Transmethylation of phosphatidylethanolamine: an initial event in embryonic chicken lens fiber cell differentiation.

Agents that induce differentiation of lens epithelial cells into lens fiber cells in vitro transiently stimulate the transmethylation of phosphatidylethanolamine. Inhibition of transmethylation by 3-deazaadenosine results in a corresponding inhibition of the cell elongation that characterizes lens fiber formation, suggesting that phospholipid methylation plays an essential role in the differentiation of these cells.

pRb and p107 regulate E2F activity during lens fiber cell differentiation.

During growth arrest and differentiation, activity of the E2F family of transcription factors is inhibited by interactions with pRb and the related proteins, p107 and p130. To determine which members of the E2F and pRb families may contribute to growth arrest as lens epithelial cells differentiate into fiber cells, we examined the expression of individual E2F species and characterized the E2F protein complexes formed in rat lens epithelia and fibers. RT/PCR detected all five known members of the E2F family in lens epithelial cells, but only E2F-1, E2F-3, and E2F-5 in fiber cells. Proteins extracted from lens epithelia of newborn rats formed at least two specific complexes with an E2F consensus oligonucleotide. Proteins from lens fiber cells formed three specific complexes, one of which comigrated with an epithelial cell complex. Incubation of epithelial and fiber cell extracts with an antibody specific for p107 demonstrated that two fiber cell complexes and one epithelial cell complex contained p107. Although the remaining fiber cell complex did not react with antibodies to pRb or p130 in this assay, a strong reaction with pRb antibody was observed when the electromobility shifted complexes were subsequently immunoblotted (shift/Western assay). Immunocytochemistry confirmed that pRb protein is present in the nuclei of both epithelial cells and fiber cells. Immunoblotting of whole cell extracts with pRb antibody showed multiple, phosphorylated forms of pRb in the epithelial cells, but predominantly hypophosphorylated pRb in the fiber cells. None of the complexes formed with E2F were recognized exclusively by the p130 antibody, although the previously identified p107 complexes reacted weakly. The absence of p130/E2F complexes was correlated with the presence of multiple ubiquitinated forms of p130, especially in the fiber cells. Thus, although p130/E2F complexes are implicated in the terminal differentiation of many cell types, in differentiating lens fiber cells pRb and p107 seem to be the primary regulators of E2F activity.

Phosphatidylcholine and phosphatidylethanolamine metabolism during lens fiber cell formation.

Phosphatidylinositol is metabolized with a half-life of about 5 h in lens epithelial cells of 6-day-old embryonic chickens. When these cells differentiate to form lens fiber cells, however, phosphatidylinositol turnover virtually ceases. The present study was undertaken to determine whether there is a similar change in the metabolism of phosphatidylcholine and phosphatidylethanolamine. [32P]Orthophosphate was injected into 6-day-old chicken embryos, and the incorporation of label into phosphatidylcholine and phosphatidylethanolamine was followed for 48 h. The specific activities of the precursors phosphorylcholine and phosphorylethanolamine were also measured during this time. The data were then analysed by means of a simple kinetic model to determine the rate of synthesis and the half-life of each phospholipid. The results showed that phosphatidylcholine is synthesized at a rate of about 1.2 X 10(-20) mol/s per cell in the lens epithelial cells, and 6.4 X 10(-20) mol/s per cell in the fiber cells. Phosphatidylethanolamine is synthesized at approximately 0.9 X 10(-2)) mol/s per cell in the epithelial cells, and 4.0 X 10(-20) mol/s per cell in the fiber cells. Both phospholipids are stable in both the epithelial cells and in the fiber cells, with half-lives of 48 h or greater. Thus, although phosphatidylcholine, phosphatidylethanolamine and phosphatidylinositol all experience an increase in synthesis following lens fiber formation, the previously observed decrease in phosphatidylinositol turnover accompanying differentiation is a specific effect.

Developmental changes in proteins of purified membranes of chicken lenses and evidence for contamination by cytoplasmic delta-crystallin.

