VEGF在人胎卵巢发育过程中的表达研究

目的研究血管内皮生长因子（VEGF）在人胚胎卵巢组织发生过程中的表达特征,探讨其在卵巢发生中的作用。方法采用HE染色和SP免疫组织化法学法检测VEGF在不同胎龄卵巢组织中的表达变化。结果VEGF在胎儿卵巢初级卵母细胞、卵泡细胞、部分基质细胞呈阳性表达,在卵母细胞的染色程度均强于卵泡细胞和基质细胞,基质小血管内皮也有阳性表达。其在卵母细胞中以胎24w阳性细胞多且表达量强,此后呈逐渐下降趋势。结论胎儿卵巢存在局部调节因子,VEGF表达于人胎卵巢中,以自分泌或旁分泌方式参与卵母细胞生长,在卵巢发生、发育过程中起着一定的作用。     

Pyridoxine stimulates filaggrin production in human epidermal keratinocytes

Molecular Biology Reports - Pyridoxine (PN), one of the vitamers of vitamin B6, plays an important role in the maintenance of epidermal function and is used to treat acne and rough skin. Clinical...     

Expression of fibroblast growth factors 18 and 23 during human embryonic and fetal development

Fibroblast Growth Factor (FGF) 18 and 23 are two recently identified members of the FGF family, a family of structurally related polypeptides with diverse roles in physiological and pathological processes. Studies mostly performed in rodents and chicken have demonstrated that FGF18 is a pleiotropic growth factor involved in the development of various organs, while there are no data supporting a direct role of FGF23 in cell proliferation or differentiation either in physiology or pathology in any species. However, it is now established that FGF23 can be a humoral messenger and an important regulator of phosphate homeostasis and vitamin D metabolism. As a first step towards elucidating the roles of these FGF in human development, we examined FGF18 and FGF23 mRNA expression by in situ hybridization in whole human embryos at 30 days and 8 weeks of gestation (GW) and in specific fetal tissues at different ages. We report a highly restricted expression pattern for both FGF genes in human embryonic development.     

Expression of fucosyltransferases in skin, conjunctiva, and cornea during human development

During human development, type-1-precursor, sialyl-Le a, and Le x antigens were present in the periderm of skin and eye at week 6. The Le x antigen disappeared from cornea at 10 weeks and then from skin at 20 weeks. H-type-1, Le a, Le b, sialyl-Le a, H-type-2, sialyl-Le x, and Le y were found in cornea, conjunctiva, and periderm between 10 and 20 weeks. They disappear from the skin (at week 20) and progressively reappear in skin derivatives, especially in the epithelium of sweat glands. The secretory part of the sweat gland is type-1-precursor and H-type-1 positive while its excretory part is Le a, Le b, sialyl-Le a, and Le y positive. On the eye surface the disappearance of Le x at 10 weeks and of the H-type-1, sialyl-Le x, and Le y at week 35 starts in the central cornea in front of the lens. The corneal epithelium and the conjunctiva have similar antigens to those of excretory and secretory parts of the sweat gland, respectively. Invaginations and folding of the epidermis might preserve the embryonic staining. We propose that fucosylation patterns are associated with the embryonic origin and differentiation stage of tissue. The early and transient presence of Le x is associated with FUT4 or FUT9 activities, while the late appearance of Lewis antigens is related to other alpha3-fucosyltransferases.     

Expression of myosin light chains during fetal development of human skeletal muscle.

