Does Nebulin Make Tropomyosin Less Dynamic in Mature Myofibrils in Cross-Striated Myocytes?

Myofibrils in vertebrate cardiac and skeletal muscles are characterized by groups of proteins arranged in contractile units or sarcomeres, which consist of four major components - thin filaments, thick filaments, titin and Z-bands. The thin actin/tropomyosin-containing filaments are embedded in the Z-bands and interdigitate with the myosin-containing thick filaments aligned in A-bands. Titin is attached to the Z-band and extends upto the middle of the A-Band. In this mini review, we have addressed the mechanism of myofibril assembly as well as the dynamics and maintenance of the myofibrils in cardiac and skeletal muscle cells. Evidence from our research as well as from other laboratories favors the premyofibril model of myofibrillogenesis. This three-step model (premyofibril to nascent myofibril to mature myofibril) not only provides a reasonable mechanism for sequential interaction of various proteins during assembly of myofibrils, but also suggests why the dynamics of a thin filament protein like tropomyosin is higher in cardiac muscle than in skeletal muscles. The dynamics of tropomyosin not only varies in different muscle types (cardiac vs. skeletal), but also varies during myofibrillogenesis, for example, premyofibril versus mature myofibrils in skeletal muscle. One of the major differences in protein composition between cardiac and skeletal muscle is nebulin localized along the thin filaments (two nebulins/thin filament) of mature myofibrils in skeletal muscle cells, but which is expressed in a minimal quantity (one nebulin/50 actin filaments) in ventricular cardiomyocytes. Interestingly, nebulin is not associated with premyofibrils in skeletal muscle. Our FRAP(Fluorescence Recovery After Photobleaching) results suggest that tropomyosin is more dynamic in premyofibrils than in mature myofibrils in skeletal muscle, and also, the dynamics of tropomyosin in mature myofibrils is significantly higher in cardiac muscle compared to skeletal muscle. Our working hypothesis is that the association of nebulin in mature myofibrils renders tropomyosin less dynamic in skeletal muscle.

Molecular and immunohistochemical analyses of cardiac troponin T during cardiac development in the Mexican axolotl, Ambystoma mexicanum.

The Mexican axolotl, Ambystoma mexicanum, is an excellent animal model for studying heart development because it carries a naturally occurring recessive genetic mutation, designated gene c, for cardiac nonfunction. The double recessive mutants (c/c) fail to form organized myofibrils in the cardiac myoblasts resulting in hearts that fail to beat. Tropomyosin expression patterns have been studied in detail and show dramatically decreased expression in the hearts of homozygous mutant embryos. Because of the direct interaction between tropomyosin and troponin T (TnT), and the crucial functions of TnT in the regulation of striated muscle contraction, we have expanded our studies on this animal model to characterize the expression of the TnT gene in cardiac muscle throughout normal axolotl development as well as in mutant axolotls. In addition, we have succeeded in cloning the full-length cardiac troponin T (cTnT) cDNA from axolotl hearts. Confocal microscopy has shown a substantial, but reduced, expression of TnT protein in the mutant hearts when compared to normal during embryonic development.

Downregulation of N1 gene expression inhibits the initial heartbeating and heart development in axolotls.

Recessive mutant gene c in the axolotl results in a failure of affected embryos to develop contracting hearts. This abnormality can be corrected by treating the mutant heart with RNA isolated from normal anterior endoderm or from endoderm conditioned medium. A cDNA library was constructed from the total conditioned medium RNA using a random priming technique in a pcDNAII vector. We have previously identified a clone (designated as N1) from the constructed axolotl cDNA library, which has a unique nucleotide sequence. We have also discovered that the N1 gene product is related to heart development in the Mexican axolotl [Cell Mol. Biol. Res. 41 (1995) 117]. In the present studies, we further investigate the role of N1 on heartbeating and heart development in axolotls. N1 mRNA expression has been determined by using semi-quantitative RT-PCR with specifically designed primers. Normal embryonic hearts (at stages 30-31) have been transfected with anti-sense oligonucleotides against N1 to determine if downregulation of N1 gene expression has any effect on normal heart development. Our results show that cardiac N1 mRNA expression is partially blocked in the hearts transfected with anti-sense nucleotides and the downregulation of N1 gene expression results in a decrease of heartbeating in normal embryos, although the hearts remain alive as indicated by calcium spike movement throughout the hearts. Confocal microscopy data indicate some myofibril disorganization in the hearts transfected with the anti-sense N1 oligonucleotides. Interestingly, we also find that N1 gene expression is significantly decreased in the mutant axolotl hearts. Our results suggest that N1 is a novel gene in Mexican axolotls and it probably plays an important role in myofibrillogenesis and in the initiation of heartbeating during heart development.

