Intermediate filament proteins and epithelial differentiation in the embryonic ovary of the rat

Abstract. The development and sexual differentiation of gonads in female rat embryos and fetuses between the ages of 11 and 17 days was studied by immunocytochemical analysis of intermediate filament proteins and laminin by light and electron microscopy. In the 11-day-old pregonadal embryo, the surface epithelial cells in the ventral cortex of the mesonephros contained desmin but not cytokeratin or vimentin. The development of the gonad began on the following day by proliferative growth of the mesonephric surface cells, which like the subepithelial cells soon expressed vimentin in addition to desmin. The differentiation continued by formation of separate epithelial cell clusters, which joined into cords, irregular in shape and size. Desmin disappeared from the cord cells and cytokeratins appeared while vimentin remained in all somatic cell types. Desmin was especially abundant in some stromal cells adjacent to the epithelial tissues. After the segration of the basic ovarian tissues, vimentin and desmin decreased and cytokeratins appeared in the surface epithelial cells. New changes in cytokeratin expression appeared with the differentiation of the embryonic cords in a sex-specific manner with gradual decrease of reactivity for cytokeratin 18. No immunoreaction to the neurofilament proteins was found at the present ages, and the germ cells were negative for intermediate filaments. The results show that desmin is expressed in several primitive ovarian and mesonephric cells even though they are not myogenic. The sexual differences emerge after the incipient formation of the genetically female gonad, as different organization of the internal epithelial tissue with different timing of changes in intermediate filament proteins when compared with the male gonad.     

Structural proteins in sexual differentiation of embryonic gonads

Sexual differentiation of embryonic gonads was studied by immunocytochemical analysis of cytoskeleton, basement membrane and extracellular matrix. The epithelial cells of the prospective gonadal region in both sexes contained vimentin and desmin intermediate filament proteins but not cytokeratin. Basement membrane components laminin, collagen types IV and V, heparan sulfate proteoglycan, and fibronectin were seen in an unorganized form in the extracellular space. The development of the gonads started by proliferation of the pregonadal epithelial cells, which formed separate clusters and loose mesenchyme. In the male gonad the clusters joined together into elongated cords, outlined by basement membrane components. The cord cells became polarized epithelial cells, and cytokeratin appeared with the disappearance of desmin in their cytoplasm. Desmin and vimentin remained in the interstitial cells. In the female gonad the clusters were smaller, and the cords were irregular in shape and size. Desmin disappeared from the cord cells and cytokeratin appeared, but more slowly and less well polarized than in the testis. The present results show that after common early development, the sexual differences in gonads emerge as different organization of the internal epithelial tissue with different timing of changes in intra- and extracellular components.     

Intermediate filaments in the testis of the teleost mosquito fish Gambusia affinis holbrooki: a light and electron microscope immunocytochemical study and Western blotting analysis

Summary A light and electron microscope immunocytochemical study and Western blotting analysis has been performed on intermediate filaments (vimentin, desmin and cytokeratins) in the testis of the teleost fish Gambusia affinis holbrooki. An immunoreaction to vimentin was observed in the epithelium of the efferent ducts, testicular canal and their surrounding peritubular cells. Positive vimentin immunostaining was also observed in the cells located around seminiferous tubules (boundary cells), Leydig cells, interstitial fibroblasts, chromatophores, and blood vessel endothelial cells. In contrast to mammals, no vimentin immunoreactivity was found in the Sertoli cells. Immunoreactivity to desmin was weak in the epithelial cells of the efferent ducts and testicular canal and intense in the peritubular cells that surrounded these ducts. Desmin immunoreactivity was also observed in the seminiferous tubule boundary cells. The immunoreactivity was weak in the boundary cells that surrounded germ cell cysts containing spermatogonia or spermatocytes and intense in the boundary cells around cysts with elongated or mature spermatids. Immunoreactivity towards cytokeratins was observed only in testicular blood vessels. Cytokeratin immunolabelling was intense in the endothelium and weak in the vascular smooth muscle cells. No cytokeratin immunoreactivity was found in the Sertoli cells, germ cells, interstitial cells or in the efferent duct epithelium. The absence of intermediate filaments in the Sertoli cells, the absence of cytokeratins in the epithelium of the sperm excretory ducts, and the presence of desmin filaments in these epithelial cells are the most important differences with regards to the intermediate filament phenotype in mammalian testes.     

