein kinases.

Protein phosphorylation stimulates the rate of malate uptake across the peribacteroid membrane of soybean nodules

Incubation of intact isolated symbiosomes with [gamma-32P]ATP, followed by isolation of the peribacteroid membrane and polypeptide analysis, showed that a single major polypeptide at 26 kDa was labelled. Antibodies raised against nodulin 26 reacted with a similar sized polypeptide. Incubation of the symbiosomes with alkaline phosphatase removed the label from this polypeptide. Pre-incubation with ATP stimulated malate accumulation by isolated symbiosomes, but only slightly (10-30%). Pre-treatment of symbiosomes with alkaline phosphatase inhibited malate uptake substantially and this inhibition was completely relieved by addition of ATP. The ATP stimulation of malate uptake was not affected by ATPase inhibitors. It is suggested that the rate of malate uptake across the peribacteroid membrane is controlled by phosphorylation of nodulin 26.

MP26, a protein of intercellular junctions in the bovine lens: electrophoretic and chromatographic characterization

We have characterized the membrane protein of apparent molecular weight 26 kD from bovine lenses (MP26 or MIP) with respect to six different electrophoretic and chromatographic procedures. These include one- and two-dimensional gel electrophoretic procedures, as well as SDS-hydroxylapatite chromatography. The two-dimensional gels include isoelectric focusing with both conventional ampholytes and buffer focusing methods. With buffer focusing, the membranes are solubilized without the use of SDS and the isoelectric focusing is performed in the absence of SDS. As specific probes for MP26, a monoclonal antibody and an anti-MP26 rabbit serum were used, the latter prepared against electrophoretically purified MP26. These separation techniques were adapted to MP26 in order to permit a more detailed characterization of this protein and to search for any heterogeneity in this size range, specifically other junctional proteins or protein fragments. We have found evidence for charge heterogeneity in MP26, but no evidence for multiple membrane proteins of Mr 26,000 in urea-treated membranes. The charge heterogeneity appears to be related to a phosphorylation of MP26. The results reported here aid the interpretation of a variety of data, especially findings on the reconstitution of MP26 in artificial membranes and results from work with polyclonal MP26 antibodies. These investigations are all designed to evaluate the proposed role of MP26 as a protein of cell-to-cell channels in the lens fiber cell.

Calcium-dependent phosphorylation of symbiosome membrane proteins from nitrogen-fixing soybean nodules : evidence for phosphorylation of nodulin-26

By using a peptide (CK-15) based on the COOH-terminal sequence of nodulin-26, we have demonstrated the presence of a Ca(2+)-dependent protein kinase in soluble as well as particulate fractions of nitrogen-fixing soybean (Glycine max) root nodules. Substantial enzyme activity was found in symbiosome membranes. The soluble enzyme was purified 1570-fold. The enzyme was fractionated from endogenous calmodulin and yet was fully activated by Ca(2+) (K(0.5) = 0.4 micromolar) in the absence of exogenous calmodulin, phosphatidylserine and 1,2-dioleylglycerol, oleic acid, and platelet activating factor. CK-15 was used to generate a site-specific antibody to nodulin-26. The antibody reacted with a protein in the symbiosome membrane with an apparent molecular mass of 27,000 daltons, consistent with the molecular mass predicted for nodulin-26 from the deduced amino acid sequence. A symbiosome membrane protein with an identical electrophoretic mobility was phosphorylated in vitro in a Ca(2+)-dependent manner. Additionally, this symbiosome membrane protein was phosphorylated when nodules were incubated with (32)P-phosphate. Overall, the results show the existence of a Ca(2+)-dependent and calmodulin/lipid-independent enzyme in nitrogen-fixing soybean root nodules and suggest that nodulin-26 is a substrate for Ca(2+)-dependent phosphorylation.

