Human fetal lens epithelial cells in culture: an in vitro model for the study of crystallin expression and lens differentiation

Methodologies to unlock the molecular expression and cellular structure of ocular lens epithelial cells

The transparent ocular lens in the anterior chamber of the eye is responsible for fine focusing of light onto the retina. The lens is entirely cellular with bulk of the tissue composed of fiber cells, and the anterior hemisphere of the lens is covered by a monolayer of epithelial cells. Lens epithelial cells are important for maintaining fiber cell homeostasis and for continual growth of the lens tissue throughout life. Cataracts, defined as any opacity in the lens, remain the leading cause of blindness in the world. Following cataract surgery, lens epithelial cells can undergo a process of epithelial-to-mesenchymal transition (EMT), leading to secondary cataracts due to posterior capsular opacification (PCO). Since the epithelial cells make up only a small fraction of the lens, specialized techniques are required to study lens epithelial cell biology and pathology. Studies using native lens epithelial cells often require pooling of samples to obtain enough cells to make sufficient samples for traditional molecular biology techniques. Here, we provide detailed protocols that enable the study of native mouse lens epithelial cells, including immunostaining of the native lens epithelium in flat mounts, extraction of RNA and proteins from pairs of lens epithelial monolayers, and isolation of lens epithelial cells for primary culture. These protocols will enable researchers to gain better insight on representative molecular expression and cellular structure of lens epithelial cells. We also provide comparative data between native, primary culture, and immortalized lens epithelial cells and discuss the advantages and disadvantages of each technique presented.

Lanosterol reverses protein aggregation in cataracts

The human lens is comprised largely of crystallin proteins assembled into a highly ordered, interactive macro-structure essential for lens transparency and refractive index. Any disruption of intra- or inter-protein interactions will alter this delicate structure, exposing hydrophobic surfaces, with consequent protein aggregation and cataract formation. Cataracts are the most common cause of blindness worldwide, affecting tens of millions of people, and currently the only treatment is surgical removal of cataractous lenses. The precise mechanisms by which lens proteins both prevent aggregation and maintain lens transparency are largely unknown. Lanosterol is an amphipathic molecule enriched in the lens. It is synthesized by lanosterol synthase (LSS) in a key cyclization reaction of a cholesterol synthesis pathway. Here we identify two distinct homozygous LSS missense mutations (W581R and G588S) in two families with extensive congenital cataracts. Both of these mutations affect highly conserved amino acid residues and impair key catalytic functions of LSS. Engineered expression of wild-type, but not mutant, LSS prevents intracellular protein aggregation of various cataract-causing mutant crystallins. Treatment by lanosterol, but not cholesterol, significantly decreased preformed protein aggregates both in vitro and in cell-transfection experiments. We further show that lanosterol treatment could reduce cataract severity and increase transparency in dissected rabbit cataractous lenses in vitro and cataract severity in vivo in dogs. Our study identifies lanosterol as a key molecule in the prevention of lens protein aggregation and points to a novel strategy for cataract prevention and treatment.

AlphaB-crystallin: a Golgi-associated membrane protein in the developing ocular lens

PURPOSE

All crystallins have non-crystallin catalytic functions. Because catalytic functions do not require large concentrations of protein, as are seen in the lens, there is a perception of dichotomy in the catalytic/physiological function of crystallins within and outside the lens. The status of alphaB-crystallin, a ubiquitously expressed small heat shock protein (and a crystallin) in the ocular lens, was investigated.

METHODS

Discontinuous sucrose density gradients were used for fractionation of Golgi membranes and vesicles. Light microscopy and confocal microscopy were used for immunolocalization in cultured cells and the native lens.

RESULTS

alphaB-crystallin is highly organized, as indicated by its polar presence in the apical Golgi in lens epithelium and in the perinuclear Golgi streaks in differentiating lens fiber cells. Assessment of the distribution of alphaB-crystallin in Golgi-enriched and vesicular fractions (characterized by the presence of Golgi membrane protein GM130 and vesicle coat protein gammaCOP) in the developing lens reveal a gradual transition from Golgi to vesicular fraction, concomitant with the appearance of alphaB-crystallin as a "soluble" protein.

