Bradley Kane

Maintenance of the keratocyte phenotype during cell proliferation stimulated by insulin.

Keratocytes normally express high levels of aldehyde dehydrogenase and keratocan. They proliferate and lose their keratocyte markers when they become fibroblastic during corneal wound healing. Keratocytes cultured in fetal bovine serum also become fibroblastic, proliferate, and lose these markers. In this report, we studied the effects of three serum growth factors, fibroblast growth factor-2, insulin, and platelet-derived growth factor-BB, on keratocyte proliferation and the maintenance of the keratocyte markers in 7-day cultures in cells plated at low (5,000 cells/cm2) and high (20,000 cells/cm2) density in serum-free medium. Keratocyte proliferation was measured by [3H]thymidine incorporation and by DNA content of the cultures. Cytosolic aldehyde dehydrogenase and keratocan accumulated in the medium were quantified by Western blot. The results showed that all the growth factors stimulated proliferation, but insulin stimulated proliferation more consistently. The keratocyte markers aldehyde dehydrogenase and keratocan were maintained after 7 days in culture in all growth factors, but keratocyte cell morphology was only maintained in medium containing insulin. Most of the proteoglycans were degraded in cultures of keratocytes plated at low density and cultured in the absence of growth factors. This degradation was prevented when keratocytes were cultured in the presence of the growth factors or when keratocytes were plated at high density. The results of this study show that insulin can expand keratocytes in vitro, maintain their phenotype, and prevent proteoglycan degradation.

The effect of growth factor signaling on keratocytes in vitro and its relationship to the phases of stromal wound repair.

PURPOSE To determine the relationship between signaling by different growth factors and the phases of corneal stromal wound repair. The authors hypothesize that the process involves sequential signaling, resulting first in proliferation and then in extracellular matrix (ECM) synthesis. METHODS The effects of IGF-I, TGF-beta1, FGF-2, and PDGF on proliferation and ECM production by primary cultured bovine keratocytes were evaluated. DNA synthesis was determined by (3)H-thymidine incorporation, and maximal cell density was determined by measurement of DNA content. Relative levels of ECM components synthesized by keratocytes and secreted into the media were evaluated by (3)H-glycine incorporation into total ECM protein and collagen, by (3)H-glucosamine incorporation into chondroitin sulfate, keratan sulfate, and hyaluronan, and by Western blotting with antibodies specific to procollagen types Iota and IotaIotaIota. RESULTS FGF-2 stimulated the highest level of proliferation and the lowest level of glycosaminoglycan synthesis and inhibited the synthesis of collagen types Iota and IotaIotaIota. IGF-I, in contrast, stimulated the lowest level of proliferation and the highest levels of collagen synthesis. PDGF and TGF-beta1 had intermediate effects on proliferation and collagen synthesis. Although FGF-2 inhibited collagen production, it could be restored by subsequent treatment with IGF-I, TGF-beta1, and PDGF. CONCLUSIONS The results of this study showed that the level of proliferation induced by the growth factors was inversely related to the levels of collagen production. The authors suggest that FGF-2 initiates the hypercellular phase of corneal wound healing and that IGF-I and PDGF are involved in the restoration of a normal ECM.

Increased SPARC accumulation during corneal repair

Keratocytes can become fibroblasts and myofibroblasts during corneal injury and wound healing. We used the in vitro bovine keratocyte repair model system, which involves culturing collagenase-isolated keratocytes in serum-free media and then adding serum or serum plus TGF-beta to the culture media to induce the fibroblast and myofibroblast phenotypes, respectively, to evaluate the synthesis of secreted products by the cells. Serum and serum plus TGF-beta rapidly induced the fibroblast morphology and alpha smooth muscle actin, a marker of myofibroblasts. Keratocytes cultured in serum and serum plus TGF-beta also increased the synthesis of several high molecular weight products (approximately 100kD and larger) and the accumulation of a 43kD protein shown to be osteonectin/SPARC by both sequencing tryptic peptides from the protein and by reaction with antisera to osteonectin/SPARC. Immunohistochemical staining of mouse corneas with antisera to SPARC seven days post-wounding also demonstrated an increased accumulation of SPARC in the regions undergoing repair. These results indicate SPARC accumulation is a marker for stromal repair.