Amino acid sequence of in vivo phosphorylation sites in the main intrinsic protein (MIP) of lens membranes

The main intrinsic membrane protein of the lens fiber cell, MIP, has been previously shown to be phosphorylated in preparations of lens fragments. Phosphorylation occurred on serine residues near the cytoplasmic C-terminus of the molecule. Since MIP is thought to function as a channel protein in lens plasma membranes, possibly as a cell-to-cell channel protein, phosphorylation could regulate the assembly or gating of these channels. We sought to identify the specific serines which are phosphorylated in order to help identify the kinases involved in regulating MIP function. To this end we purified a peptide fragment from native membranes that had not been subjected to any exogenous kinases or kinase activators. Any phosphorylation detected in these fragments must be due to cellular phosphorylation and thus is termed in vivo phosphorylation. Purified membranes were also phosphorylated with cAMP-dependent protein kinase to determine the mobility of phosphorylated and unphosphorylated MIP-derived peptides on different HPLC columns and to determine possible cAMP-dependent protein kinase phosphorylation sites. Lens membranes, which contain 50-60% of the protein as MIP, were digested with lysylendopeptidase C. Peptides were released from the C-terminal region of MIP and a major product of 21-22 kDa remained membrane-associated. Separation of the lysylendopeptidase-C-released peptides on C8 reversed-phase HPLC demonstrated that one of these fragments, corresponding to residues 239-259 in MIP, was partially phosphorylated. The phosphorylated and nonphosphorylated forms of this peptide were separated on QAE HPLC. In vivo phosphorylation sites were found at residues 243 and 245 through phosphoserine modification via ethanethiol and sequence analysis. Phosphorylation was never detected on serine 240. The phosphorylation level of serine 243 could be increased by incubation of membranes with cAMP-dependent protein kinase under standard assay conditions. Other kinases that phosphorylate serines found near acidic amino acids must be responsible for the in vivo phosphorylation demonstrated at serine 245.

ATP directly affects junctional conductance between paired ventricular myocytes isolated from guinea pig heart

Effects of ATP on junctional conductance (gj) were investigated in paired ventricular myocytes isolated from guinea pig hearts. One cell of the pair was voltage-clamped with a single-patch pipette, and gj was measured after the perforation of the nonjunctional membrane of the partner cell. The current-voltage relation of gj was linear between -30 and +30 mV. The control gj at 5.0 mM ATP in 88 pairs of cells ranged from 100 to 1,055 nS (average, 268 nS). ATP within the range from 0.1 to 5.0 mM increased gj in a dose-dependent manner. The Hill coefficient was 2.6, and the half-maximum effective concentration of ATP was 0.68 mM. Adenylylimidodiphosphate (2 mM) caused a transient increase in gj in the presence of 0.5 mM ATP, but forskolin (30 microM), cyclic AMP (50 microM), catalytic subunit of cyclic AMP-dependent protein kinase (1 microM), and ADP (10 mM) had no significant effect on gj. The temperature coefficient of gj in the presence of 5.0 mM ATP was 1.29. These findings suggest that gj in paired ventricular myocytes is directly regulated by ATP probably through a specific ligand-receptor interaction between ATP and gap junctional channel protein.

In vitro and in vivo phosphorylation of chicken beta B3-crystallin

Incubations of chicken lens homogenates with [32P]-ATP revealed the phosphorylation of a 28 kDa protein, and phosphoamino acid analysis of the phosphorylated protein showed the presence of phosphoserine. The protein is present in the beta-crystallin fraction and after purification and partial sequence determination, by way of peptide mapping and subsequent amino acid analyses and Edman degradation, this 28 kDa protein was identified as the beta B3-crystallin subunit, based on its homology with the bovine and rat orthologue. From phosphate content determination it could be concluded that this chicken beta B3 subunit contains in vivo 2 mol phosphate/mol polypeptide.

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

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 with 32P-phosphate and in cell homogenates with 32P-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 microM 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/calmodulin-dependent protein kinase II. Thus, protein kinase C may have phosphorylated MP26 in a direct manner.