CONCLUSIONS

These data demonstrate that alphaB-crystallin, known to be a soluble protein, starts life as a Golgi-associated membrane protein in the fetal and early postnatal lens and that the developmentally controlled physical state of the Golgi determines the status of this protein in the lens. These findings also show the similarity in the localization/physiological function of alphaB-crystallin within and outside the ocular lens and suggest that non-crystallin/catalytic function is an innate component of the expression of a crystallin in the lens.

A comparative analysis of αA- and αB-crystallin expression during the cell cycle in primary mouse lens epithelial cultures

AlphaA- and alphaB-crystallins are small heat shock proteins and molecular chaperones that prevent non-specific aggregation of denaturing proteins. Previous work in our laboratory has shown that lens epithelial cells derived from alphaA-/- mice exhibit slower growth, whereas alphaB-/- lens epithelial cells hyperproliferate at a higher rate in culture [Andley et al., J. Biol. Chem. 273 (1998) 31252; FASEB J. 15 (2001) 221]. Although both have been implicated in apoptosis and cell proliferation, direct analysis of their expression during the cell cycle has not been investigated. This study was undertaken to define the expression levels of alphaA and alphaB-crystallins during the cell cycle. Primary lens epithelial cell cultures derived from wild type mice were synchronized by serum starvation, and pulsed with bromodeoxyuridine (BrdU) at different times after re-stimulation with serum. Dual parameter flow cytometric studies with BrdU and propidium iodide (PI)-labeled cells were performed. Cells entered S phase 14 hr after serum re-stimulation. The duration of the S phase was 6 hr, and the total cell cycle transit time was between 24-27 hr. Enhanced expression of cyclin A, a protein essential for DNA synthesis was used as an additional marker to define the initiation of the S phase. Immunoblotting analysis demonstrated that the expression of alphaA and alphaB-crystallin was up to 10-fold higher in cells synchronized in G0 phase than in G1 phase. The levels of the proteins increased three-fold again as the cells entered the S phase and progressed to mitosis, but did not rise to the levels observed in G0 phase. This increase in expression of alphaA-crystallin resulted in part from enhanced synthesis during the S phase, as shown by an increase in [35S]methionine-labeling and immunoprecipitation of the radiolabeled alphaA-crystallin. The results were further confirmed by flow cytometric analysis using DNA content and alphaA-crystallin expression. The increase in alphaB-crystallin in S phase was paralleled by an increase in gene expression as shown by real-time RT-PCR analysis. These results demonstrate for the first time that in lens epithelial cells, alphaA and alphaB-crystallin levels are modulated during the cell cycle. Since the absence of alphaA and alphaB- crystallin in lens epithelial cells has been associated with disturbance of the tubulin cytoskeleton during mitosis, and with increased cell death or genomic instability, our results indicating that the alphaA- and alphaB-crystallin expression increases prior to mitosis are significant. The differential expression of these crystallins in the cell cycle may be important for optimal lens epithelial growth and lens transparency.

Crystallins, genes and cataract

Far from being a physical entity, assembled of inanimate structural proteins, the ocular lens epitomizes the biological ingenuity that sustains an essential and near-perfect physical system of immaculate optics. Crystallins (alpha, beta, and gamma) provide transparency by dint of their high concentration, but it is debatable whether proteins that provide transparency are any different, biologically or structurally, from those that are present in non-transparent structures or tissues. It is becoming increasingly clear that crystallins may have a plethora of metabolic and regulatory functions, both within the lens as well as outside of it. Alpha-crystallins are members of a small heat shock family of proteins and beta/gamma-crystallins belong to the family of epidermis-specific differentiation proteins. Crystallin gene expression has been studied from the perspective of the lens specificity of their promoters. Mutations in alpha-, beta-, and gamma-crystallins are linked with the phenotype of the loss of transparency. Understanding catalytic, non-structural properties of crystallins may be critical for understanding the malfunction in molecular cascades that lead to cataractogenesis and its eventual therapeutic amelioration.