Urea-washed membranes from embryonic chick lenses (15 days old) and from the cortical and nuclear regions of adult chicken lenses (1 year) have been prepared by repeated centrifugation through discontinuous density gradients. The protein components of the isolated membranes have been examined by electrophoresis in polyacrylamide gels containing sodium dodecyl sulfate and urea. Proteins with molecular weights of 75 000, 56 000, 54 000, 48 000, 34 000, 32 000, 25 000, and 22 000 were present in all the membrane preparations, although their proportions changed during development. One additional protein, molecular weight 70 000, was seen only in the embryonic lens membranes. The greatest developmental change was the increase in 25 000 molecular weight protein from 12% in the embryonic lens to about 45% in the adult lens. Since it has been suggested that this protein is associated with gap junctions, its increase during development may reflect a corresponding increase in the number of gap junctions in the lens. The 50 000 molecular weight protein of embryonic lens membranes and membranes of adult nuclear lens fibers consisted at least partly of delta-crystallin, since delta-crystallin peptides could be identified in tryptic peptide maps of the isolated protein after in vitro radioiodination. Peptide maps of the 50 000 molecular weight protein of cortical lens fiber membranes contained no identifiable delta-crystallin peptides, although it is possible that modified delta-crystallin peptides may be present. The level of cytoplasmic contamination of the membrane fraction was estimated by preparing lens membranes in the presence of added delta-[35S]crystallin. The results indicated that cytoplasmic contamination contributes significantly to the presence of delta-crystallin in lens membrane preparations.

Decreased turnover of phosphatidylinositol accompanies in vitro differentiation of embryonic chicken lens epithelial cells into lens fibers.

The in vivo differentiation of embryonic chicken lens epithelial cells into lens fibers is accompanied by a marked decrease in the rate of degradation of phosphatidylinositol. The present experiments were undertaken to determine whether a similar change in phosphatidylinositol metabolism occurs during in vitro lens fiber formation in cultured explants of embryonic chicken lens epithelia. Lens epithelial cells in the explants differentiate into lens fibers following the addition of fetal calf serum, insulin or chicken vitreous humor to the culture medium. The results show that phosphatidylinositol is degraded with a half-life of 3-6 h in cultured lens epithelia that are not stimulated to differentiate. In contrast, no degradation occurs for at least 6 h in lens epithelia stimulated to form lens fibers. The stabilization of phosphatidylinositol is apparent within 4 h after the onset of fiber cell formation, and thus represents an early event in differentiation. The rapid degradation of phosphatidylinositol in lens epithelia is accompanied by comparably rapid synthesis. During this metabolic turnover only the phosphorylinositol portion of the molecule is renewed, as expected if hydrolysis occurs by the action of a phospholipase C, such as phosphatidylinositol phosphodiesterase. Thus, these data suggest that agents which produce in vitro differentiation of embryonic chicken lens epithelial cells into lens fibers lead to a reduction in either the amount or the activity of phospholipase C.

Expression of alternatively spliced PCTAIRE-1 mRNA in PC12 cells and neonatal rat brain.

A rat PCTAIRE-1 cDNA clone was isolated by immunoscreening of a PC12 cDNA library, followed by 5' RACE (rapid amplification of cDNA ends) to determine the 5' end. The rat PCTAIRE-1 cDNA sequence is 96% identical to mouse PCTAIRE-1 and contains an alternatively spliced exon of 131 bp near the 5' end. Although a mouse cDNA containing this exon has been reported, examination of several mouse cell lines provided no evidence for expression of the corresponding mRNA (Okuda et al., 1992). In contrast, reverse transcription and polymerase chain reaction (RT/PCR) across this region using RNA from proliferating, differentiated, and apoptotic PC12 cells demonstrated that alternatively spliced forms of PCTAIRE-1 mRNA with and without this exon are expressed. Both forms of PCTAIRE-1 mRNA are also expressed in vivo in neonatal rat brain, although other tissues examined contained only the form lacking the alternatively spliced exon. In the absence of the alternatively spliced exon PCTAIRE-1 mRNA contains an open reading frame of 1488 bp, corresponding to a 55-kDa protein that is 97% identical to mouse PCTAIRE-1 protein. When the alternatively spliced exon is present, this open reading frame is terminated by a stop codon and a second open reading frame is initiated, predicting a second PCTAIRE-1 protein of 52 kDa. The two predicted PCTAIRE-1 proteins are identical downstream of the splice site, but share no homology at their N-terminal ends.

A role for 12(S)-HETE in the response of human lens epithelial cells to epidermal growth factor and insulin.

