Donnie S. Bundman

Identification of a major keratinocyte cell envelope protein, loricrin

During epidermal cell cornification, the deposition of a layer of covalently cross-linked protein on the cytoplasmic face of the plasma membrane forms the cell envelope. We have isolated and characterized cDNA clones encoding a major differentiation product of mouse epidermal cells, which has an amino acid composition similar to that of purified cell envelopes. Transcripts of this gene are restricted to the granular layer and are as abundant as the differentiation-specific keratins, K1 and K10. An antiserum against a C-terminal peptide localizes this protein in discrete granules in the stratum granulosum and subsequently at the periphery of stratum corneum cells. Immunofluorescence and immunoelectron microscopy detect this epitope only on the inner surface of purified cell envelopes. Taken together, these results suggest that it is a major component of cell envelopes. On the basis of its presumed function, this protein is named loricrin.

Delayed Wound Healing in Keratin 6a Knockout Mice

ABSTRACT Keratin 6 (K6) expression in the epidermis has two components: constitutive expression in the innermost layer of the outer root sheath (ORS) of hair follicles and inducible expression in the interfollicular epidermis in response to stressful stimuli such as wounding. Mice express two K6 isoforms, MK6a and MK6b. To gain insight into the functional significance of these isoforms, we generated MK6a-deficient mice through mouse embryonic stem cell technology. Upon wounding, MK6a was induced in the outer ORS and the interfollicular epidermis including the basal cell layer of MK6a+/+ mice, whereas MK6b induction in MK6a−/− mice was restricted to the suprabasal layers of the epidermis. After superficial wounding of the epidermis by tape stripping, MK6a−/− mice showed a delay in reepithelialization from the hair follicle. However, the healing of full-thickness skin wounds was not impaired in MK6a−/−animals. Migration and proliferation of MK6a−/−keratinocytes were not impaired in vitro. Furthermore, the migrating and the proliferating keratinocytes of full-thickness wounds in MK6a−/− animals expressed neither MK6a nor MK6b. These data indicate that MK6a does not play a major role in keratinocyte proliferation or migration but point to a role in the activation of follicular keratinocytes after wounding. This study represents the first report of a keratin null mutation that results in a wound healing defect.

Formation of the rabbit zona pellucida and its relationship to ovarian follicular development

The zona pellucida is the unique extracellular glycoprotein matrix which is assembled during growth of the mammalian oocyte. The present studies were carried out to examine the formation of this structure in relation to the differentiation of ovarian cell types during follicular development. Specific antibodies were developed against total rabbit ZP proteins as well as against ZP proteins electrophoretically purified by high-resolution two-dimensional polyacrylamide electrophoresis gels (2D-PAGE). Antibodies were characterized by (a) immunoelectrophoresis, (b) a Staphylococcus aureus protein A binding assay, and (c) immunoblotting following 2D-PAGE separation of ZP proteins. Immunoperoxidase localization with these antibodies was used to determine the stage of ovarian follicular development at which ZP antigens first appear as well as to evaluate the cellular and extracellular distribution of these proteins throughout folliculogenesis. The ZP proteins were first observed in the cytoplasm and at the periphery of the oocytes surrounded by a thin squamous follicular cell layer. No staining was observed in the cytoplasm of follicle cells during early folliculogenesis. As the ZP matrix was assembled extracellularly, the intensity of staining of the outer and inner regions could be distinguished. This differentiation of the matrix coincided with the differentiation of the follicular cells into a multilayer cell complex. At this stage, specific ZP proteins are localized within the cytoplasm of the inner layers of these follicular cells. The staining is then diminished in cells of preantral follicles. These studies demonstrate that the formation of the ZP is an excellent model system to study the early stages of follicular development and cell differentiation.

Human keratin-1. bcl -2 transgenic mice aberrantly express keratin 6, exhibit reduced sensitivity to keratinocyte cell death induction, and are susceptible to skin tumor formation

Nonmelanoma skin cancers (NMSC) are among the most common malignancies in the world. Typically, these neoplasms grow slowly and are comparatively indolent in their clinical behavior. The most frequent molecular alterations implicated in the pathogenesis of these neoplasms involve genes known to be regulators of cell death including p53, Ha-ras and bcl-2. In order to evaluate the significance cell death deregulation during skin carcinogenesis, we generated a transgenic mouse model (HK1.bcl-2) using the human keratin 1 promoter to target the expression of a human bcl-2 minigene to the epidermis. Transgenic HK1.bcl-2 protein was expressed at high levels specifically in the epidermis extending from the stratum basale through the stratum granulosum. The epidermis of HK1.bcl-2 mice exhibited multifocal hyperplasia without associated hyperkeratosis and aberrant expression of keratin 6. The rate of proliferation was similar in HK1.bcl-2 and control epidermis although suprabasal BrdUrd incorporating cells were present only in HK1.bcl-2 skin. Keratinocytes from the HK1.bcl-2 mice were significantly more resistant to cell death induction by U.V.-B, DMBA, and TPA, compared to control keratinocytes. Furthermore, papillomas developed at a significantly greater frequency and shorter latency in the HK1.bcl-2 mice compared to control littermates following initiation with DMBA and promotion with TPA. Together these results support a role for bcl-2 in the pathogenesis of NMSC.

A bichromatic fluorescent reporter for cell-based screens of alternative splicing.

Alternative splicing is the primary source of proteome complexity in metazoans and its regulation shapes the proteome in response to shifting physiological requirements. We developed a bichromatic splicing reporter that uses a peculiar feature of some fluorescent protein coding regions to express two different fluorescent proteins from a single alternative splicing event. The mutually exclusive expression of different fluorescent proteins from a single reporter provides a uniquely sensitive approach for high-throughput screening and analysis of cell-specific splicing events in mixed cell cultures and tissues of transgenic animals. This reporter is applicable to the majority of alternative splicing patterns and can be used to quantify alternative splicing within single cells and to select cells that express specific splicing patterns. The ability to perform quantitative single-cell analysis of alternative splicing and high-throughput screens will enhance progress toward understanding splicing regulatory networks and identifying compounds that reverse pathogenic splicing defects.

Genetic disorders of keratin: are scarring alopecias a sub-set?

Recent advances have challenged the prevailing view that keratins are merely passive bystanders of keratinocyte biology. With the exciting discovery that three autosomal dominant genetic skin disorders, epidermolysis bullosa simplex (EBS), epidermolytic hyperkeratosis (EHK) and palmoplantar keratoderma (PPK), are in fact disorders of keratins comes the realization that the integrity of the keratin filament network is crucial to the structural integrity of the skin. Since it has been recently established that mutations in keratins K5/K14, K1/K10 and K9 are causative for these keratinocyte disorders, it is very likely that mutations in K6 or in its obligate partner, K16 will result in disease. In order to test this we have produced transgenic mice that express a mutant K6 gene. These mice develop a progressive scarring alopecia at about 6 months of age. Later, the denuded areas developed a keratosis which was prone to infection. Ultrastructural analysis suggests that hair loss is due to the destruction of the outer root sheath. We believe that these mice are models of another keratin disorder.