Isolation of a putative keratocyte activating factor from the corneal stroma

Fetal bovine serum has commonly been used to expand the population of keratocytes in culture. Tissue extracts, however, have also been used to grow other cell types. We prepared a DMEM/F12 extract of corneal stroma and compared the growth and morphology of collagenase-isolated keratocytes cultured in DMEM/F12, or DMEM/F12 containing either stromal extract or fetal bovine serum. Cell proliferation was measured by 3H-thymidine and BrdU incorporation as well as by DNA quantitation. The extract was fractionated by gel filtration. Cell morphology was assessed by phase-contrast microscopy. Culture in both extract and serum stimulated keratocytes to proliferate, but keratocytes cultured in the extract grew more slowly due to a longer cell cycle and to a lower final density because of greater sensitivity to contact inhibition. Keratocytes cultured in serum became fibroblastic while those cultured in extract retained the dendritic morphology of quiescent keratocytes. The stimulating factors in the corneal extract were more sensitive to heat inactivation and of higher molecular weight than the stimulating factors in serum. These results indicate that the mitogenic activity in extract and serum are different and that the phenotypes resulting from growth in serum and extract are also different. Keratocytes cultured at low cell densities in the corneal extract may mimic keratocyte activation, an initial and crucial event for keratocytes during the corneal wound healing process.

Increased stromal extracellular matrix synthesis and assembly by insulin activated bovine keratocytes cultured under agarose.

Previously, pharmacological levels of insulin have been shown to stimulate the synthesis of normal corneal stromal collagen and proteoglycans by bovine keratocytes in culture. Here we compared insulin to physiological levels of IGF-I and found that IGF-I also stimulated the synthesis of these extracellular matrix components, but less than that of insulin. Keratocytes in monolayer culture secreted most of the collagen synthesized into the media in the form of procollagen, a precursor of collagen. We found that an overlay of 3% agarose on the keratocytes in culture enhanced the conversion of procollagen to collagen and increased the deposition of collagen and proteoglycans into the cell layer. The extracellular matrix associated with the keratocytes cultured under agarose exhibited a corneal stromal-like architecture. These results suggest that enhancing the conversion of procollagen to collagen is a key step in the formation of extracellular matrix by keratocytes in vitro. Agarose overlay of insulin activated keratocytes in culture is a useful model for studying corneal stromal extracellular matrix assembly in vitro.

IGF-II is present in bovine corneal stroma and activates keratocytes to proliferate in vitro.

Extracts of bovine corneal stroma have been shown to activate keratocytes in culture to proliferate. We fractionated stromal extract on a column of Sephacryl S-300 and tested the fractions for mitogenic activity using cell culture and for the presence of IGF-II and its binding protein IGFBP-2 by Western blot. We found that the mitogenic activity in the extract separated into major and minor peaks and that immunologically detectable IGF-II and IGFBP-2 co-eluted with the minor peak. We also compared the effects of 10 ng IGF-II/ml on keratocytes in culture to that of 2 ng TGF-beta/ml over a 7-day culture period. We found that IGF-II and TGF-beta, alone or combined, increased both (3)H-thymidine incorporation and DNA content of the cultures. The phenotype of the cells was determined by using antibodies to alpha-SM (smooth muscle) actin, fibronectin, SPARC, lumican and keratocan in Western blots of cell layers of media. Keratocytes cultured in IGF-II expressed no alpha-SM actin or fibronectin, low levels of SPARC and high levels of lumican and keratocan, indicating a native phenotype. Keratocytes in TGF-beta expressed alpha-SM actin, fibronectin, SPARC and lumican, and expressed no or low levels of keratocan, indicating a myofibroblast phenotype. Keratocytes cultured in IGF-II plus TGF-beta, however, expressed alpha-SM actin, fibronectin, SPARC, lumican, and keratocan by day 7 of culture. The results of this study show that IGF-II to be present in the corneal stroma, to stimulate keratocyte proliferation while maintaining native phenotype and to override the TGF-beta mediated down regulation of keratocan production. The IGF-II in the stroma may serve as a mechanism to immediately activate keratocytes upon wounding and to ameliorate the scarring effects of TGF-beta.

Relationship of PTSD symptoms with combat exposure, stress, and inflammation in American soldiers

Posttraumatic stress disorder (PTSD) is of great concern in veterans. PTSD usually occurs after a person is exposed to death, threatened death, actual or threatened serious injury, or actual or threatened sexual violence. Active duty soldiers deployed to war zones are at risk for PTSD. Psychoneuroimmunological theory predicts that PTSD, depression, and stress can lead to low-grade, chronic inflammation. We asked whether there were relationships between PTSD symptoms and chronic stress, depression and inflammation in active duty U.S. soldiers. We enrolled 52 active duty enlisted and reservist soldiers in a cross-sectional study while they participated in a week of military training in fall 2011. They completed a demographic questionnaire, the Center for Epidemiological Studies–Depression Scale, the Combat Exposure Scale, and the PTSD symptom Checklist–Military version (PCL-M). Blood samples were taken for analysis of cytokines and C-reactive protein (CRP). Hair samples shaved from the forearm were measured for cortisol. Of the soldiers, 11 had PCL-M scores in the moderate to severe range. Regression analysis demonstrated that depression and war zone deployment were strong predictors of PTSD symptoms. CRP and hair cortisol were correlated with each other and with depression and PTSD symptoms. These results suggest relationships among war zone deployment, depression, and PTSD. Chronic stress associated with depression, PTSD, and war zone experiences may be related to inflammation in active duty soldiers.

