Evidence for a novel glutamate-mediated signaling pathway in keratinocytes.

Phenotypic alterations in keratinocyte behavior are essential for maintaining epidermal integrity during growth and wound repair and rely on co-ordinated cell signaling events. Numerous growth factors and cytokines have been shown to be instrumental in guiding such changes in keratinocyte activity; here we provide evidence which proposes a novel epidermal signaling pathway mediated by the excitatory amino acid glutamate. Glutamate is the major excitatory neurotransmitter at synaptic junctions within the central nervous system; however, we have identified expression in vivo of several regulatory molecules associated with glutamate signaling in keratinocytes. In resting rat skin epidermis, different classes of glutamate receptors, transporters, and a recently described clustering protein were shown to display distinct distribution patterns, supportive of a multifunctional cellular communication pathway. Immunoreactive N-methyl-D-aspartate-type, alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionate-type, and metabotropic-type glutamate receptors were colocalized with the specific glutamate transporter EAAC1 in basal layer keratinocytes, and GLT-1, a related transporter, was expressed suprabasally. In full-thickness rat skin wounds, marked modifications in the distribution of N-methyl-D-aspartate receptors and EAAC1 were observed during re-epithelialization, and alterations in N-methyl-D-aspartate receptor expression accompanied embryonic epidermal development, implicating glutamate signaling in these important biologic events. Furthermore, we provide evidence that these receptors are functional in vitro. These data provide strong evidence to support a role for glutamate in the control of epidermal renewal, and therefore suggest potentially novel therapeutic targets for the treatment of skin disease and enhancement of wound healing.

Specificity and reciprocity in the interactions between TGF-beta and macrophage inflammatory protein-1 alpha.

TGF-beta and macrophage inflammatory protein-1 alpha (MIP-1 alpha) appear to share a number of biologic properties. We have been attempting to examine the interactions between these two peptides in the hope of gaining an insight into the basis for the apparent functional redundancy. Our earlier observations have indicated that TGF-beta is a potent down-regulator of MIP-1 alpha and MIP-1 beta expression in bone marrow macrophages and also of MIP-1 alpha receptor numbers on FDCPmix cells. We now demonstrate that the interplay between TGF-beta and MIP-1 alpha beta is relatively specific, in that only MIP-1 alpha and MIP-1 beta appear to be potently suppressed by TGF-beta, and that this suppressive activity is restricted to the direct TGF-beta isoforms. Activin and the bone morphogenetic proteins (BMPs) appear to be inactive in this regard. We also demonstrate the existence of an endogenous TGF-beta-mediated block that acts to minimize MIP-1 alpha expression in TGF-beta-expressing macrophages. This coupled with the observations that MIP-1 alpha can induce expression of TGF-beta suggests to us that the complex interactions between MIP-1 alpha and MIP-1 beta and the direct TGF-beta isoforms (beta 1, beta 2, and beta 3) act to ensure minimized MIP-1 alpha beta expression and maximized TGF-beta expression. However, such interplay may also be dependent on the local cytokine or inflammatory profile to which the cells are exposed.

Transforming growth factor beta: is it a downregulator of stem cell inhibition by macrophage inflammatory protein 1 alpha?

Transforming growth factor beta 1 (TGF-beta 1) and macrophage inflammatory protein 1 alpha (MIP-1 alpha) have recently been identified as potent inhibitors of hemopoietic stem cell proliferation. From previous studies, these molecules appear to have similar functions in the control of stem cell proliferation. This study was designed to investigate the relationship, if any, between these two negative regulators in an attempt to elucidate possible distinctive roles for each within the hemopoietic system. We report here that both MIP-1 alpha and TGF-beta are capable of inhibiting the same stem cell population (colony-forming unit [CFU]-A/CFU-S) with similar potencies. We further show that TGF-beta potently inhibits MIP-1 alpha gene expression in bone marrow-derived macrophages, the presumed source of MIP-1 alpha in the bone marrow. This inhibition is not specific to MIP-1 alpha in that expression of MIP-1 beta, a related molecule that does not exhibit potent stem cell inhibitory properties, is inhibited in a similar manner. The inhibition of MIP-1 alpha gene expression is also seen as a reduction in MIP-1 alpha protein production, which markedly decreases 24 h after treating RAW 264.7 cells, a murine macrophage cell line, with TGF-beta. These in vitro results suggest that in the presence of active TGF-beta in vivo, and in the absence of upregulators of MIP-1 alpha transcription, very little MIP-1 alpha will be produced. To address how MIP-1 alpha's target cells, the stem cells, would respond to TGF-beta, and the consequently low levels of MIP-1 alpha produced, we analyzed the effect of TGF-beta on MIP-1 alpha receptor levels on FDCP-MIX cells, a murine stem cell line. We show that TGF-beta (100 pM) reversibly downregulates MIP-1 alpha receptor levels on these cells to a maximum of 50-70% after 24 h. This level of downregulation does not change upon increasing the concentration of TGF-beta or the length of exposure of the cells to TGF-beta. Scatchard analysis shows that TGF-beta downregulates MIP-1 alpha receptor numbers with no change in affinity of the remaining receptors. These results suggest that TGF-beta may be capable of interfering with MIP-1 alpha's role as a stem cell inhibitor. Indeed, they suggest that in the presence of active TGF-beta in vivo, MIP-1 alpha is at best a weak contributor to the overall physiological inhibition of stem cells.