Immunocytochemical localization and immunochemical characterization of an insulin-related peptide in the insect Leucophaea maderae

Summary Immunocytochemical tests with eight monoclonal antibodies against either bovine or human insulin and seven polyclonal antibodies against bovine insulin were carried out to determine the presence of insulin-like neuropeptides in the brain and affiliated neuroendocrine structures of the insect Leucophaea maderae. Reaction products identified in the brain, subesophageal ganglion, and corpus cardiacum-corpus allatum complex indicate the presence of materials resembling mammalian insulins in its antigenic properties. The immunostaining observed with monoclonal antibodies appears to indicate the occurrence of an insulin-related peptide that shows sequential similarities with parts of both the A- and B-chains of mammalian insulin molecules. These suppositions are supported by the results of dot-blot and two-site time-resolved immunofluorometric assay (TR-IFMA) screenings of fractions of Leucophaea tissue extracts obtained by chromatography. The polyclonal antibodies yielded reaction products in some of the same areas and in additional parts of the neuroendocrine system not visualized by the monoclonal antibodies. Immunoreaction was observed in the following areas: the pars intercerebralis of the protocerebrum, the nervi corporis cardiaci I transporting insulin-like material to the corpus cardiacum, the dorsolateral protocerebral area and the optic lobes, the deutocerebrum, the tritocerebrum, and the subesophageal ganglion. In addition, smaller cell bodies with immunoreactive deposits occur at the border between proto- and deutocerebrum, and in the central area of the protocerebrum. The distribution of reactive material in the corpus cardiacum-corpus allatum complex after use of both groups of antibodies was the same. The fact that polyclonal and monoclonal antibodies yielded reaction products in different cells of the brain suggests either that the two groups of antibodies recognize different epitopes of the same molecule, or that they reveal two different types of immunoreactive molecules related to mammalian insulins. Together with the biochemical data reported by Nagasawa and coworkers (PNAS 83, 1986) the present immunocytochemical analysis has established a closer relationship between mammalian and insect insulins than was previously known.Supported in part by NIH grant NS 2344-02 (B.S.) and SNF grant 11-5082 and 11-7705 (G.N.H.)     

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     

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.     

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     

The relationship between migration and chondrogenic potential of trunk neural crest cells in Ambystoma mexicanum

Based on results of transplantation experiments, it has long been believed that trunk neural crest cells are incapable of chondrogenesis. When pigmented trunk neural crest cells of Ambystoma mexicanum are transplanted to cranial levels of albino (a/a) embryos, the graft cells ultimately produce ectopic fins, but are incapable of following the chondrogenic cranial neural crest pathways. Therefore, heterotopic transplantation does not expose these cells to the same environment experienced by cranial neural crest cells, and is neither an adequate nor a sufficient test of chondrogenic potential. However, in vitro culture of trunk neural crest cells with pharyngeal endoderm does provide a direct test of chondrogenic ability. That cartilage does not form under these conditions demonstrates conclusively that trunk neural crest cells possess no chondrogenic potential.     

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.     

Immunocytochemical localization of Bombyx-PTTH-like molecules in neurosecretory cells of the brain of the migratory locust,Locusta migratoria

Summary Using a monoclonal antibody directed against a synthetic pentadecapeptide corresponding to the N-terminus of the prothoracicotropic hormone (PTTH) of Bombyx mori, we report the presence of immunoreactive molecules in a large number of median neurosecretory cells of the pars intercerebralis of the migratory locust, Locusta migratoria. These cells correspond to the A₁ cell type which we show to contain also neuroparsins, a family of predominant neurohormones of the migratory locust. In contrast, PTTH-like molecules are absent from A₂ cells of the pars intercerebralis which contain Locusta insulin-related peptide (LIRP). Developmental studies show the presence of PTTH-related substances in neurosecretory cells of Locusta migratoria from late embryogenesis to adult development, including ageing vitellogenic female adults.     

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.     

