Tgfbeta receptor expression in lens: implications for differentiation and cataractogenesis.

TGFbeta induces changes characteristic of some forms of cataract. However, the responsiveness of lens epithelial cells to TGFbeta is age-dependent; weanling and adult, but not neonatal, lens epithelial cells respond. This study investigated TGFbeta receptor (TbetaRI and TbetaRII) expression during rat lens development and the effects of FGF-2 on TGFbeta responsiveness and TbetaR expression. Immunofluorescence, immunoblotting, RT-PCR and in situ hybridization were used to examine the spatio-temporal expression patterns of TbetaR. Lens explants were used to investigate the effects of FGF-2 on TGFbeta responsiveness and TbetaR expression. In the lens epithelium, little or no immunoreactivity was detected at P3 but at P21 there was distinct reactivity for TbetaRI and TbetaRII. Reactivity for both receptors was also found in the differentiating fibers in the transitional zone and cortex at both ages. Western blotting of lens membrane extracts identified multiple molecular weight forms of TbetaRI (30, 50, 90 kDa) and TbetaRII (70-120 kDa). In situ hybridization with a rat probe for Alk5 (TbetaRI) showed that the lens expresses Alk5 mRNA in epithelium and fibers throughout development. A rat TbetaRII probe revealed distinct expression of a TbetaRII mRNA in lens fibers throughout development and in the lens epithelium at P21 but not at P3. In vitro studies showed that lens epithelial explants from P9 rats did not undergo cataractous changes in response to TGFbeta but P13 explants did. Addition of FGF-2 to P9 explants induced increased TbetaR immunoreactivity and enhanced the competency of lens epithelial cells to respond to TGFbeta. These data indicate that the overall increased expression of TGFbeta receptors in lens epithelium during postnatal development (P3-P21) underlies an age-related change in TGFbeta responsiveness. The results also suggest that lens cells may express multiple forms of TbetaR. Expression of TbetaR in lens fibers throughout lens development and the induction of enhanced TbetaR expression by FGF suggest a role for TGFbeta signaling during FGF-induced responses and fiber differentiation.

Susceptibility to TGFbeta2-induced cataract increases with aging in the rat.

PURPOSE: Cataract is the most common cause of blindness in the world today, and yet there is no generally accepted treatment other than surgical intervention. Studies in rodent models designed to increase understanding of the molecular basis of cataract have shown that transforming growth factor (TGF)-beta induces morphologic and molecular changes similar to those associated with some forms of human cataract. Because aging is the most widely recognized risk factor for cataract, it is important that any animal model be examined in this context. This was a study of the effects of aging on susceptibility to TGFbeta-induced cataract. METHODS: Lenses from weanling, adult, and senile rats were cultured in defined serum-free medium with a range of concentrations of TGFbeta2. The lenses were cultured for up to 7 days, photographed daily, fixed, and prepared for histology and immunolocalization. Opacification was quantified by image analysis. RESULTS: Lenses from weanling, adult, and senile rats all underwent similar cataractous changes when exposed to TGFbeta. This included opacification, the formation of anterior subcapsular plaques, and accumulation of type I collagen and alpha-smooth muscle actin. Lenses from adult and senile animals, however, were generally more adversely affected by TGFbeta than lenses from weanlings. This study also showed that a low dose of TGFbeta administered over a prolonged period had an effect similar to that of a higher dose administered over a shorter period. CONCLUSIONS: An elevation of TGFbeta activity, either acute or chronic, and/or an age-related increase in lens cell susceptibility to TGFbeta may be triggering factors in the etiology of certain forms of cataract.

Intravitreal injection of TGFbeta induces cataract in rats.

