Immunohistochemical analysis of C-protein isoforms in cardiac and skeletal muscle of the axolotl,Ambystoma mexicanum

Of the several proteins located within sarcomeric A-bands, C-protein, a myosin binding protein (MyBP) is thought to regulate and stabilize thick filaments during assembly. This paper reports the characterization of C-protein isoforms in juvenile and adult axolotls, Ambystoma mexicanum, by means of immunofluorescent microscopy and Western blot analyses. C-protein and myosin are found specifically within the A-bands, whereas tropomyosin and -actin are detected in the I-bands of axolotl myofibrils. The MF1 antibody prepared against the fast skeletal muscle isoform of chicken C-protein specifically recognizes a cardiac isoform (Axcard1) in juvenile and adult axolotls but does not label axolotl skeletal muscle. The ALD66 antibody, which reacts with the C-protein slow isoform in chicken, localizes only in skeletal muscle of the axolotl. This slow axolotl isoform (Ax_slow) displays a heterogeneous distribution in fibers of dorsalis trunci skeletal muscle. The C₃₁₅ antibody against the chicken C-protein cardiac isoform identifies a second axolotl cardiac isoform (Ax_card2), which is present also in axolotl skeletal muscle. No C-protein was detected in smooth muscle of the juvenile and adult axolotl with these antibodies.This work was supported by NIH grants HL-32184 and HL-37702 and a grant-in-aid from the American Heart Association to L.F.L.     

Interdigitating cells in the thymus of the turtle Mauremys caspica

Summary Interdigitating cells are non-lymphoid elements in the thymus and peripheral, secondary lymphoid organs of higher vertebrates. Their origin and functional significance are a matter of controversy. In the present investigation we analyze, for the first time, the nature of presumptive interdigitating cells of the thymus of an ectothermic vertebrate, the turtle Mauremys caspica. This model is specially useful because of the seasonal variations that affect the reptilian lymphoid organs. Immature pro-interdigitating cells and phagocytosing mature interdigitating cells are described with special emphasis on their ultrastructural characteristics and possible relationships with monocytes and macrophages.     

An immunocytochemical survey of endocrine cells in the gastrointestinal tract of chicks at hatching

Summary The ultrastructure of the micro-environment of the fully functional rat thymus was studied. The thymus consists of two discrete compartments, viz., an epithelial and a mesenchymal compartment. Thymus fibroblasts/fibrocytes, mast cells and granulocytes, are restricted to the mesenchymal compartment. The thymocyte maturation process seems to occur in the epithelial compartment in a network of reticular epithelial cells. The cortex is finely meshed and filled with proliferating thymocytes and some scattered macrophages. Moreover, in the medulla vacuolated epithelial cells form part of a loosely meshed reticulum which is filled with thymocytes and interdigitating cells (IDCs). IDCs frequently contain Birbeck granules and appear to be phagocytic. Together with macrophages, they probably enter the thymus, predominantly in the cortico-medullary region, and cross the separating wall between the two compartments. Some functional aspects of the non-lymphoid cells and in particular the IDCs, which form the micro-environment of the thymus, are discussed with respect to T-cell development.     

Identification of the non-specific cytotoxic cell receptor protein 1 (NCCRP1) in regenerating axolotl limbs

The teleost non-specific cytotoxic cells (NCC) are evolutionary precursors of the mammalian natural killer (NK) cells and an important element of innate immunity. The non-specific cytotoxic cell receptor protein (NCCRP1) is a characteristic cell surface protein with main functions in target cell recognition and cytotoxicity with sequence information available for many species of fish. We have isolated a cDNA encoding the Axolotl homologue of fish NCCRP1 out of limb regeneration blastema and analysed its expression by RT-PCR. Sequence analysis revealed a high degree of homology with teleost NCCRP1 on nucleotide and deduced amino acid levels. NCCRP1 contains a conserved C-terminal F-box-associated domain (FBA) and proline-rich motifs (PRM) characteristic for this protein family. NCCRP1 is expressed in multiple tissues with high levels in limb regeneration blastema. The present work describes for the first time the cloning of the NCCRP1 gene in a tetrapod vertebrate providing a valuable link between fish and higher vertebrates. Our findings suggest the existence of NCC in axolotl and a role of the innate immune system in the processes of limb regeneration.     

