Two-dimensional gel analysis of chick lens proteins

Cytoskeletal Proteins of the Ageing Human Lens

The cytoskeletal proteins of the human lens were studied by sodium dodecylsulphate-polyacrylamide gel electrophoresis, two-dimensional electrophoresis, and immunologically. Spectrin, vimentin and actin were identified in the superficial fibre cells of human lenses even to age 87 years. These proteins are lost from the deeper cortical and nuclear fibre cells, where a broad zone of water-insoluble proteins of Mr 36 000-45 000 emerges even in the transparent normal lens. Age-related changes in the water-soluble fraction include the increased prominence of W 56 and W 36 proteins in the cortex and of W 38 in the nucleus.

Eye lens proteomics

The eye lens is a fascinating organ as it is in essence living transparent matter. Lenticular transparency is achieved through the peculiarities of lens morphology, a semi-apoptotic process where cells elongate and loose their organelles and the precise molecular arrangement of the bulk of soluble lenticular proteins, the crystallins. The 16 crystallins ubiquitous in mammals and their modifications have been extensively characterized by 2-DE, liquid chromatography, mass spectrometry and other protein analysis techniques. The various solubility dependant fractions as well as subproteomes of lenticular morphological sections have also been explored in detail. Extensive post translational modification of the crystallins is encountered throughout the lens as a result of ageing and disease resulting in a vast number of protein species. Proteomics methodology is therefore ideal to further comprehensive understanding of this organ and the factors involved in cataractogenesis.

Kinetics of cyclic AMP-dependent accumulation of novel intermediate filament proteins in cultured chick lens cells

PURPOSE

To refine the parameters affecting the accumulation of cytoskeletal markers of lens fiber terminal differentiation.

METHODS

Primary cultures of chick lens annular pad cells were treated with a lipid soluble cyclic AMP analog under various culture conditions. The accumulation of beaded filament proteins, unique markers of lens fiber terminal differentiation, was quantified with an ELISA assay. The incorporation of beaded filament proteins into macromolecular structures was followed with immunofluorescence microscopy.

RESULTS

In a time- and dose-dependent manner, beaded filament protein levels were increased in cyclic nucleotide treated cells. The addition of serum to treated cells caused a further dose-dependent increase in beaded filament protein levels. The continuous presence of cyclic nucleotides for maximal beaded filament protein accumulation was also established. At the light microscopic level, cyclic nucleotide treatment produced much more extensive multilayering of cells and lentoid formation. Macromolecular structures containing beaded filament proteins also increased in both abundance and complexity after cyclic nucleotide treatment and were restricted to the multilayers/lentoids.

CONCLUSIONS

These results indicate that multiple mechanisms (including cyclic AMP, serum factors, and the degree of cell-cell interactions) affect the accumulation of beaded filament proteins during the normal differentiation of lens fibers.

Regulation of lens beta-adrenergic receptors by receptor occupancy and dexamethasone

Beta-adrenergic binding sites in primary cultures of chick lens annular pad (CLAP) cells were characterized with dihydroalprenolol (DHAP). Binding site affinities and densities were similar to beta-adrenergic receptors (BARs) previously characterized on crude membranes from freshly isolated cells. In competitive displacement studies, the beta-blocker propranolol was shown to increase the number of available binding sites in a concentration dependent manner. Acute exposure of CLAP cells to propranolol prior to DHAP binding also resulted in an increase in the number of available binding sites. Finally, lens beta-adrenergic binding site levels could be modulated by dexamethasone treatment. These results indicate that lens BARs are subject to common regulatory mechanisms and further implicate ophthalmic pharmaceuticals as possible cataractogenic agents.