Expression of intermediate filament proteins in fetal and adult human lung tissues

The expression patterns of intermediate filament proteins in fetal and normal or nonpathological adult human lung tissues are described using (chain-specific) monoclonal antibodies. In early stages of development (9-10 weeks and 25 weeks of gestation) only so-called simple cytokeratins such as cytokeratins 7 (minor amounts). 8, 18 and 19 are detected in bronchial epithelial cells. At later stages of development, the cytokeratin expression patterns become more complex. The number of bronchial cells positive for cytokeratin 7 increases, but basal cells in the bronchial epithelium remain negative. These latter cells show, however, expression of cytokeratin 14 in the third trimester of gestation. Developing alveolar epithelial cells express cytokeratins 7, 8, 18 and 19. In adult human bronchial epithelium cytokeratins 4 (varying amounts), 7, 8, 13 (minor amounts), 14, 18 and 19 can be detected, with the main expression of cytokeratins 7, 8, and 18 in columnar cells and the main expression of cytokeratin 14 in basal cells. Vimentin is detected in all mesenchymal tissues. In addition, fetal lung expresses vimentin in bronchial epithelium, however, to a lesser extent with increasing age, resulting in the expression of vimentin in only few scattered bronchial cells at birth. Also in adult bronchial epithelium the expression of vimentin is noticed in part of the basal and columnar epithelial cells. Desmin filaments, present in smooth muscle cells of the lung, appear to alter their protein structure with age. In early stages of development smooth muscle cells surrounding blood vessels are partly reactive with some cytokeratin antibodies and with a polyclonal desmin antibody. At week 9-10 and week 25 of gestation a monoclonal antibody to desmin, however, is not reactive with blood vessel smooth muscle cells but is only reactive with smooth muscle cells surrounding bronchi. With increasing age the reactivity of cytokeratin antibodies with smooth muscle cells in blood vessels decreases, while the reactivity with the monoclonal desmin antibody increases. Our results show that during differentiation profound changes in the intermediate filament expression patterns occur in the different cell types of the developing lung.     

Low level expression of cytokeratins 8, 18 and 19 in vascular smooth muscle cells of human umbilical cord and in cultured cells derived therefrom, with an analysis of the chromosomal locus containing the cytokeratin 19 gene

Of the various intermediate filament (IF) proteins certain cytokeratins, usually a hallmark of epithelial differentiation, can also be detected in some non-epithelial cells in low amounts. We have studied a representative case of this atypical expression, the smooth muscle cells of the blood vessel walls of the human umbilical cord, at the protein and nucleic acid level, by light and electron microscopic immunolocalization, gel electrophoresis and immunoblotting of cytoskeletal proteins, and mRNA identification by Northern blotting. For the latter we have used sensitive probes for various cytokeratins, including new probes for cytokeratin 19. We also describe the chromosome 17 locus comprising the genes for cytokeratins 15 and 19, and we emphasize the occurrence of several unusual and evolutionarily stable sequence elements in the introns of the cytokeratin 19 gene. Most, perhaps all smooth muscle cells of these blood vessels, positively identified by the presence of desmin and smooth muscle type alpha-actin, are immunostained by antibodies specific for cytokeratins 8 and 18, and a subpopulation also contains cytokeratin 19. Immunoelectron microscopy indicates that these cytokeratins are arranged in IFs that are distributed differently from the majority of the IFs formed by desmin and vimentin. Gel electrophoresis of cytoskeletal proteins from microdissected vascular wall tissue shows that the amounts of cytokeratins 8 and 18 present in these tissues are very low, representing less than 1% of the total IF protein, and that cytokeratin 19 is present only in trace amounts. Correspondingly, the contents of mRNAs for cytokeratins 8, 18 and 19 in these tissues are much lower than those present in epithelial cells examined in parallel. We have also established cell cultures derived from umbilical cord vascular smooth muscles that have maintained the expression of cytokeratins 8, 18 and 19, together with vimentin and the smooth muscle type alpha-actin, but do not synthesize desmin. In these cell cultures the cytokeratins are present in much higher amounts than in the original tissue and form IFs that, surprisingly, show a similar distribution as the vimentin IFs and, upon treatment of the cells with colcemid, collapse into juxtanuclear aggregates, often even more effectively than the vimentin IFs do. We conclude that in a certain subtype of smooth muscle cells, the genes encoding cytokeratins of the "simple epithelial type", i.e., cytokeratins 8, 18 and 19, are expressed and that the low level expression of these genes is compatible with myogenic differentiation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Ultrastructure of the early ovary and testis in pig embryos.