Relationship between cardiac protein tyrosine phosphorylation and myofibrillogenesis during axolotl heart development.

The axolotl, Ambystoma mexicanum, is a useful system for studying embryogenesis and cardiogenesis. To understand the role of protein tyrosine phosphorylation during heart development in normal and cardiac mutant axolotl embryonic hearts, we have investigated the state of protein tyrosine residues (phosphotyrosine, P-Tyr) and the relationship between P-Tyr and the development of organized sarcomeric myofibrils by using confocal microscopy, two-dimensional isoelectric focusing (IEF)/SDS-polyacrylamide gel electrophoresis (PAGE) and immunoblotting analyses. Western blot analyses of normal embryonic hearts indicate that several proteins were significantly tyrosine phosphorylated after the initial heartbeat stage (stage 35). Mutant hearts at stages 40-41 showed less tyrosine phosphorylated staining as compared to the normal group. Two-dimensional gel electrophoresis revealed that most of the proteins from mutant hearts had a lower content of phosphorylated amino acids. Confocal microscopy of stage 35 normal hearts using phosphotyrosine monoclonal antibodies demonstrated that P-Tyr staining gradually increased being localized primarily at cell-cell boundaries and cell-extracellular matrix boundaries. In contrast, mutant embryonic hearts showed a marked decrease in the level of P-Tyr staining, especially at sites of cell-cell and cell-matrix junctions. We also delivered an anti-phosphotyrosine antibody (PY 20) into normal hearts by using a liposome-mediated delivery method, which resulted in a disruption of the existing cardiac myofibrils and reduced heartbeat rates. Our results suggest that protein tyrosine phosphorylation is critical during myofibrillogenesis and embryonic heart development in axolotls.

Creation of chimeric mutant axolotls: a model to study early embryonic heart development in Mexican axolotls.

The Mexican axolotl (Ambystoma mexicanum) provides an excellent model for studying heart development since it carries a cardiac lethal mutation in gene c that results in failure of contraction of mutant embryonic myocardium. In cardiac mutant axolotls (c/c) the hearts do not beat, apparently because of an absence of organized myofibrils. To date, there has been no way to analyze the genotypes of embryos from heterozygous spawnings (+/c x +/c) until stage 35 when the normal (+/c or +/+) embryos first begin to have beating hearts; mutant (c/c) embryos fail to develop normal heartbeats. In the present study, we created chimeric axolotls by using microsurgical techniques. The general approach was to transect tailbud embryos and join the anterior and posterior halves of two different individuals. The chimeric axolotl is composed of a normal head and heart region (+/+), permitting survival and a mutant body containing mutant gonads (c/c) that permits the production of c/c mutant offspring: 100% c/c offspring were obtained by mating c/c chimeras (c/c x c/c). The mutant phenotypes were confirmed by the absence of beating hearts and death at stage 41 in 100% of the embryos. Examination of the mutant hearts with electron microscopy and comfocal microscopy after immunofluorescent staining for tropomyosin showed identical images to those described previously in naturally-occurring c/c mutant axolotls (i.e., lacking organized sarcomeric myofibrils). These "c/c chimeric" axolotls provide a useful and unique way to investigate early embryonic heart development in cardiac mutant Mexican axolotls.

Expression of HoxA5 in the heart is upregulated during thyroxin-induced metamorphosis of the Mexican axolotl (Ambystoma mexicanum).

Widespread external and internal changes in body morphology have long been known to be hallmarks of the process of metamorphosis. However, more subtle changes, particularly at the molecular level, are only now beginning to be understood. A number of transcription factors have recently been shown to alter expression either in levels of message or in isoforms expressed. In this article, we describe a dramatic increase in the expression of the homeobox gene HoxA5 in the heart and aorta of the Mexican axolotl Ambystoma mexicanum during the process of thyroxin-induced metamorphosis. Immunohistochemical analysis with anti-HoxA5 antibody in thyroxin-induced metamorphosing animals showed a pattern of expression of HoxA5 comparable to that in spontaneously metamorphosing animals. Further, by in situ hybridization, we were able to show significant qualitative differences in the expression of this gene within the heart. Maximum HoxA5 expression occurred at the midpoint of metamorphosis in the myocardium, whereas the hearts of completely metamorphosed animals had the highest levels of expression in the epicardium and endocardium. In the aorta, smooth-muscle cells of the tunica media as well as cells of the tunica adventitia had an increase in expression of HoxA5 with thyroxin-induced metamorphosis. HoxA5 expression significantly changed in cells of the aorta and ventricle with treatment by thyroid hormone. HoxA5, a positive regulator of p53, may be involved with the apoptotic pathway in heart remodeling during amphibian metamorphosis.