PURPOSE: In a previous study, it was determined that TGFbeta induces cataractous changes in the rat lens in vitro. The purpose of the present study was to determine whether the introduction of biologically active TGFbeta into the vitreous stimulates cataractous changes in the rat lens in situ. METHODS: TGFbeta was injected into the vitreous of the left eye of anesthetized adult male Wistar rats. The right eye received sterile vehicle as a control. Three to four months after injection, animals were killed, and lenses were enucleated and examined for cataractous changes. RESULTS: All lenses from control eyes remained transparent and maintained normal cellular architecture throughout. In contrast, lenses from TGFbeta-injected eyes displayed cloudiness in the cortex. In some lenses, distinct opacities were also apparent at the equator and extending some distance toward the anterior and posterior poles. Histologically, the opacities corresponded to subcapsular plaques containing aberrant cells and accumulations of extracellular matrix. In addition, cortical fibers in the anterior and posterior of all lenses displayed variable degrees of swelling, and many retained their nuclei. In some regions, the fiber cells appeared to have degenerated to form large homogeneous areas. The cellular architecture of the equator of these lenses was also disrupted and, in the most severe case, no bow zone was apparent with nucleated cells extending to the posterior pole. CONCLUSION: The introduction of active TGFbeta into the vitreous induced lenses to undergo cataractous changes. In addition to the TGFbeta-induced changes in the epithelium that were reported previously, cataractous changes observed in this study also involved the lens fiber cells and resembled changes observed in human posterior subcapsular and cortical cataracts.

Lens development.

This review gives a brief account of the main processes of lens development, including induction, morphogenesis, differentiation and growth. It describes what is known about the molecules and mechanisms that control and regulate these processes. Some of the recent progress made in understanding the molecular basis of lens development is highlighted along with some of the challenging areas for future research.

Differential cataractogenic potency of TGF-beta1, -beta2, and -beta3 and their expression in the postnatal rat eye.

PURPOSE: Transforming growth factor-beta has been shown to induce cataractous changes in rat lenses. This study assesses the relative cataractogenic potential of TGF-beta1, TGF-beta2, and TGF-beta3 and their expression patterns in the rat eye. METHODS: Lens epithelial explants and whole lenses from weanling rats were cultured with TGF-beta1, TGF-beta2, or TGF-beta3 at concentrations ranging from 0.025 ng/ml to 4 ng/ml for 3 to 5 days. Cataractous changes were monitored daily by phase contrast microscopy and by immunofluorescent detection of cataract markers alpha-smooth muscle actin and type I collagen. Expression of TGF-beta was studied by immunofluorescence and in situ hybridization on eye sections from neonatal and weanling rats. RESULTS: All three isoforms induced morphologic changes in lens epithelial explants and cultured lenses that are typically associated with human subcapsular cataract. Transforming growth factor-beta2 and TGF-beta3 were approximately 10 times more potent than TGF-beta1. All three isoforms were expressed in the eye in spatially distinct but overlapping patterns. Transforming growth factor-beta1 and TGF-beta2 and their mRNA were detected in most ocular tissues, including the lens. Although TGF-beta3 was immunolocalized in lens epithelium and fibers and in other ocular tissues, its mRNA was detected only in the retina and choroid. CONCLUSIONS: All three isoforms of TGF-beta are potentially available to lens cells and have the potential to induce cataractous changes. The results suggest that TGF-beta activity is normally tightly regulated in the eye. Activation of TGF-beta in the lens environment, such as may occur during injury, in wound healing, or in pathologic conditions may contribute to cataractogenesis in vivo.

Estrogen protects lenses against cataract induced by transforming growth factor-beta (TGFbeta).

Cataract, already a major cause of visual impairment and blindness, is likely to become an increasing problem as the world population ages. In a previous study, we showed that transforming growth factor-beta (TGFP) induces rat lenses in culture to develop opacities and other changes that have many features of human subcapsular cataracts. Here we show that estrogen protects against cataract. Lenses from female rats are more resistant to TGFbeta-induced cataract than those from males. Furthermore, lenses from ovariectomized females show increased sensitivity to the damaging effects of TGFbeta and estrogen replacement in vivo, or exposure to estrogen in vitro, restores resistance. Sex-dependent and estrogen-related differences in susceptibility to cataract formation, consistent with a protective role for estrogen, have been noted in some epidemiological studies. The present study in the rat indicates that estrogen provides protection against cataract by countering the damaging effects of TGFbeP. It also adds to an increasing body of evidence that hormone replacement therapy protects postmenopausal women against various diseases.

Cataract induction in lenses cultured with transforming growth factor-beta.