Immunocytochemical localization and immunochemical characterization of an insulin-related peptide in the pancreas of the urodele amphibian,Ambystoma mexicanum

Summary The pancreas of the axolotl, Ambystoma mexicanum, was investigated by immunocytochemical methods for the presence of immunoreactivity to a number of antisera raised against mammalian insulins. All anti-insulin antisera tested revealed substantial amounts of reaction products confined solely to the aldehyde-fuchsinophilic B cells of the endocrine pancreas. The reactive cell population was detected by use of one polyclonal antiserum against bovine insulin and eight different monoclonal antibodies against insulins from various mammalian species. Six of these antibody clones have known specificity to sub-regions of the insulin molecule. Additionally, fractions of an ethanol-HCl extract of pancreatic tissue from Ambystoma was studied in both conventional dot-blot tests by means of the same panel of antibodies and a two-site sandwich time-resolved immunofluorometric assay for human insulin involving two of the monoclonal antibodies. These experiments support the immunocytochemical observations by demonstrating the existence of an insulin-related peptide with a great deal of structural resemblance to mammalian insulins and displaying antigenic determinants in common at least with the amino acid residues A_8–10 and B_26–30. In conclusion, we interpret the findings as indicating that the immunocytochemically revealed tissue bound antigen in the Ambystoma pancreatic B-cells may be a peptide related to human insulin.Supported in part by SNF grant 11-5082 (G.N.H.). The authors are indebted to Dr. P. Rosenkilde for the gift of the Ambystoma material     

Xanthophores in chromatophore groups of the premigratory neural crest initiate the pigment pattern of the axolotl larva

Summary The barred pigment pattern (Lehman 1957) of the axolotl larva is best observed from stage 41 onwards, where it already consists of alternating transverse bands of melanophores and xanthophores along the dorsal side of the trunk. The present study investigateswhen the two populations of neural crest derived chromatophores, melanophores and xanthophores become determined andhow they interact to create the barred pigment pattern. The presence of phenol oxidase (tyrosinase) in melanophores (revealed by dopa incubation) and pteridines in xanthophores (visualized by fluorescence) were used as markers for cell differentiation in order to recognize melanophores and xanthophores before they became externally visible. It was found that melanophores and xanthophores were already determined in the premigratory neural crest, at stages 30/31 and 35–36, respectively. Between stages 35–36 and 38 they were arranged in a prepattern of several distinct, mixed chromatophore groups along the dorsal trunk, morphologically correlated in the scanning electron microscope with humps on the original crest cell string. While the occurrence of xanthophores was restricted to the chromatophore groups and around them, melanophores were already uniformly distributed in the dorsolateral flank area, having migrated from trunk neural crest portions including the groups. The bar component of the pigment pattern was subsequently initiated by xanthophores, which caused melanophores in and around the chromatophore groups to fade or become invisible. The barred pattern was established by the formation of alternating clusters of like cells, melanophores and xanthophores.     

The effects of retinoic acid on mitosis during tail and limb regeneration in the axolotl larva,Ambystoma mexicanum

Summary Regenerating tails and limbs of axolotl larvae (A. mexicanum) were studied for overall growth and for mitosis after the animals received intraperitoneal injections of all-trans retinoic acid. Both processes were depressed to approximately the same extent (60–70%). Some mitosis always survived, even when the treatment was in effect during the entire history of the regenerate. The treatment duration was a major variable in the severity of the effect, whereas the post-amputation age of the regenerate was not. In limb regenerates the epithelial cap and the mesenchymal blastema were affected to roughly the same degree.Supported by PHS Grant 507RR7031H of the BMRG, Indiana University     

Axial characteristics of nerve induced supernumerary limbs in the axolotl

Summary Supernumerary limbs were produced by deviating the sciatic nerve to the surface of the axolotl hindlimb either alone or in combination with small skin grafts from specific limb positions. With no skin grafts a very low frequency of good supernumeraries were produced. However, when associated with skin grafts, this frequency was significantly increased. The pattern of skeletal elements and muscles were analysed in the supernumeraries which formed at each location. In both the anterior-posterior and dorsal-ventral axes specific anatomical features were found which correlated with their position of origin on the host limb. Characteristic features were also observed with respect to the proximal-distal axis of the outgrowths. These phenomena are discussed in relation to our current understanding of the rules of pattern regulation in the regenerating limb.     