Two-dimensional gel electrophoretic analysis of human lens proteins

Human lens proteins from clear lenses were separated and identified using two-dimensional polyacrylamide electrophoresis. Isoelectric focusing, both equilibrium and non-equilibrium, was performed in the first dimension and SDS electrophoresis in the second dimension. Proteins were identified by Western blotting and sequencing techniques and by comparison with patterns obtained with purified crystallin fractions. Analyses were performed on total urea soluble proteins of lenses varying in age from fetal to 73 yr. Several hundred protein spots representing crystallins, cytoskeletal proteins and enzymes were resolved in the fetal lens. In the older lenses there was a dramatic increase in the number of protein species in the molecular weight range of the crystallins and a reduced number of discrete protein species visible at molecular weights greater than 50,000. Conversely, a number of proteins below approximately 15 kDa were visible even in the fetal lens. The number and amount of polypeptides in this molecular weight range were increased in the older lenses. Many of these low molecular weight species could be assigned to either the alpha-, beta- or gamma-crystallin fractions. An age dependent increase in the number of acidic species of both crystallins and other proteins, such as, glyceraldehyde 3-phosphate dehydrogenase was observed as well as the loss or mobility change of gamma-crystallin. Two-dimensional gel electrophoresis provides a sensitive and practical technique for characterizing all of the proteins of the human lens.

Reconstitution of the filamentous backbone of lens beaded-chain filaments from a purified 49kD polypeptide

The beaded-chain filaments unique to the fiber cells of the crystalline lens are composed of a linear array of spheroidal particles which appear to be connected by a filamentous backbone. In order to determine the existence of the putative backbone and to characterize its constituents, one of the major proteins associated with beaded-chains in the chicken lens was investigated. 49kD was isolated in an enriched fraction derived from the 8M urea extract of the lens cell water-insoluble residue. The polypeptide (which exists in several charge isoforms, the major at pI 5.2) was purified sequentially by gel filtration on Sephacryl S-200, hydrophobic interaction chromatography on phenyl-Sepharose, and anionic exchange chromatography on Mono Q, all under denaturing conditions. Immunoblot analyses established that 49kD was immunologically distinct from vimentin, actin, and tubulin/MAPs (representing the three classes of cytoplasmic filaments), as well as from the crystallins. Amino acid analyses demonstrated compositional differences for 49kD compared with lens actin and vimentin, and one- and two-dimensional peptide mapping of 49kD and vimentin revealed no homology. Electron microscopy demonstrated that short, contorted filaments were produced upon removal of purified 49kD from urea to low-salt buffers. In the presence of physiological salt concentrations 49kD assembled into extensive 4-6nm diameter, straight filaments similar to the backbone seen in native beaded-chain filaments, but morphologically distinct from the other cytoplasmic filament classes.

An improved method combining two electrophoretic procedures: application to the separation of lens alpha-crystallin isoforms

Polypeptides having different net electric charges and very similar molecular weights, visualized as one single band in sodium dodecyl sulfate--polyacrylamide gel electrophoresis (SDS-PAGE), can be readily analyzed by an improved method combining two electrophoretic procedures. The methodology consists of the identification and isolation of selected protein bands from SDS-PAGE, their equilibration in an isoelectric focusing (IEF) sample buffer, and their casting and separation in an IEF flat-bed gel. This method requires no extra equipment, is highly reproducible, is suitable for quantitative and comparative studies, and is especially useful in the case of small samples. As a particular example, we analyze here the subunit composition of alpha-crystallins of young and embryonic quail lenses.

Enolase in the avian and turtle lens

Enolase is a dimeric enzyme of molecular weight of 100,000 daltons, which plays an important role in the glycolytic cycle. The aim of this study was to characterize the enzyme of the chicken lens epithelium and to compare its distribution in different regions of the chicken, duck and turtle lens. Enolase of the chicken lens epithelium was found to be an enzymatically active dimeric protein of molecular weight 100,000 daltons and representing alpha-enolase. It is a major component of the epithelium comprising 4%, 12% and 46% of the water-soluble protein of chicken, duck and turtle epithelium respectively. Enolase is found in trace amount in the fiber cells of the chicken and duck, but is retained in much greater concentration in the turtle fiber mass as a predominantly inactive enzyme.