The expression of myosin light chains (MLCs) during the development of human skeletal muscle was investigated by using two different two-dimensional electrophoretic techniques. In both electrophoretic systems the predominant light chain 1 (LC1) expressed during the whole fetal period was found to co-migrate with the adult fast LC1 (LC1F). The main LC2 expressed during the whole fetal period was found to be different from the main fast LC2 (LC2F) and slow LC2 (LC2S) usually present in adult muscle, but co-migrated with a minor component often present in adult muscle. This fetal LC2 was phosphorylatable, and the phosphorylated form co-migrated with the main component of LC2F expressed in the adult. The adult fast LC3 appeared as early as week 20 of gestation, whereas the adult slow light chains (LC1S and LC2S) appeared only during the late fetal period. A minor component of LC1, previously described in humans as an 'embryonic LC' (LCemb.) [Strohman, Micou-Eastwood, Glass & Matsuda (1983) Science 221, 955-957], was only expressed in the early fetal period and was found to co-migrate with atrial LC1 (ALC1). We discuss the expression of these specific developmental forms of MLCs co-existing with immature myosin heavy chains during fetal life.     

Changes in gap junction distribution and connexin expression pattern during human fetal skin development.

Gap junctions are intercellular channels composed of connexin subunits that mediate cell-cell communication. The functions of gap junctions are believed to be associated with cell proliferation and differentiation and to be important in maintaining tissue homeostasis. We therefore investigated the expression of connexins (Cx)26 and 43, the two major connexins in human epidermis, and examined the formation of gap junctions during human fetal epidermal development. By immunofluorescence, Cx26 expression was observed between 49 and 96 days' estimated gestational age (EGA) but was not present from 108 days' EGA onwards. Conversely, Cx43 expression was observed from 88 days' EGA onwards. Using electron microscopy, the typical structure of gap junctions was observed from 120 days' EGA. The number of gap junctions increased over time and they were more common in the upper layers, within the periderm and intermediate keratinocyte layers rather than the basal layer. Immunoelectron microscopy revealed Cx43 labeling on the gap junction structures after 105 days' EGA. Formation of gap junctions increased as skin developed, suggesting that gap junctions may play an important role in fetal skin development. Furthermore, the changing patterns of connexin expression suggest that Cx26 is important for early fetal epidermal development.     

Interaction of filaggrin with keratin filaments during advanced stages of normal human epidermal differentiation and in Ichthyosis vulgaris

Filaggrin is a histidine-rich, basic protein whose name was first proposed based on its ability to aggregate intermediate filaments in vitro. Based on this in vitro observation, it has generally been assumed that filaggrin functions in vivo as a matrix protein which causes keratin filaments to become densely packed in the terminally differentiated cornified cells. Inconsistent with this view however, is the well-known observation that keratin aggregation appears to proceed normally in the affected epidermis of ichthyosis vulgaris patients despite a greatly reduced quantity of filaggrin. To address this issue, we used immuno-electron microscopy to localize filaggrin and its cross-reactive precursor, profilaggrin, in human and mouse epidermis, as well as in ichthyosis vulgaris epidermis. We found that the localization of filaggrin in lower cornified cells correlates precisely with the formation of aggregated keratin filaments, and the disappearance of filaggrin in upper cornified cells correlates precisely with the loosening of keratin filaments. Furthermore, we showed that, even in ichthyosis vulgaris, small amounts of filaggrin/profilaggrin are present as electron-dense deposits associated with keratin filaments in the granular cells, and that the localization of this small amount of antigen again correlates with the aggregation state of keratin filaments. These data strongly suggest that filaggrin is indeed involved in filament aggregation in vivo.     

Expression pattern of glypican-3 (GPC3) during human embryonic and fetal development

Glypicans represent a family of cell surface proteoglycans. Loss-of-function mutations in the human glypican-3 (GPC3) gene results in the Simpson-Golabi-Behmel syndrome, characterized by severe malformations and pre- and postnatal overgrowth. Because the expression of GPC3 during human embryonic and fetal periods remains largely unknown, we investigated by immunohistochemistry its pattern of expression during four periods of human development covering the embryonic period (P1) from 5 to 8 weeks of development, and the fetal periods (P2, P3 and P4) from 9 to 28 weeks of development. Hepatocytes were homogeneously positive for GPC3 during the four periods while pancreatic acini and ducts showed a rather high staining only during P1. GPC3 was also detected in several kidney structures and in the genital system where the sex cords were weakly positive in P1 and P2. In later developmental stages the male's genital system expressed GPC3 while the female's did not. While the mesenchyme in the limbs showed positive staining in P1, GPC3 was not detected during the following stages. The mesenchymal tissue localized between the most caudal vertebrae was also positive in P1. A strong GPC3 signal was observed in neurons of the spinal cord and dorsal root ganglia in P2 and P3, while the brain was negative. In sum our studies revealed that GPC3 expression is highly tissue- and stage-specific during human development. The expression pattern of GPC3 is consistent with the abnormalities seen in the Simpson-Golabi-Behmel syndrome.     

