江豚表皮超微结构的研究

本文用透射电镜和扫描电镜对捕自莱州湾的两头江豚表皮的超微结构作了观察。见其表皮中MCG的板层结构与海豚的有所不同,MCG内容物排出到细胞间隙形成表皮屏障。其黑素颗粒可能通过黑素细胞的突起与角蛋白细胞相接触处胞膜的消失出现缺口的方式输入角蛋白细胞。并对江豚表皮的不全角化现象等问题进行了讨论。     

大鼠小肠5-HT免疫活性内分泌细胞的角蛋白免疫细胞化学定位

本文作者用免疫组化双色反应,对大鼠小肠5-HT免疫活性内分泌细胞进行表皮角蛋白免疫细胞化学定位。结果表明,5-HT免疫活性内分泌细胞含有表皮角蛋白阳性颗粒,提示胃肠的正常内分泌细胞和其它粘膜上皮细胞一样含有角蛋白中间丝,它们可能也和其它粘膜上皮细胸一样共同起源于内胚层。     

角蛋白酵解工艺研究进展

角蛋白是构成人和动物生皮表皮、毛皮毛囊的主要蛋白质,是结缔组织重要的结构蛋白。以畜禽副产物作为角蛋白开发的原材料,比较传统物理和化学方法与微生物发酵的优缺点,综述了微生物发酵角蛋白的优势菌株及现今的运用价值,旨在为今后研究角蛋白提取工艺和对其进行高附加值利用提供参考。     

人表皮生长因子基因的化学合成和克隆及其在酵母中的表达

用固相亚磷酰胺法合成了人表皮生长因子基因,全长为173个核苷酸,它被分成8个寡核苷酸,分别在DNA合成仪上合成。经分离纯化后的寡聚核苷酸进行酶促连接,然后被克隆到噬菌体M13mpl8中,克隆经分子杂交、限制酶酶切以及DNA序列分析检测,证明合成的人表皮生长因子基因和设计的完全一致。将人表皮生长因子基因的DNA片段插入酵母分泌型表达载休YFD59 HindⅢ位点中,建成表达人表皮生长因子基因的质粒YFDl04,再将此质粒转化酿酒酵母,所得转化子经摇瓶发酵,发酵上清液用受体结合试验表明有人表皮生长因子表达。     

重组人表皮生长因子的研究概况

人表皮生长因子又称尿抑胃素,是存在于人体内的一种重要的多肽生长因子。它是在1975年由Cohen等和Gregory各自独立地从人尿液中分离得到的,并被分别命名为“人表皮生长因子(Human Epidermal Growth Factor, hEGF)”和“尿抑胃素(Urogastrone, UG)”。后来的研究证明两者实为同一物质,遂将其名称统一为“人表皮生长因子”。     

人发角蛋白人工腱材料体内降解及生物相容性研究

目的研究人发角蛋白人工腱(humanhairkeratinartificaltendon,HHKAT)材料在体内的可降解性及其生物相容性.方法对12只日本大耳白兔随机分组,在脊旁肌埋藏不同处理时间的人发角蛋白人工腱试件F及Z,用正常人发O做对照,分别在2、6、12、24周取材,观察人发角蛋白的降解吸收过程及其周围的组织反应.结果动物植入实验中发现不同时间处理的材料其降解速度不同,其中降解最快的F组在24周已完全吸收,而Z组在24周只有部分降解,O组未见降解.HHKAT及人发在肌肉组织内无明显的炎症排斥反应,随着HHKAT材料的降解吸收,其周围的组织反应逐渐降低.结论本研究表明人发角蛋白人工腱材料具有良好的生物相容性,在体内能够被降解吸收,可根据不同的需要调节其降解速度,是良好的肌腱替代材料.     

中等纤维在几种人体上皮细胞有丝分裂过程中的行为

本文用间接免疫荧光法和电镜术观察了分别来自人表皮(PcaSE-1)、复层上皮(CNE)和单层上皮(SPC-A-1)的3个上皮细胞系的细胞在有丝分裂过程中中等纤维的行为。结果表明,CNE细胞和SPC-A-1细胞表达两种不同类型的中等纤维系统:角蛋白纤维和波形纤维,而PcaSE-1细胞仅表达角蛋白纤维。当细胞进入有丝分裂时,PcaSE-1细胞的角蛋白纤维维持完整的形态且将有丝分裂纺锤体围绕在细胞中央。相反,在CNE细胞和SPC-A-1细胞中,在细胞有丝分裂时,角蛋白纤维解聚成无定形的胞质小体,然而它们的波形纤维始终保持完整的形态。我们认为(1)在分裂上皮细胞中,角蛋白纤维的解聚与细胞的恶性程度有关,而与间期上皮细胞中是否含有丰富的角蛋白纤维无明显关系。(2)在上皮细胞有丝分裂时,中等纤维可能参于纺锤体的定位和趋中。(3)在分裂CNE细胞中,波形纤维的可能功能是染色体的定位和定向。     