Regional distribution of the enzymes and substrates mediating the action of cAMP in the mammalian lens

Localization of adenylate cyclase activity in the outer cortical regions of the bovine lens correlates with the restriction of the Gs and Gi guanine nucleotide regulatory subunits of this enzyme to these same regions of the lens. In contrast, the major membrane substrates for cAMP-dependent protein kinase (cAMP-PK) (molecular masses of 18, 26 and 28 kDa) were identified in both the inner nuclear and the outer cortical regions of the lens. However, there were differences in the relative amounts of Pi incorporated into the 18 kDa and 28 kDa components in different lens regions. The three major membrane substrates for cAMP-PK were also phosphorylated when homogenates of lens cortex were incubated with [gamma-32P]ATP plus activators of the lens adenylate cyclase. In contrast, there was no incorporation of 32P into these substrates when homogenates of lens nucleus were used. When exogenous cAMP was added to homogenates of lens nucleus or cortex, 32P was incorporated into the membrane substrates for cAMP-PK in both regions of the lens, indicating that cAMP-PK was present in both regions. Interestingly, cAMP phosphodiesterase activity was at least 10-times greater in lens cortex than in the lens nucleus. These results indicate that while the major membrane substrates for cAMP-PK could be phosphorylated in all regions of the lens, there is a restriction of those enzymes that synthesize and degrade cAMP to the outer cortical regions of this organ.

Structural and molecular biology of the eye lens membranes

Lens transparency is associated with a unique design in tissue development and architecture. The fiber plasma membrane has domains which link with the cytoskeleton, thus maintaining cell shape. Other membrane regions form processes which interlock adjacent lens fibers, and intercellular junctions contain transmembrane pores which allow passage of metabolites between cells. Much interest has recently focused on the study of lens membrane structure and function, mainly because membrane dysfunction may be associated with cataract formation. This article reviews what is known about the structure of membrane domains, about the identification of domain-specific proteins, and describes current attempts to relate these results to function. Much of the presently available data is controversial, and an attempt will be made to reconcile them in revised models and testable hypotheses.

Cell uncoupling and protein kinase C: correlation in a cell line but not in a differentiated tissue

Second messengers have been implicated in the control of communication between cells of various tissues and of a number of cell lines. To assess whether protein kinase C (PKC) is involved in the regulation of gap junctions between primary differentiated cells, we studied the effects of 12-O-tetradecanoylphorbol-13-acetate (TPA) on PKC translocation and junctional conductance of rat pancreatic exocrine cells. Our results show that although TPA induced the translocation of PKC from a "cytosolic" to a "microsomal" fraction within minutes, it failed to block the junctional conductance of acinar cell pairs up to 30 min after application. By contrast, analogous experiments on a liver-derived cell line (WB cells) showed that TPA-induced PKC translocation was paralleled by a marked and irreversible inhibition of intercellular coupling. These results indicate that, in contrast to the effects on transformed or dedifferentiated permanent cell lines, PKC is not involved in gating gap junctional channels between primary differentiated secretory cells of the pancreas.

Sequence and developmental expression of mRNA coding for a gap junction protein in Xenopus

Cloned complementary DNAs representing the complete coding sequence for an embryonic gap junction protein in the frog Xenopus laevis have been isolated and sequenced. The cDNAs hybridize with an RNA of 1.5 kb that is first detected in gastrulating embryos and accumulates throughout gastrulation and neurulation. By the tailbud stage, the highest abundance of the transcript is found in the region containing ventroposterior endoderm and the rudiment of the liver. In the adult, transcripts are present in the lungs, alimentary tract organs, and kidneys, but are not detected in the brain, heart, body wall and skeletal muscles, spleen, or ovary. The gene encoding this embryonic gap junction protein is present in only one or a few copies in the frog genome. In vitro translation of RNA synthesized from the cDNA template produces a 30-kD protein, as predicted by the coding sequence. This product has extensive sequence similarity to mammalian gap junction proteins in its putative transmembrane and extracellular domains, but has diverged substantially in two of its intracellular domains.

Inhibition of chicken embryo lens differentiation and lens junction formation in culture by pp60v-src

A culture system was developed which permitted the differentiation of chicken lens epithelial cells to lentoid bodies which contained several cell layers, accumulated high levels of delta-crystallin, and produced extensive gap junctions. This differentiation process was prevented when the cells were infected with a temperature-sensitive src mutant of Rous sarcoma virus and maintained at the permissive temperature. These transformed cells continued to proliferate and also synthesized the major lens gap junction protein, MP28, at near-normal rates. However, this MP28 was not assembled to produce gap junctions. Cultures shifted to the nonpermissive temperature formed lentoid bodies similar to those in uninfected lens cultures, including the establishment of gap junctions containing MP28.

