Isolation and properties of inner sheath cells of hair follicles

Cracking the Skin Barrier: Liquid-Liquid Phase Separation Shines under the Skin

Central to forming and sustaining the skin’s barrier, epidermal keratinocytes (KCs) fluxing to the skin surface undergo a rapid and enigmatic transformation into flat, enucleated squames. At the crux of this transformation are intracellular keratohyalin granules (KGs) that suddenly disappear as terminally differentiating KCs transition to the cornified skin surface. Defects in KGs have long been linked to skin barrier disorders. Through the biophysical lens of liquid-liquid phase separation (LLPS), these enigmatic KGs recently emerged as liquid-like membraneless organelles whose assembly and subsequent pH-triggered disassembly drive squame formation. To stimulate future efforts toward cracking the complex process of skin barrier formation, in this review, we integrate the key concepts and foundational work spanning the fields of LLPS and epidermal biology. We review the current progress in the skin and discuss implications in the broader context of membraneless organelles across stratifying epithelia. The discovery of environmentally sensitive LLPS dynamics in the skin points to new avenues for dissecting the skin barrier and for addressing skin barrier disorders. We argue that skin and its appendages offer outstanding models to uncover LLPS-driven mechanisms in tissue biology.

Redefining the structure of the hair follicle by 3D clonal analysis

The hair follicle (HF) is a multi-tissue mini-organ that self-renews periodically. However, the cellular organisation of this much-studied model is not fully understood. The structures of the outer layer and of the bulb, which ensures HF growth, have not been completely established. To clarify these points, we have conducted in vivo clonal analyses with 3D imaging in mice. The upper two-thirds of the HF outer layer consists of two clonally unrelated groups of cells that exhibit different modes of growth. They correspond to the basal outer root sheath (ORS) and the companion layer (Cp). The basal ORS has an unusual anisotropic mode of growth from a suprabulbar zone, which we named the privileged proliferation zone. The Cp has a stem/transient-amplifying mode of growth and is shown to be an HF internal structure. Furthermore, we describe an additional element, the bulb outer layer, which is contiguous and shares markers (e.g. Lgr5) with the basal ORS but is formed by a separate lineage that belongs neither to the ORS nor Cp lineage. It represents a novel element with proximal cells that are contiguous with the germinative layer in the bulb. In reference to its shape and position we named it the lower proximal cup (LPC). These clonal hierarchies reveal a novel model of HF organisation and growth based on two major entities: the basal ORS and the LPC plus the seven internal layers.

Ultrastructural immunolocalization of involucrin in the medulla and inner root sheath of the human hair

The participation of involucrin in the cornification of the human hair has been studied by light and electron microscopy immunohistochemistry. Immunoreactivity for involucrin is absent in keratinized cuticle and cortical cells although some immunolabeling is observed in the corneous membrane of internal cortical cells surrounding the hair medulla. Conversely, immunolabeling for involucrin is present in the cytoplasm of keratinizing cells of the medulla and inner root sheath. During the maturation and final cornification of medullary and inner root sheath cells the immunolabeling for involucrin tends to concentrate in the peripheral cytoplasm and along the cornified cell plasma membrane in both medullary and inner root sheath cells, a pattern similar to that known for corneocytes of the epidermis. This observation suggests that in the hair involucrin mainly participates in the formation of the corneous material of the medulla and inner root sheath in conjunction with trichohyalin, probably by the formation of isopeptide-bonds. Therefore, together with trichohyalin, the cross-linking due to involucrin is also responsible for the mechanical resistance of the corneous trabeculae present among the empty spaces of the medulla of the human hair.