角蛋白纤维的新功能--在爪蟾卵提取物核膜重组装中的作用

激活的非洲爪蟾卵提取物温育过程中,直径２００ｎｍ的膜泡附着在一种直径１０ｎｍ纤维上,形成“珠链”结构。用透射电镜整装制样技术观察了温育中“珠链”结构的形成过程,发现１０ｎｍ纤维可抗Ｔｒｉｔｏｎ抽提,免疫荧光和蛋白免疫印迹试验表明１０ｎｍ纤维可能是由５６ｋＤ的碱性角蛋白与４２ｋＤ的酸性角蛋白构成。向提取物中加入碱性角蛋白抗体ＡＥ３则可抑制环状片层的形成,而核膜的组装也受到很大影响。这些结果显示角蛋白     

动物的毛与人发角蛋白组分的比较研究

本文用SDS-聚丙烯酰胺凝胶电泳(SDS-PAGE)对10科18种50份动物毛与人发进行了角蛋白组分分析。结果证实,动物的毛与人发角蛋白组分的主要差异在<18.500低分子量区域;不同种属的动物毛角蛋白组分也存在明显差异;大熊猫毛的角蛋白组分与小熊猫和黑熊的相比有显著不同。不同种属动物毛角蛋白组分的差异对动物分类学研究能提供有参考价值的实验依据。     

恒河猴皮肤干细胞的体外培养纯化与鉴定

探索恒河猴皮肤干细胞的体外培养及纯化条件,为进一步的研究奠定基础. 通过组织块培养法和消化培养法 在体外培养恒河猴表皮细胞,然后用Ⅳ型胶原吸附法吸附20 min,获得快吸附细胞. 对快吸附细胞进行克隆培养,并进行免疫细胞化学双标染色、RT PCR鉴定 β1 整合素和角蛋白15的表达,用流式细胞仪鉴定纯化前后的细胞中 β1 整合素和角蛋白15的阳性细胞比例,并通过透射电镜观察细胞的超微结构. 组织块培养法和消化培养法均可获得表皮细胞,Ⅳ型胶原纯化后的细胞胞体较小,饱满,核/浆比例大,细胞镶嵌状排列. 细胞克隆分析显示,细胞全克隆生长率高. 细胞免疫荧光显示,分选后的细胞显示 β1 整合素和角蛋白15阳性. RT PCR检查呈现 β1 整合素和角蛋白15的特异性片段. 流式细胞仪检查显示,纯化前的细胞中角蛋白15阳性细胞占总细胞中的比例为8％, β1 整合素阳性细胞的比例为10.7％;纯化后,角蛋白15阳性细胞的比例为89.4％, β1 整合素阳性细胞的比例为88.5％. 通过组织块培养法和消化培养法均可培养获得活性良好的表皮细胞,Ⅳ型胶原吸附法是一种简便、有效的皮肤干细胞分离方法,可以为进一步的眼表上皮替代重建眼表提供足量的高纯度的干细胞建立可靠的物质基础.     

一种新的抗人角蛋白单克隆抗体

In this paper, we reported a novel monoclonal antibody against human keratins, R 6-2-14. The antigen used for immunization was derived from human callus, keratins in which traditionally are classified as "Soft" keratins. However, when we studied the tissue specificity of this antibody, it was found that it only reacted strongly with "Hard" keratins of various mammalian species, but no detectable cross-reactivity with any of the "Soft" keratins. This antibody may provide a useful tool for the study of hair regeneration, nail regeneration, corn pathology and differentiation of mammalian epidermal derivatives.     

