Improvement of wool production through genetic engineering.

Wool is a natural fibre popular in the manufacture of outer clothing and is a vital source of income for several countries. Fundamental knowledge of how wool grows has been gained from research on the biology of sheep, and the prospects ahead are to take advantage of the development and application of recombinant DNA technology to improve the efficiency of production of wool and its quality. This review surveys the possibilities for producing transgenic sheep, modifying rumen bacteria and forage crops, thus increasing the nutritional benefit sheep gain from pasture.     

Interactions of intermediate filament proteins from wool.

Filaments of wool are heteropolymers formed by interaction of type I and type II intermediate filament (IF) proteins. There are four proteins in each of these two classes. Interaction of the reduced wool IF proteins was studied by two-dimensional electrophoresis which showed that complexes between type I and type II proteins were formed in solution at urea concentrations below 6 M. Complex formation between the carboxymethyl derivatives of wool IF proteins was studied using a filter binding assay in which radio-labelled individual components were allowed to react under various conditions with SDS-PAGE separated components after transfer to nitrocellulose. The results suggested that (i) absolute type specificity of interaction was maintained, (ii) fine specificity, i.e. preferential reaction between specific components is observed, (iii) wool IF proteins (hard keratins) also react, with the same type specificity, with soft keratins isolated from cow snout, (iv) the initial step in the polymerization sequence that leads to filament formation yields heterodimers.     

The chemical composition of wool. XV. The cell membrane couplex.

The cell membrane complex of wool has been examined by electron microscopy of stained cross sections after immersion of the wool in formic acid. The cell membrane complex of the cortex is considerably modified by the treatment, but that of the cuticle appears unchanged. Resistant membranes from cuticle cells, cortical cells and wool have been prepared by treatment with performic acid-ammonia. Amino acid analyses show that the resistant membranes from the cuticle contain citrulline but those from cortical cells do not. It is concluded that the cell membrane complex of the cuticle differs from that of the cortex. Because of the high lysine content of the resistant membranes, their resistance to chemical attack, the hydrophobicity of epicuticle and the observation of a small amount of epsilon-(gamma-glutamyl)lysine, it is postulated that the resistant membranes may contain an appreciable amount of epsilon-(gamma-glutamyl)lysine cross links.     

Growth of wool follicles in culture

Summary A procedure for the culture of isolated wool follicles from Merino sheep is described. Follicles were microdissected from midside skin samples of 2-yr-old wethers and transferred, individually, to 24-well tissue culture plates. When maintained in supplemented Williams’ E medium containing 5 to 10% fetal bovine serum (FBS), insulin, hydrocortisone, and a trace element mixture, fiber growth rates of 40 to 80 μm/day were observed. Follicles maintained their morphologic integrity for up to 7 days, incorporated [methyl-³H]thymidine into DNA and [³⁵S]methionine into intermediate-filament keratins of the growing fiber. Insulin and hydrocortisone stimulated fiber growth at concentrations of 10 μg/ml and 50 ng/ml, respectively, but higher doses were inhibitory. The growth of fibers in response to hydrocortisone and the changes in follicle morphology was similar to those induced in skin after systemic administration of cortisol in vivo. A positive interaction between hydrocortisone and trace elements for follicle survival and hydrocortisone, insulin, and FBS for fiber growth was also found. The successful culture of Merino sheep follicles provides a model with which to study the direct influence of endocrine, nutritional and local factors on wool keratin synthesis independently of systemic shifts in the animals’ metabolism.     

Preparation of metabolically active cell suspensions from wool roots.

A method is described for the preparation of metabolically active cell suspensions from plucked wool roots using the proteolytic enzyme trypsin. The suspensions consist of a heterogeneous population of cells which appear similar in morphology to follicle bulb cells, differentiating keratinocytes and possibly cells of the inner root sheath. The concentrations of trypsin and of inorganic ions for optimum activity of the suspensions have been determined, and the inclusion of EGTA was found to increase the yield of cells. The cell suspensions incorporate [14C]leucine, [3H]uridine and [3H]thymidine into acid-insoluble products, and are sensitive to the action of cycloheximide and emetine, but not to chloramphenicol or rifampin. Autoradiography has shown that the cells believed to be derived from the follicle bulbs show the greatest activity.     

Grafting onto wool: 10. Quantitative analysis of the high-angle X-ray diffraction intensity from grafted and ungrafted wool keratin

The equatorial and the meridional scattering intensities at prominent reflections (0.98 nm, 0.465 nm and 0.51 nm) of X-rays by the keratin in grafted fibres stretched in water have been quantitatively determined. Introduction of poly(methyl methacrylate) into the fibres leads to a marked decrease in -content. It is suggested that the two types of -helical component present in the wool fibres are identical with respect to the ease of unfolding of the -helix during fibre extension. During extension, no significant difference was observed for the rates of production of β-materials by native and grafted fibres. On the basis of these experimental findings, the β transformation of the keratin system is discussed.     

Sequences of wool keratin proteins: the CSIRO connection.

Wool, a dead tissue of epithelial origin, derives many of its properties as a textile fibre from the structure and arrangement of the proteins from which it is comprised. Much of the progress in the elucidation of wool protein structures, as a step towards understanding this relationship between structure and properties, has been made in the Division of Protein Chemistry of Australia's Commonwealth Scientific and Industrial Research Organization.     

Unravelling the proteome of wool: towards markers of wool quality traits

With ongoing efforts to make wool more competitive alongside other fibres, notably synthetics, there is a need to obtain a better understanding of the relationship between protein composition and characteristic wool properties to assist sheep breeding programmes. Before this can be achieved, the wool proteome needs to be mapped, by gel and non-gel techniques, and methods developed to reliably quantitate protein expression. Nevertheless, in setting out to achieve this, there are numerous challenges to be faced in the application of proteomics to wool, including the relative lack of wool protein sequence information in the publically accessible databases, the wide variety of proteins in the wool fibre, the high homology within the Type I and Type II keratins, the high degree of homology and polymorphism within individual keratin associated protein families, the dominance of the keratin proteins over others in wool and the peculiar chemistries found in keratins and their associated proteins. This review will discuss the various strategies that have been developed to both identify these proteins in the wool protein map and quantify them with the view to their application to the identification of markers for wool quality traits.     

Newly isolated Bacillus sp. G51 from Patagonian wool produces an enzyme combination suitable for felt-resist treatments of organic wool

Bacteria from Patagonian Merino wool were isolated to assess their wool-keratinolytic activity and potential for felt-resist treatments. Strains from Bacillus, Exiguobacterium, Deinococcus, and Micrococcus produced wool-degrading enzymes. Bacillus sp. G51 showed the highest wool-keratinolytic activity. LC-MS/MS analysis revealed that G51 secreted two serine proteases belonging to the peptidase family S8 (MEROPS) and a metalloprotease associated with Bacillolysin, along with other enzymes (γ-glutamyltranspeptidase and dihydrolipoyl dehydrogenases) that could be involved in reduction of keratin disulfide bonds. Optimum pH and temperature of G51 proteolytic activity were 9 and 60 °C, respectively. More than 80% of activity was retained in H₂O₂, Triton X-100, Tween 20, Lipocol OXO650, Teridol B, and β-mercaptoethanol. Treatment of wool top with G51 enzyme extract caused a decrease in wool felting tendency without significant weight loss (<1.5%). Sparse work has so far been performed to investigate suitable keratinases for the organic wool sector. This eco-friendly treatment based on a new enzyme combination produced by a wild bacterium has potential for meeting the demands of organic wool processing which bans the use of hazardous chemicals and genetic engineering.