Pig embryos aged 26-27 days were used for an ultrastructural study of the early ovary and testis. Sex was identified by both chromosomal analysis and gonadal histology, with consistent results. The gonads occupied their original site in the medial coelomic angles in both sexes. The female gonad was composed of three tissues: the surface epithelium, the gonadal blastema and the mesenchyme. The gonadal structure was similar to that seen earlier at the age of 24 days. At 26 days the testis had distinctly differentiated into four tissues. The new components were the testicular cords and the interstitium, both derived from the gonadal blastema. The testicular cords resembled anastomosing sheets more than cords. The ultrastructure of the tissues and their cell types are described and compared to the previous indifferent stage at the age of 24 days. The cells of the surface epithelium, of the primitive cords, of the mesenchyme, and the primordial germ cells had an ultrastructure that was similar in both sexes. The sustentacular cells of the testicular cords resembled the primitive cord cells and the spermatogonia were similar to the primordial germ cells. No Leydig cells were present yet. The process of testicular differentiation is described on the basis of the present and a previous study, and a new hypothesis, based on the vascular organization, is presented.     

Heterogeneity of intermediate filament expression in human testicular seminomas

Testicular seminoma has in the past been considered to represent a germ cell tumor incapable of further differentiation. In recent years this view has been challenged on the basis of morphologic and chromosomal studies. Moreover, studies of intermediate filaments (IF) of seminoma cells have provided evidence of the capability of seminoma cells to differentiate in different directions. In the present study of the IF protein profile of 26 human testicular seminomas, using frozen as well as formalin-fixed, paraffin-embedded tissues, we report evidence of a heterogeneous differentiation potential inherent in these neoplasms. Thus, in 4 of the seminomas neither cytokeratins nor vimentin were detected; 3 showed vimentin positive cells but no cytokeratins; in 4 seminomas only cytokeratins were detected. In the remaining 15 cases both cytokeratins and vimentin were present, with occasional cells demonstrating coexpression of cytokeratin and vimentin. While the cytokeratins present were mostly of the "simple epithelial type", in 2 instances seminoma cells also contained cytokeratins 4 and 17, normally found in stratified and/or complex glandular epithelia. Furthermore, in 3 cases scattered tumor cells stained for desmin and in 2 other seminomas neurofilaments were identified. All of the cases showed variable positive staining for desmoplakins and desmoglein, indicative of the presence of desmosomes. It can therefore be concluded that, while some seminomas seem to be devoid of IFs, most of them show varied differentiation patterns usually with epithelial features but occasionally also with components commonly regarded as characteristic of myogenic or neurogenic differentiation. These observations may help to elucidate the relationship of seminomas to other germ cell tumors, and also contribute to our understanding of the histogenesis of these neoplasms.     

Transient coexpression of cytokeratin and vimentin in differentiating rat Sertoli cells

The expression of cytokeratin and vimentin type intermediate filaments were studied in fetal, postnatal, and adult rat testes. Immunocytochemical observations were correlated with the light and electron microscopic analysis of the developing organs. The Sertoli cell precursors in 15-day-old fetal testes contained both cytokeratin and vimentin. A gradual reorganization of both filaments, accompanied by a decrease of cytokeratin-positivity, was observed toward the end of the fetal period. The simultaneous presence of cytokeratin and vimentin in the same cells was shown by double immunofluorescence of newborn testes and the primary culture of dissociated testicular cells. In postnatal Sertoli cells, cytokeratin-positivity continued to decrease and disappeared by the age of 14 days. The increase in vimentin content and the appearance of axially oriented vimentin filaments coincided with the acquisition of the columnar shape of the Sertoli cells. The presence of cytokeratin and vimentin in fetal and newborn testes, and only vimentin in the adult testes was confirmed by immunoblotting. The present results suggest that major qualitative changes in the expression of intermediate filament proteins can take place during the embryonic development. The expression of cytokeratin in developing Sertoli cells, although only transient, supports the epithelial origin of these cells and can be applied as a marker for embryonic and early postnatal Sertoli cells.     