Human lens epithelial cell line

Although primary cultures of human lens epithelial (HLE) cells provide important information concerning the role of epithelium in normal lens and cataract formation, the lack of a cell line precludes a broad range of studies on the metabolism and molecular biology of these cells. We have, therefore developed an HLE cell line. Primary cultures of HLE cells were transfected with plasmid vector DNA containing a large T antigen of SV40. The immortalized cells were characterized with regard to morphology, growth rate, karyotype, and expression of crystallins, aldose reductase and other enzymes. A single clone of the immortalized cells, SRA 01/04, formed a monolayer and grew constantly over 130 passages. Isozyme phenotype showed that SRA 01/04 was of human origin, and the chromosome counts were in the hypotetraploid range. Western blot analysis showed that the cells expressed a very low level of crystallins (alphaA and betaB2) and aldose reductase. Messenger RNA (mRNA) for both alpha and beta crystallins was detected by reverse transcription polymerase chain reaction (RT-PCR) in both early and late passages. Sequence analysis of the PCR products, corresponding to alphaA and betaB2 crystallins in the cell line and in primary cultures of HLE, revealed a 100% match with published human alphaA and betaB2 sequences. These characteristics were unchanged in the cell line in early and late passages. This is the first report of the presence of alphaA and transcripts of mRNA for both alphaA and betaB2 in an established human cell line. This new HLE cell line makes it possible to undertake many future studies on the role of epithelium in lens and cataract formation.

Ontogeny of alpha-crystallin subunits in the lens of human and rat embryos

The distribution of alpha A- and alpha B-crystallin in the developing lens of human (Carnegie stages 13 to 23) and rat embryos (embryonic days E11 to 18) was examined immunohistochemically. In a human embryo at stage 13, the lens placode was already immunoreactive to alpha B-crystallin, but not to alpha A-crystallin. At stage 15, the lens vesicle was intensely immunoreactive both to alpha A- and alpha B-crystallin. From stages 16 to 23, the lens epithelial cells and fiber cells were immunoreactive to alpha A- and alpha B-crystallin. In rat embryos, alpha A-crystallin appeared in the lens pit at E12, and alpha B-crystallin appeared in the elongating lens fiber cells at E14. From E15 to E18, the lens epithelial cells and fiber cells were immunoreactive to alpha A-crystallin. The lens fiber cells were also immunoreactive to alpha B-crystallin, but the epithelial cells were not. These findings suggest that alpha B-crystallin appears earlier than alpha A-crystallin in the human lens, but at a later period than alpha A-crystallin in the rat lens. alpha B-Crystallin was not detected in the epithelial cells of the rat lens, but was persistently present in the epithelial cells of the human lens.

Crystallin gene expression in the process of lentoidogenesis in cultures of chicken lens epithelial cells

One alpha B- and three different beta-crystallin cDNA clones were isolated from a chicken lens cDNA library by using anti-crystallin antibodies. The sequence of alpha B-crystallin cDNA showed more than 70% homology with exons of alpha B-crystallin genes of the human and hamster. Two beta-crystallin cDNAs showed almost identical sequences with previously reported chicken beta B1- and beta A3/A1-crystallin genes. The remainder showed 80% homology of sequence with bovine beta B2-crystalline cDNA. Using these newly cloned cDNAs, in addition to cDNAs of alpha A- and delta-crystallin, we examined the expression pattern of these crystallins in the process of lentoidogenesis of cultured lens epithelial cells of the chicken. All crystallins except beta-crystallins were expressed through the period of cell culture, but three beta-crystallins were expressed only after the confluent stage. These results suggest that: (1) alpha A-, alpha B- and delta-crystallin cDNAs can be used to detect differentiation of the lens epithelial cell; and (2) beta-crystallin cDNAs are superior in the detection of chicken lens fibre differentiation in vitro to delta-crystallin cDNA, which is ectopically expressed by various non-lenticular tissues.

Synthesis of interleukin-1 and prostaglandin E2 by lens epithelial cells of human cataracts

To test our hypothesis that pseudophakic inflammation, including the fibrin reaction, may be caused by cytokines, prostaglandins (PG), or both, synthesised by residual lens epithelial cells (LECs), we measured interleukin-1 alpha (IL-1 alpha) and PGE2 in the incubation medium of cultures of human LECs obtained by capsulotomy during cataract surgery. After 1 week radioimmunoassay showed that there were 1.46 (0.62) ng of PGE2/10(6) cells (mean (SD) six cultures), and after 4 weeks, there were 5.50 (2.20) ng of PGE2/10(6) cells (seven cultures). During culture the cells proliferated and underwent fibroblast-like cell changes on exposure to the plastic of the wells. In the medium of control plates to which sodium diclofenac had been added PGE2 was not detected. Some IL-1 alpha was found in four of 10 samples, each of which contained media from 12 cultures; 207 pg/10(6) cells in one of the two pools of 2-week cultures, 120 pg/10(6) cells in one pool and 139 pg/10(6) cells in another of the three pools of 3-week cultures, and 111 pg/10(6) cells in the one pool of 4-week cultures. PGE2 and IL-1 alpha may therefore be produced in vivo by residual LECs after cataract surgery, and may be involved in postoperative inflammation, including the fibrin reaction.