Alteration of cardiac myofibrillogenesis by liposome-mediated delivery of exogenous proteins and nucleic acids into whole embryonic hearts.

A precise organization of contractile proteins is essential for contraction of heart muscle. Without a necessary stoichiometry of proteins, beating is not possible. Disruption of this organization can be seen in diseases such as familial hypertrophic cardiomyopathy and also in acquired diseases. In addition, isoform diversity may affect contractile properties in such functional adaptations as cardiac hypertrophy. The Mexican axolotl provides an uncommon model in which to examine specific proteins involved with myofibril formation in the heart. Cardiac mutant embryos lack organized myofibrils and have altered expression of contractile proteins. In order to replicate the disruption of myofibril formation seen in mutant hearts, we have developed procedures for the introduction of contractile protein antibodies into normal hearts. Oligonucleotides specific to axolotl tropomyosin isoforms (ATmC-1 and ATmC-3), were also successfully introduced into the normal hearts. The antisense ATmC-3 oligonucleotide disrupted myofibril formation and beating, while the sense strands did not. A fluorescein-tagged sense oligonucleotide clearly showed that the oligonucleotide is introduced within the cells of the intact hearts. In contrast, ATmC-1 anti-sense oligonucleotide did not cause a disruption of the myofibrillar organization. Specifically, tropomyosin expression can be disrupted in normal hearts with a lack of organized myofibrils. In a broader approach, these procedures for whole hearts are important for studying myofibril formation in normal hearts at the DNA, RNA, and/or protein levels and can complement the studies of the cardiac mutant phenotype. All of these tools taken together present a powerful approach to the elucidation of myofibrillogenesis and show that embryonic heart cells can incorporate a wide variety of molecules with cationic liposomes.

Expression of axolotl RNA-binding protein during development of the Mexican axolotl.

Amphibians occupy a central position in phylogeny between aquatic and terrestrial vertebrates and are widely used as model systems for studying vertebrate development. We have undertaken a comprehensive molecular approach to understand the early events related to embryonic development in the Mexican axolotl, Ambystoma mexicanum, which is an exquisite animal model for such explorations. Axolotl RBP is a RNA-binding protein which was isolated from the embryonic Mexican axolotl by subtraction hybridization and was found to show highest similarity with human, mouse, and Xenopus cold-inducible RNA-binding protein (CIRP). The reverse transcriptase polymerase chain reaction (RT-PCR) analysis suggests that it is expressed in most of the axolotl tissues except liver; the expression level appears to be highest in adult brain. We have also determined the temporal and spatial pattern of its expression at various stages of development. RT-PCR and in situ hybridization analyses indicate that expression of the AxRBP gene starts at stage 10-12 (gastrula), reaches a maxima around stage 15-20 (early tailbud), and then gradually declines through stage 40 (hatching). In situ hybridization suggests that the expression is at a maximum in neural plate and neural fold at stage 15 (neurula) of embryonic development.

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.

The complete genomic sequence of an HTLV-II isolate from a Guahibo Indian from Venezuela.

A polyclonal CD3(+), CD8(+) T-cell line, G2, was derived from the peripheral blood of a seropositive, PCR-positive, HTLV-IIB infected Guahibo Indian from Venezuela. The cell line is productively infected with HTLV-IIB. The entire HTLV-II G2 proviral DNA was sequenced via PCR using overlapping HTLV-II primer pairs. Phylogenetic analyses indicate that HTLV-II G2 is the most divergent HTLV-IIB strain identified to date. Characterization of its deduced proteins and its relationship to other members of the PTLV/BLV genus of retroviruses are discussed.

Ectopic expression of tropomyosin promotes myofibrillogenesis in mutant axolotl hearts.