Expression of hair-related keratins in a soft epithelium: subpopulations of human and mouse dorsal tongue keratinocytes express keratin markers for hair-, skin- and esophageal-types of differentiation

The dorsal surfaces of mammalian tongues are covered with numerous projections known as filiform papillae whose morphology varies in different species. Using a panel of monoclonal antibodies to keratins as probes, we have established that, in both human and mouse, the interpapillary epithelia express mainly the "esophageal-type" keratins, while the papillary epithelia express "skin-type" keratins as well as some keratins reacting with a monoclonal antibody (AE13) to hair keratins. The AE13-reactive proteins of the mouse were found to be very similar to those of authentic mouse hair keratins. However, the corresponding protein of human tongue appears to be different from all known human keratins. This protein has a MW of 51K; it is relatively acidic; it is sulfhydryl-rich, as revealed by iodoacetic acid-induced charge and apparent size shift; it shares an epitope with all the known acidic human hair keratins; and it is associated with keratin fibrils in vivo. This protein may therefore be regarded as a novel type I "hard" keratin. These data establish that mammalian dorsal tongue epithelia can be divided into at least three compartments that undergo mainly "esophageal-", "skin-" and "hair"-types of differentiation. Different keratin filaments, e.g., those of the esophageal- and hair-types, exhibit strikingly different degrees of lateral aggregation, which can potentially account for the different physical strength and rigidity of various cellular compartments. Our data also suggest the possibility that variations in papillary structure in human and mouse may arise from different spatial arrangements of specific keratinocytes, and/or from the expression of specialized hair-related keratins.     

The use of aIF, AE1, and AE3 monoclonal antibodies for the identification and classification of mammalian epithelial keratins

Recent data have indicated that specific keratin molecules can provide useful markers for studying different types and stages of epithelial differentiation. To utilize these protein markers, however, it is important to establish the keratin nature of the molecules and identify unambiguously the individual keratin species. In this paper, we show that this can be done relatively easily by one- and two-dimensional gel electrophoresis combined with immunoblotting using three monoclonal antibodies (aIF, AE1, and AE3). The aIF antibody has previously been shown to crossreact with all classes of intermediate-filament proteins. Using one- and two-dimensional immunoblotting, we establish that this antibody recognizes all known epithelial keratins of human and rabbit, although the reaction is relatively strong for the larger, basic keratins and is relatively weak for some of the smaller, acidic keratins. In contrast, AE1 and AE3 monoclonal antibodies have previously been shown to be highly specific for the acidic and basic subfamilies of the keratins, respectively. The combined use of the broadly reacting aIF antibody and the subfamily-specific AE1 and AE3 monoclonal antikeratin antibodies should facilitate the immunological definition, identification, and classification of mammalian epithelial keratins.     

Distribution and characterization of keratins in the epidermis of the tuatara (Sphenodon punctatus; Lepidosauria, Reptilia)

Reptilian scales are mainly composed of alpha-and beta-keratins. Epidermis and molts from adult individuals of an ancient reptilian species, the tuatara (Sphenodon punctatus), were analysed by immunocytochemistry, mono- and bi-dimensional electrophoresis, and western blotting for alpha- and beta-keratins. The epidermis of this reptilian species with primitive anatomical traits should represent one of the more ancient amniotic epidermises available. Soft keratins (AE1- and AE3-positive) of 40-63 kDa and with isoelectric points (pI) at 4.0-6.8 were found in molts. The AE3 antibody was diffusely localised over the tonofilaments of keratinocytes. The lack of basic cytokeratins may be due to keratin alteration in molts, following corneification or enzymatic degradation of keratins. Hard (beta-) keratins of 16-18 kDa and pI at 6.8, 8.0, and 9.2 were identified using a beta-1 antibody produced against chick scale beta-keratin. The antibody also labeled filaments of beta-cells and of the mature, compact beta-layer. We have shown that beta-keratins in the tuatara resemble those of lizards and snakes, and that they are mainly basic proteins. These proteins replace cytokeratins in the pre-corneoum beta-layers, from which a hard, mechanically resistant corneoum layer is formed over scales. Beta-keratins may have both a fibrous and a matrix role in forming the hard texture of corneoum scales in this ancient species, as well as in more recently evolved reptiles.     

Monoclonal antibody analysis of bovine epithelial keratins. Specific pairs as defined by coexpression