Immunohistochemical investigation of different cytokeratins and vimentin in the human epididymis from the fetal period up to adulthood

Summary The anatomical distribution of cytokeratins and vimentin was investigated by means of immunohistochemistry in the human epididymis. Epithelial cells of the ductuli efferentes and the corpus epididymidis were positive for cytokeratins and vimentin. The expression of epithelial vimentin decreased toward the cauda epididymidis, whereas cytokeratins remained unchanged. The epithelium of the ductus deferens was negative when antibodies against vimentin were used. With monoclonal antibodies to individual cytokeratins, the presence of cytokeratins 7, 8, 18, and 19 was demonstrated histochemically throughout the epithelium of the epididymis. Monoclonal antibodies specific for cytokeratin 17 allowed immunohistochemical differentiation between the ductuli efferentes and the ductus epididymidis.     

Reaggregates of cells from rat testis resemble developing gonads

Reaggregates prepared from newborn rat testis cells in Moscona-type rotation cultures were analyzed and compared with normal fetal (12-21 days) and newborn testes at the light and electron microscope level. After 25 h of culture, the aggregates resembled normal testicular tissue. The cells of the surface layer were spindle-shaped and connected by adherent junctions. The epithelial cords were composed exclusively of Sertoli cells and were surrounded by elongated cells resembling the developing myoid cells in newborn testes. The basal aspect of the cords was covered by a layer of flocculent material which, in places, was organized like an ordinary basement membrane. Individual spermatogonia with pseudopodes were observed in the interstitial tissue. Some Leydig cells were organized into small clusters like those typical in newborn testes. The present observations indicate that, histologically, the reaggregation of separated testicular cells resembles the differentiation of embryonic male gonads.     

Identification of the cytoskeletal proteins in lens-forming cells, a special epithelioid cell type

Proteins of contractile and cytoskeletal elements have been studied in bovine lens-forming cells growing in culture as well as in bovine and murine lenses grown in situ by immunofluorescence microscopy using antibodies to the following proteins: actin, myosin, tropomyosin, α-actinin, tubulin, prekeratin, vimentin, and desmin. Lens-forming cells contain actin, myosin, tropomyosin, and α-actinin which in cells grown in culture are enriched in typical cable-like structures, i.e. microfilament bundles. Antibodies to tubulin stain normal, predominantly radial arrays of microtubules. In the epithelioid lens-forming cells of both monolayer cultures grown in vitro and lens tissue grown in situ intermediate-sized filaments of the vimentin type are abundant, whereas filaments containing prekeratin-like proteins (‘cytokeratins’) and desmin filaments have not been found. The absence of cytokeratin proteins observed by immunological methods is supported by gel electrophoretic analyses of cytoskeletal proteins, which show the prominence of vimentin and the absence of detectable amounts of cytokeratins and desmin. This also correlates with electron microscopic observations that typical desmosomes and tonofilament bundles are absent in lens-forming cells, as opposed to a high density of vimentin filaments. Our observations show that the epithelioid lens-forming cells have normal arrays of (i) microfilament bundles containing proteins of contractile structures; (ii) microtubules; and (iii) vimentin filaments, but differ from most true epithelial cells by the absence of cytokeratins, tonofilaments and typical desmosomes. The question of their relationship to other epithelial tissues is discussed in relation to lens differentiation during embryogenesis. We conclude that the lens-forming cells either represent an example of cell differentiation of non-epithelial cells to epithelioid morphology, or represent a special pathway of epithelial differentiation characterized by the absence of cytokeratin filaments and desmosomes. Thus two classes of tissue with epithelia-like morphology can be distinguished: those epithelia which contain desmosomes and cytokeratin filaments and those epithelioid tissues which do not contain these structures but are rich in vimentin filaments (lens cells, germ epithelium of testis, endothelium).     