In vitro translation of cytoskeletal beaded-chain filament proteins from chicken lens mRNA

The beaded-chain filament is a unique cytoskeletal structure that appears in the elongating fiber cells during the differentiation of lens epithelial cells to form the mature fiber cells. This beaded-chain structure is made up of two proteins of molecular weight 95 kDa and 49 kDa. As a prerequisite for cloning the cDNAs of these proteins, newborn chicken lens total poly(A+) mRNA was translated in vitro, using a rabbit reticulocyte lysate system and [35S]-L-methionine. The labelled translation products were analyzed by one-and two dimensional gel electrophoresis followed by autoradiography. Immunoprobing of the translation products on Western blots using specific polyclonal antibodies identified the above proteins, and demonstrated the presence and expression of specific mRNAs in the neonatal chick lens, that code for the in vitro synthesis of these two cytoskeletal proteins. These mRNAs are low abundant mRNAs as compared to the crystallin mRNAs.

Expression of the chicken vimentin gene in transgenic mice: efficient assembly of the avian protein into the cytoskeleton

To study expression and function of the vimentin gene, transgenic mice were generated by microinjecting the entire chicken gene plus 2.4 kilobases of 5' and 2.6 kilobases of 3' flanking sequences. All the transgenic mice obtained had incorporated multiple copies of the gene. RNA analyses demonstrated that the chicken vimentin gene was efficiently expressed in an appropriate tissue-specific pattern and that the transcripts were properly processed, as in chicken, giving rise to two RNAs. The vimentin transgene was predominantly expressed in lens at levels of up to 10-fold the endogenous level in every transgenic line studied. The chicken vimentin transcripts were efficiently translated into polypeptides that were modified posttranslationally and could assemble into the mouse cytoskeleton. Overexpression of the chicken vimentin gene did not obviously affect the expression of the endogenous gene at the RNA or the protein level. Immunofluorescence microscopy further demonstrated that the chicken protein was properly expressed spatially in lens. However, the levels were much higher in the transgenic animals.

delta- and beta-Crystallin mRNA levels in the embryonic and posthatched chicken lens: temporal and spatial changes during development

The levels of delta- and beta-crystallin mRNAs were examined by cDNA hybridization in the embryonic and posthatched chicken eye lens. Four different cloned beta-crystallin cDNAs were used, allowing discrimination among different members of the beta-crystallin family. Each crystallin mRNA displayed a characteristic temporal and spatial pattern in the developing lens. delta-Crystallin mRNA accumulated rapidly during early embryonic development; by contrast, the beta-crystallin mRNAs began to accumulate rapidly near the end of embryogenesis. Both delta- and beta-crystallin mRNAs increased in the lens for the first month after hatching and began to decrease 3 months after hatching. The levels of the delta- and the different beta-crystallin mRNAs were also differentially regulated in cultured embryonic lens epithelia. The most fiber cell specific crystallin gene product in the differentiating lens was the beta 35 mRNA. These experiments provide a quantitative basis for exploring the differential expression of the delta- and beta-crystallin gene families in the chicken lens.

Vimentin synthesis by ocular lens cells

A study of the synthesis of the intermediate filament protein, vimentin, is reported here. The following systems were examined: the epithelial cells of the organ-cultured rabbit lens, the epithelial and cortical fiber cells of the organ-cultured adult chicken lens and the epithelial cells of the rabbit lens grown in tissue culture. Vimentin is actively synthesized by all of the above mentioned cells.

Expression of the intermediate-filament-associated protein synemin in chicken lens cells

Synemin, a 230-kilodalton polypeptide component of avian muscle and erythrocyte intermediate filaments, is also found in association with the vimentin filaments of lens tissue. In chicken lens cells, synemin is bound to the core vimentin polymer with the same 180-nm periodicity that it exhibits in erythrocytes. Its solubility properties are characteristic of those of intermediate filaments in general and similar to those of synemin in muscle cells and erythrocytes. Synemin appears at an early stage of lens development and undergoes a dramatic accumulation as the epithelial cells elongate and differentiate into fiber cells. In contrast to synemin in cultured skeletal muscle, lens synemin is not confined to postmitotic, terminally differentiating cells but is present in proliferative cells as well. It is lost from the fibers near the center of the lens, as are many other cellular structures including intermediate filaments. These findings provide new information about the occurrence and expression of avian synemin and new insight regarding its presumptive role as a modulator of intermediate-filament function.

