Fine structure and immunocytochemistry of monotreme hairs, with emphasis on the inner root sheath and trichohyalin-based cornification during hair evolution

The fine structure of hairs in the most ancient extant mammals, the monotremes, is not known. The present study analyzes the ultrastructure and immunocytochemistry for keratins, trichohyalin, and transglutaminase in monotreme hairs and compares their distribution with that present in hairs of the other mammals. The overall ultrastructure of the hair and the distribution of keratins is similar to that of marsupial and placental hairs. Acidic and basic keratins mostly localize in the outer root sheath. The inner root sheath (IRS) comprises 4-8 cell layers in most hairs and forms a tile-like sheath around the hair shaft. No cytological distinction between the Henle and Huxley layers is seen as cells become cornified about at the same time. Externally to the last cornified IRS cells (homologous to the Henle layer), the companion layer contains numerous bundles of keratin. Occasionally, some granules in the companion layer show immunoreactivity for the trichohyalin antibody. This further suggests that the IRS in monotremes is ill-defined, as the companion layer of placental hairs studied so far does not express trichohyalin. A cross-reactivity with an antibody against sheep trichohyalin is present in the IRS of monotremes, suggesting conserved epitopes across mammalian trichohyalin. Trichohyalin granules in the IRS consist of a framework of immunolabeled coarse filaments of 10-12 nm. The latter assume a parallel orientation and lose the immunoreactivity in fully cornified cells. Transglutaminase immunolabeling is diffuse among trichohyalin granules and among the parallel 10-12 nm filaments of maturing inner root cells. Transglutaminase is present where its substrate, trichohyalin, is modified as matrix protein. Cornification of IRS is different from that of hair fiber cuticle and from that of the cornified layer of the epidermis above the follicle. The different consistency among cuticle, IRS, and corneous layer of the epidermis determines separation between hair fiber, IRS, and epidermis. This allows the hair to exit on the epidermal surface after shedding from the IRS and epidermis. Based on comparative studies of reptilian and mammalian skin, a speculative hypothesis on the evolution of the IRS and hairs from the skin of synapsid reptiles is presented.     

Fine structure of marsupial hairs, with emphasis on trichohyalin and the structure of the inner root sheath

The fine structure and cornification of marsupial hairs are unknown. The distribution of keratins, trichohyalin, and transglutaminase in marsupial hairs was studied here for the first time by electron microscopy and immunocytochemistry. The localization of acidic and basic keratins in marsupial hairs is similar to that of hairs in placental mammals, and the keratins are mainly localized in the outer root sheath and surrounding epidermis. Marsupial trichohyalin in both medulla and inner root sheath (IRS) cross-reacts with a trichohyalin antibody that recognizes trichohyalin across placental species, indicating a common epitope(s) among mammalian trichohyalin. Roundish to irregular trichohyalin granules are composed of a network of immunolabeled 10-15-nm-thick coarse filaments within an amorphous matrix in which a weak labeling for transglutaminases is present. This suggests that the enzyme, and its substrate trichohyalin, are associated in mature granules. Transglutaminase labeling mainly occurs in condensing chromatin of mature cells of the outer and inner root sheaths, suggesting formation of the nuclear envelope connected with terminal differentiation of these cells. In mature Huxley or Henle layers the filaments lose the immunolabeling for trichohyalin when they are reoriented into parallel rows linked by short bridges, thus suggesting that the filaments with their reactive epitopes are chemically modified during cornification, as seen in the IRS of hairs of placental mammals. The Huxley layer probably acts as a cushion, absorbing the tensions connected with the distalward movement of the growing hair fiber. Variations in stratification of the Huxley layer are probably related to the diameter of the hair shaft. The cytoplasmic and junctional connections between cells of the Huxley layer and the companion layer and the outer root sheath enhance the grip of the IRS and hair fiber within the follicle. The role of cells of the IRS in sculpturing the fiber cuticle and in the mechanism of shedding that allows the exit of hair on the epidermal surface in mammals are discussed.     

Hr突变体转基因小鼠的构建和表型分析

无毛基因（Hr）定位于8p12,在染色体上跨越14 kb,包含19个外显子。无毛基因的自发突变能引起人和动物毛发脱落及相关毛发疾病的产生。为深入研究Hr基因的功能,本文利用Gateway技术构建Hr表达载体,在该基因的3 427位引入点突变(G→A),通过显微注射建立转基因小鼠。采用PCR方法鉴定出阳性的转基因小鼠,确定首建鼠,通过与C57BL/6小鼠回交后互交数代建系。观察转基因小鼠毛发生长发育规律。结果表明,成功构建了pRP(Exp)-EF1A>mHairless mutant>IRES/EGFP真核表达载体,通过与野生型小鼠杂交获得阳性子代,进行同窝交配,第2代小鼠出生后14 d开始脱发,30 d左右脱落的毛发重新长出。取部分皮肤组织做石蜡切片,皮肤组织学观察发现,脱毛期无毛小鼠毛囊瓦解,真皮内形成大小不等的包囊,毛发重新生长时,真皮内见大量新生的毛囊。蛋白印迹实验表明,转基因小鼠脱发时HR蛋白表达量明显高于同龄阴性小鼠。本文成功建立稳定遗传的Hr突变的转基因小鼠品系,推测无毛基因突变引发转基因小鼠的脱发,为研究Hr基因的功能提供了良好的动物模型。     

The catalog of human hair keratins. II. Expression of the six type II members in the hair follicle and the combined catalog of human type I and II keratins.