PURPOSE: To determine whether the 12-lipoxygenase pathway of arachidonic acid metabolism is present in the human lens and whether 12(S)-hydroxyeicosatetraenoic acid (12(S)-HETE) plays a role in regulating proto-oncogene expression and DNA synthesis in human lens epithelial cells (HLECs). METHODS: Second- and third-passage primary cultures of HLECs were used for analysis. Human cataract epithelia were obtained from surgery. 12-lipoxygenase mRNA was detected by reverse transcription-polymerase chain reaction (RT-PCR), and the PCR product was sequenced. The 12-lipoxygenase protein was detected by immunoblotting. 12(S)-HETE was detected in HLEC-conditioned medium by radioimmunoassay. For studies of growth factor-induced mitogenesis, HLECs were serum starved, then stimulated with 15 ng/ml epidermal growth factor (EGF) and 1 microgram/ml insulin or with 0.3 microM 12(S)-HETE. The 12-lipoxygenase inhibitor, cinnamyl-3,4-dihydroxy-alpha-cyanocinnamate (CDC, 10 microM) was used to block endogenous 12-lipoxygenase activity. Expression of c-fos mRNA was determined by RT-PCR, and DNA synthesis was measured by 3H-thymidine incorporation. RESULTS: 12-lipoxygenase mRNA and protein were detected in HLECs and in human cataract tissues. 12(S)-HETE was released into the medium by HLECs in the presence of EGF-insulin. Stimulation of c-fos mRNA expression and DNA synthesis by EGF-insulin was inhibited when the 12-lipoxygenase pathway was blocked by CDC. This inhibition was reversed completely by exogenously added 12(S)-HETE. However, exogenous 12(S)-HETE was unable to stimulate HLEC DNA synthesis in the absence of growth factors. CONCLUSIONS: The 12-lipoxygenase pathway of arachidonic acid metabolism is present in human lens epithelial cells. 12(S)-HETE does not stimulate HLEC DNA synthesis in the absence of growth factors but enables the cellular response to EGF and insulin.

Regulation of c-fos induction in lens epithelial cells by 12(S)HETE-dependent activation of PKC.

PURPOSE: 12(S)-Hydroxyeicosatetraenoic acid (12(S)HETE), a 12-lipoxygenase metabolite of arachidonic acid, is required for epidermal growth factor (EGF)-dependent DNA synthesis and c-fos induction in lens epithelial cells. The present study was undertaken to identify signal transduction events upstream of c-fos induction that may be regulated by 12(S)HETE. METHODS: The rabbit lens epithelial cell line, N/N1003A, was cultured in serum-free medium, with or without EGF. Activation of PKC and other selected enzymes was examined in the presence of the lipoxygenase inhibitor baicalein and/or exogenous 12(S)HETE. Relative abundance of PKC isoforms in subcellular fractions was determined by immunoblot analysis with isoform-specific antibodies. PKC activity in subcellular fractions was measured by peptide substrate phosphorylation, with and without pseudosubstrate peptide inhibitor. Phosphorylated enzymes were detected by immunoblot analysis. Relative levels of c-fos mRNA were determined by RT/PCR with internal standard. RESULTS: Baicalein blocked EGF-dependent translocation and activation of PKC, without affecting phosphorylation of Erk1/2. Of several PKC isoforms investigated (alpha, betaI, betaII, and gamma), only PKCalpha and betaII were significantly activated by EGF and inhibited by baicalein. 12(S)HETE, in combination with EGF, countered the effect of lipoxygenase inhibitors on PKC activation, and 12(S)HETE in the absence of EGF stimulated PKC translocation. Also of note, 12(S)HETE alone activated PKCgamma, an isoform that was not significantly activated by EGF. Inhibiting PKC activation with GF109203X blocked induction of c-fos by EGF but did not affect EGF-stimulated phosphorylation of Erk1/2, indicating that the effect of PKC on c-fos induction is independent of the Erk1/2 pathway. CONCLUSIONS: In lens epithelial cells, 12(S)HETE-dependent activation of PKCalpha and betaII acts in concert with other EGF-dependent signals to induce c-fos mRNA.

Mechanical stretch alters the actin cytoskeletal network and signal transduction in human trabecular meshwork cells.