Diseases of epidermal keratins and their linker proteins

Epidermal keratins, a diverse group of structural proteins, form intermediate filament networks responsible for the structural integrity of keratinocytes. The networks extend from the nucleus of the epidermal cells to the plasma membrane where the keratins attach to linker proteins which are part of desmosomal and hemidesmosomal attachment complexes. The expression of specific keratin genes is regulated by differentiation of the epidermal cells within the stratifying squamous epithelium. Progress in molecular characterization of the epidermal keratins and their linker proteins has formed the basis to identify mutations which are associated with distinct cutaneous manifestations in patients with genodermatoses. The precise phenotype of each disease apparently reflects the spatial level of expression of the mutated genes, as well as the types and positions of the mutations and their consequences at mRNA and protein levels. Identification of specific mutations in keratinization disorders has provided the basis for improved diagnosis and subclassification with prognostic implications and has formed the platform for prenatal testing and preimplantation genetic diagnosis. Finally, precise knowledge of the mutations is a prerequisite for development of gene therapy approaches to counteract, and potentially cure, these often devastating and currently intractable diseases.     

Expression of filaggrin-2 protein in the epidermis of human skin diseases: A comparative analysis with filaggrin

Filaggrin-2 is a member of the S100 fused-type protein family, and the structural features and expression of filaggrin-2 are similar to those of profilaggrin, a protein essential for keratinization. In the present study, we investigated the expression profile of filaggrin-2 in patients with skin diseases using antibodies against the repetitive region of filaggrin-2. In tissue samples from patients with skin diseases which are associated with a decrease in filaggrin, including ichthyosis vulgaris, atopic dermatitis and psoriasis vulgaris, the expression level of filaggrin-2 was markedly decreased compared to that in normal skin samples. In contrast, the expression of filaggrin-2 increased in parallel with that of filaggrin in samples of tissue from patients with skin diseases associated with hyperkeratosis, such as lichen planus and epidermolytic ichthyosis. Interestingly, filaggrin-2 signals were observed in slightly higher layers of the epidermis in comparison to those of filaggrin. Similarly, the expression of filaggrin-2 proteins was induced slightly later than filaggrin in the cultured keratinocytes. These findings suggest that filaggrin-2 may play an overlapping role with filaggrin in epithelial cornification; however, it may also have a partially distinct role in the molecular processes of cornification.     

Non-invasive proteomic analysis of human skin keratins: screening of methionine oxidation in keratins by mass spectrometry

Keratins are the main constituent of human skin and have been identified as major oxidative target proteins. However, there has been a lack of studies aimed at identifying the oxidation sites of keratins because of the difficulties associated with their insolubility and handling. Here, we introduce a mass spectrometry (MS)-based proteomic methodology to screen oxidative modifications in human skin keratins. Human skin proteins were obtained non-invasively by tape stripping and solubilized in SDS buffer, followed by purification and digestion using the modified filter-aided sample preparation method. The tryptic peptides were then analyzed by MALDI-TOF/MS, LC-ESI/MS, and MS/MS. PMF analyses have identified keratins K1 and K10 as the major proteins of human skin. Met(259), Met(262), Met(296), and Met(469), located in the α-helical rod domain of K1, were the most susceptible sites to oxidation induced by hydrogen peroxide in vitro and in vivo. Our results indicate a potential use of the identified methionine residues as biomarkers of oxidative skin damage. The present methodology is the first MS-based approach to detecting oxidative modifications in keratins obtained directly from human skin and can be easily applied to the monitoring of other keratin modifications in various skin conditions.     