Cysteamine and the endocrine pancreas: Immunocytochemical,immunochemical, and functional aspects

Summary To evaluate the previously reported depletion of pancreatic somatostatin by cysteamine (-mercaptoethylamine), mice were injected subcutaneously with the drug at 300 mg/kg. Immunocytochemical analysis performed on sections from tissue taken at 4 h after the injection revealed an elimination of somatostatin-14-like immunoreactivity without alterations in the somatostatin-28_{(1 – 12)}-like immunoreactivity. In sections from tissues taken at 24 h after injection, no differences between cysteamine-injected animals and controls were observed. Immunochemical analysis of somatostatin-14-like immunoreactivity in pancreatic extracts showed a significant reduction of the concentration (P< 0.001). In contrast, no change in the insulin concentration was observed. Functionally, cysteamine lowered the plasma glucose levels at l h after injection; this effect persisted for 6 h. Plasma insulin levels were likewise reduced transiently by cysteamine. Concomitant administration of somatostatin did not influence these effects of cysteamine. The plasma glucose-lowering effect of cysteamine was seen also in alloxan-diabetic mice. We conclude that cysteamine alters the immunoreactive characteristics of pancreatic somatostatin without affecting the immunoreactivity of insulin, and that cysteamine transiently reduces plasma glucose and insulin levels     

Noradrenergic and adrenergic systems in the brain of the urodele amphibian,Pleurodeles waltlii,as revealed by immunohistochemical methods

The distribution of noradrenaline and adrenaline in the brain of the urodele amphibian Pleurodeles waltlii has been studied with antibodies raised against noradrenaline and the enzymes dopamine--hydroxylase and phenylethanolamine-N-methyltransferase. Noradrenaline-containing cell bodies were found in the anterior preoptic area, the hypothalamic nucleus of the periventricular organ, the locus coeruleus and in the solitary tract/area postrema complex at the level of the obex. Noradrenergic fibers are widely distributed throughout the brain innervating particularly the ventrolateral forebrain, the medial amygdala, the lateral part of the posterior tubercle, the parabrachial region and the ventrolateral rhombencephalic tegmentum. Putative adrenergic cell bodies were found immediately rostral to the obex, ventral to the solitary tract. Whereas the cell bodies and their dendrites were Golgi-like stained, axons were more difficult to trace. Nevertheless, some weakly immunoreactive fibers could be traced to the basal forebrain. A comparison of these results with data previously obtained in anurans reveals not only several general features, but also some remarkable species differences.Abbreviations Acc Nucleus accumbens - AP area postrema - Apl amygdala, pars lateralis - Apm amygdala, pars medialis - ca commissura anterior - Cb cerebellum - cc central canal - Dp dorsal pallium - epl external plexiform layer - gl glomerular layer of the olfactory bulb - H ganglion habenulae - igl internal granular layer - Ip nucleus interpeduncularis - Lc locus coeruleus - Ll lateral line lobe - Lp lateral pallium - Ls lateral septum - ml mitral cell layer - Mp medial pallium - Ms medial septum - nPT nucleus pretectalis - NPv nucleus of the periventricular organ - nV nervus trigeminus - oc optic chiasm - Poa preoptic area - Ri nucleus reticularis inferior - SC nucleus suprachiasmaticus - sol solitary tract - Str striatum - thd thalamus dorsalis - thv thalamus ventralis - To tectum opticum - TP tuberculum posterius - V ventricle - VH ventral hypothalamic nucleus - III nucleus nervi oculomotorii - IXm nucleus motorius nervi glossopharyngei - Xm nucleus motorius nervi vagi     

Comparative immunocytochemical localization of prolactin and somatotropin in the pituitaries of Lepidosiren paradoxa,Rana temporaria and Ambystoma mexicanum