We have characterized the keratin proteins of various bovine epithelial tissues by one- and two-dimensional gel electrophoresis, coupled with the immunoblot technique using AE1, AE2, AE3, AE5, CA20, BE14, and 6.11 monoclonal antikeratin antibodies. The results indicate that all known bovine keratins can be divided into two subfamilies. The "acidic" (Type I) subfamily consists of 41-, 43-, 45-, 46-, 50-, 54-, 56-, and 56.5-kDa keratins, all of which have a pI of less than 5.6, and most of them are recognized by our AE1 antibody, whereas the "neutral-to-basic" (Type II) subfamily consists of 55-, 57-, 58-, 62-65-, 66-, and 67-kDa keratins, all of which have a pI of greater than 6.0 and are recognized by our AE3 antibody. Tissue distribution data and cell culture studies show that, within the two subfamilies, keratins with similar "size ranks" form a "pair" as defined by frequent co-expression. Furthermore, within most "keratin pairs," the basic keratin is larger than the acidic one by 8-10 kDa. These results provide further support for the concepts of "keratin subfamilies" and keratin pairs and are consistent with the possibility that the acidic and basic members of at least some keratin pairs may interact specifically during in vivo tonofilament assembly and/or function. Immunoblotting data derived from the use of several monospecific antibodies show that although the size, charge, and pattern of expression of most bovine keratins are similar to those of the human counterparts, there are important exceptions to this rule.     

Type I keratin cDNAs from the rainbow trout: independent radiation of keratins in fish

Five different type I keratins from a teleost fish, the rainbow trout Oncorhynchus mykiss, have been sequenced by cDNA cloning and identified at the protein level by peptide mass mapping using MALDI-MS. This showed that the entire range of type I keratins detected biochemically in this fish has now been sequenced. Three of the keratins are expressed in the epidermis (subtype Ie), whereas the other two occur in simple epithelia and mesenchymal cells (subtype Is). Among the Is keratins is an ortholog of human K18; the second Is polypeptide is clearly distinct from K18. We raised a new monoclonal antibody (F1F2, subclass IgG1) that specifically recognizes trout Is keratins, with negative reactions on zebrafish. A phylogenetic tree has been constructed from a multiple alignment of the rod domains of the new sequences together with type I sequences from other vertebrates such as shark, zebrafish, and human; a recently sequenced lamprey Is keratin was applied as outgroup. This tree shows one branch defining the K18 orthologs and a second branch containing all other type I keratins (mostly subtype Ie). Within this second branch, the teleost keratins form a separate, highly bootstrap-supported twig. This tree leaves little doubt that the teleost Ie keratins diversified independently from the mammalian Ie keratins.     

Correlation of specific keratins with different types of epithelial differentiation: monoclonal antibody studies

We have prepared three monoclonal antibodies against human epidermal keratins. These antibodies were highly specific for keratins and, in combination, recognized all major epidermal keratins of several mammalian species. We have used these antibodies to study the tissue distribution of epidermis-related keratins. In various mammalian epithelia, the antibodies recognized seven classes of keratins defined by their immunological reactivity and size. The 40, 46 and 52 kilodalton (kd) keratin classes were present in almost all epithelia; the 50 kd and 58 kd keratin classes were detected in all stratified squamous epithelia, but not in any simple epithelia; and the 56 kd and 65-67 kd keratin classes were unique to keratinized epidermis. Thus the expression of specific keratin classes appeared to correlate with different types of epithelial differentiation (simple versus stratified; keratinized versus nonkeratinized).     

Keratin and vimentin expression in early organogenesis of the rabbit embryo

Summary The expression of vimentin and keratins is analysed in the early postimplantation embryo of the rabbit at 11 days post conceptionem (d.p.c.) using a panel of monoclonal antibodies specific for single intermediate filament polypeptides (keratins 7, 8, 18, 19 and vimentin) and a pan-epithelial monoclonal keratin antibody. Electrophoretic separation of cytoskeletal preparations obtained from embryonic tissues, in combination with immunoblotting of the resulting polypeptide bands, demonstrates the presence of the rabbit equivalents of human keratins 8, 18, and vimentin in 11-day-old rabbit embryonic tissues. Immunohistochemical staining shows that several embryonic epithelia such as notochord, surface ectoderm, primitive intestinal tube, and mesonephric duct, express keratins, while others (neural tube, dermomyotome) express vimentin, and a third group (coelomic epithelia) can express both. Similarly, of the mesenchymal tissues sclerotomal mesenchyme expresses vimentin, while somatopleuric mesenchyme (abdominal wall) expresses keratins, and splanchnopleuric mesenchyme (dorsal mesentery) expresses both keratins and vimentin. While these results are in accordance with most results of keratin and vimentin expression in embryos of other species, they stand against the common concept of keratin and vimentin specificity in adult vertebrate tissues. Furthermore, keratin and vimentin are not expressed in accordance with germ layer origin of tissues in the mammalian embryo; rather the expression of these proteins seems to be related to cellular function during embryonic development.Supported by the Deutsche Forschungsgemeinschaft and by the Netherlands Cancer Foundation     

