Localization of platelet-derived growth factor receptor subunit expression in chronic venous leg ulcers.

Cellular responses to platelet-derived growth factor, which affects all phases of the wound healing process, are dependent on the interaction of the growth factor with its cell surface receptors. Recently, we have shown that the platelet-derived growth factor-receptor was not expressed in uninjured human skin. In acute human wounds healing by secondary intention, both platelet-derived growth factor-receptor subunits were coordinately expressed, whereas no expression was found after reepithelialization at day 47. Even though impaired wound healing may be due to uncoordinated expression or the failure to express platelet-derived growth factor-receptor subunits, little is known regarding their expression in chronic ulcers. We studied the localization of platelet-derived growth factor-receptor expression in chronic venous leg ulcers of 15 patients with a median age of 73 years. Cryostat sections of biopsy specimens were immunostained with the use of antibodies against the alpha- and the beta-platelet-derived growth factor subunits. RNA was extracted from biopsy specimens and subjected to Northern blot analysis with the use of oligolabeled complementary DNA for the platelet-derived growth factor-receptor. Platelet-derived growth factor-receptor alpha- and beta-subunit expression was found in fibroblast-like cells within the wound bed and in cells beneath the epidermis of the wound edge. Platelet-derived growth factor-receptor beta-subunit expression was detected in endothelial cells of the vessels, in the granulation tissue, and the wound edge, whereas platelet-derived growth factor-receptor alpha-subunit was not expressed in endothelial cells of the uninjured skin. This finding suggests that the platelet-derived growth factor alpha-subunit may be involved in vessel formation during tissue repair. Both platelet-derived growth factor-receptor subunits were expressed at the messenger RNA level indicating that the synthesis is at least partly regulated at a pretranslational level. As the cellular responsiveness to growth factors depends on their specific receptors, our finding that both platelet-derived growth factor-receptor subunits are expressed in chronic venous ulcers substantiates the concept of therapeutic trials with recombinant platelet-derived growth factor.

Divalent cations (Mg2+, Ca2+) differentially influence the beta 1 integrin-mediated migration of human fibroblasts and keratinocytes to different extracellular matrix proteins.

Directed migration of keratinocytes and fibroblasts is a fundamental prerequisite in wound healing. Cation-dependent affinity changes of integrins are responsible for cell adhesion to and deadhesion from extracellular matrix proteins and have been implicated in driving cell migration. The specific requirements for divalent cations in the integrin-dependent migration of human dermal fibroblasts and human epidermal keratinocytes to various extracellular matrix proteins have been studied in vitro using blindwell Boyden chambers. The migration of the tested cells to collagen type I was mediated by the alpha 2 beta 1 integrins, to fibronectin by the combined action of the alpha 3 beta 1 and the alpha 5 beta 1 integrin, and the migration of fibroblasts to laminin dependent both on the alpha 2 beta 1 and the alpha 6 beta 1 integrins. No migration of keratinocytes to laminin was detected. Mg2+ alone induced cell migration with an optimum at 2 mM for fibroblasts and at 10 mM for keratinocytes. Ca2+ alone at 2 mM only marginally enhanced fibroblast and keratinocyte migration. At higher concentrations Ca2+ suppressed the stimulatory Mg2+ effect. 2 mM Ca2+ combined with 2 mM Mg2+ showed an additive stimulatory effect on the migration of fibroblasts to fibronectin. These data suggest that extracellular divalent cations differentially influence the integrin-mediated cell migration. A concentration gradient of Mg2+/Ca2+, as reported in tissue injury, thus may play a regulatory role in cell migration required for tissue remodelling.

Glucose uptake and catabolite repression in dominant HTR1 mutants of Saccharomyces cerevisiae.

Growth and carbon metabolism in triosephosphate isomerase (delta tpi1) mutants of Saccharomyces cerevisiae are severely inhibited by glucose. By using this feature, we selected for secondary site revertants on glucose. We defined five complementation groups, some of which have previously been identified as glucose repression mutants. The predominant mutant type, HTR1 (hexose transport regulation), is dominant and causes various glucose-specific metabolic and regulatory defects in TPI1 wild-type cells. HTR1 mutants are deficient in high-affinity glucose uptake and have reduced low-affinity transport. Transcription of various known glucose transporter genes (HXT1, HXT3, and HXT4) was defective in HTR1 mutants, leading us to suggest that HTR mutations affect a negative factor of HXT gene expression. By contrast, transcript levels for SNF3, which encodes a component of high-affinity glucose uptake, were unaffected. We presume that HTR1 mutations affect a negative factor of HXT gene expression. Multicopy expression of HXT genes or parts of their regulatory sequences suppresses the metabolic defects of HTR1 mutants but not their derepressed phenotype at high glucose concentrations. This suggests that the glucose repression defect is not a direct result of the metabolically relevant defect in glucose transport. Alternatively, some unidentified regulatory components of the glucose transport system may be involved in the generation or transmission of signals for glucose repression.