Lens fiber cell differentiation and expression of crystallins in co-cultures of human fetal lens epithelial cells and fibroblasts

Growth of the ocular lens is directed by the division and differentiation of a single layer of epithelial cells located at the equatorial region. It is conceivable that this region of the lens capsule presents a special microenvironment modulated by molecular cues emanating from the surrounding tissues. In an effort to investigate the source and nature of these molecular cues, we co-cultured human fetal lens epithelial cells and fibroblasts derived from the ciliary body. We observed morphological differentiation as evidenced by the appearance of differentiating lentoid structures associated with fibroblasts. Characterization of the expression of lens-specific proteins revealed that in addition to alpha B-crystallin, these lentoid structures contain the lens fiber cell-specific proteins, alpha A-crystallin, beta B2-crystallin and gamma S-crystallin. None of these crystallins could be found in the surrounding undifferentiated lens epithelial cells. Interestingly, alpha B-crystallin usually present in lens epithelial cells when cultured alone, was found to be markedly decreased, both in synthesis and content in the cells surrounding the differentiated structures, suggesting that the process of differentiation in vitro may concomitantly produce a factor(s) which modulates alpha B-crystallin expression in these cells.

Expression and distribution of cytoskeletal IFAP-300kD as an index of lens cell differentiation

By their implication in the organization of the intermediate filament (IF) cytoskeleton, IF-associated proteins (IFAPs) can delineate subsets of the same IF type within a cell; moreover, they are proving useful as markers of the differentiation states of certain cells. For these reasons the expression of the vimentin-associated IFAP-300kD was investigated in the constantly differentiating cell lineage of the adult bovine lens. Immunofluorescence microscopy and immunoblot analysis were employed using a monoclonal anti-IFAP-300kD and a rabbit anti-lens vimentin. Cultures of adult lens epithelial cells were immunopositive for the IFAP. By double-label studies the IFAP-300kD pattern co-localized with that of the vimentin-type IF; moreover, the IFAP pattern co-distributed with that of both colchicine-sensitive and -insensitive IF systems. IFAP-300kD was also present in a co-distributing pattern with vimentin IF in fresh lens epithelial cells on whole mounts. There was a differential expression of the IFAP in the lens fiber cells in that those of the cortex exhibited the IFAP and vimentin IF, while both proteins were absent from the nuclear fiber cells. Furthermore, there was a differential distribution of the IFAP within the cortical fiber cells in that the IFAP localized only with a paramembranal subset of IF. Immunoblot analysis supported the presence of IFAP-300kD in the lens cytoskeletal fraction. IFAP-300kD thus identified a subset of vimentin IF whose location may have functional significance for the cortical fiber cell. The changes in the IFAP's expression and distribution pattern throughout lens cell differentiation in the adult organ suggest the usefulness of IFAP-300kD as a potential marker in studying lens cell differentiation in vitro.

Study of crystallin expression in human lens epithelial cells during differentiation in culture and in non-lenticular tissues

Crystallin expression in human lens epithelial cells in culture and a number of non-lenticular tissues was studied by the technique of immunoblotting using monoclonal antibodies. The expression of alpha A, beta 5 and beta 6 crystallins per unit number of cells increased with passage number while alpha B appeared to be constant Lentoid bodies derived from cultured human lens epithelial cells not only expressed gamma-crystallin and MP26 as previously demonstrated, but also produced alpha A, alpha B, beta 5 and beta 6 crystallins. In human non-lenticular tissues including ciliary body, vitreous body, neural retina, cultured retinal pigment epithelial cells and scleral fibroblasts, alpha B-crystallin was detected, but was undetectable in cornea and iris. Alpha A was present only in the lens. These studies demonstrate that HLE cells maintain the ability to synthesize crystallins through several passages. Following differentiation, they not only synthesize gamma-crystallin and MP26 but continue to express alpha- and beta-crystallins similar to differentiated lens fiber cells in vivo. Consistent with previous observations, the expression of alpha B-crystallin does not appear to be specific for the lens.