Summary The cellular binding sites of anti-oPRL IgG and anti-bSTH IgG were demonstrated in the pituitary glands of Lepidosiren paradoxa, Rana temporaria and Ambystoma mexicanum by means of the unlabeled antibody enzyme method by light and electron microscopy (the latter only in Lepidosiren). With the light microscope PRL or PRL-like substances and STH or STH-like substances were revealed in two different cell types in the distal lobe corresponding to the acidophils. However, as a result of the insufficient differentiation of the acidophils in Lepidosiren after staining with Brookes' procedure it was not possible to distinguish the two types of acidophils in this animal. Treatment with low dilutions of both anti-oPRL and anti-bSTH IgG revealed simultaneous immunocytochemical staining in both types of acidophils in Lepidosiren and in Rana. These results, indicating that there is antigenic cross-reaction between anti-oPRL and anti-bSTH IgG and both PRL and STH in these animals, are discussed.The electron microscopic investigations of Lepidosiren revealed that the specific anti-oPRL IgG reactive cells contain granules ranging in size from 200 to 300 nm, while the specific anti-bSTH IgG reactive cells contain smaller immunoreactive granules ranging from 80 to 160nm.     

Immunocytochemical localization of muscarinic acetylcholine receptors in the rat endocrine pancreas

Summary Immunocytochemical application of the antimuscarinic acetylcholine receptor antibody M35 to pancreas tissue revealed the target areas for the parasympathetic nervous system. Immunoreactivity in the endocrine pancreas was much higher than that in the exocrine part. Moreover, the endocrine cells at the periphery of the islets of Langerhans displayed the highest level of immunoreactivity. Based on these findings in the mantle of the islets, two types of islets have been distinguished: type-I islets with intensely stained mantle cells, and type-II islets with a much lower concentration of these cells. On average, type-I islets were larger (244.8 m±6.1 SEM) than type-II islets (121.5 m±3.8 SEM). M35-immunoreactivity was present on the majority of D cells, which were characterized by their immunoreactivity to somatostatin [of 446 D cells 356 (79.8%) were M35-immunopositive]. However, only a small proportion of the intensely stained mantle cells belonged to the D cell population. Therefore, it is concluded that the majority of the intensely stained mantle cells represent glucagon-secreting A and/or pancreatic polypeptide-secreting F cells. The intensity of M35-immunoreactivity at the periphery and central core of the islets paralleled the density of cholinergic innervation, suggesting a positive correlation between the intensity of cholinergic transmission and the number of muscarinic acetylcholine receptors at the target structures. The present study further revealed some striking parallels for the muscarinic acetylcholine receptor characteristics between the (endocrine) pancreas and the central nervous system.     

Peripheral projections of nervus terminalis LHRH-containing neurons in the tiger salamander,Ambystoma tigrinum

The peripheral projections of the nervus terminalis (NT) have been difficult to examine due to the weak immunoreactivity of the processes to various antibodies. We performed two experimental manipulations in the tiger salamander in an attempt to increase the luteinizing hormone-releasing hormone-immunoreactive (LHRH-ir) labelling in the peripheral processes of the NT: 1) the NT was sectioned centrally, or 2) a 100 mg melatonin pellet was embedded subcutaneously for 3 days prior to sacriffice. Following these manipulations, animals were sacrifficed and tissue was processed with standard immunocytochemical techniques for the analysis of the distribution of LHRH-ir processes. In the nasal cavity, LHRH-ir fibers were observed projecting 1) into the rostral olfactory epithelium, 2) to Bowman's glands in the lamina propria of the rostromedial olfactory mucosa and ventrolateral mucosa between the main nasal cavity and Jacobson's organ, 3) into the naris constrictor muscle, and 4) along the palatine nerves and ganglia. These lesion and hormone manipulations have enabled the detection of peripheral projections of the NT not observed previously with immunocytochemical procedures alone. The wide distribution of LHRH-ir NT processes in the nasal cavity and cranium suggests that this nerve may influence many different cranial structures during appropriate pheromonal or neuroendocrine events.     