Activin A and transforming growth factor-β stimulate heart formation in axolotls but do not rescue cardiac lethal mutants

In the Mexican axolotl (salamander), Ambystoma mexicanum, a recessive cardiac lethal mutation causes an incomplete differentiation of the myocardium. Mutant hearts lack organized sarcomeric myofibrils and do not contract throughout their lengths. We have previously shown that RNA purified from normal anterior endoderm or from juvenile heart tissue is able to rescue mutant embryonic hearts in an in vitro organ culture system. Under these conditions as many as 55% of formerly quiescent mutant hearts initiate regular contractions within 48 hours. After earlier reports that transforming growth factor-1 and, to a lesser extent, platelet-derived growth factor-BB could substitute for anterior endoderm as a promoter of cardiac mesodermal differentiation in normal axolotl embryos, we decided to examine the effect of growth factors in the cardiac mutant axolotl system. In one type of experiment, stage 35 mutant hearts were incubated in activin A, transforming growth factors-1 or 2, platelet-derived growth factor, or epidermal growth factor, but no rescue of mutant hearts was achieved. Considering the possibility that growth factors would only be effective at earlier stages of development, we tested transforming growth factors-1 and 5, and activin A on normal and mutant precardiac mesoderm explanted in the absence of endoderm at neurula stage 14. We found that, although these growth factors stimulated heart tube formation in both normal and mutant mesodermal explants, only normal explants contained contractile myocardial tissue. We hypothesize that transforming growth factor- superfamily peptides initiate a cascade of responses in mesoderm that result in both changes in cell shape (the basis for heart morphogenesis) and terminal myocardial cytodifferentiation. The cardiac lethal mutation appears to be deficient only in the latter process.This work was supported by NIH grants HL-32184 and HL-37702 and a grant-in-aid from the American Heart Association to L.F.L.F.J. Mangiacapra and M.E. Fransen contributed equally to this work     

Thymic accessory cell complexes in vitro and in vivo: morphological study

Summary Murine thymic macrophages and interdigitating cells, also called thymic accessory cells, were characterized by means of light- and electron microscopy. The cells were studied in suspension, during isolation by enzymatic digestion and in vivo. They were observed as isolated cells or as components of multicellular complexes, some of which were rosettes and were composed of lymphoid cells centered on each type of accessory cell. We also noted other cell complexes including macrophages that resembled classical epithelial nurse cells. We consider that multicellular complexes represent lymphostromal associations already existing in vivo, because we observed them at the periphery of thymic pieces undergoing enzymatic treatment. The heterogeneity of macrophages that we observed in vitro was also noted in vivo. In vivo macrophages were of three types: classical phagocytic cells distributed throughout the gland, cortical elongated cells in close contact with lymphoid blast cells, and atypical nurse cells containing mitotic cells and located in the inner cortex. The morphological aspects of the latter two cell types suggest that cortical macrophages in vivo have other roles: they can be interpreted as images of positive or negative cell selection. We also believe that rosettes are formed by elongated cortical macrophages when they are enzymatically isolated from the thymus.Part of this work was presented at the Second Thymus Workshop, Rolduc, The Netherlands, April 1989     

Homing of hemopoietic precursor cells to the fetal rat thymus: intercellular contact-controlled cell migration and development of the thymic microenvironment