The human thymic microenvironment: Thymic epithelium contains specific keratins associated with early and late stages of epidermal keratinocyte maturation

Normal T-cell development is dependent on interactions with the thymic microenvironment; thymic epithelial cells are thought to play a key role in the induction of thymocyte maturation, both through direct contact and, indirectly, via thymic hormone secretion. It has been postulated that thymic epithelial cells progress through an antigenically defined pathway of differentiation similar to that of epidermal keratinocytes. As keratins vary according to epithelial cell type and the stage of epithelial cell maturation, we used a panel of monoclonal antibodies against keratins to study specific types of keratin intermediate filaments within human thymic epithelium. The demonstration in human thymus of keratins previously shown to be associated with distinct stages of epidermal keratinocytic maturation would support the hypothesis that thymic epithelial cells undergo sequential stages of differentiation. Two-dimensional immunoblot analysis of cytoskeletal extracts from human thymus revealed that thymic epithelium contains the following keratins: 1-2, 5, 6, 7, 8, 10, 13, 14, 15, 16, and 17 (molecular masses, 65-67, 58, 56, 54, 52, 56.5, 51, 50, 50', 48, and 46 kilodaltons, respectively). Thus, in thymic epithelium, we found keratins previously observed in epidermal basal cells (5, 14, 15), as well as keratins specific for terminally differentiated keratinocytes in supra-basal epidermis (1-2, 10). Indirect immunofluorescence (IF) performed on fetal and postnatal human thymus demonstrated that keratin epitopes recognized by antibodies AE-3, 35 beta H11, and RTE-23 are present on epithelial cells of the subcapsular cortex, the cortex, the medulla, and Hassall's bodies. In contrast, antibodies AE-1 and RTE-22 reacted primarily with neuroendocrine thymic epithelium (subcapsular cortex, medulla, Hassall's bodies). The epithelial reactivity of antibody AE-2 was limited to epithelial cells in Hassall's bodies and did not appear until 16 weeks of fetal gestation i.e., when Hassall's bodies first formed. Two-dimensional gel analysis of thymic keratins demonstrated that antibody AE-2 identified only the keratins with molecular masses of 56.6 and 65-67 kilodaltons (10 and 1-2 respectively) in thymus. These data, together with the selective reactivity of AE-2 with Hassall's bodies in fluorescence assays, demonstrate the localization in Hassall's bodies of the high-molecular-weight keratins associated with the late stages of epidermal cell maturation. In summary, we demonstrated that human thymic epithelium contains specific keratins found in multiple epithelial types as well as keratins associated with both early and late stages of epidermal cell differentiation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Similarities between the Mr 245,000 calmodulin-binding protein of the dogfish erythrocyte cytoskeleton and alpha-fodrin

The Mr 245,000 calmodulin-binding protein of the dogfish erythrocyte cytoskeleton (D245) has been compared with human erythrocyte spectrin and mammalian brain fodrin [J. Levine and M. Willard (1981) J. Cell Biol. 90, 631-643]. Mammalian erythrocyte alpha-spectrin, brain alpha-fodrin, and D245 are all localized in the cell surface-associated cytoskeleton, and have similar molecular weights. Like mammalian erythrocyte spectrin, D245 was extracted from erythrocyte ghosts under low-ionic-strength conditions. However, D245 failed to bind an antibody which reacted strongly with both subunits of human erythrocyte spectrin. Unlike mammalian erythrocyte alpha- and beta-spectrin, D245 bound calmodulin in the absence of urea both in a "gel-binding" assay and in situ using azidocalmodulin [D.C. Bartelt, R.K. Carlin, G.A. Scheele, and W.D. Cohen (1982) J. Cell Biol. 95, 278-284]. Striking similarities were noted between D245 and alpha-fodrin in that both exhibited (a) comparable calcium-dependent calmodulin binding properties, (b) strong reactivity with two different anti-fodrin antibody preparations, (c) similar reactivity with antibody to brain CBP-I, now believed to be fodrin, (d) proteolytic degradation yielding an Mr 150,000 calmodulin-binding fragment, and (e) lack of reactivity with an anti-spectrin antibody. A protein with calmodulin-binding and anti-fodrin-binding properties similar to D245 was detected in cytoskeletal preparations of chicken erythrocytes. Moderate and consistent cross-reactivity of anti-fodrin with human erythrocyte alpha-spectrin was also observed. The data indicate that D245 is functionally and immunologically more closely related to alpha-fodrin than to alpha-spectrin of the mammalian erythrocyte.