A unique type I keratin intermediate filament gene family is abundantly expressed in the inner root sheaths of sheep and human hair follicles

A unique type I keratin intermediate filament group, comprising three highly related proteins and expressed in the inner root sheath of hair follicles, has been identified in both sheep and human. The first members from these species are named oIRSa1 and hIRSa1 and each encodes a protein of 450 amino acids, with compositional characteristics intermediate between those of previously described hair keratin and epidermal cytokeratin type I intermediate filaments. Detection of abundant mRNA transcripts derived from the sheep and human genes by cRNA in situ hybridization only in the inner root sheath and not in the medulla concurs with the findings of earlier ultrastructural analyses that have reported intermediate filaments only in the inner root sheath. Clustering of the IRSa keratin genes is apparent in the genomes of both species. The three hIRSa genes, known to reside on human chromosome 17, are closely linked to three further type I keratin intermediate filament genes of unknown function. This new gene complex, contained almost entirely within a 156 kb BAC (hRPK.142_H_19), is likely to lie near the type I intermediate filament cytokeratin and hair keratin gene loci at 17q12-q21. A phylogenetic analysis including all known human type I intermediate filament cytokeratins, hHa keratins, hIRSa, and hIRSa-linked keratins suggests that origin of the IRSa keratin intermediate filament linkage group preceded origin of most of the epidermal cytokeratins and all hair keratins during emergence of the keratin intermediate filament genes.

Peptidylarginine deiminase of the hair follicle: characterization, localization, and function in keratinizing tissues

The enzyme peptidylarginine deiminase (PAD; EC 3.5.3.15) is responsible for the formation of protein-bound citrulline, a major amino acid in the inner root sheath (IRS) and in the medulla of the hair follicle. From mainly biochemical evidence, it is known that the substrate for the enzyme is trichohyalin and that trichohyalin granules gradually disappear to form a matrix with intermediate-like filaments in the IRS cells. In the medulla, the granules aggregate into large masses without filaments. The proteins in both the IRS and medulla are finally cross-linked by transglutaminase. A corollary of the apparent central role of PAD acting on the trichohyalin protein in these processes is that it should be present in the IRS and medulla cells, coincident with trichohyalin. Hair-follicle PAD has not previously been isolated. In the current study, the enzyme was isolated from wool follicles of adult sheep and peptide sequences were used to design DNA primers for the synthesis of PCR products from follicle mRNA. Subsequently, a PAD-specific complementary RNA probe and a trichohyalin complementary RNA probe were prepared for localization studies by in situ hybridization in wool follicles and the epithelia of the rumen, embryonic hoof, and tongue papillae. The experiments have revealed a striking co-expression of PAD and trichohyalin in all of these tissues. The amino acid sequence of the wool-follicle PAD molecule has been deduced from sequencing of the cloned PCR products.

Mapping of the trichohyalin gene: co-localization with the profilaggrin, involucrin, and loricrin genes

The chromosomal location of the gene encoding the human hair follicle protein trichohyalin has been determined by in situ hybridization. The human gene has been localized to the region 1q21.1-1q23 (probably 1q21.3) using a sheep trichohyalin cDNA probe. The genes encoding three other epithelial proteins, namely, profilaggrin, involucrin, and loricrin, are also located in the same region of chromosome 1, which, together with their similar gene and protein structures, suggests that the four proteins form a novel superfamily of epithelial structural proteins.

Trichohyalin: purification from porcine tongue epithelium and characterization of the native protein

Trichohyalin, a protein of Mr between 190 and 220 kDa in different species, was first demonstrated in large granules of the inner root sheath and medulla of hair follicles and may provide a matrix for keratin filaments. We have purified trichohyalin in milligram quantities from a citric acid-insoluble fraction derived from pig tongue epithelium. Trichohyalin was extracted under conditions of low ionic strength from the citric acid-insoluble fraction, separated by gel-filtration chromatography in buffer containing 1 M NaBr, and concentrated by ion-exchange chromatography in buffer containing 4 M urea. The purified material, which is soluble in buffers containing 1 M NaBr, was considered to be trichohyalin because of its characteristic molecular weight and amino acid composition and its localization to hair follicle inner root sheath and medulla by indirect immunofluorescence using antibodies against the purified protein. Immunofluorescence showed that trichohyalin is a major protein of filiform papillae of the tongue. Unlike trichohyalin from other animals examined, the porcine protein is a doublet on SDS polyacrylamide gels of 195 and 210 kDa; both bands are recognized by different antibodies, their two-dimensional peptide maps are nearly identical, and they have nearly identical isoelectric points of about 6.6. Trichohyalin has a Stokes radius of 124 A on gel filtration and a Svedberg constant of 6, consistent with an extended structure. The protein probably associates reversibly in solution, and the native protein we have isolated may be dimeric, because crosslinking of the iodinated purified protein with disuccinimidyl suberate demonstrated the presence of a dimer, which could be dissociated in the presence of high concentrations of urea. Rotary shadowing electron microscopy of the native protein showed a filamentous structure averaging 85 nm in length with a single globular-appearing end-domain. The purification of native trichohyalin provides a basis for future functional studies.