PURPOSE: Human trabecular meshwork (HTM) cells were mechanically stretched in vitro as a potential model for the distension of this tissue that can occur in vivo in response to increased pressure gradients. Cell morphology and certain components of the signal transduction pathways, including the mitogen-activated protein kinase (MAPK) and c-Jun N-terminal protein kinase (JNK) pathways, were evaluated for stretch-induced alterations. METHODS: Primary HTM cells grown in tissue culture were subjected to a mechanical stretch lasting from 10 seconds to 4 days. The actin cytoskeletal network was visualized by phalloidin staining. Proteins phosphorylated on their tyrosine residues were isolated using an immunoaffinity system and were analyzed by gel electrophoresis and immunostaining. Mitogen-activated protein kinase activity was evaluated using an in-gel assay system, and the mRNA levels of c-fos and c-jun were determined by quantitation of competitive reverse transcription-polymerase chain reaction. In addition, the amount of c-Fos protein was estimated by chemiluminescent immunoblot analysis. RESULTS: On stretching, the HTM cells elongated but regained their normal morphologic characteristics within 24 hours. Unstretched HTM cells displayed a diffuse F-actin microfilament network, whereas stretched cells exhibited complex geodesic patterns. Ten seconds after stretching began, the level of tyrosine phosphorylation on the six major phosphoproteins significantly decreased between 80% and 100%, whereas the level of paxillin tyrosine phosphorylation significantly increased 39%. Stretching caused MAPK activity and the amount of mRNA and protein of the immediate-early gene c-fos to decrease more than 60% within 2 minutes, but within 15 to 30 minutes they increased above or equivalent to normal levels. The level of c-jun mRNA was unchanged by stretching. CONCLUSIONS: In response to a mechanical stretch, major cytoskeletal alterations occur in HTM cells, which involve changes in the levels of tyrosine phosphorylation. Mechanotransduction (signal transduction by mechanical stimulation) through the MAPK signaling pathway was significantly depressed immediately after stretching; however, the JNK pathway appeared to be unaffected. The data suggest that HTM cells adapt to mechanical stress by altering the cytoskeletal network and signaling cascades.

The rabbit lens epithelial cell line N/N1003A requires 12-lipoxygenase activity for DNA synthesis in response to EGF.

PURPOSE: Cultured rat lenses and primary human lens epithelial cells (HLECs) express12-lipoxygenase (12-LOX) and require a 12-LOX metabolite of arachidonic acid for growth in response to EGF and insulin. This study seeks to identify an established cell line with these characteristics. METHODS: Immunoblotting was used to screen eight lens epithelial cell lines for 12-LOX expression: the human line, HLE-B3; mouse lines alphaTN4, 17EM15, 21EM15, and MLE6, and rabbit lines N/N1003A, LEP2 and B3. DNA synthesis was measured as incorporation of 3H-thymidine into DNA. Expression of c-fos mRNA was detected by RT-PCR. The involvement of 12-lipoxygenase metabolites was determined using the lipoxygenase inhibitors baicalein, cinnamyl 3,4-dihydroxy-alpha-cyanocinnamate (CDC), or nordihydroguiairetic acid (NDGA). RESULTS: 12-LOX was detected only in the rabbit lines N/N1003A, LEP2 and B3. N/N1003A cells were chosen for further study. 12-LOX inhibitors blocked DNA synthesis in response to EGF with or without insulin. Inhibition of EGF-stimulated DNA synthesis was reversed by 0.3 microM to 3 microM 12(S)hydroxyeicosatetraenoic acid (HETE), but not by equivalent concentrations of 5(S)HETE, 8(S)HETE, 15(S)HETE, or 12(R)HETE. Baicalein prevented EGF induction of c-fos mRNA. The transformed HLEC line, HLE-B3, showed little stimulation of DNA synthesis in response to EGF and was unaffected by the presence of 12-LOX inhibitors. CONCLUSIONS: N/N1003A cells, like primary cultured human lens epithelial cells or neonatal rat lenses, require 12-LOX activity for EGF dependent growth. This line will be useful for studies of the mechanism of action of 12(S)HETE.

Lens lipids.