The human type II hair keratin subfamily consists of six individual members and can be divided into two groups. The group A members hHb1, hHb3, and hHb6 are structurally related, whereas group C members hHb2, hHb4, and hHb5 are rather distinct. Specific antisera against the individual hair keratins were used to establish the two-dimensional catalog of human type II hair keratins. In this catalog, hHb5 showed up as a series of isoelectric variants, well separated from a lower, more acidic, and complex protein streak containing isoelectric variants of hair keratins hHb1, hHb2, hHb3, and hHb6. Both in situ hybridization and immunohistochemistry on anagen hair follicles showed that hHb5 and hHb2 defined early stages of hair differentiation in the matrix (hHb5) and cuticle (hHb5 and hHb2), respectively. Although cuticular differentiation proceeded without the expression of further type II hair keratins, cortex cells simultaneously expressed hHb1, hHb3, and hHb6 at an advanced stage of differentiation. In contrast, hHb4, which is undetectable in hair follicle extracts and sections, could be identified as the largest and most alkaline member of this subfamily in cytoskeletal extracts of dorsal tongue. This hair keratin was localized in the posterior compartment of the tongue filiform papillae. Comparative analysis of type II with the previously published type I hair keratin expression profiles suggested specific, but more likely, random keratin-pairing principles during trichocyte differentiation. Finally, by combining the previously published type I hair keratin catalog with the type II hair keratin catalog and integrating both into the existing catalog of human epithelial keratins, we present a two-dimensional compilation of the presently known human keratins.     

The catalog of human hair keratins. I. Expression of the nine type I members in the hair follicle.

The human type I hair keratin subfamily comprises nine individual members, which can be subdivided into three groups. Group A (hHa1, hHa3-I, hHa3-II, hHa4) and B (hHa7, hHa8) each contains structurally related hair keratins, whereas group C members hHa2, hHa5, and hHa6 represent structurally rather unrelated hair keratins. Antibodies produced against these individual hair keratins, first analyzed for specificity by one- dimensional Western blots of total hair keratins, were used to establish the two-dimensional catalog of the human type I hair keratin subfamily. The catalog comprises two different series of type I hair keratins: a strongly expressed, Coomassie-stainable series containing hair keratins hHa1, hHa3-I/II, hHa4, and hHa5, and a weakly expressed, immunodetectable series harboring hHa2, hHa6 hHa7, and hHa8. In situ hybridization and immunohistochemical expression studies on scalp follicles show that two hair keratins, hHa2 and hHa5, define the early stage of hair differentiation, i.e. hHa5 expression in hair matrix and hHa5/hHa2 coexpression in the early hair cuticle cells. Whereas cuticular differentiation proceeds without the expression of further type I hair keratins, matrix cells embark on the cortical pathway by sequentially expressing hHa1, hHa3-I/II, and hHa4, which are supplemented by hHa6 at an advanced stage of cortical differentiation, and hHa8, which is expressed heterogeneously in cortex cells. Thus, six type I hair keratins are involved in the terminal differentiation of anagen hairs. The expression of hHa7 is conspicuously different from that of the other hair keratins in that it does not occur in the large anagen follicles of terminal scalp hairs but only in central cortex cells of the rare and small follicle type that gives rise to vellus hairs.     

常见毛囊细胞角蛋白在毛囊周期中的表达研究

目的探讨常见毛囊细胞角蛋白在毛囊周期中的表达特征。 方法取毛囊发育期、生长期启动、生长期、退化期和静止期的小鼠皮肤,石蜡切片后通过免疫荧光的方法,检测细胞角蛋白Krt5、Krt6、Krt10、Krt14、Krt15和Krt19的表达情况。 结果Krt5在静止期和生长期启动表达于所有毛囊上皮细胞,在其他时期表达不一致;Krt6表达于所有时期的外根鞘细胞和内根鞘细胞;Krt10表达于生长期和退化期的毛母质和内根鞘细胞,在其他时期表达不一致;Krt14在生长期和退化期表达于所有毛囊上皮细胞,在其他时期表达不一致;Krt15和Krt19表达于毛囊发育期、生长期启动和静止期的毛囊隆突区细胞,在生长期和退化期表达不一致。 结论角蛋白作为毛囊结构或毛囊干细胞标记物仅适用于特定的毛囊周期。研究者在使用毛囊角蛋白作为标记物时,应首先明确其在毛囊周期中的表达情况。     