Two-dimensional gel electrophoresis of human lens epithelium: a study of spatial protein patterns and aging

The polypeptides in portions of human lens epithelium from individuals of various ages were resolved by two-dimensional (2D) gel electrophoresis. The epithelium was divided into a central area of 12.5 mm2, a surrounding area of 50.2 mm2, and an area which was outside of this region. The proteins were solubilized in urea and run on gels to determine if differences existed in the major polypeptides of the lens epithelium with regard to position in the lens as well as if differences might occur with age. The patterns obtained were remarkably similar in regions of the epithelium examined. The results also demonstrated that the composition of the major polypeptides were not substantially altered in the adult epithelium with age. Two-dimensional gels of proteins from a 3-month-old specimen prepared in a manner similar to that used during extracapsular cataract extraction were also similar to the other samples; however, this sample contained slightly increased staining of proteins greater than 30 kD.

Electrophysiology of cultured human lens epithelial cells

The lens epithelial K+ conductance plays a key role in maintaining the lens ionic steady state. The specific channels responsible for this conductance are unknown. We used cultured lens epithelia and patch-clamp technology to address this problem. Human lens epithelial explants were cultured and after 1-4 passages were dissociated and used in this study. The cells from which we measured had a mean diameter of 31 +/- 1 microns (SEM, n = 26). The resting voltage was -19 +/- 4 mV (SEM, n = 10) and the input resistance was 2.5 +/- 0.5 G omega (SEM, n = 17) at -60 mV. Two currents were prominent in whole-cell recordings. An outwardly rectifying current was seen in nearly every cell. The magnitude of this current was a function of K+ concentration and was blocked by 3 mM tetraethylammonium. The instantaneous current-voltage relationship was linear in symmetric K+, implying that the outward rectification was due to gating. The current showed complex activation and inactivation kinetics. The second current seen was a transient inward current. This current had kinetics very similar to the traditional Na+ current of excitable cells and was blocked by 0.1 microM tetrodotoxin. In single-channel recordings, a 150-pS K+ channel and a 35-pS nonselective cation channel were seen but neither account for the macroscopic currents measured.

Age-related changes in the response of chick lens cells during long-term culture to insulin, cyclic AMP, retinoic acid and a bovine retinal extract

We have reported that 1-day-old post-hatch chick lens epithelial cells lose the capacity for lentoid body formation and delta-crystallin expression during long-term serial subculture, although they continue to synthesize, but not to accumulate, alpha- and beta-crystallins, even in cells with a transformed phenotype. Here we present evidence that dedifferentiation may reflect an age-related change in the capacity for response to regulatory signals. We have tested the capacity of these cells in serial subcultures to respond to agencies which affect lens cell growth and differentiation in primary culture: retinoic acid (RA), insulin, cAMP and bovine retinal extract (BRE). Secondary cultures responded only to RA and BRE, by an increase in lentoid formation and by alpha- and beta-accumulation, while RA also restored delta-crystallin expression. Later cultures showed no such responses. The results suggest that the process of lens cell dedifferentiation may, at first, be reversible but later becomes irreversible, despite the continuing persistence of low levels of crystallin expression.

Synthesis of alpha-crystallin by a cell line derived from the lens of a transgenic animal

Cultured cells derived from transgenic animals have not generally been utilized to investigate questions in cell biology; however, to study the properties of proteins from the lens of the eye, a cell line which synthesizes alpha-crystallin was established from a transgenic mouse. All the alpha-crystallins, alpha A, alpha B, and alpha Insert, accumulate in the cell line. The alpha-crystallin, 1.6% of the cellular protein, is found in large molecular weight aggregates similar to the aggregates found in the normal mouse lens. The alpha-crystallins in the lens cells correspond exactly to both the unmodified and the phosphorylated alpha-crystallins found in the lens of the mouse, suggesting that some post-translational modification of the mouse alpha-crystallin may be important to the structure of this protein.