Expression of tropomyosin protein, an essential component of the thin filament, has been found to be drastically reduced in cardiac mutant hearts of the Mexican axolotl (Ambystoma mexicanum) with no formation of sarcomeric myofibrils. Therefore, this naturally occurring cardiac mutation is an appropriate model to examine the effects of delivering tropomyosin protein or tropomyosin cDNA into the deficient tissue. In this study, we describe the replacement of tropomyosin by using a cationic liposome transfection technique applied to whole hearts in vitro. When mouse alpha-tropomyosin cDNA under the control of a cardiac-specific alpha-myosin heavy chain promoter was transfected into the mutant hearts, tropomyosin expression was enhanced resulting in the formation of well-organized sarcomeric myofibrils. Transfection of a beta-tropomyosin construct under control of the same promoter did not result in enhanced organization of the myofibrils. Transfection of a beta-galactosidase reporter gene did not result in the formation of organized myofibrils or increased tropomyosin expression. These results demonstrate the importance of alpha-tropomyosin to the phenotype of this mutation and to normal myofibril formation. Moreover, we have shown that a crucial contractile protein can be ectopically expressed in cardiac muscle that is deficient in this protein, with the resulting formation of organized sarcomeres.

Cloning, sequencing and expression of a novel homeobox gene AxNox-1 from the Mexican axolotl.

We have cloned and sequenced a cDNA containing a homeobox gene, AxNox-1, from a stage 18 axolotl embryonic cDNA library which shows only moderate levels of similarity to other known homeobox genes. The nucleotide sequence of the cDNA has an open reading frame for 335 amino acids and besides the homeodomain, there is an acidic domain and a proline-rich domain present in the protein. The transcripts for this gene are detectable at stage 4 of embryonic development and, hence, there is a good possibility that the transcripts are maternally contributed. Expression levels for AxNox-1 reach maximum levels by stage 12 of development and thereafter decline to very low levels by stage 25. High levels of the transcript for AxNox-1 are later found in the brains of both neotenous and metamorphosing adult axolotls. Low amounts of the message are also found to be present in a number of other organs that were tested. In situ hybridization studies on whole mounts and sections suggest that this gene is expressed predominantly in neural tissue during development.

Cloning and sequencing of the cDNA for an RNA-binding protein from the Mexican axolotl: binding affinity of the in vitro synthesized protein.

A full length cDNA for an RNA-binding protein (axolotl RBP) with consensus sequence (RNP-CS) from the Mexican axolotl, Ambystoma mexicanum, has been cloned from a subtraction library. In vitro translation with synthetic mRNA and subsequent hybrid-arrested translation with a specific antisense oligonucleotide confirms that the axolotl RBP cDNA encodes an approx. 16 kDa polypeptide. Computer-assisted analyses revealed amino acid similarities of 58-60% to various RNA-binding proteins and a 90 amino acid region at the amino-terminal end constituting the putative RNA-binding domain (RNP-CS) with two highly conserved motifs, RNP2 and RNP1. Phylogenetic analysis suggests that the putative RNA-binding protein from axolotl is unique. A binding assay with radiolabeled axolotl RBP showed that this RNA-binding protein bound strongly with poly(A) and to a lesser degree with poly(U), but not at all with poly(G), poly(C), or DNA.

The heart of metamorphosing Mexican axolotl but not that of the cardiac mutant is associated with the upregulation of Hox A5.

The Mexican axolotl (Ambystoma mexicanum) is a facultative neotene which rarely undergoes metamorphosis in the wild. We now report for the first time a dramatic increase in the expression of HoxA5 in axolotl hearts as determined by RT-PCR and in situ hybridization analyses during spontaneous metamorphosis. The Mexican axolotl has a naturally occurring mutation called gene c which allows hearts in homozygous (c/c) embryos to form but never to beat. RT-PCR analysis has not shown any significant differences of HoxA5 expression in normal and mutant hearts. The predicted open reading frame of our already published partial cDNA clone of HoxA5 was confirmed by expressing it as a fusion protein with Glutathione transferase (GST fusion protein). Phylogenetic analysis with the deduced amino acid sequence of the isolated cDNA of the axolotl homolog of the murine HoxA5 shows that the axolotl sequence clusters more closely with the human and mouse HoxA5 homologs than with axolotl sequence. Western blot analysis revealed that anti-mouse HoxA5 antibody recognizes the axolotl HoxA5 protein.

Differential expression of a novel isoform of alpha-tropomyosin in cardiac and skeletal muscle of the Mexican axolotl (Ambystoma mexicanum).

Alternative mRNA splicing is a fundamental process in eukaryotes that contributes to tissue-specific and developmentally regulated patterns of tropomyosin (TM) gene expression. Northern blot analyses suggest the presence of multiple transcripts of tropomyosin in skeletal and cardiac muscle of adult Mexican axolotls. We have cloned and sequenced two tropomyosin cDNAs designated ATmC-1 and ATmC-2 from axolotl heart tissue and one TM cDNA from skeletal muscle, designated ATmS-1. Nucleotide sequence analyses suggest that ATmC-1 and ATmC-2 are the products of the same alpha-TM gene produced via alternate splicing, whereas ATmC-1 and ATmS-1 are the identical isoforms generated from the alpha-gene. RT-PCR analysis using isoform-specific primer pairs and detector oligonucleotides suggests that ATmC-2 is expressed predominantly in adult axolotl hearts. ATmC-2 is a novel isoform, which unlike ATmC-1 and other known striated muscle isoforms expresses exon 2a instead of exon 2b.