Keratins of the human hair follicle: "Hyperproliferative''keratins consistently expressed in outer root sheath cells in vivo and in vitro

Keratins produced by morphologically distinct compartments of the human hair folicle (hHF) were analysed and compared to those produced by cultured hHF and interfollicular keratinocytes. Five of the major keratins, the basic keratins nos. 5 and 6 (apparent mol. mass 60 and 58 kDa) and the acidic keratins nos. 14, 16, and 17 (51, 49 and 48 kDa), could be labelled in intact hHF and were found in all fractions of the outer root sheath (ORS). The other major keratins, which were not labelled under these conditions (basic-neutral hHbI and -II; 60-62 kDa and acidic hHaI and -II; 40-42 kDa) were associated with hair shaft (hHS) both in the follicle and, virtually unchanged, in the distal part of the hair. Another, previously undescribed, group of proteins with keratin-like properties exhibiting a broad pI-spectrum (basic to slightly acidic: hIC-I, -II, -III, 64-67 kDa; distinctly acidic: hIC-IV, about 54 kDa) was detected in isolated inner root sheath (IRS), in the cuticular material shed from denuded hHS, and also in nail plates. In our experiments only ORS cells grew readily in culture irrespective of their origin from peripheral (mesenchyme-adjacent) or more central ORS-cell layers. In contrast to keratinocytes from interfollicular epidermis (IFE) the cultured ORS cells expressed a keratin set virtually identical to that expressed in vivo. This set also closely resembled that expressed by IFE keratinocyte cultures. The identity of the respective keratins (nos. 5, 6, 14, 16, and 17) present in all these cells in vivo and in vitro was confirmed by tryptic peptide mapping. The data indicated that the microenvironment (in situ) directs the differentiation of ORS cells in a manner comparable to the way it is directed by conventional culture conditions, with consistent expression of the "basal" and "hyperproliferative" set of keratins. This, however, does not exclude the possibility that other types of environmentally induced response may occur, as seen for example during the reepithelialization of superficial skin wounds by ORS cells.     

Hairless and Wnt Signaling: Allies in Epithelial Stem Cell Differentiation

Nuclear receptors and Wnt signaling are both important regulators of developmental and physiological processes. Recent work linking these pathways in epithelial stem cell differentiation has come from studies analyzing the in vivo function of the nuclear receptor corepressor, Hairless (HR). The HR protein has long been suspected to regulate a stem cell-mediated process, hair cycling, as mutations in the Hr gene cause hair loss in both mice and men. The discovery that the HR protein is a nuclear receptor corepressor indicated that HR function in hair cycling is by regulating gene expression. A recent study revealed that HR represses expression of Wise, an inhibitor of Wnt signaling, leading to a model in which HR controls the timing of Wnt signaling required for hair cycling. Here we review these data, and provide new data showing that HR corepressor activity is essential for its in vivo function, and identify an additional putative Wnt inhibitor regulated by HR. This work complements previous studies demonstrating the role of Wnt signaling in epithelial stem cell differentiation.     

LPA-producing enzyme PA-PLA₁α regulates hair follicle development by modulating EGFR signalling

Recent genetic studies of human hair disorders have suggested a critical role of lysophosphatidic acid (LPA) signalling in hair follicle development, mediated by an LPA-producing enzyme, phosphatidic acid-selective phospholipase A(1)α (PA-PLA(1)α, also known as LIPH), and a recently identified LPA receptor, P2Y5 (also known as LPA(6)). However, the underlying molecular mechanism is unknown. Here, we show that epidermal growth factor receptor (EGFR) signalling underlies LPA-induced hair follicle development. PA-PLA(1)α-deficient mice generated in this study exhibited wavy hairs due to the aberrant formation of the inner root sheath (IRS) in hair follicles, which resembled mutant mice defective in tumour necrosis factor α converting enzyme (TACE), transforming growth factor α (TGFα) and EGFR. PA-PLA(1)α was co-localized with TACE, TGFα and tyrosine-phosphorylated EGFR in the IRS. In PA-PLA(1)α-deficient hair follicles, cleaved TGFα and tyrosine-phosphorylated EGFR, as well as LPA, were significantly reduced. LPA, P2Y5 agonists and recombinant PA-PLA(1)α enzyme induced P2Y5- and TACE-mediated ectodomain shedding of TGFα through G12/13 pathway and consequent EGFR transactivation in vitro. These data demonstrate that a PA-PLA(1)α-LPA-P2Y5 axis regulates differentiation and maturation of hair follicles via a TACE-TGFα-EGFR pathway, thus underscoring the physiological importance of LPA-induced EGFR transactivation.