Cytochemistry of trichohyalin granules: a possible role for cornification of inner root sheath cell in the hair follicle

We studied ultracytochemically how trichohyalin granules (TGs) were involved in the cornification of the inner root sheath (IRS) cells in the hair follicle. After storing unfixed mouse skin samples in glycerol and then low ionic strength salt solution (G-LISS), the TGs reduced electron-dense amorphous material (EDM) to various degrees, with the appearance of filamentous material in routine staining. As the IRS cells were differentiating, these changes in the TGs became successively prominent; Some TGs consisted of the filamentous material and residual granular EDM, showing a "filamentogranular structure". In the cells in transition to cornified cells, or transitional cells, the EDM of the TGs disappeared and consisted of only filamentous material which was intertwined with keratin filaments (KFs). The internal substructure of the TGs induced by the G-LISS treatment stained well with ethanolic phosphotungstic acid, which reacts with basic proteins, and the KFs associated with the TGs also stained well. In skin samples not treated with G-LISS, the TGs of the transitional cells often exhibited fibrogranular structure after PTA staining to detect tissue basic proteins, suggesting a release of PTA stainable proteins(s) by the TGs in living transitional cells. The KFs of the cornified cells were more intensively stained and thicker (about 20 nm wide) than those of the differentiating IRS cells. These findings suggest that the TGs may contain at least two kinds of basic proteins; One is G-LISS-soluble, and the other is a very insoluble filamentous protein. These protein materials may be added to or incorporated into the KFs in the cornified cells with the disappearance of the TGs, since the KFs are markedly thick with PTA staining.

Trichohyalin, an intermediate filament-associated protein of the hair follicle

A precursor protein associated with the formation of the citrulline-containing intermediate filaments of the hair follicle has been isolated and characterized. The protein, with a molecular weight of 190,000, was isolated from sheep wool follicles and purified until it yielded a single band on a SDS polyacrylamide gel. The Mr 190,000 protein has a high content of lysine and glutamic acid/glutamine residues and is rich in arginine residues, some of which, it is postulated, undergo a side chain conversion in situ into citrulline residues. Polyclonal antibodies were raised to the purified protein, and these cross-react with similar proteins from extracts of guinea pig and human follicles and rat vibrissae inner root sheaths. Tissue immunochemical methods have localized the Mr 190,000 protein to the trichohyalin granules of the developing inner root sheath of the wool follicle. We propose that the old term trichohyalin be retained to describe this Mr 190,000 protein. Immunoelectron microscopy has located the Mr 190,000 protein to the trichohyalin granules but not to the newly synthesized filaments. This technique has revealed that trichohyalin becomes associated with the filaments at later stages of development. These results indicate a possible matrix role for trichohyalin.

The origin of citrulline-containing proteins in the hair follicle and the chemical nature of trichohyalin, an intracellular precursor

The present studies have demonstrated that the medulla and inner root sheath cells develop within their cytoplasm a protein that is unique in composition and is present in the trichohyalin granules. The protein is rich in arginine residues, some of which undergo a side-chain conversion in situ into citrulline residues. An unusual Ca2+-dependent enzyme activity distinguishable from cross-linking transamidase has been detected in the hair follicle and will act in vitro on trichohyalin protein as the natural substrate. The conversion in vivo must occur during the time that the medullary and inner root sheath cells move up the follicle and their cytoplasm fills with cross-linked protein containing citrulline. The function of citrulline in these proteins is not understood but its formation is a major process during hair growth.