Colonization of rat thymic anlage by the first wave of hemopoietic precursor cells (HPc) was investigated by means of transmission electron microscopy and immunocytochemistry. HPc began migration into the thymic anlage between 13 and 13.5 gestation days (GD), terminated colonization at about GD 16, and migrated sequentially through the two compartments of the thymic anlage under the control of typical populations of stromal cells. First, HPc migrated through the external compartment of the perithymic mesenchyme, tightly interconnected with fibroblasts. The type of junctions between the cells indicated that the fibroblasts played a role in the control of HPc trafficking and in their entrance to the epithelial compartment. The second stage of colonization was initiated by the entrance of HPc to the epithelial compartment and their interaction with thymic epithelial cells (TECs). Based on morphological criteria, two populations of HPc were distinguished that colonized the anlage at various stages of its development. The predominant population with ultrastructural traits common to thymocytes “homed” into the epithelial type primordium. A small number of HPc, identified by protein S-100 expression and by Birbeck’s granules as precursors of dendritic cells, colonized lymphoepithelial anlage in which subsets of cortical and medullary TECs could be distinguished. Thymocyte migration and their reciprocal interactions with cortical TECs differed from the trafficking of dendritic cells toward the medulla. The results demonstrated the influence of maturing thymocytes on the development of cortical epithelial cells and the dynamic organization of the medullary microenvironment with direct involvement of dendritic cells. This study was supported by UMS grant 501-2-0003404.     

A scanning electron-microscopic study of the rat thymus with special reference to cell types and migration of lymphocytes into the general circulation

Summary The three-dimensional structure of the rat thymus was studied by combined scanning and transmission electron microscopy. The thymus consists mainly of four types of cells: epithelial cells, lymphocytes, macrophages, and interdigitating cells (IDCs).The epithelial cells form a meshwork in the thymus parenchyma. Cortical epithelial cells are stellate in shape, while the medullary cells comprise two types: stellate and large vacuolated elements. A continuous single layer of epithelial cells separates the parenchyma from connective tissue formations of the capsule, septa and vessels. Surrounding the blood vessels, this epithelial sheath is continuous in the cortex, while it is partly interrupted in the medulla, suggesting that the blood-thymus barrier might function more completely in the cortex.Cortical lymphocytes are round and vary in size, whereas medullary lymphocytes are mainly small, although they vary considerably in surface morphology.Two types of large wandering cells, macrophages and IDCs, could be distinguished, as well as intermediate forms. IDCs sometimes embraced or contacted lymphocytes, suggesting their role in the differentiation of the latter cells.Perivascular channels were present around venules and some arterioles in the cortico-medullary region and in the medulla. A few lymphatic vessels were present in extended perivascular spaces.The present study suggests the possible existence of two routes of passage of lymphocytes into the general circulation. One is via the lymphatics, while the other is through the postcapillary venules into the blood circulation. Our SEM images give evidence that lymphocytes use an intracellular route, i.e., the endothelium of venules.     

Ultrastructural changes in the thymus of the turtle Mauremys caspica in relation to the seasonal cycle

Summary Changes in the ultrastructure of the thymus of the turtle Mauremys caspica, with special reference to its non-lymphoid components, were studied in relation to the seasonal cycle. The thymic cortex contains framework-forming epithelial-reticular cells and free macrophages, while the medulla includes, in addition, mature and presumptive pro-interdigitating cells. The ultrastructural features of these cells are generally similar to those described for non-lymphoid components of the mammalian thymus. The turtle thymus undergoes cortical involution in spring, with recovery periods in May–June and during autumn. A moderate involution occurs in winter. At the beginning of spring, cortical (but not medullary) epithelial-reticular cells show degenerative changes, probably related to high levels of circulating testosterone. In spring and autumn, mature interdigitating cells are absent, but macrophages, monocytes, and pro-interdigitating cells are found. During May–June, the cortical epithelial-reticular population recovers and macrophages, monocytes, and interdigitating cells are actively phagocytic. In summer, the epithelial-reticular cells in both cortex and medulla display normal ultrastructural features; mature and immature interdigitating cells are absent and some macrophages are detected occasionally. The results suggest that non-lymphoid components of the reptilian thymus can play a role in governing T-lymphocyte differentiation, and that the thymic cortex and medulla exhibit different cycles of seasonal activity.     