PURPOSE: Anterior subcapsular cataracts are characterized by the appearance of opaque plaques of abnormal cells. Distinctive spindle-shaped cells containing alpha-smooth muscle actin are present and are associated with wrinkling of the overlying lens capsule. Accumulations of extracellular matrix, including type I collagen, also are found. The authors previously reported that transforming growth factor-beta (TGF-beta) induces similar aberrant morphologic changes in lens epithelial explants. More recently, they identified alpha-smooth muscle actin in explants cultured with TGF-beta. The aim of this study was to determine whether TGF-beta induces comparable cataractous changes in whole lenses and to examine the effects of this treatment on the transparency of the lens. METHODS: Whole lenses from 21-day-old rats were cultured in defined serum-free medium with TGF-beta 2 or without added growth factors for 5 days. Lenses were then photographed and prepared for histology and immunolocalization. RESULTS: Lenses cultured with TGF-beta developed distinct anterior opacities just beneath the lens capsule. Histologically, clumps of abnormal cells corresponded with these opacities. Spindle-shaped cells, which contained alpha-smooth muscle actin, were present, and the overlying capsule was often wrinkled. The clumps contained accumulations of type I collagen, laminin, and heparan sulphate proteoglycan. In contrast, lenses cultured without growth factors remained transparent, retained normal lens morphology, and did not accumulate alpha-smooth muscle actin or type I collagen. CONCLUSIONS: These results show that TGF-beta induces whole lenses to form opacities that contain morphologic and biochemical markers for subcapsular cataract.

TGF-beta 1 induces lens cells to accumulate alpha-smooth muscle actin, a marker for subcapsular cataracts.

Spindle-shaped myofibroblast-like cells, which contain alpha-smooth muscle actin, have been described in anterior subcapsular cataract and after-cataract. In a previous study in this laboratory, it was shown that transforming growth factor-beta (TGF beta) induces the formation of spindle-shaped cells in lens epithelial explants. The aim of this investigation was to determine whether these TGF beta-induced spindle-shaped cells contain alpha-smooth muscle actin. Lens epithelial explants were prepared from 21-day-old rats and cultured with either TGF beta 1 or basic FGF alone, a combination of both growth factors, or without added growth factors. After three days, cellular changes were monitored by phase contrast microscopy, localisation of filamentous actin with rhodamine-phalloidin, and immunolocalisation and immunoblotting of alpha-smooth muscle actin. TGF beta induced rapid cell elongation and formation of characteristic spindle-shaped cells in lens epithelial explants in the presence or absence of FGF. These cells contained alpha-smooth muscle actin, a marker for myofibroblastic cells and a protein not normally found in the lens. The present study thus provides molecular evidence that TGF beta induces cataractous changes in lens epithelial cells. As TGF beta is potentially available to lens cells in situ throughout life, these findings are consistent with a key role for TGF beta in the aetiology of major forms of subcapsular cataract.

Induction of cataract-like changes in rat lens epithelial explants by transforming growth factor beta.

PURPOSE: To investigate the possible role of transforming growth factor beta (TGF beta) in lens development and growth, the authors studied the influence of TGF beta, alone and in combination with fibroblast growth factor (FGF), on lens epithelial explants. METHODS: Lens explants were prepared from both postnatal and adult rats, and changes during 5 days of culture with growth factor(s) were monitored by light and electron microscopy, immunolocalization of laminin, heparan sulfate proteoglycan and fiber-specific crystallins, and crystallin enzyme-linked immunosorbent assays. RESULTS: TGF beta induced cells in explants to undergo an extensive and rapid elongation with features that distinguished it from FGF-induced fiber differentiation. TGF beta also induced accumulation of extracellular matrix, capsule wrinkling, cell death by apoptosis, and distinctive arrangements of cells. Standard explants from 10-day-old rats responded to TGF beta only in the presence of FGF. Comparable explants from adult rats or from 21-day-old rats (cultured on a laminin substratum) responded readily to TGF beta whether or not FGF was present. CONCLUSIONS: First, these results suggest a role for TGF beta in regulating normal processes in lens cells such as the production of extracellular matrix and capsule formation. Second, because many of the changes induced by TGF beta resembled changes reported to occur during the formation of various kinds of subcapsular cataracts, the results suggest that detailed studies of factors that influence the ability of lens cells to respond to TGF beta and the bioavailability of TGF beta in the ocular media may provide important insights into the etiology of some forms of cataract.