The characterization of human epidermal filaggrin. A histidine-rich, keratin filament-aggregating protein

Filaggrin is a histidine-rich, cationic protein that aggregates with keratin filaments in vitro and may function as the keratin matrix protein in the terminally differentiated cells of the epidermis. This protein has been previously isolated from rodent epidermis. In this investigation, a similar protein from human skin was identified, isolated and characterized by biochemical and immunologic techniques. Indirect immunofluorescence of human skin using antiserum to rat filaggrin gave positive immunofluorescence of keratohyalin granules and the stratum corneum. This indicated the presence of a human filaggrin in the epidermis in a localization similar to that of the rodent. The protein was isolated from human epidermis and purified by ion-exchange chromatography and preparative gel electrophoresis. The purified protein crossreacts with antibody to rat filaggrin and migrates as a doublet of molecular weight (Mr) approximately 35 000 on SDS-polyacrylamide gels. It is relatively rich in polar amino acids such as histidine, arginine, serine and glycine, but is poor in nonpolar amino acids. Unlike rodent filaggrin, the human protein contains ornithine. This protein aggregates with human keratin filaments, forming compact macrofibrils in a manner analogous to that of rodent filaggrin. Thus, a human epidermal protein has been isolated which has many of the characteristics of rodent filaggrin and may function as the human keratin matrix protein.     

Lessons from disorders of epidermal differentiation-associated keratins

A number of diseases have been associated with mutations in genes encoding keratin intermediate filaments. Several of these disorders have skin manifestations, in which histological changes highlight the role of various different keratins in epidermal differentiation. For example, mutations in either K1 or K10 (the major keratin pair expressed in differentiated keratinocytes) usually lead to clumped keratin filaments and cytolysis. Furthermore, the precise nature of the mutation has direct implications for disease phenotype. Specifically, mutations in the H1 and alpha-helical rod domains of K1/K10 result in bullous congenital ichthyosiform erythroderma, underscoring the critical role for this keratin filament domain in maintaining cellular integrity. However, a lysine to isoleucine substitution in the V1 domain of K1 underlies a form of palmoplantar keratoderma, which has different cell biological implications. Keratins are cross-linked into the cornified cell envelopes through this particular lysine residue and the consequences of the mutation lead to changes in keratin-desmosome association and cornified cell morphology, suggesting a role for this keratin subdomain in cornified cell envelope formation. Recently, to extend genotype-phenotype correlation, a frameshift mutation in the V2 region of the K1 tail domain was identified in ichthyosis hystrix (Curth-Macklin type), in which keratin filaments show a characteristic shell-like structure and fail to form proper bundles. In this case, the association of desmosomes with loricrin was also altered, implicating this keratin domain in organizing the intracellular distribution of loricrin during cornification. Collectively, these mutations in K1/K10 provide a fascinating insight into both normal and abnormal processes of epidermal differentiation.     

Expression of the HB9 homeobox gene concomitant with proliferation accompanying epidermal stratification during development of chick embryonic tarsometatarsal skin

