Cellular distribution of lens epithelium-derived growth factor (LEDGF) in the rat eye: loss of LEDGF from nuclei of differentiating cells

Lens epithelium-derived growth factor (LEDGF) enhances the survival and growth of cells. To understand LEDGF's spatial localization and its putative function(s) during proliferation and differentiation, we localized LEDGF during terminal differentiation in whole rat lenses, lens epithelial cell (LEC) explants stimulated with FGF-2, and insulin, iris, human LECs with lentoids. In addition, intracellular localization of LEDGF was performed in other ocular tissues: ciliary body, retina, and cornea. We found the immunopositivity of nuclear LEDGF decreased in LECs of the equatorial region. In contrast, immunopositivity of LEDGF was detected in the cytoplasm of LECs and superficial fiber cells. After treating LEC explants with FGF-2 and insulin, which are known to be differentiating factors for LECs, the nuclei of these cells showed no LEDGF immunopositivity, but explants did express p57(kip2), a differentiation marker protein. Also, immunopositive LEDGF was not detected in the nuclei of differentiated cells, lentoid body, and corneal epithelial cells. This demonstrated that the loss of LEDGF from the nucleus may be associated with the process of terminal differentiation that might be in some way common with the biochemical mechanisms of apoptosis. The spatial and temporal distribution of LEDGF in the present study also provides a vision for further investigation as to how this protein is involved in cell fate determination.     

Lens epithelium-derived growth factor (LEDGF/p75) and p52 are derived from a single gene by alternative splicing

A human gene that encodes lens epithelium-derived growth factor (LEDGF) was isolated, and the DNA sequence and the exon/intron organization was determined. The gene contains at least 15 exons and 14 introns and encodes LEDGF mRNA and p52 mRNA. Exons 1-15 encode LEDGF mRNA, and exons 1-9, and a part of the ninth intron encode a splice variant (p52). Sequences of the exon/intron junctions of the gene have the highly conserved GT/AG rule. Most intron/exon junctions correspond to junctions of individual protein motifs. Almost equal amounts of LEDGF and p52 are expressed in lens epithelial cells in culture. The LEDGF gene is assigned to chromosome 9p22.2, which is adjacent to the major cell malignancy locus.     

Transcriptional regulation of the antioxidant protein 2 gene, a thiol-specific antioxidant, by lens epithelium-derived growth factor to protect cells from oxidative stress.

Antioxidant protein 2 (AOP2), a member of the newly defined family of thiol-specific antioxidant proteins, has been shown to remove H(2)O(2) and protect proteins and DNA from oxidative stress. Here we report that LEDGF is one of the regulatory factors for the AOP2 gene. We found that LEDGF bound to the heat shock element and to stress-related elements in the AOP2 promoter. It trans-activated expression of AOP2-CAT in COS-7 cells and lens epithelial cells overexpressing LEDGF. Mutations in the heat shock element and stress-related elements of the AOP2 promoter reduced LEDGF-dependent trans-activation. Lens epithelial cells showed a higher level of AOP2 mRNA in the presence of LEDGF. Cells overexpressing LEDGF exhibited a higher level of AOP2 protein, the level of which was directly related to the increase in cellular protection. Thus, LEDGF, by activating the AOP2 gene, protected and enhanced the survival of cells under oxidative stress.     

A serum-free, chemically-defined medium for function and growth of primary neonatal rat heart cell cultures

A serum-free, chemically defined medium for supporting rhythmic contraction, maximum survival, and moderate growth of cardiac cells was achieved by using a combination of hormones and growth supplements in a mixture of equal volumes of Ham's F12 and Dulbecco's modified Eagle's medium. The hormones and growth supplements included insulin, transferrin, selenium, fetuin, bovine serum albumin, hydrocortisone (HC), L-thyroxine (T4), and epidermal growth factor (EGF). Cardiac cells were grown on fibronectin-precoated plates using the above serum-free medium. Cells grown in this medium exhibited a higher beating rate and were maintained for a longer time compared to those cells grown in serum. The effects of T4, EGF, and HC on beating rate and survival time of both cultures of mixed cell population and enriched myoblast cell population were studied. In the enriched myoblast cell cultures grown in serum-supplemented medium, the beating rate ranged from 40 to 200 beats/min, and these cultures survived for 30 d. When these enriched cell cultures were grown in serum-free hormone-supplemented medium, the beating rate ranged from 190 to 240 beats/min, and these cultures survived for more than 90 d. These results show that some hormones affect growth, whereas others affect function.     

Insulin-like growth factors, IGF-1, IGF-2 and somatomedin C trigger cell proliferation in mammalian epithelial cells cultured in a serum-free medium

A single insulin-like growth factor which constitutes part of a defined serum-free medium is sufficient to stimulate DNA synthesis and mitosis in mammalian lens epithelial cells. Rabbit lenses were cultured in KEI-4, a medium which mimics rabbit aqueous humor, or in KEI-4 containing insulin growth factor I (IGF I), insulin growth factor II (IGF II) or somatomedin C. The magnitude of DNA synthesis and mitosis was evaluated on whole mount preparations of the epithelium at various times of culture. IGF I and II, the most highly purified of the insulin-like growth factors, and somatomedin C were equipotent lens mitogens, were active at the ng level, were more mitogenic toward lens epithelial cells than insulin, and initiated cell proliferation throughout the normally amitotic central region of the lens epithelium. The time course of the mitotic response elicited by the insulin-like growth factors was identical to that noted in lenses cultured in medium supplemented with serum or insulin. The present results, coupled with those of other investigators, suggest that insulin-like factors may regulate cell division in the mammalian lens in vivo.     

