Mesenchymal-epithelial signalling between the dermal papilla and the hair matrix regulates cell proliferation and differentiation in mature hair follicles. The molecular basis of these interactions is largely unexplored. According to its expression in the dermal papilla, IGF-I is likely involved in reciprocal signalling. To examine its biological function in pelage follicles further, we generated transgenic mice that express Igf-I in the inner root sheath and the medulla using an involucrin promoter fragment. We demonstrate that Igf-I affects follicular proliferation, tissue remodelling, and the hair growth cycle, as well as folliclular differentiation. Transgenic skin temporarily lacks visible adipose tissue in telogen. The onset of the second, aberrant growth phase is markedly retarded. Transgenic guard hairs are significantly elongated and a small fraction of hair follicles is severely disoriented. The microscopic appearance of most hair shafts is altered and, strikingly, Igf-I transgenic mice lack hairs with a zigzag shape due to the suppression of hair shaft bending. All transgenic effects are partially compensated by ectopic expression of Igfbp3. Finally, Pdgfralpha was identified as the first molecular target that is affected in Igf-I transgenic mice. In summary, our data identify IGF-I signalling as an important mitogenic and morphogenetic regulator in hair follicle biology.
The ubiquitous species Pseudomonas stutzeri has type IV pili, and these are essential for the natural transformation of the cells. An absolute transformation-deficient mutant obtained after transposon mutagenesis had an insertion in a gene which was termed pilT. The deduced amino acid sequence has identity with PilT of Pseudomonas aeruginosa (94%), Neisseria gonorrhoeae (67%), and other gram-negative species and it contains a nucleotide-binding motif. The mutant was hyperpiliated but defective for further pilus-associated properties, such as twitching motility and plating of pilus-specific phage PO4. [3 H]thymidine-labeled DNA was bound by the mutant but not taken up. Downstream of pilT a gene, termed pilU, coding for a putative protein with 88% amino acid identity with PilU of P. aeruginosa was identified. Insertional inactivation did not affect piliation, twitching motility, or PO4 infection but reduced transformation to about 10%. The defect was fully complemented by PilU of nontransformable P. aeruginosa. When the pilAI gene (coding for the type IV pilus prepilin) was manipulated to code for a protein in which the six C-terminal amino acids were replaced by six histidine residues and then expressed from a plasmid, it gave a nonpiliated and twitching motility-defective phenotype in pilAI::Gm r cells but allowed transformability. Moreover, the mutant allele suppressed the absolute transformation deficiency caused by the pilT mutation. Considering the hypothesized role of pilT ؉ in pilus retraction and the presumed requirement of retraction for DNA uptake, it is proposed that the pilT-independent transformation is promoted by PilA mutant protein either as single molecules or as minimal pilin assembly structures in the periplasm which may resemble depolymerized pili and that these cause the outer membrane pores to open for DNA entry.
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