The cardiac mutant Mexican axolotl is a unique animal model for evaluation of cardiac myofibrillogenesis

Hearts from cardiac mutant Mexican axolotl, Ambystoma mexicanum, do not form organized myofibrils and fail to beat. Though previous biochemical and immunohistochemical experiments showed a possible reduction of cardiac tropomyosin it was not clear that this caused the lack of organized myofibrils in mutant hearts. We used cationic liposomes to introduce both rabbit and chicken tropomyosin protein into whole hearts of embryonic axolotls in whole heart organ cultures. The mutant hearts had a striking increase in the number of well-organized sarcomeric myofibrils when treated with rabbit or chicken tropomyosin. FITC-labeled rabbit tropomyosin was used to examine the kinetics of incorporation of the exogenous protein into mutant hearts and confirmed the uptake of exogenous protein by the cells of live hearts in culture. By 4 h of transfection, both normal and mutant hearts were found to incorporate FITC-labeled tropomyosin into myofibrils. We also delivered an anti-tropomyosin antibody (CH 1) into normal hearts to disrupt the existing cardiac myofibrils which also resulted in reduced heartbeat rates. CH1 antibody was detected within the hearts and disorganization of the myofibrils was apparent when compared to normal controls. Introduction of a C-protein monoclonal antibody (ALD 66) did not result in a disruption of organized myofibrils. The results show clearly that chicken or rabbit tropomyosin could be incorporated by the mutant hearts and that it was sufficient to overcome the factors causing a lack of myofibril formation in the mutant. This finding also suggests that a lack of organized myofibrils is caused primarily by either inadequate levels of tropomyosin or endogenous tropomyosin in mutant hearts is unsuitable for myofibril formation, which we were able to duplicate with the introduction of tropomyosin antibody. Furthermore, incorporation of a specific exogenous protein or antibody into normal and mutant hearts of the Mexican axolotl in whole heart organ culture offers an unique model to evaluate functionalroles of contractile proteins necessary for cardiac development and differentiation.     

Myofibril-Inducing RNA (MIR) is essential for tropomyosin expression and myofibrillogenesis in axolotl hearts

The Mexican axolotl, Ambystoma mexicanum, carries the naturally-occurring recessive mutant gene 'c' that results in a failure of homozygous (c/c) embryos to form hearts that beat because of an absence of organized myofibrils. Our previous studies have shown that a noncoding RNA, Myofibril-Inducing RNA (MIR), is capable of promoting myofibrillogenesis and heart beating in the mutant (c/c) axolotls. The present study demonstrates that the MIR gene is essential for tropomyosin (TM) expression in axolotl hearts during development. Gene expression studies show that mRNA expression of various tropomyosin isoforms in untreated mutant hearts and in normal hearts knocked down with double-stranded MIR (dsMIR) are similar to untreated normal. However, at the protein level, selected tropomyosin isoforms are significantly reduced in mutant and dsMIR treated normal hearts. These results suggest that MIR is involved in controlling the translation or post-translation of various TM isoforms and subsequently of regulating cardiac contractility.     

A lethal mutant gene in the Mexican axolotl

Gene ph was discovered in a wild-type axolotl male received from Mexico City. Larvae homozygous for this gene become recognizable by their lighter color at hatching or shortly after. The development of their forelimbs is retarded, and all limbs are of subnormal length because of the reduction in length of their long bones. Many affected larvae die without feeding, and very few survive beyond their third month. At death, older larvae usually show abnormalities of the renal system, edema, ascites, or adhesions of the viscera. The gene is apparently a simple recessive with full penetrance.     