A homeobox gene, HB9, has been isolated from the tarsometatarsal skin of 13-day-old chick embryos using a degenerate RT-PCR-based screening method. In situ hybridization analysis revealed that, during development of chick embryonic skin, the HB9 gene was expressed in epidermal basal cells of the placodes, but not in those of interplacodes, and in the dermal cells under the placodes at 9 days before addition of an intermediate layer by proliferation of the basal cells in the placodes. With the onset of epidermal stratification, the direction of the basal cell mitosis changed, with the axis becoming vertical to the epidermal surface. Placodes and interplacodes form outer and inner scales, respectively, after they have elongated distally (Tanaka S, Kato Y (1983b) J Exp Zool 225: 271–283). During scale ridge elongation at 12–15 days, HB9 was strongly expressed in the epidermis of the outer scale face, where the cell proliferation is more active than in the epidermis of the inner scale face; hence, stratification of the outer scale face is more prominent than that of the inner scale face. After 16 days, when mitotic activity in the epidermal basal cells decreases and the thickness of the epidermis is maintained at a constant level, the HB9 expression decreases with the onset of epidermal keratinization. These results suggest that HB9 may be involved in the proliferation of the epidermal basal cells that accompanies epidermal stratification.     

Regulated expression of differentiation-associated keratins in cultured epidermal cells detected by monospecific antibodies to unique peptides of mouse epidermal keratins

Monospecific antibodies to mouse epidermal keratins were generated in rabbits and guinea pigs by injecting synthetic peptides of unique keratin sequences. The sequences were deduced from nucleotide sequences of cDNA clones representing basal (K14) and suprabasal (K1 and K10) cell-specific and hyperproliferative (K6) keratins of both the type-I and type-II subclasses. By applying single-and double-label immunofluorescence analysis, the expression of keratin peptides was analyzed in cultured keratinocytes maintained in the basal or suprabasal cell phenotypes. These cell types were selected by growth in medium containing 0.05 mM Ca2+ (basal cell) or 1.4 mM Ca2+ (suprabasal cell). The cultured basal cells expressed K6 and K14, but less than 1% expressed K1 and K10. Within a few hours after being placed in 1.4 mM Ca2+, K1 expression was observed, and by 24 h, 10%-17% of the cells expressed K1. K10 expression appeared to lag behind K1 expression, with only 5%-10% of cells in 1.4 mM Ca2+ exhibiting K10 immunoreactivity. Double-labeling studies indicated that virtually all K10-positive cells also expressed K1, while only about one-half of the K1-positive cells expressed K10. The treatment of basal cells with retinoic acid at pharmacological concentrations prevented the expression of K1 and K10 when cells were challenged by 1.4 mM Ca2+. Similarly, the introduction of the v-rasH oncogene into basal cells by a defective retroviral vector prevented the expression of suprabasal keratins in 1.4 mM Ca2+ medium.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interactions of organophosphates with keratins in the cornified epithelium of human skin

Methods to unequivocally assess and quantify exposure to organophosphate anti-cholinesterase agents are highly valuable, either from a biomonitoring or a forensic perspective. Since for both OP pesticides and various nerve agents the skin is a predominant route of entry, we hypothesized that proteins in the skin might represent an ideal source of unequivocal and persistent biomarkers for exposure to these compounds. In this exploratory study we show that keratin proteins in human skin are relevant binding sites for organophosphates. The thick cornified epithelium of human plantar skin (callus) was exposed to a selection of relevant organophosphorus compounds and keratin proteins were subsequently extracted. After carboxymethylation of cysteine residues, enzymatic digestion of the keratins with pronase and trypsin was performed and the resulting amino acid and peptides were analyzed to assess whether covalent adducts had formed. LC-tandem MS analysis of the pronase digests demonstrated that tyrosine and to a lesser extent serine residues were selectively modified by organophosphate pesticides (both phosphorothioates and the corresponding oxon forms) under physiological conditions. In addition, modification of tyrosine with the nerve agent VX was unequivocally assessed. In order to elucidate specific binding sites, LC-tandem MS analysis of trypsin digests showed two separate tryptic keratin fragments, i.e. LASY*LDK and SLY*GLGGSK, with Y* the modified tyrosine residues, originating from keratin 1/6 and keratin 10, respectively. These preliminary findings, revealing novel binding targets for anti-cholinesterase organophosphates, will form a firm basis for the development of novel (non-invasive) methods for assessment of exposure to organophosphates. Whether this binding will also have biological implications remains an issue for further investigations.