Enhanced cell accumulation and collagen processing by keratocytes cultured under agarose and in media containing IGF-I, TGF-β or PDGF.

We previously showed an agarose overlay on keratocytes cultured in media containing pharmacological levels of insulin enhanced collagen processing and collagen fibril formation. In this study, we compared collagen processing by keratocytes cultured in media containing physiological levels of IGF-I, TGF-β, FGF-2, and PDGF in standard and in agarose overlay cultures. Pepsin digestion/SDS PAGE was used to determine the levels of procollagen secreted into the media and the collagen content of the ECM associated with the cell layer. Distribution of collagen type I and fibronectin in the ECM of the agarose cultures was determined by immunoflorescence. Collagen fibril and keratocyte morphology was evaluated by electron microscopy. The agarose overlay significantly enhanced the cell number in the IGF-I, TGF-β and PDGF treated cultures by 2-3 fold. The overlay also significantly enhanced the processing of procollagen to collagen fibrils from 29% in standard cultures to 63-68% in agarose cultures for the IGF-I and PDGF cultures, and from 66% in standard culture to 85% in agarose culture for the TGF-β cultures. Cell accumulation and collagen processing was not enhanced by agarose overlay of the FGF-2 treated cultures. Collagen type I and fibronectin were more uniformly distributed and the collagen fibrils smaller in the ECM of the TGF-β treated cultures. Keratocytes in the FGF-2 treated cultures were in close cell contact with few collagen fibrils while IGF-I, TGF-β, and PDGF cultures had an extensive ECM with abundant collagen fibrils. The results of this study indicate that the agarose overlay enhances collagen fibril assembly and cell accumulation by keratocytes when both collagen synthesis and cell proliferation are stimulated.

Cytokines, Chemokines, and Growth Factors in Banked Human Donor Milk for Preterm Infants

Background: There has been a recent increase in availability of banked donor milk for feeding of preterm infants. This milk is pooled from donations to milk banks from carefully screened lactating women. The milk is then pasteurized by the Holder method to remove all microbes. The processed milk is frozen, banked, and sold to neonatal intensive care units (NICUs). The nutrient bioavailability of banked donor milk has been described, but little is known about preservation of immune components such as cytokines, chemokines, and growth factors (CCGF). Objective: The objective was to compare CCGF in banked donor milk with mother’s own milk (MOM). Methods: Aliquots (0.5 mL) were collected daily from MOM pumped by 45 mothers of NICU-admitted infants weighing < 1500 grams at birth. All daily aliquots of each mother’s milk were pooled each week during 6 weeks of an infant’s NICU stay or for as long as the mother provided MOM. The weekly pooled milk was measured for a panel of CCGF through multiplexing using magnetic beads and a MAGPIX instrument. Banked donor milk samples (n = 25) were handled and measured in the same way as MOM. Results: Multiplex analysis revealed that there were levels of CCGF in banked donor milk samples comparable to values obtained from MOM after 6 weeks of lactation. Conclusion: These data suggest that many important CCGF are not destroyed by Holder pasteurization.

Suppression of Natural Killer Cell Cytotoxicity in Postpartum Women Time Course and Potential Mechanisms

Little is known about the recovery of the immune system from normal pregnancy and whether the postpartum period is a uniquely adapted immune state. This report extends previous observations from our group of decreased natural killer (NK) cell cytotoxicity in the postpartum period. NK cytotoxicity was measured from 1 week through 9 months postpartum. In addition, NK cytotoxicity was assayed in the presence or absence of pooled plasmas collected from either postpartum or nonpostpartum women. Samples of cells were stained for inhibitory receptors and analyzed by flow cytometry. NK cytotoxicity remained decreased in postpartum women compared to controls through the first 6 postpartum months, returned to normal levels by 9 months, and remained normal at 12 months. NK cytotoxicity during the first 6 months was further inhibited by the addition of pooled plasma to NK cultures from postpartum women, but the addition of pooled plasma from the control group did not affect that group’s NK cultures. There were differences in inhibitory receptor staining between the two groups, with decreased CD158a and CD158b and increased NKG2A expression on postpartum NK cells during the first 3 postpartum months. These data suggest that NK cytotoxicity postpartum inhibition lasts 6 months and is influenced by unidentified postpartum plasma components. The effect may also involve receptors on NK cells.