Lens cells can synthesize, degrade, and remodel lipids. Endogenous lipid synthesis, in conjunction with uptake of exogenous cholesterol and certain fatty acids, leads to the formation of a plasma membrane that is especially rich in sphingomyelin, cholesterol, and long-chain saturated fatty acids. As a result of this unusual lipid composition, lens membranes have very low fluidity, which is restricted even further by lipid-protein interactions. The composition and metabolism of membrane lipids may affect the formation of various types of cataracts. Diets rich in vegetable oils offer some protection against the formation of osmotic cataracts and the hereditary cataract of the RCS rat, although the mechanism of this effect is not clear. Vitamin E also protects against the formation of several types of cataract in vivo and in vitro, suggesting that lipid peroxidation may play a role in cataractogenesis. Certain drugs which inhibit lipid synthesis or degradation are cataractogenic, and a deficiency in cataractogenic, and a deficiency in phosphatidylserine is associated with a loss of Na+/K+ ATPase activity in several types of cataract. Human senile cataracts show a marked loss of protein-lipid interactions, although the overall lipid composition is normal. This loss of protein-lipid interactions may be related to oxidative damage to membrane-associated proteins. Interestingly, the decrease in the fluidity of lens membranes with age would counteract the formation of aqueous pores in the membrane, which can result from the oxidative cross-linking of membrane-associated proteins. Certain pathways of lipid metabolism seem to have regulatory functions. Among these are phosphatidylinositol turnover, phosphatidylethanolamine methylation, and arachidonic acid metabolism. All of these pathways function in the lens. Phosphatidylinositol turnover is correlated with the rate of lens epithelial cell division, while phosphatidylethanolamine methylation seems to be related to the initiation of lens fiber cell formation. Both pathways are associated with the release and metabolism of arachidonic acid in other cell types. While it is not known whether phosphatidylinositol turnover or phosphatidylethanolamine methylation result in the release of arachidonic acid in the lens, recent work has shown that lens cells from a variety of species can metabolize arachidonic acid by both the cyclooxygenase and lipoxygenase pathways. The possible physiological significance of these metabolites to the lens is yet to be determined.

Phosphorylation of ribosomal protein S6 during lens cell differentiation: correlation with translational efficiency.

In vitro differentiation of embryonic chicken lens epithelial explants to form lens fiber cells is accompanied by an increase in protein synthesis without a corresponding increase in mRNA levels. This apparent increase in translational efficiency is correlated with a specific enhancement of phosphorylation of a 32K protein, which we identify as ribosomal protein S6 by two dimensional gel electrophoresis of purified ribosomal proteins. Serum, insulin, and chicken vitreous humor, three agents known to initiate differentiation in this system, all lead to enhanced S6 phosphorylation. Maximal enhancement of phosphorylation is reached within the first hour after the onset of differentiation, and is not blocked by inhibitors of RNA and protein synthesis.

Identification of the EDTA-extractable protein in lens as calpactin I.

The EDTA-extractable protein (EEP) is a major extrinsic protein of lens membrane. The 35 kilodalton (kDa) polypeptide of the EEP cross-reacted to antibody prepared against calpactin I, a substrate for the src protein and an inhibitor of phospholipase A2. Calpactin I is also thought to play a structural role in linking cytoskeleton to membrane. The 35 kDa protein in bovine lens contained phosphotyrosine residues that can be detected by affinity purified antibody to this moiety. Although there is some microheterogeneity of EEP using two dimensional gel electrophoresis, at least one of the chick polypeptides, immunoreactive for calpactin I, can be phosphorylated in whole lens culture. These results suggest a regulatory function for the EEP in lens.

Coordinating cell proliferation and migration in the lens and cornea.

Migration is a complex process for epithelial tissues, because the epithelium must move as an intact sheet to preserve its barrier function. The requirement for structural integrity is met by coupling cell-to-matrix and cell-to-cell adhesion at the cellular level, and by coordinating cell proliferation and cell migration in the tissue as a whole. Proliferation is suppressed at the migrating cell front, allowing cells in this region to remain tightly packed while advancing rapidly. At the same time, proliferation is enhanced in a region behind the advancing cell front to expand the epithelial cell sheet. This review considers the extracellular signals and intracellular signaling pathways that regulate these processes in the lens and corneal epithelium, with emphasis on the commonalities that link these tissues.

Changes in phosphatidylinositol metabolism during differentiation of lens epithelial cells into lens fiber cells in the embryonic chick.

During the development and growth of the lens, lens epithelial cells differentiate to form lens fiber cells. The present study investigates phosphatidylinositol metabolism in these two lens cell populations in the 6-day-old embryonic chick in vivo, to determine whether changes in the metabolism of this phospholipid are associated with lens fiber differentiation. [32P]Orthophosphate was injected into the embryos in ovo, and the incorporation of label into phosphatidylinositol in the lens epithelia and lens fiber masses was followed for 42 h. The time course of the specific activity of the gamma-PO4 of ATP was also determined during this time period, and was shown to be approximately equal to the specific activity of CDP-diacylglycerol, the immediate precursor of phosphatidylinositol. Analysis of the data by means of a simple kinetic model yielded a value of about 2 x 10(-9) pmol/s/cell for the rate of phosphatidylinositol synthesis in the lens epithelial cells, and 6.4 x 10(-9) pmol/s/cell in the lens fiber cells; the corresponding half-lives of phosphatidylinositol were 5 h and 63 h in the epithelial cells and fiber cells, respectively. Thus, lens fiber formation in the 6-day-old embryonic chick is associated with increased synthesis and decreased turnover of phosphatidylinositol. This is the first report of changes in phosphatidylinositol metabolism associated with cell differentiation during embryonic development.