Expression of the intermediate-filament-associated protein synemin in chicken lens cells

Synemin, a 230-kilodalton polypeptide component of avian muscle and erythrocyte intermediate filaments, is also found in association with the vimentin filaments of lens tissue. In chicken lens cells, synemin is bound to the core vimentin polymer with the same 180-nm periodicity that it exhibits in erythrocytes. Its solubility properties are characteristic of those of intermediate filaments in general and similar to those of synemin in muscle cells and erythrocytes. Synemin appears at an early stage of lens development and undergoes a dramatic accumulation as the epithelial cells elongate and differentiate into fiber cells. In contrast to synemin in cultured skeletal muscle, lens synemin is not confined to postmitotic, terminally differentiating cells but is present in proliferative cells as well. It is lost from the fibers near the center of the lens, as are many other cellular structures including intermediate filaments. These findings provide new information about the occurrence and expression of avian synemin and new insight regarding its presumptive role as a modulator of intermediate-filament function.

A simple method to characterize gamma-crystallin synthesized in vitro

Investigation of the migration of in vitro synthesized gamma-crystallin which has not been heat denatured on polyacrylamide gel electrophoresis in presence of sodium dodecyl sulfate indicates that this class of proteins behaves in an anomalous manner. While other in vitro synthesized lens proteins under these conditions migrate as theoretically expected, gamma-crystallin is retarded, having a mobility comparable to a 92 000 dalton component. Only upon heat denaturation does this protein fraction migrate as a 20 000 dalton species. Since other in vitro synthesized lens proteins have molecular weights of approximately 20 000 daltons, it is only with this methodology that gamma-crystallin synthesis can be unequivocally followed in a simple, rapid, one-dimensional fractionation system.

Phosphorylation of chick lens proteins

Phosphorylated proteins of the chick lens were identified following incubation of lenses in a medium containing 32P and subsequent analysis by gel electrophoresis. The acidic variant of the vimentin and both subunits of fodrin were phosphorylated, as were the 95 Kd and 49 Kd proteins associated with the beaded-chain filaments. Neither crystallins nor the main intrinsic membrane proteins were phosphorylated. Several low molecular weight phosphoproteins of the epithelial cell were not present in the fiber cells.

A cytoskeletal protein unique to lens fiber cell differentiation

A chick lens urea-soluble polypeptide of estimated mol. wt. 49 000 daltons is unique to fiber cell differentiation and is a component of the beaded-chain filaments of the chick cytoskeleton. Antigenically related proteins are also present in the human and bovine lens. There is no similarity between this protein and actin as determined by immunological analysis and two-dimensional gel electrophoresis.

Cytoskeletal proteins of the aging human lens

The cytoskeletal proteins of the human lens were studied by SDS-PAGE, 2-D electrophoresis and immunologically. Spectrin, vimentin and actin were identified in the superficial fiber cells of human lenses even to age 87 years. These proteins are lost from the deeper cortical and nuclear fiber cells, where a broad zone of acidic protein (36-42 Kd) emerges even in the transparent normal lens. Age-related changes in the water-soluble fraction include the increased prominence of proteins of 56 Kd and 36 Kd in the cortex, and of 38 Kd in the nucleus.

Studies on lens vimentin

Antibody prepared against chick lens vimentin cross-reacts with chick fibroblast vimentin and with vimentin of mammalian, reptilian, amphibian and fish lenses. This protein is localized in the epithelial and cortical fiber cells and is progressively lost from the deeper cortical cells. It is absent from the nuclear cells. Lens vimentin is readily oxidized to form high molecular components.