Light- and electron-microscopic immunocytochemistry of a molluscan insulin-related peptide in the central nervous system of Planorbarius corneus

Summary Two groups of cerebral dorsal cells of the pulmonate snail Planorbarius corneus stain positively with antisera raised against synthetic fragments of the B- and C-chain of the molluscan pro-insulin-related prohormone, proMIP-I, of another pulmonate snail, Lymnaea stagnalis. At the light-microscopic level the somata of the dorsal cells and their axons and neurohemal axon terminals in the periphery of the paired median lip nerves are immunoreactive with both antisera. Furthermore, the canopy cells in the lateral lobes of the cerebral ganglia are positive. In addition, MIP_B-immunoreactive neurons are found in most other ganglia of the central nervous system. At the ultrastructural level, pale and dark secretory granules are found in somata and axon terminals of the dorsal cells. Dark granules are about 4 times as immunoreactive to both antisera as pale granules. Release of anti-MIP_B- and anti-MIP_C-immunopositive contents of the secretory granules by exocytosis is apparent in material treated according to the tannic acid method. It is concluded that the dorsal and canopy cells synthesize a molluscan insulin-related peptide that is packed in the cell body into secretory granules and that is subsequently transported to the neurohemal axon terminals and released into the hemolymph by exocytosis. Thus, MIP seems to act as a neurohormone on peripheral targets. On the basis of the analogy between the dorsal cells and the MIP-producing cells in L. stagnalis, it is proposed that the dorsal cells of P. corneus are involved in the control of body growth and associated processes.     

Immunocytochemical localization of CCAP,a novel crustacean cardioactive peptide,in the nervous system of the shore crab,Carcinus maenas L.

Summary Polyclonal antibodies were raised in rabbits against synthetic crustacean cardioactive peptide (CCAP) conjugated to bovine thyroglobulin, and were used to map CCAP-immunoreactive structures in the central nervous system of Carcinus maenas. As expected, the neurohemal pericardial organs (PO) displayed abundant immunoreactivity in nerve fibers and terminals. In addition, immunoreactive neurons were demonstrated in other parts of the nervous system. At least some of them do not appear to terminate in neurohemal structures and may have a non-endocrine, as yet unknown function. Immunoreactive perikarya with a diameter of 25–30 m occur in the brain. They project into the optic and antennary neuropil, and into the eyestalk. One cell was found in the medulla terminalis of the eyestalk and in the connective ganglion, respectively. From the latter, axonal branches could be traced into the brain and the thoracic ganglia (TG). In the TG, small-diameter perikarya give rise to extensive networks of varicose fibers. Some of the perikarya occur in a characteristic paired arrangement with larger CCAP-immunoreactive somata (diameter 40–50 m). These pairs of one small and one large cell occur in all mouthpart and leg segments of the TG, except the abdominal ganglia (AG), where only large cells were found. The main projections of the large neurons comprise one or more fibers in each of the seven segmental nerves (SN), leading to neurosecretory terminals in the PO. The fibers in the SN are joined by branches of an ascending axonal tract from the large perikarya in the AG. The large-type perikarya are considered to be the principal source of CCAP in the PO. The optic ganglia in the eyestalk, except the medulla terminalis, the neurohemal sinus gland and the stomatogastric nervous system are devoid of CCAP-immunoreactivity.In axon terminals of the PO, CCAP is not colocalized with other PO-neuropeptides, i.e. proctolin-, FMRFamide-like, and Leu-enkephalin-like immunoreactive materials. Electron-microscopic immunocytochemistry revealed a distinct CCAP-containing granule type in specific axon profiles and terminals in the PO.The architecture of CCAP-immunoreactive neurons is discussed with respect to previous morphological studies on the origin and pathways of fibers terminating in the PO.Dedicated to Professor K.E. Wohlfarth-Bottermann, Bonn, on the occasion of his 65^th birthday     

Immunocytochemical localization of histamine in flatworms

Summary Specific antibodies against histamine were used to demonstrate the occurrence and cellular distribution of histamine-like immunoreactivity in three species of flatworms (phylum Platyhelminthes). In the parasitic cestode Diphyllobothrium dendriticum, histamine-reactivity was found in neurons of the main nerve cords, and in cells lining the central and peripheral excretory ducts. In the free-living microturbellarian Microstomum lineare and in the planarian Polycelis nigra, histamine-immuno-reactivity was restricted to cells and fibres of the nervous system. The occurrence of histamine or a related substance in the nervous system of flatworms, which represent primary bilateria, indicates the importance of this neuroactive substance in the animal kingdom.     