Insulin-like growth factor-I and transferrin mediate growth and survival of Chinese hamster ovary cells

The aim of this investigation was to elucidate the roles of insulin-like growth factor-I (IGF-I) and transferrin in the survival and proliferation of Chinese hamster ovary (CHO) cells upon withdrawal of serum. For this purpose, we employed DNA analysis and flow cytometry to compare CHO cell lines expressing either IGF-I alone or IGF-I and transferrin. The ability of cells to cycle and the occurrence of apoptosis were monitored in these cells in serum-free medium. These results indicate that IGF-I alone is able to maintain the viability of CHO cells for an extended length of time in the absence of serum. Transferrin alone does not promote survival or proliferation. Only in the presence of both IGF-I and transferrin do cells survive and proliferate. Therefore, in attached CHO cultures, IGF-I alone does not stimulate cell proliferation but is a requirement for growth in serum-free medium in cooperation with transferrin. We report on the dual role of IGF-I as a survival factor in CHO cells and its interlocking role with transferrin to stimulate cell growth.     

Overexpression of the lens epithelium-derived growth factor/p75 integrase binding domain inhibits human immunodeficiency virus replication

We initially identified lens epithelium-derived growth factor/p75 (LEDGF/p75) as a binding partner of human immunodeficiency virus type 1 (HIV-1) integrase. To investigate the role of LEDGF/p75 in HIV replication and its potential as a new antiviral target, we stably overexpressed two different fragments containing the integrase binding domain (IBD) of LEDGF/p75 fused to enhanced green fluorescent protein (eGFP). HIV-1 replication was severely inhibited by overexpression of the eGFP-IBD fusion proteins, while no inhibition was observed in cell lines overexpressing the interaction-deficient D366A mutant. Quantitative PCR pinpointed the block to the integration step, whereas nuclear import was not affected. Competition of the IBD fusion proteins with endogenous LEDGF/p75 for binding to integrase led to a potent defect in HIV-1 replication in both HeLaP4- and MT-4-derived cell lines. A previously described diketo acid-resistant HIV-1 strain remained fully susceptible to inhibition, suggesting that this strategy will also work in patients who harbor strains resistant to the current experimental integrase inhibitors. These data support LEDGF/p75 as an important cofactor for HIV replication and provide proof of concept for the LEDGF/p75-integrase interaction as a novel target for treating HIV-1 infection.     

Regulation of rat ovarian cell growth and steroid secretion

A cultured rat ovarian cell line (31 A-F(2)) was used to study the effect of growth factors (epidermal growth factor [EGF] and fibroblast growth factor [FGF]), a survival factor (ovarian growth factor [OGF]), a hormone (insulin), and an iron-binding protein (transferring) on cell proliferation and steroid production under defined culture conditions. EGF and insulin were shown to be mitogenic (half-maximal response at 0.12 nM and 0.11 muM, respectively) for 31A-F(2) cells incubated in serum-free medium. EGF induced up to three doublings in the cell population, whereas insulin induced an average of one cell population doubling. FGF, OGF, and transferrin were found not to have any prominent effect on cell division when incubated individually with 31A-F(2) cells in serum-free medium. However, a combination of EGF, OGF, insulin, and transferrin stimulated cell division to the same approximate extent as cells incubated in the presence of 5 percent fetal calf serum. EGF or insulin did not significantly affect total cell cholesterol levels (relative to cells incubated in serum-free medium) when incubated individually with 31A-F(2) cells. However, cell cholesterol levels were increased by the addition of OGF (250 percent), FGF (370 percent), or a combination of insulin and EGF (320 percent). Progesterone secretion from 31A-F(2) cells was enhanced by EGF (25 percent), FGF (80 percent), and insulin (115 percent). However, the addition of a mitogenic mixture of EGF, OGF, insulin, and transferrin suppressed progesterone secretion 150 percent) below that of control cultures. These studies have permitted us to determine that EGF and insulin are mitogenic factors that are required for the growth of 31A-F(2) cells and that OGF and transferrin are positive cofactors that enhance growth. Also, additional data suggest that cholesterol and progesterone production in 31A-F(2) cells can be regulated by peptide growth factors and the hormone insulin.     

A serum-free,chemically-defined medium for function and growth of primary neonatal rat heart cell cultures

Summary A serum-free, chemically defined medium for supporting rhythmic contraction, maximum survival, and moderate growth of cardiac cells was achieved by using a combination of hormones and growth supplements in a mixture of equal volumes of Ham’s F12 and Dulbecco’s modified Eagle’s medium. The hormones and growth supplements included insulin, transferrin, selenium, fetuin, bovine serum albumin, hydrocortisone (HC),l-thyroxine (T₄), and epidermal growth factor (EGF). Cardiac cells were grown on fibronectin-precoated plates using the above serum-free medium. Cells grow in this medium exhibited a higher beating rate and were maintained for a longer time compared to those cells grown in serum. The effects of T₄, EGF, and HC on beating rate and survival time of both cultures of mixed cell population and enriched myoblast cell population were studied. In the enriched myoblast cell cultures grown in serum-supplemented medium, the beating rate ranged from 40 to 200 beats/min, and these cultures survived for 30 d. When these enriched cell cultures were grown in serum-free hormone-supplemented medium, the beating rate ranged from 190 to 240 beats/min, and these cultures survived for more than 90 d. These results show that some hormones affect growth, whereas others affect function.