Analysis of the endocardium and cardiac jelly in truncal development in the cardiac lethal mutant axolotl Ambystoma mexicanum

Recessive mutant gene c in axolotls results in a failure of the heart to function because of abnormal embryonic induction processes. The myocardium in this mutant lacks organized sarcomeric myofibrils. The present study was undertaken to determine if developmental abnormalities were evident in other areas of the heart besides the myocardium. A detailed comparative survey of the structure of developing normal and mutant hearts, including the endocardium, its cellular derivatives, and the extracellular matrix, known as cardiac jelly, showed that in the mutant there are fewer than the normal number of endocardial cells lining the heart lumen, the number of mesenchyme cells is reduced, and the cardiac jelly area is greatly enlarged in the posterior part of the truncus adjacent to the ventricle.     

Induction of metallothionein by zinc in lethal milk mutant mice

Adult lethal milk (lm/lm) mutant mice display increased induction of hepatic metallothionein synthesis compared to wild-type mice following the subcutaneous injection of 40 µmol ZnCl₂/kg mouse. At this zinc dose the rate of incorporation of |³⁵S| cysteine into hepatic metallothionein in adult (100-to 230-day-old) lm/lm mice was approximately 2.4-fold greater than the rate of incorporation of isotope in wild-type animals. At a higher zinc dose (160 µmol ZnCl₂/kg) the incorporation of |³⁵S| cysteine into hepatic metallothionein was similar in lm/lm and wild-type mice. The altered dose-response to zinc administration was not due to a change in hepatic zinc, copper, or manganese levels, to a difference in ⁶⁵Zn uptake, or to an alteration in ⁶⁵Zn bound to differential centrifugation fractions of adult lm/lm liver. ⁶⁵Zn bound to hepatic metallothionein was, however, increased in aging lm/lm mice with symptomatic skin lesions.     

Induction by the endoderm in birds

Ohne Zusammenfassung     

Immunofluorescent studies on titin and myosin in developing hearts of normal and cardiac mutant axolotls

Homozygous recessive cardiac mutant gene c in the axolotl, Ambystoma mexicanum, results in a failure of the embryonic heart to initiate beating. Previous studies show that mutant axolotl hearts fail to form sarcomeric myofibrils even though hearts from their normal siblings exhibit organized myofibrils beginning at stage 34–35. In the present study, the proteins titin and myosin are studied using normal (+/+) axolotl embryonic hearts at stages 26–35. Additionally, titin is examined in normal (+/c) and cardiac mutant (c/c) embryonic axolotl hearts using immunofluorescent microscopy at stages 35–42. At tailbud stage-26, the ventromedially migrating sheets of precardiac mesoderm appear as two-cell-layers. Myosin shows periodic staining at the cell peripheries of the presumptive heart cells at this stage, whereas titin is not yet detectable by immunofluorescent microscopy. At preheartbeat stages 32–33, a myocardial tube begins to form around the endocardial tube. In some areas, periodic myosin staining is found to be separated from the titin staining; other areas in the heart at this stage show a co-localization of the two proteins. Both titin and myosin begin to incorporate into myofibrils at stage 35, when normal hearts initiate beating. Additionally, areas with amorphous staining for both proteins are observed at this stage. These observations indicate that titin and myosin accumulate independently at very early premyofibril stages; the two proteins then appear to associate closely just before assembly into myofibrils. Staining for titin in freshly frozen and paraffin-embedded tissues of normal embryonic hearts at stages 35, 39, and 41 reveals an increased organization of the protein into sarcomeres as development progresses. The mutant siblings, however, first show titin staining only limited to the peripheries of yolk platelets. Although substantial quantities of titin accumulate in mutant hearts at later stages of development (39 and 41), it does not become organized into myofibrils as in normal cells at these stages. © 1994 Wiley-Liss, Inc.     