Proto-oncogenes in cell differentiation.

Proto-oncogene products may be multi-functional proteins with various roles in cell differentiation as well as cell proliferation. The molecular biology of the gene products of three well characterized proto-oncogenes (c-fos, c-myc and c-src) are described, and the roles of three other proto-oncogene products, involved in hormone and growth factor reception, are reviewed.

Isolation and in vitro translation of delta-crystallin mRNA from embryonic chick lens fibers.

Of the protein synthesized and accumulated during differentiation of embryonic chick lens fibers, 70-80% is the tissue specific protein delta-crystallin. We have isolated and partially characterized the total cytoplasmic mRNA from purified lens fibers of 15-day-old embryos as an initial step toward understanding the regulated expression of delta-crystallin during development. Each lens fiber mass contained an average of 10 mug of cytoplasmic RNA; approximately 0.1 mug per fiber mass was recovered in the mRNA fraction by oligo(dT)-cellulose chromatography. The mRNA electrophoresed primarily as a single peak on a polyacrylamide-agarose gel with an apparent molecular weight of about 9 x 10(5) estimated by comparison with 28S and 18S rRNA markers. Of the protein synthesized in response to the mRNA in cell-free systems derived from Krebs II ascites tumor cells or rabbit reticulocytes, 70-80% comigrated with delta-crystallin on sodium dodecyl sulfatepolyacrylamide-agarose gels. Comparison of the tryptic peptides of delta-crystallin with those of the in vitro products from both heterologous systems established that the lens fiber mRNA contained delta-crystallin mRNA, and that no other functional mRNAs were present in detectable quantities. Thus, the specialization of protein synthesis in embryonic chick lens fibers apparently results from an accumulation of delta-crystallin mRNA in the cytoplasm.

Reiteration frequency of delta-crystallin DNA in lens and non-lens tissues of chick embryos. delta-Crystallin gene is not amplified during lens cell differentiation.

The differentiation of embryonic chick lens fibers is characterized by an increased rate of synthesis of the lens protein, delta-crystallin, and accumulation of delta-crystallin mRNA. In the present study, the number of delta-crystallin genes in lens and non-lens tissues of embryonic chicks has been determined to test whether the accumulation of delta-crystallin mRNA during lens fiber differentiation is associated with an amplification of delta-crystallin genes. DNA from embryonic chick lens fibers, embryonic chick lens epithelia, or whole chick embryos with the eyes removed, was annealed with [3H]DNA complementary to delta-crystallin mRNA. Analysis of the annealing reactions indicated that the sequences for delta-crystallin are in the unique fraction of the chick genome, and are not amplified in the lens during embryonic development.

Cyclins, cyclin-dependent kinases and differentiation.

Cyclin-dependent kinases and their regulatory subunits, the cyclins, are known to regulate progression through the cell cycle. Yet these same proteins are often expressed in non-cycling, differentiated cells. This review surveys the available information about cyclins and cyclin-dependent kinases in differentiated cells and explores the possibility that these proteins may have important functions that are independent of cell cycle regulation.

Correlation between phosphatidylinositol degradation and cell division in embryonic chicken lens epithelia.

Differentiation of embryonic chicken lens epithelial cells to form lens fibers is associated with a marked decrease in both the rate of phosphatidylinositol degradation and the rate of cell division. In cells of the central region of the lens epithelium, the rate of cell division also declines with developmental age. The present study measures phosphatidylinositol degradation in cultured explants of the central lens epithelium of chicken embryos of different ages to determine the extent of the correlation between phosphatidylinositol degradation and cell division in this tissue. The results show that the rate of phosphatidylinositol degradation also decreases during development and is proportional to the rate of cell division throughout the period from 6 to 19 days of development. Furthermore, stimulating cell division in central explants of lens epithelia of 19-day-old chicken embryos by culturing them in the presence of fetal calf serum produces a proportional increase in the rate of phosphatidylinositol degradation. These findings indicate that cell division and phosphatidylinositol degradation are tightly coupled in this tissue, and raise the possibility that phosphatidylinositol metabolism may regulate some aspect of the cell cycle.