The axolotl thymus: cell types of the microenvironment

Summary The three-dimensional structure of the axolotl (urodele amphibian) thymus was studied by combined scanning and transmission electron microscopy. The epithelial cell is the major component of the microenvironment forming the meshwork where thymocytes differentiate. Three different types of epithelial cells could be defined by their intracytoplasmic organelles and their localization in the subcapsular or deeper part of the organ. These epithelial cells participate in various types of lymphostromal interactions. Other stromal elements, such as interdigitating reticular cells, macrophages, eosinophil granulocytes and epithelial cysts were also defined. The absence of a true cortico-medullary differentiation in the axolotl thymus, the presence of different stromal elements and the physiological significance of these various microenvironments are discussed.     

Immunocytochemical localization and characterization of mammalian prolactin- and somatotropin-like material in the pituitary of the Australian lungfish,Neoceratodus forsteri

The aim of the present study was to define at the light-microscopic level expression of prolactin and somatotropin material in the pituitary gland of the Australian lungfish, Neoceratodus forsteri, by use of polyclonal antibodies against ovine prolactin (oPRL) and bovine somatotropin (bSTH). Substances immunologically related to mammalian oPRL as well as bSTH were detected in two morphologically different cell types in the distal lobe, corresponding to the acidophilic cells. The specificity of the antibodies was initially confirmed in a porcine tissue control system. First, our absorption studies confirm that in Neoceratodus the anti-oPRL identifies part of an oPRL-like molecule different from bSTH. Secondly, the anti-bSTH identifies both part of a bSTH-like molecule proper to bovine and Neoceratodus STH, and part of a bSTH-like molecule having antigenic determinants in common with both bSTH and oPRL. This part of the oPRL is, however, not shared with the Neoceratodus PRL as revealed by the anti-oPRL. Altogether these observations support the concepts: (1) that mammalian PRL and STH, or part of those, were established early in evolution, and (2) that dipnoans as living sarcopterygians have an ancestor in common with the early amphibians. The exact nature and physiological functions of the substances detected remain to be defined.     

Immunocytochemical localization of vasotocin-like immunoreactivity in the brain of the cartilaginous fish,Scyliorhinus caniculus

Summary The distribution of vasotocin-like peptides in the central nervous system of the cartilaginous fish Scyliorhinus canicula was determined by indirect immunofluorescence and peroxidase anti-peroxidase techniques, using a specific antiserum raised in rabbits against synthetic vasotocin. Immunoreactive perikarya were mainly detected in the anterior hypothalamus, within the midcaudal part of the preoptic nucleus. The most rostral positive cell bodies were located in the dorso-lateral parts of the preoptic area, whereas at a more caudal level, they took a ventro-medial position within the deepest layers of the nucleus. Throughout the preoptic region these cells varied in shape according to their location. Occasionally, scattered vasotocin-like immunopositive cells were also identified in the nucleus periventricularis hypothalami. Vasotocin immunoreactivity was detected in numerous varicose nerve fibers of the preopticohypophysial tract. These fibers were seen to course through the medio-basal hypothalamus and caudally, after having passed the hypophysial stem, they reached the neurointermediate lobe of the pituitary. Numerous immunoreactive fibers were also observed within the rostro-medial region of the median eminence. At this level the fibers were in close proximity to the capillary loops. In the preoptic region, some stained cells exibited short processes that appeared to contact non-reactive perikarya. By comparing the distribution of vasotocin- and corticotropin-releasing factor immunoreactivity on adjacent then serial sections, it was revealed that these peptides, in S. canicula, do not coexist in the same perikarya. The present results, are compared with those obtained in other vertebrate groups, and their possible functional implications are discussed.     

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