Myocardial cell relationships during morphogenesis in normal and cardiac lethal mutant axolotls, Ambystoma mexicanum

Sarcomere formation has been shown to be deficient in the myocardium of axolotl embryos homozygous for the recessive cardiac lethal gene c. We examined the developing hearts of normal and cardiac mutant embryos from tailbud stage 33 to posthatching stage 43 by scanning electron microscopy in order to determine whether that deficiency has any effect on heart morphogenesis. Specifically, we investigated the relationships of myocardial cells during the formation of the heart tube (stage 33), the initiation of dextral looping (stages 34-36), and the subsequent flexure of the elongating heart (stages 38-43). In addition, we compared the morphogenetic events in the axolotl to the published accounts of comparable stages in the chick embryo. In the axolotl (stage 33), changes in cell shape and orientation accompany the closure of the myocardial trough to form the tubular heart. The ventral mesocardium persists longer in the axolotl embryo than in the chick and appears to contribute to the asymmetry of dextral looping (stages 34-36) in two ways. First, as a persisting structure it places constraints on the simple elongation of the heart tube and the ability of the heart to bend. Second, after it is resorbed, the ventral myocardial cells that contributed to it are identifiable by their orientation, which is orthogonal to adjacent cells: a potential source of shearing effects. Cardiac lethal mutant embryos behave identically during these events, indicating that functional sarcomeres are not necessary to these processes. The absence of dynamic apical myocardial membrane changes, characteristic of the chick embryo (Hamburger and Hamilton stages 9-11), suggests that sudden hydration of the cardiac jelly is less likely to be a major factor in axolotl cardiac morphogenesis. Subsequent flexure (stages 38-43) of the axolotl heart is the same in normal and cardiac lethal mutant embryos as the myocardial tube lengthens within the confines of a pericardial cavity of fixed length. However, the cardiac mutant begins to exhibit abnormalities at this time. The lack of trabeculation (normally beginning at stage 37) in the mutant ventricle is evident at the same time as an increase in myocardial surface area, manifest in extra bends of the heart tube at stage 39. Nonbeating mutant hearts (stage 41) have an abnormally large diameter in the atrioventricular region, possibly the result of the accumulation of ascites fluid. In addition, mutant myocardial cells have a larger apical surface area compared to normals.     

High molecular weight extracellular proteins synthesized by endoderm cells derived from mouse teratocarcinoma cells and normal extraembryonic membranes

Rabbit antiserum raised against teratocarcinoma embryoid bodies reacts with two extracellular, collagenase-resistant glycoproteins, PYS A and B, with molecular weights of approximately 350,000 and 220,000 daltons. The 220,000-dalton protein is distinguishable from fibronectin. The two proteins are synthesized and secreted into the medium in large amounts by the teratocarcinoma-derived parietal endoderm line PYS-1, and by normal parietal endoderm cells from the 10.5-day embryo. There was no detectable synthesis of PYS A and B by normal visceral endoderm cells isolated from the 10.5-day embryo, and only trace amounts of PYS A were synthesized by the teratocarcinoma-derived visceral endoderm line PSA5E and by mesodermal cells isolated from the visceral yolk sac. The two proteins therefore seem to be good biochemical markers for distinguishing parietal from visceral endoderm cells. Synthesis and secretion of PYS A and B could not be detected in undifferentiated embryonal carcinoma cells or in endoderm cells derived from them in the presence of retinoic acid.     

Role of desmin filaments in chicken cardiac myofibrillogenesis

Desmin filaments are muscle-specific intermediate filaments located at the periphery of the Z-discs, and they have been postulated to play a critical role in the lateral registration of myofibrils. Previous studies suggest that intermediate filaments may be involved in titin assembly during the early stages of myofibrillogenesis. In order to investigate the putative function of desmin filaments in myofibrillogenesis, rabbit anti-desmin antibodies were introduced into cultured cardiomyocytes by electroporation to perturb the normal function of desmin filaments. Changes in the assembly of several sarcomeric proteins were examined by immunofluorescence. In cardiomyocytes incorporated with normal rabbit serum, staining for alpha-actinin and muscle actin displayed the typical Z-line and I-band patterns, respectively, while staining for titin with monoclonal anti-titin A12 antibody, which labels a titin epitope at the A-I junction, showed the periodic doublet staining pattern. Staining for C-protein gave an amorphous pattern in early cultures and identified A-band doublets in older cultures. In contrast, in cardiomyocytes incorporated with anti-desmin antibodies, alpha-actinin was found in disoriented Z-discs and the myofibrils became fragmented, forming mini-sarcomeres. In addition, titin was not organized into the typical A-band doublet, but appeared to be aggregated. Muscle actin staining was especially weak and appeared in tiny clusters. Moreover, in all ages of cardiomyocytes tested, C-protein remained in the disassembled form. The present data suggest the essential role of desmin in myofibril assembly.     

