Human hair follicle dermal sheath and papilla cells support keratinocyte growth in monolayer coculture.

Traditional skin grafting techniques are effective but limited methods of skin replacement. Autologous transplantation of rapidly cultured keratinocytes is successful for epidermal regeneration, but the current gold-standard technique requires mouse fibroblast feeders and serum-rich media, with serum-free systems and dermal fibroblast (DF) feeders performing relatively poorly. Here, we investigated the capacity of human hair follicle dermal cells to act as alternative supports for keratinocyte growth. Dermal papilla (DP) dermal sheath (DS), DF and 3T3 cells were used as inactivated feeder cells for human keratinocyte coculture. Under conditions favouring dermal cells, proliferation of keratinocytes in the presence of either DS or DP cells was significantly enhanced compared with DF cells, at levels comparable to keratinocytes cultured under gold-standard conditions. Secreted protein acidic and rich in cysteine (SPARC) expression increased DS and DP cells relative to DFs; however, further experiments did not demonstrate a role in keratinocyte support.

The negative transcriptional regulator NmrA discriminates between oxidized and reduced dinucleotides.

NmrA, a transcription repressor involved in the regulation of nitrogen metabolism in Aspergillus nidulans,is a member of the short-chain dehydrogenase reductase superfamily. Isothermal titration calorimetry and differential scanning calorimetry have been used to show NmrA binds NAD+ and NADP+ with similar affinity (average KD 65 microM) but has a greatly reduced affinity for NADH and NADPH (average KD 6.0 mM). The structure of NmrA in a complex with NADP+ reveals how repositioning a His-37 side chain allows the different conformations of NAD+ and NADP+ to be accommodated. Modeling NAD(P)H into NmrA indicated that steric clashes, attenuation of electrostatic interactions, and loss of aromatic ring stacking can explain the differing affinities of NAD(P)+/NAD(P)H. The ability of NmrA to discriminate between the oxidized and reduced forms of the dinucleotides may be linked to a possible role in redox sensing. Isothermal titration calorimetry demonstrated that NmrA and a C-terminal fragment of the GATA transcription factor AreA interacted with a 1:1 stoichiometry and an apparent KD of 0.26 microM. NmrA was unable to bind the nitrogen metabolite repression signaling molecules ammonium or glutamine.

PDZ domains facilitate binding of high temperature requirement protease A (HtrA) and tail-specific protease (Tsp) to heterologous substrates through recognition of the small stable RNA A (ssrA)-encoded peptide.

The Escherichia coli protease HtrA has two PDZ domains, and sequence alignments predict that the E. coli protease Tsp has a single PDZ domain. PDZ domains are composed of short sequences (80-100 amino acids) that have been implicated in a range of protein:protein interactions. The PDZ-like domain of Tsp may be involved in binding to the extreme COOH-terminal sequence of its substrate, whereas the HtrA PDZ domains are involved in subunit assembly and are predicted to be responsible for substrate binding and subsequent translocation into the active site. E. coli has a system of protein quality control surveillance mediated by the ssrA-encoded peptide tagging system. This system tags misfolded proteins or protein fragments with an 11-amino acid peptide that is recognized by a battery of cytoplasmic and periplasmic proteases as a degradation signal. Here we show that both HtrA and Tsp are able to recognize the ssrA-encoded peptide tag with apparent K(D) values of approximately 5 and 390 nm, respectively, and that their PDZ-like domains mediate this recognition. Fusion of the ssrA-encoded peptide tag to the COOH terminus of a heterologous protein (glutathione S-transferase) renders it sensitive to digestion by Tsp but not HtrA. These observations support the prediction that the HtrA PDZ domains facilitate substrate binding and the differential proteolytic responses of HtrA and Tsp to SsrA-tagged glutathione S-transferase are interpreted in terms of the structure of HtrA.