Transient coexpression of desmin and cytokeratins 8 and 18 in developing myocardial cells of some vertebrate species

During myogenesis the intermediate-sized filament (IF) cytoskeleton is characterized by increasing proportions of desmin. While skeletal and smooth muscle formation occurs in free mesenchymal cells containing vimentin-type IFs, myocardial development starts from a polar epithelium containing cytokeratin IFs and desmosomes. Therefore, we have studied the formation of the epicardium and the myocardium in different vertebrate species, combining light and electron microscopic immunolocalization techniques with gel-electrophoretic analyses of cytoskeletal proteins of microdissected myocardial tissue at differing developmental stages. In this report, we describe results obtained from advanced stages of myocardial differentiation. In all species studied the myocardial cell possess IFs abundant in desmin, often together with smaller amounts of vimentin, and the mesothelial layer of the epicardium contains cytokeratin IFs. However, we have observed remarkable interspecies differences with respect to the occurrence of cytokeratins in embryonic myocardial cells. In fetal human myocardium, from week 10 of pregnancy on, but not in juvenile and adult myocardium, and in chicken myocardium of all stages examined (until several days after hatching) specific immunostaining was seen with certain broad-range cytokeratin antibodies as well as with antibodies specific for cytokeratins 18 (in both species) and 8 (showing significant reaction only in human). This cytokeratin immunoreaction, however, did not appear in IFs extending throughout the cytoplasm or at Z-lines, but was localized in punctate arrays representing aggregates of dense material. The aggregates were often enriched at, but not restricted to, the desmosomal plaques of the intercalated discs. These observations were supported by gel-electrophoretic demonstration of small but significant amounts of cytokeratins 18 (in both species) and 8 (detected only in human) in microdissected myocardial tissue. We also observed cytokeratins in smooth muscle cells of some cardiac blood vessels. In contrast, bovine myocardium of advanced fetal age as well as rat and mouse myocardium (from fetal day 12 on) were negative for cytokeratins with all methods, although epicardial cytokeratin IFs were demonstrable. These observations are discussed in relation to myocardial histogenesis and to general problems of cytokeratin gene expression control in epithelial and nonepithelial cells.     

Involvement of actin filaments in mouse testicular cord organization in vivo and in vitro.

Involvement of actin filaments in mouse fetal testicular differentiation was examined in vivo and in vitro. During testicular cord formation in vivo, actin filaments accumulated in the basal cytoplasm of Sertoli cells. Addition of cytochalasin D (CD) to organ cultures of undifferentiated gonadal primordia significantly inhibited testicular cord formation. In brief, treatment with 25 ng/ml CD induced the formation of slender testicular cords, and treatment with 50 ng/ml largely inhibited cord formation in the explants. However, development and growth of the testicular parenchyma and Leydig cell differentiation occurred in the presence of CD. By electron microscopic and immunohistochemical examinations, it became clear that CD also affected formation of the basal lamina and accumulation of vimentin filaments in Sertoli cells. On the other hand, treatment with colcemid at 12.5 or 15 ng/ml prevented growth of the testicular parenchyma and development of interstitial regions. Interestingly, testicular cords formed under this condition. These results indicate that the basal actin filaments of Sertoli cells may play an important role in testicular cord formation, especially Sertoli cell polarization. Cell mitosis and/or microtubules, on the other hand, may not be directly involved in this process.     

Differential expression of acidic cytokeratins 18 and 19 during sexual differentiation of the rat gonad.