Inhibition of chicken embryo lens differentiation and lens junction formation in culture by pp60v-src

A culture system was developed which permitted the differentiation of chicken lens epithelial cells to lentoid bodies which contained several cell layers, accumulated high levels of delta-crystallin, and produced extensive gap junctions. This differentiation process was prevented when the cells were infected with a temperature-sensitive src mutant of Rous sarcoma virus and maintained at the permissive temperature. These transformed cells continued to proliferate and also synthesized the major lens gap junction protein, MP28, at near-normal rates. However, this MP28 was not assembled to produce gap junctions. Cultures shifted to the nonpermissive temperature formed lentoid bodies similar to those in uninfected lens cultures, including the establishment of gap junctions containing MP28.

Proteolytic changes in main intrinsic polypeptide (MIP26) from membranes in selenite cataract

Experimental nuclear cataract produced by an overdose of sodium selenite exhibited limited proteolysis, including breakdown of main intrinsic polypeptide (MIP26) to 24 and 22 kD fragments. Micro-sequencing and site specific immunologic probes were used in the present study to determine regions of cleavage in MIP26 during selenite cataractogenesis. Data suggested that proteolysis occurred in the C-terminus of MIP26. This may have lead to exposure of normally hidden amino acid residues on the C-terminal extension of MIP26. Loss of antigenicity of the N-terminus occurred. These significant changes to the MIP26 molecule might adversely affect communication between lens fiber cells and contribute to selenite cataract.

MP17, a fiber-specific intrinsic membrane protein from mammalian eye lens

A major protein with a molecular weight of 17,000, designated as MP17, has been identified in mammalian eye lens plasma membranes. Hydrophobic photolabeling experiments revealed that MP17 is a genuine intrinsic membrane protein. By using monoclonal antibodies we demonstrated that MP17 is not detectable in liver, heart, muscle, spleen and kidney, and thus can be considered, like MP26, as a lens-specific membrane protein. Furthermore, we showed that MP17 is a substrate for cAMP-dependent protein kinase and that it is a calmodulin-binding protein.

Roles of cell junctions in gametogenesis and in early embryonic development

Recent reviews of the role of cell junctions in development have focused primarily upon functions related to the relatively subtle physiological modulation of their subunits in relation to fundamental developmental processes in a wide variety of organisms. There is, however, considerable support from numerous laboratories that the more radical modulation of the presence and number of junctional subunits in many diverse tissues may play a pivotal role in a wide spectrum of developmental phenomena ranging from gametogenesis to organogenesis. Since a great deal of recent interest in this latter subject has concentrated upon vertebrate systems including mammals, this review will examine the functional significance of the modulation of gap junctions, tight junctions and desmosomes in a developing idealized mammalian system from gamete formation to tissue and organ differentiation during embryo-genesis.

Retinal horizontal cell gap junctional conductance is modulated by dopamine through a cyclic AMP-dependent protein kinase

The action of many neuromodulators is mediated by intracellular second messengers such as cyclic AMP. In the retina, exogenously applied dopamine alters the conductance of gap junctions between cultured horizontal cells and this effect is mediated by cyclic AMP. However, it is not known how cyclic AMP modulates horizontal cell gap junction function. Here I report that cyclic AMP works by way of a cyclic AMP-dependent protein kinase. Cyclic AMP-dependent protein kinase injected into coupled horizontal cells from white bass (Roccus chrysops) rapidly and reversibly uncoupled the cells, mimicking the actions of dopamine. The threshold for the effect was between 0.06 and 0.03 microM. Injection of Walsh inhibitor of protein kinase [Walsh, D. A., Ashby, C. D., Gonzalez, C., Calkins, D., Fischer, E. H. & Krebs, E. G. (1971) J. Biol. Chem. 246, 1977-1985] blocked the effect of dopamine. Thus, the action of dopamine is to raise intracellular levels of cyclic AMP, which then activates a cyclic AMP-dependent protein kinase. Although not tested, it is likely that the cyclic AMP-dependent protein kinase phosphorylates a protein, possibly a gap junction protein, to alter conductance.