Identification of pigment cells during early amphibian development (Triturus alpestris,Ambystoma mexicanum)

Summary The purpose of the present investigation was to provide and apply a methodological manual with which the distribution, patterning and relationship of melanophores and xanthophores can be analyzed during early amphibian development. For demonstration of the methods, which include ultrastructural, histochemical and biochemical approaches, Triturus alpestris and Ambystoma mexicanum (axolotl) embryos are used. These two species differ conspicuously in their larval pigment patterns, showing alternating melanophore bands in horizontal (T. alpestris) and vertical (axolotl) arrangements. With transmission- and scanning electron microscopy melanophores and xanthophores were distinguished by their different pigment organelles and surface structures. The presence of phenol oxidase (tyrosinase) was used to reveal externally invisible or faintly visible melanophores by applying an excess of 3,4 dihydroxy-phenylalanine (dopa). Xanthophores were made visible in fixed and living embryos by demonstrating their pterin fluorescence. In addition, pterins were analyzed by HPLC in embryos before and after pigmentation was visible.Abbreviations DOPA dihydroxy-phenylalanine - FCS fetal calf serum - FIF formaldehyde-induced fluorescence - FITC fluorescein isothiocyanate - HPLC high performance liquid chromatography Dedicated to the memory of Dr. Michael Claviez     

Characterization of glycosaminoglycans during tooth development and mineralization in the axolotl, Ambystoma mexicanum

Glycosaminoglycans (GAGs) involved in the formation of the teeth of Ambystoma mexicanum were located and characterized with the cuprolinic blue (CB) staining method and transmission electron microscopy (TEM). Glycosaminoglycan-cuprolinic blue precipitates (GAGCB) were found in different compartments of the mineralizing tissue. Various populations of elongated GAGCB could be discriminated both according to their size and their preferential distribution in the extracellular matrix (ECM). GAGCB populations that differ in their composition could be attributed not only to the compartments of the ECM but also to different zones and to different tooth types (early-larval and transformed). Larger precipitates were only observed within the dentine matrix of the shaft of the early-larval tooth. The composition of the populations differed significantly between the regions of the transformed tooth: pedicel, shaft and dividing zone. In later stages of tooth formation, small-sized GAGCBs were seen as intracellular deposits in the ameloblasts. It is concluded that the composition of GAGCB populations seems to play a role in the mineralization processes during tooth development in A. mexicanum and influence qualitative characteristics of the mineral in different tooth types and zones, and it is suggested that GAGs might be resorbed by the enamel epithelium during the late phase of enamel formation.     

Three muscle fibre types in the axial muscle of axolotl (Ambystoma mexicanum Shaw) A quantitative lightand electron microscopic study

Morphometric analysis by light microscopy of p-phenylene-diamine stained semithin sections of axolotl tail muscle revealed differences in the cross-sectional area of the fibres and in the number of mitochondria and of lipid inclusions per fibre, and indicated the presence of three distinct types of fibres. The tripartition was found to be statistically highly significant. Representative fibres from each group established by light microscopic morphometry were subjected to an ultrastructural morphometric analysis. The volume content of mitochondria amounted to 9.8% of the fibre volume for red, 4.0% for intermediate and 0.8% for white fibres. The myofibrils composed 60%, 70% and 83% in the same fibres. The volume of the sarcotubular system (t-tubuli and sarcoplasmic reticulum) was 2.5% in red, 4.5% in intermediate and 11.7% in white fibres. The three fibre types also demonstrated differences in myofibrillar cross-striation pattern and number of triads. The reliability of the light microscopic morphometry was tested by correlation with EM montages of the representative fibres.     

Melanin as a natural germ cell marker for intraspecific transplantation experiments in Ambystoma mexicanum (Urodela,Amphibia)

Summary In urodele amphibians, the lack of a reliable germ cell marker restricts the experimental study of the germ lineage. In the present work, we conducted genetic and histological analyses in order to demonstrate that melanin from oocytes constitutes a germ cell marker available for intraspecific experiments in Ambystoma mexicanum. Then, using this marker, we implanted germ cells from undifferentiated gonads (stage 48) into the blastocoel of host embryos and investigated their fate and determined state. Our results show that, from this stage on, the donor cells do not differentiate into other cell types; therefore, they are restricted in developmental capacity and irreversibly determined as germ cells. On the other hand, exogenous germ cells were found in an isotopic position until the young tail-bud stage, and then were found in an ectopic position; these results suggest that, from the middle tail-bud stage on, an active process contributes to migration of primordial germ cells to the gonadal territory.     