The expression of cytokeratins (CKs) 8, 18 and 19 was analyzed in male and female rat gonads from the undifferentiated stage (12.5 days of gestation) until two weeks after birth by indirect immunofluorescence, using specific monoclonal antibodies anti-CK 8 (LE41), anti-CK 19 (LP2K) and anti-CK 18 (LE65 and RGE53). In the undifferentiated blastema, the somatic cells were stained for CK 8 and CK 19, whereas no detectable immunoreactivity for CK 18 was obtained. The same staining CK pattern was observed in ovaries, in the somatic cells of ovigerous cords and in primary follicles. The staining was progressively decreasing in growing follicles after one week after birth. At the onset of testicular differentiation, when the first Sertoli cells differentiate in the gonad of 13.5-day old male fetuses, positive staining for CK 18 became evident, in addition to CK 8 and CK 19 expression. In the following days, CK 8, CK 18 and CK 19 were detected in Sertoli cells in the differentiating seminiferous cords, but progressively the reactivity for CK 19 decreased and was no longer observed after 18.5-19.5 days of gestation. In all cases, CKs were found to be coexpressed with vimentin, and germ cells were negative for both vimentin and CKs. The results reported here show first, that CKs are expressed before sexual differentiation in gonadal blastema in which no epithelial organization is observed, and second, that there is a CK 18/CK 19 shift in expression during morphogenesis of the testis which is not observed in the differentiating ovary. Future studies will have to determine whether these differences in CK expression are due to epitope-masking phenomena or to the regulation of CK synthesis.     

Changes in the distribution of intermediate-filament types in Japanese quail embryos during morphogenesis

We examined the distribution of intermediate filaments in early quail embryos in order to determine whether these cytoskeletal proteins play a role in the epithelial-mesenchymal transitions that commonly occur during embryogenesis, e.g., the separation of neural-crest cells from the neural epithelium. The distribution of cytokeratins, vimentin, and desmin was examined in frozen sections of quail embryos at stages during which dramatic reorganizations of tissues take place. All embryonic tissues were found to contain either vimentin or cytokeratins, but the distribution of these cytoskeletal proteins was characteristic neither of the cellular organization (e.g., epithelium vs. mesenchyme) nor of the germ-layer derivation of the tissues. Cytokeratin monoclonal antibodies stained most embryonic epithelia (defined here as being sheet-like tissue with an underlying basement membrane), including epidermis and extraembryonic membranes derived in part from the ectoderm, splanchnopleure and kidney tubules derived from mesoderm, and endoderm. Cytokeratin antibodies did not stain some epithelia, including the neural tube, neural plate, and dermatome/myotome. Whereas the cytokeratin antibodies exclusively stained epithelia, the vimentin antibodies labeled both epithelial (the neural tube, dermatome/myotome, and somatic and splanchnic mesoderm) and mesenchymal tissues (the sclerotome and neural-crest cells), regardless of their germ-layer derivation. In early embryos, antibodies against desmin only stained the myotome and, in 4-day embryos, the heart and mesenchyme around the pharynx. As the distribution of intermediate-filament types did not reflect tissue organization or germ-layer derivation, we propose that the distribution of intermediate filaments in early avian embryos reflects the motile capacity of an embryonic cell and/or the presence of specialized cell junctions, i.e., desmosomes.     

Early stages of testicular differentiation in the rat

Summary The initial phases of the development of the seminiferous cords (future seminiferous tubules) were studied with histological techniques and with electron microscopy. On day 14 after fertilization, seminiferous cords are well differentiated in the anterior part of the testis near the mesonephric tubules. They comprise Sertoli cells which encompass the primordial germ cells. The Sertoli cells show an expanded clear cytoplasm and microfilaments beneath the outer surface; they differentiate complex contact zones. On day 13 a few cells localized near the mesonephric tubules display the characteristics of the Sertoli cells. These cells become more and more numerous. They aggregate and they form the seminiferous cords.The primordia of male gonads explanted in vitro on the mesonephros, realize testicular organogenesis in a synthetic medium. Adding 15% fetal calf serum to the medium prevents the morphogenesis of the testicular cords, although the Sertoli cells seem to differentiate morphologically and physiologically. In these gonads differentiation of the Sertoli cells was obtained but their aggregation and the morphogenesis of the seminiferous cords were prevented. This gives new insights into testicular morphogenesis and probably provides an experimental model for a new type of gonadal anomaly.     