Electron microscopic observations of reconstituted proteoliposomes with the purified major intrinsic membrane protein of eye lens fibers

The purified major intrinsic protein of the lens fiber plasma membrane (MP26) reconstituted into liposomes favored membrane-to-membrane close contacts as visualized by freeze fracture and immunoelectron microscopy. Reconstituted apposed unilamellar vesicles formed pentalaminar profiles, and multilamellar liposomes showed regions of stacked bilayers. Immunogold labeling, using antibody directed against MP26, demonstrated that this polypeptide is present in regions of membrane-to-membrane close interaction. Fracture faces displayed both randomly distributed clusters of 8-nm polygonal intramembrane particles and membrane domains where a bidimensional lattice of repeating subunits was present. The structural pleomorphism which characterized the MP26-reconstituted proteoliposomes seems quite comparable to that visualized in natural fiber plasma membrane domains.

EDTA-extractable proteins from calf lens fiber membranes are phosphorylated by Ca2+-phospholipid-dependent protein kinase

A distinct group of EDTA-extractable proteins (EEP), being a major protein component of calf lens fiber membranes, is bound to these membranes in a calcium-dependent way. Both purified and membrane-bound EEP can be phosphorylated in vitro by a Ca2+-activated, phospholipid-dependent protein kinase (protein kinase C). In general, this protein kinase preferentially phosphorylates serine and threonine residues of protein substrates. Phosphoamino-acid analysis of the two major bands of EEP phosphorylated by protein kinase C, representing the 33,000 + 34,000 EEP proteins and the 30,700-31,800 proteins, respectively, revealed differences in the phosphoamino-acid patterns. For the 33,000 + 34,000 EEP proteins, only phosphothreonine was detected whereas for the 30,700-31,800 proteins, the label was incorporated in both threonine and serine residues. No label was found on tyrosine residues. These results implicate differences in the primary structure of the individual EEP proteins. Regarding previous observations that EEP is a main protein component of lens fiber junctions and of the many covering epithelial and endothelial cells, and considering the fact that protein kinase C is involved in cell-cell communication, growth and differentiation processes we suggest that a correlation exists between phosphorylation-dephosphorylation of EEP and the regulation of a number of cellular processes.

Phosphorylation of lens intrinsic membrane proteins by protein kinase C

Two intrinsic proteins of bovine lens membranes with apparent relative molecular masses (Mr, app) of 26,000 and 18,000 were phosphorylated in intact membranes by protein kinase C prepared from either bovine brain or lens. The kinase preparations exhibited histone H1 phosphorylation dependent on calcium and phospholipid but not on cAMP. Sodium dodecyl sulfate/polyacrylamide gel electrophoresis of the lens membranes showed a major band at Mr, app = 26,000 (identified as MP26, the main intrinsic protein of lens fiber cells), an intermediate band at Mr, app = 18,000 and several minor bands. Autoradiography of complete assay mixture containing protein kinase C, calcium, magnesium and [gamma-32P]ATP showed major bands at Mr, app = 18,000 and 26,000. Several lines of evidence indicated that the label at Mr, app = 26,000 was associated with MP26, a protein which has been found in lens junctions and which may form cell-cell channels. Treatment of the phosphorylated membranes with chymotrypsin and V8 protease cleaved the major band at Mr, app = 26,000 to fragments of Mr, app .= 22,000 and 24,000. Label was not detected in the resulting Mr, app = 22,000 peptide, but the Mr, app = 24,000 peptide was found to be labeled. Phosphoamino acid analysis of MP26 indicated that approximately 75% of the label was on phosphoserine and 25% was on phosphothreonine. No label was found on phosphotyrosine. These results differ from those reported for cAMP-dependent phosphorylation of lens proteins. Phosphorylation by protein kinase C may account for some of the labeling of MP26 detected in vivo.