Heterogeneity of epithelial cells in the human thymus

Summary To evaluate interrelationships among epithelial cells, and between morphology and function in the microenvironment, we studied the ultrastructural morphology of epithelial cells in sections of human thymus from donors aged 2 months to 31 years. Six types of epithelial cells were observed: subcapsular-perivascular (type 1); pale (type 2); intermediate (type 3); dark (type 4); undifferentiated (type 5); and large-medullary (type 6). Cells of types 2, 3 and 4 were found throughout the organ. The type-2 to -4 epithelial cells may represent various stages in a differentiation process. In this, type-2 cells are very active and type-4 cells are possibly degenerating elements. Type-4 cells can also contribute to Hassall's corpuscles. Type-5 cells were located mainly in the cortico-medullary region and showed the morphological characteristics of undifferentiated elements. Type-6 cells were located exclusively in the medulla and displayed characteristics of cellular activity. Small Hassall's corpuscles consisted of type-6 epithelial cells; in larger corpuscles many nuclei of type-6 cells were found. Cells of types 2 and 6 contained tubular structures (diameter approximately 20 nm).Concerning the function of thymus epithelial cells, the features associated with protein synthesis observed in cellular types 2 and 6 make them likely candidates for humoral factor-producing and/or secreting elements. In addition, type-2 and -3 cells in the cortex appear to contribute to a special pattern of epithelium-lymphocyte interaction (thymic nurse cells), as demonstrated by the intracytoplasmic location of lymphocytes in the epithelial cells. The various steps in intrathymic T-cell maturation occur at locations in a microenvironment composed of morphologically distinct epithelial cells.     

Effects of retinoids on regenerating limbs: comparison of retinoic acid and arotinoid at different amputation levels

Summary Retinoic acid and the synthetic retinoid, arotinoid, were compared for their efficacy in inducing proximodistal (PD) pattern duplication in regenerating axolotl limbs, after amputation through either the distal zeugopodium (lower arm or leg) or distal stylopodium (upper arm or leg). At each level of amputation, the morphology of the duplications produced was the same for both retinoids, and the mean level of proximalization was dose-dependent. Blastema formation was delayed by both retinoids and the delay was associated with regression of the limb stump. Blastemas which produced PD duplication to the stylopodial or girdle level grew out from the stump in a posterior direction. In several zeugopodial regenerates, a partially duplicated, PD-reversed zeugopodium regenerated between the stump cartilages and a completely duplicated zeugopodium distally. Arotinoid was 50 times more effective than retinoic acid in evoking duplication. The dose of arotinoid required to duplicate a stylopodium in a stylopodial regenerate was several times higher than the dose required to duplicate a zeugopodium in a zeugopodial regenerate, suggesting differences either in the sensitivity of zeugopodial and stylopodial cells to retinoid, or in the numbers of positional value specifying these segments.     

Differentiation of epithelial cells in the mouse thymus

Summary The foetal and post-natal development of the mouse thymus was studied with the electron microscope paying particular attention to the differentiation of the epithelial cells. At about 13 days' gestation, the thymus was composed principally of undifferentiated epithelial cells and some lymphoblasts. The latter accumulated rapidly but did not show much evidence of mitotic activity until after the development of differentiated cortical epithelial cells which appeared during the 15th day of gestation. Further differentiation of epithelial cells did not occur until near term when medullary cystic epithelial cells appeared, and post-natally when small Hassall's corpuscles were developed. Undifferentiated and dividing epithelial cells were seen in the medulla and were present in all postnatal animals examined.This is publication number 1400 from the Walter & Eliza Hall Institute of Medical Research.The author is grateful to Prof. G. J. V. Nossal, Dr. J. F. A. P. Miller and Dr. P. J. Russell for their interest and assistance with various aspects of this study. Special thanks are due to Miss Mary Bravington for her skilled technical assistance. This investigation was supported by grants from the Jane Coffin Childs Memorial Fund for Medical Research and the National Health and Medical Research Council of Australia. The Electron Microscope Laboratory was equipped and supported by grants from the Australian Research Grants Committee, J. B. Were and Sons and the Potter Foundation.