Morphology of developing heart in cardiac lethal mutant Mexican axolotls, Ambystoma mexicanum

In Ambystoma mexicanum, recessive mutant gene c results in an absence of embryonic heart function because of altered influences from surrounding tissues (Humphrey, 1972). The present light and electron microscope study compares heart development in normal and mutant embryos from Harrison stage 34 or 6 days (at which normal heart beat initiates) through stage 41 or 25 days (at which mutant embryos die). The hearts display increasing differences as development progresses, and by stage 41 mutant abnormalities are striking. The normal myocardium shows organized sarcomeres at stage 34 and numerous intercalated discs subsequently appear. By stage 41, the normal myocardium is composed of highly differentiated muscle cells and shows extensive trabeculation. The mutant myocardium throughout development remains only one cell layer thick with no indication of developing trabeculae. Mutant cells at stage 34 have a few 140 Å and 60 Å filaments along with what appear to be Z bodies. A partial organization of myofibrillar components is occasionally noted at stages 38–41; however, distinct sarcomeres are not apparent and intercalated discs are rarely seen. In general the mutant cells appear less differentiated than usual and in many respects are reminiscent of pre-heart-beat normal cells. Although most mutant cells show images characteristic of pathological conditions (e.g., pleomorphic mitochondria, membranous whorls, and numerous autophagic vacuoles), selective myocardial cell death, a phenomenon associated with normal trabeculation, is not evident. It is clear that gene c, in homozygous condition, results in an altered pattern of heart cell differentiation. The mutation, by way of abnormal inductive processes, appears to affect the synthesis and organization of heart contractile proteins.     

Induction of autophagy by anthrax lethal toxin

Autophagy is an evolutionary conserved intracellular process whereby cells break down long-lived proteins and organelles. Accumulating evidences suggest increasing physiological significance of autophagy in pathogenesis of infectious diseases. Anthrax lethal toxin (LT) exerts its influence on numerous cells and herein, we report a novel effect of LT-induced autophagy on mammalian cells. Several autophagy biochemical markers including LC3-II conversion, increased punctuate distribution of GFP-LC3 and development of acidic vesicular organelles (AVO) were detected in cells treated with LT. Analysis of individual LT component revealed a moderate increase in LC3-II conversion for protective antigen-treated cells, whereas the LC3-II level in lethal factor-treated cells remained unchanged. In addition, our preliminary findings suggest a protective role of autophagy in LT intoxication as autophagy inhibition resulted in accelerated cell death. This study presents a hitherto undescribed effect of LT-induced autophagy on cells and provides the groundwork for future studies on the implication of autophagy in anthrax pathogenesis.     

Immunofluorescent, immunogold, and electrophoretic studies for desmin in embryonic hearts of normal and cardiac mutant Mexican axolotls, Ambystoma mexicanum

