Ovine keratome: identification, localisation and genomic organisation of keratin and keratin-associated proteins.

Wool is composed primarily of proteins belonging to the keratin family. These include the keratins and keratin-associated proteins (KAPs) that are responsible for the structural and mechanical properties of wool fibre. Although all human keratin and KAP genes have been annotated, many of their ovine counterparts remain unknown and even less is known about their genomic organisation. The aim of this study was to use a combinatory approach including comprehensive cDNA and de novo genomic sequencing to identify ovine keratin and KAP genes and their genomic organisation and to validate the keratins and KAPs involved in wool production using ovine expressed sequence tag (EST) libraries and proteomics. The number of genes and their genomic organisation are generally conserved between sheep, cattle and human, despite some unique features in the sheep. Validation by protein mass spectrometry identified multiple keratins (types I and II), epithelial keratins and KAPs. However, 15 EST-derived genes, including one type II keratin and 14 KAPs, were identified in the sheep genome that were not present in the NCBI gene set, providing a significant increase in the number of keratin genes mapped on the sheep genome.

Myogenic differentiation of dermal papilla cells from bovine skin.

Cells from the dermal papilla and dermal sheath of hair follicles exhibit pronounced plasticity in vitro, being capable of adopting fat, bone, hematopoietic, and nerve cell phenotypes. In this study, we show that bovine dermal papilla cells (DPC) are also capable of undergoing skeletal muscle differentiation. DiI labeled DPC incorporated into myotubes when co-cultured with differentiating C(2)C(12) myoblasts. Bovine-specific PCR assays showed that the muscle markers MyoD and myogenin were up-regulated, confirming that the DPC had adopted a myogenic gene expression program. Nine clonal lines of DPC underwent both adipogenic and myogenic differentiation, demonstrating the multipotency of individual cells. Primary populations of both DPC and extra-follicular dermal fibroblasts were also capable of both adipogenic and myogenic differentiation. However, on myogenic differentiation, cells derived from dermal papillae expressed higher levels of myogenin than primary fibroblasts derived from extra-follicular dermis, suggesting that papilla cells undergo myogenesis more efficiently. This result shows that populations of fibroblastic cells derived from different anatomical sites within the skin are not equivalent with respect to their plasticity. Cultured DPC and dermal fibroblasts both expressed Pax3, a marker for the dermomyotome which represents a common embryological origin of muscle and dermis. Quantitative PCR showed that Pax3 expression levels before myogenic induction correlated with myogenin expression levels after myogenesis. These results suggest that a degree of dedifferentiation may underlie the plasticity of dermal cells in vitro, and that this plasticity may be predicted, at least in part, by levels of Pax3 expression.

Regulation of prolactin receptor expression in ovine skin in relation to circulating prolactin and wool follicle growth status.

Seasonal patterns of hair growth are governed, at least in part, by levels of prolactin in circulation, and although receptors for prolactin (PRLR) have been demonstrated in hair follicles, little is known of their regulation in relation to follicular cycles. In this study, a photoperiod-generated increase in prolactin was used to induce a wool follicle cycle during which changes in PRLR expression in sheep skin were determined by ribonuclease protection assay and in situ hybridisation. mRNA for prolactin and both isoforms of PRLR were also detected in skin by reverse transcription and polymerase chain reaction. As circulating prolactin began to rise from low levels, PRLR mRNA in the skin initially fell. These changes immediately preceded the catagen (regressive) phase of the hair cycle. Further increase in prolactin resulted in up-regulation of PRLR during telogen (dormancy), particularly in the epithelial hair germ, to reach a peak during proanagen (reactivation). In anagen (when follicle growth was fully re-established), PRLR mRNA returned to levels similar to those observed before the induced cycle. Hence, this longer term rise and fall of PRLR expression followed that of plasma prolactin concentration with a lag of 12-14 days. PRLR mRNA was most abundant in the dermal papilla, outer root sheath, hair germ, skin glands and epidermis. Location of PRLR in the dermal papilla and outer root sheath indicates action of prolactin on the growth-controlling centres within wool follicles. These cycle-related patterns of PRLR expression suggest dynamic regulation of PRLR by prolactin, thereby modulating hormonal responsiveness of seasonally growing hair follicles.

Inhibitory effect of increased photoperiod on wool follicle growth.

The relationships between circulating prolactin (PRL), wool follicle growth and daylength were investigated in 24 New Zealand Wiltshire ewes housed indoors from September 1989 to May 1991. Twelve control (C) ewes were maintained under natural photoperiod. Two other groups were held in short days (SD; 8 h light: 16 h darkness) commencing from the winter solstice (22 June 1990) for either three (group SD3, n = 7) or six (group SD6, n = 5) months before reversion to natural daylength. Skin was sampled at one- to four-week intervals for histological determination of percentages of growing primary and secondary follicles. Hourly blood samples over 24 h were collected via jugular cannulae from C sheep in March and July and then monthly from all animals until December 1990 for estimation of mean monthly PRL concentrations for each treatment group. Between autumn (March 1990) and winter (July) primary follicle activity (PFA) and secondary follicle activity (SFA) declined in C ewes (PFA: 97 to 43%, SFA: 100 to 57%). Follicle regrowth during July and August in eight C ewes preceded the initial rise in plasma PRL from the winter minimum (1.6 ng/ml). Across the three groups, four instances of decreased follicle activity were observed, closely following or concurrent with increases in plasma PRL concentrations. The resumption of spring growth in four C sheep was temporarily checked by falls in follicle activities during September and October as PRL concentrations began to increase (3.4 to 8.9 ng/ml). Follicle activity also declined in November and December in eight C sheep, coincident with the rapid rise in PRL to a seasonal maximum in late November (165.4 ng/ml). The increase in SD3 follicle activity over spring was not delayed by short days but during October, after release from treatment, PRL concentrations rose (1.8 to 12.0 ng/ml) and follicle activity declined (PFA: 65 to 38%, SFA: 68 to 43%). In SD6 ewes, PRL concentrations were suppressed (2.1 ng/ml) and relatively constant levels of follicle activity (PFA: 73%, SFA: 95%) were maintained throughout short-day treatment. Release of SD6 ewes into summer photoperiod in January 1991 temporarily interrupted follicle growth (PFA: 68 to 17%, SFA: 96 to 19%) and caused out-of-season shedding in March and April. Contemporary C follicle activities were high (PFA: 95%, SFA: 98%). These data suggest that natural and experimental increases in daylength have a short-term inhibitory effect on growing wool follicles which could be mediated through rising concentrations of plasma prolactin.