Cytokeratin 18 is an M-cell marker in porcine Peyer's patches

The intermediate filaments of the dome epithelium of porcine Peyer's patches were studied by immunohistochemistry. The labelling patterns of monospecific antibodies directed against cytokeratins 8, 18 and 19 differed considerably. About 40% of the dome epithelial cells were intensely labelled by three different anti-cytokeratin 18 antibodies, indicating that large amounts of cytokeratin 18 are present in these cells. In order to verify that these cytokeratin-18-immunoreactive cells were M-cells, uptake studies using fluorescein-labelled yeast particles were performed. Numerous yeast particles were found exclusively in dome epithelial cells that were highly positive for cytokeratin 18, thus representing M-cells. In contrast, the content of cytokeratin 19 in M-cells was lower than that in neighbouring enterocytes. The labelling intensity of cytokeratin 8 did not differ between M-cells and enterocytes. In addition, the absence of vimentin and desmin from the dome epithelium of porcine Peyer's patches was demonstrated. The results show (1) that porcine M-cells differ from enterocytes in the composition of their cytoskeleton, (2) that cytokeratin 18 is a useful marker for detecting porcine M-cells and (3) that this marker directly correlas with M-cell function.     

Epithelial and mesenchymal cell differentiation in the fetal rat genital ducts: changes in the expression of cytokeratin and vimentin type of intermediate filaments and desmosomal plaque proteins

Mesonephric and paramesonephric ducts develop in different ways in male and female fetuses. We have analyzed the changes in the expression of cytokeratin and vimentin type of intermediate filaments and desmosomal plaque proteins in progressing and regressing genital ducts of rat fetuses. The concomitant changes in the basement membranes were detected by laminin antibody. Epithelial cells of the indifferent (Day 15) male and female mesonephric and paramesonephric ducts contained faint vimentin positivity which, however, later disappeared. Indifferent mesonephric duct epithelium stained strongly for cytokeratin, whereas in the corresponding paramesonephric duct only a weak and spotty positivity was seen. Immunocytochemical localization of cytokeratin filaments and desmosomal plaque proteins correlated with the ultrastructural differences in the apical junctional complexes of the mesonephric and paramesonephric ducts. Regardless of the ongoing regression of the male paramesonephric duct, cytokeratin positivity increased in the disorganizing epithelium; the most weak and a granular immunoreaction was seen in the cells found in the intensively vimentin-positive periductal mesenchyme. In the regressing female mesonephric duct cytokeratin positivity was lost before the final dissolution of the basement membrane. Immunoblotting analysis of cytokeratin and vimentin polypeptides of the individual genital ducts were in agreement with the immunocytochemical results obtained in 15- and 16-day-old fetuses. The results suggest that the expression of vimentin type intermediate filaments is an indication of the mesothelial origin of the genital ducts. The increase in cytokeratin positivity of the regressing paramesonephric duct epithelium suggests that the degenerative changes are initiated by the mesenchyme. Cytokeratin-positive cells found in the periductal mesenchyme of the male paramesonephric duct may be epithelial cells transforming into mesenchyme. The results emphasize a close relationship between the changes of the intermediate filament system and extracellular matrix upon differentiation of the fetal genital ducts.     

Cell sources of liver development

The work is devoted to consequent expression of different cell types' protein markers such as vimentin, desmin, cytokeratins 7, 18, 19, stem cell markers CD34 and Bcl-2 at early stages of human prenatal development. Desmin was revealed in sinusoidal liver cells on 3.5-12 weeks of gestation, in mesenchymal cells of ventral mesentery and hepatoblasts on the 4-7 accordingly. During hepatic period of blood formation such desmin positive sinusoidal cells were found to be located close to blood cells. So called "cholangio-" cytokeratins 7 and 19 showed different expression, the first one was found only in cholangiocytes, while cytokeratin 19 existed in hepatoblasts as well until week 15-16 of prenatal development. Mesenchymal cells of ventral mesentery are positive for cytokeratins 18 and 19 even brighter than hepatoblasts in the 4-7 weeks of gestation. Bcl-2 expression was seen in the same periods in most sinusoidal and mesenchymal cells of ventral mesentery. CD34 positive cells are strongly depicted in liver sinusoids from 4th until 9th weeks of gestation, but probably they are not a source of hepatocytes' development in embryonic ontogenesis. Ventral mesentery mesenchyme was negative for this very marker. These results let us suppose that hepatocytes and cholangiocytes may develop from quite different embryonic sources: cholangyocytes grow exceptionally from duodenum epithelial cells, while there is a strong possibility that hepatoblasts formation occurs with participation of mesenchymal cells.