Recessive mutant gene c for "cardiac nonfunction" in axolotls results in an absence of normal heart contractions in affected embryos due to a failure of myofibril formation. In the present study, the intermediate filament protein, desmin, is compared in developing normal and mutant hearts by means of two-dimensional gel electrophoresis, immunofluorescent microscopy, and immunoelectron microscopy. Tissues were fixed in periodate-lysine-paraformaldehyde or paraformaldehyde-glutaraldehyde solutions and rapidly frozen or embedded in Lowicryl resin. Frozen sections stained with FITC-conjugated antibodies by an indirect approach revealed that desmin is localized in the I-band regions of adult cardiac myofibrils. In normal embryonic hearts at stage 32 (preheartbeat) desmin is localized as "spots" or amorphous collections in the cells. As development progresses to stage 35, staining for desmin in normal hearts becomes more intense with localization being most pronounced at the cell peripheries. By stage 41 most of the desmin in normal hearts is localized in the I band areas of the organized myofibrils and the staining of amorphous areas is much less prominent. During early development, the distribution of desmin in mutant hearts is similar to normal. However, while most of the desmin in normal organs at stage 41 is associated with myofibrils, the staining remains diffuse in mutants. Two-dimensional gel electrophoresis reveals comparable patterns for desmin from normal and mutant hearts. Immunogold staining shows desmin localization to be between the myofibrils and around the I-band regions in adult cardiac muscle and in stage 41 normal embryonic hearts. Immunogold staining confirms a diffuse distribution of desmin in mutant hearts.     

Differentiation-dependent production of a platelet-derived growth factor-like mitoattractant by endoderm cells derived from embryonal carcinoma cells

Retinoic acid-induced differentiation of F9 embryonal carcinoma cells to endoderm provokes the secretion of a protein factor that acts as both a chemoattractant and mitogen for smooth muscle cells. Undifferentiated F9 cells and PSA-5E (visceral endodermlike) cells produced little of this factor. However, PYS-2 (parietal endodermlike) and Dif 5 endoderm cells were found to produce significant amounts of endoderm-derived mitoattractant (EDM) activity. The activity secreted by the Dif 5 cells was partially purified using gel filtration chromatography using chemotaxis and mitogenic assays as markers for biological activity. The partially purified activity competes with [125I]iodo-platelet-derived growth factor (PDGF) for binding to target cells, and the biological activity is neutralized with anti-PDGF IgG, suggesting shared domains in the two molecules. However, the factor appears to be different from PDGF, based on its thermal stability, molecular weight, and charge. The differentiated endoderm cells including retinoic acid (RA)-treated F9, Dif 5, PSA-5E, and PYS-2 cells also exhibit specific [125I]iodo-PDGF binding, and the PSA-5E cells respond to PDGF as a chemoattractant. Conceivably, such a PDGF-like factor may contribute to the regulation of cell growth and migration during the early stages of embryogenesis.     

Studies on the function of Rho A protein in cardiac myofibrillogenesis

The aim of this study was to provide morphological evidence for the presence of rho A protein in developing cardiomyocytes and to investigate its possible role in myofibrillogenesis. Immunostaining with a monoclonal anti-rho antibody gave a diffuse pattern in the cytosol of cultured cardiomyocytes. Introduction of C3 exoenzyme into the cells by electroporation was used to inactivate rho A protein by ADP-ribosylation. An immunostaining with anti-vinculin, anti-talin, and anti-integrin antibodies showed the focal adhesions in electroporation control cardiomyocytes to be evenly distributed in the ventral sarcolemma; the costameric structure was also detected using these antibodies. In contrast, in C3 exoenzyme treated cells, focal adhesions were disassembled and costamere were absent; in addition, β-actin-positive, non-striated fibrils were lost and assembly of M-protein, titin, and α-actinin into myofibrils was poor, as shown by diffuse and filamentous staining pattern. C3 exoenzyme treatment had a less marked effect on mature cardiomyocytes than on immature cells; in this case, cells became distorted and few myofibrils were seen. The intensity of anti-phosphotyrosine antibody staining of the focal adhesion was also decreased or diffuse in C3 exoenzyme-treated cardiomyocytes, suggesting dephosphorylation of focal adhesion components. We therefore conclude that small G protein rho A plays an important role in myofibril assembly in cardiomyocytes. J. Cell. Biochem. 66:43–53, 1997. © 1997 Wiley-Liss, Inc.