Your search keyword '"Powell, Barry C."' showing total 4 results

1. Clustered Arrangement of Keratin Intermediate Filament Genes

Author

Powell, Barry C., Cam, Graham R., Fietz, Michael J., and Rogers, George E.

Published

1986

2. Differential Expression of Genes Encoding a Cysteine-Rich Keratin Family in the Hair Cuticle.

Author

Jenkins, Brendan J. and Powell, Barry C.

Subjects

*CUTICLE, *GENES, *KERATIN, *GLYCINE, *HAIR follicles, *WOOL, *IN situ hybridization, *AMINO acids

Abstract

In the hair follicle the cuticle develops as a thin layer of cells between the hair shaft cortex and the inner root sheath. Once the cuticle cells begin to differentiate they accumulate cysteine-rich granules in their cytoplasm but the identity of their constituent proteins has remained largely an enigma. In this report we show differential expression of a family of genes encoding cysteine-rich, glycine-rich keratins in the cuticle. Two clones of the sheep KAP5 gene family were isolated: the KAP5.4 cDNA encodes a protein of 190 amino acids (Mr = 16,936) containing 32 mol% cysteine, 26 mol% glycine and the partial KAP5.5 cDNA encodes a protein of at least 197 amino acids (Mr ≥ 17,474) containing 29 mol% cysteine, 28 mol% glycine. The predicted amino acid sequences of the KAP5 family show extensive sequence conservation and all the proteins are composed almost entirely of cysteine-rich and glycine-rich repeats. Each KAP5 gene produces an ∼ 1.5- kb mRNA species but the KAP5.4 and KAP5.5 mRNA levels appear to be severalfold greater than the KAP5.1 mRNA. Comparative tissue in situ hybridizations reveal a positive correlation between the onset of expression and follicle depth. For a given KAP5 gene two widely different cuticle expression patterns were noted amongst the follicle populations, and on the basis of follicle bulb cell kinetics they are consistent with expression in either sheep primary or secondary follicle types. [ABSTRACT FROM AUTHOR]

Published

1994

3. Dietary Cysteine Regulates the Levels of mRNAs Encoding a Family of Cysteine-Rich Proteins of Wool.

Author

Fratini, Antonio, Powell, Barry C., Hynd, Philip I., Keough, Rebecca A., and Rogers, George E.

Subjects

*KERATIN, *WOOL, *NUTRITION, *GENE expression, *AMINO acids, *RNA

Abstract

The abomasal or intravenous infusion of sulphur-containing amino acids such as cysteine or methionine into sheep on low-quality diets increases the sulphur content of the wool by increasing the synthesis of proteins containing a cysteine content of ∼ 30 mol %. To investigate the molecular and cellular basis of this nutritional effect, quantitative analyses of wool keratin mRNA and protein levels, and follicle cortical cell type, were undertaken in sheep intravenously infused with cysteine. Northern blot analyses revealed that the mRNA levels of one gene family encoding cysteine-rich keratin-associated proteins (KAP4 family) expressed in the wool follicle cortex, increased ∼ 5-6 times. Furthermore, the response was rapid as the mRNA levels increased ∼ 3.5 times after 1 d of the cysteine infusion and, by 1 d post-infusion, they had fallen, approaching their basal level. No changes in the mRNA levels encoding the intermediate filament or the other keratin-associated protein families of lower cysteine content were observed. Concomitantly, two-dimensional polyacrylamide gel electrophoresis analysis of wool proteins showed a striking increase in the abundance of a group of cysteine-rich keratin-associated proteins in the wool by the end of the infusion period, returning to basal levels by 3 weeks later. At the cellular level, KAP4 expression was localized to the follicle paracortical cells, and the proportion of paracortical cells and the extent of KAP4 expression paralleled the changes in the cysteine infusion status of the sheep. [ABSTRACT FROM AUTHOR]

Published

1994

4. Organization and Expression of Hair Follicle Genes.

Author

Rogers, George E. and Powell, Barry C.

Subjects

*HAIR growth stimulants, *PROTEINS, *KERATIN, *DERMATOLOGIC agents, *GENES, *HAIR care products, *AMINO acids

Abstract

Several families of proteins are expressed in the growth of hair and an estimated 50-100 proteins constitute the final hair fiber. The cumbersome nomenclature for naming these different proteins has led to a proposal to modify that which is currently used for epidermal keratins. Investigations of the organization of hair genes indicate that the members of each family are clustered in the genome and their expression could be under some general control. Interestingly, the protein called trichohyalin, markedly distinct from the hair proteins, is produced in the inner root sheath cells and the gene for it has been found to be located at the same human chromosome locus as the genes for profilaggrin, involucrin, and loricrin. A mainstream objective is to identify controls responsible for the production in the hair cortex of keratin intermediate filaments (IFs) and two large groups of keratin-associated proteins (KAPs) rich in the amino acids cysteine or glycine/tyrosine. A specific family of cysteine-rich proteins is expressed in the hair cuticle. Comparisons of promoter regions of IF genes and KAP genes, including a recently characterized gene for a glycine/tyrosine-rich protein, have revealed putative hair-specific motifs in addition to known elements that regulate gene expression. In the sheep, the patterns of expression in hair differentiation are particularly interesting insofar as there are distinct segments of para- and orthocortical type cells that have significantly different pathways of expression. The testing of candidate hair-specific regulatory sequences by mouse transgenesis has produced several interesting hair phenotypes. Transgenic sheep over-expressing keratin genes but showing no hair growth change have been obtained and compared with the equivalent transgenic hair-loss mice. Studies of the effects of amino acid supply on the rate of hair growth have demonstrated that with cysteine supplementation of sheep a perturbation occurs in which there is a markedly increased level of only one type of mRNA and the ration of para- to orthocortical cells is increased. A molecular explanation of this phenomenon is being sought. [ABSTRACT FROM AUTHOR]

Published

1993