A specific synthetic RNA promotes cardiac myofibrillogenesis in the Mexican axolotl.

Ambystoma mexicanum is an intriguing animal model for studying heart development because it carries a mutation in gene c. Hearts of homozygous recessive (c/c) mutant embryos do not contain organized myofibrils and fail to beat. However, the defect can be corrected by organ-culturing the mutant heart in the presence of RNA from anterior endoderm or RNA from endoderm mesoderm-conditioned medium. We constructed a cDNA library from total conditioned medium RNA in a pcDNAII expression vector. We screened the cDNA library by an organ culture bioassay and isolated a single clone (Cl#4), the synthetic RNA from which corrects the heart defect by promoting myofibrillogenesis. The insert size of the active clone is 166 nt in length with a unique nucleotide sequence. The anti-sense RNA from Cl#4 using SP6 RNA polymerase failed to rescue mutant hearts. The ability of this small RNA to correct the mutant heart defect suggests that the RNA probably does not act as an mRNA. While the precise mechanism of action is not yet known, on the basis of our studies to date it is very clear that the sense strand of Cl#4 RNA has the ability to promote myofibrillogenesis and rescue the mutant hearts both in vitro and in vivo.

Endemic infection with human T cell leukemia/lymphoma virus type IIB in Argentinean and Paraguayan Indians: epidemiology and molecular characterization.

Human T cell leukemia/lymphoma virus (HTLV-II) type II infection was detected by polymerase chain reaction or serologic analyses (or both) in 22% of 697 Indians of six different ethnic back-grounds inhabiting the Argentinean and Paraguayan Gran Chaco. None was infected with HTLV-I. The prevalence of HTLV-II increased with age (14% in those < 13 years and 23% in those > or = 13 years). HTLV-II infection was found in all 20 Gran Chaco communities studied, but marked differences (44%-4%) in the rate of infection were observed even in communities separated by only a few miles. These variations correlated closely with ethnicity. In the high-incidence communities, infection clustered within families, with evidence for both sexual and perinatal transmission, primarily via breast-feeding. By contrast, only 2% of 94 Mapuche Indians from southern Argentina were positive for HTLV-II. Analyses of pol and long terminal repeat sequences from 15 Gran Chaco HTLV-II strains indicated that they constitute a highly conserved branch of the HTLV-IIB substrain.

Nucleotide sequence and expression of ribosomal protein S3 mRNA during embryogenesis in the Mexican axolotl (Ambystoma mexicanum).

We have isolated and sequenced a full-length (0.9 kb) cDNA clone of ribosomal protein S3 by subtraction hybridization using a single-stranded cDNA library from stage 25-27 (tracer) and the mRNA from stage 15-17 (driver) of embryonic Mexican axolotl (Ambystoma mexicanum). The axolotl is a unique animal model for studying heart development as well as myofibrillogenesis because it carries a mutation in gene c. The deduced amino acid sequence of axolotl S3 protein shows about 93.9% identity with human S3 protein over a 243 amino acid residue overlap. When compared with mouse and Xenopus laevis ribosomal S3 proteins, the axolotl sequenc shows 94.3 and 93.9% identity respectively. Interestingly, the axolotl S3 sequence shows higher identity at the nucleic acid level with human and/or other mammals than with Xenopus. The S3 transcript, as determined by RT-PCR, is present at stage 2-4 in a lower amount and the onset of transcription is most likely at the beginning of gastrulation (10-12). The expression level of S3 transcripts reaches a maximum by mid gastrulation (stages 13-14) and then follows a biphasic pattern being lower at stages 16-17 with subsequently steady increases until the mid tailbud stages (25-27).

Differential expression of C-protein isoforms in the developing heart of normal and cardiac lethal mutant axolotls (Ambystoma mexicanum).

Regulated assembly of contractile proteins into sarcomeric structures, such as A- and I-bands, is still currently being defined. The presence of distinct isoforms of several muscle proteins suggests a possible mechanism by which myocytes regulate assembly during myofibrillogenesis. Of several muscle isoforms located within the A-band, myosin binding proteins (MyBP) are reported to be involved in the regulation and stabilization of thick filaments during sarcomere assembly. The present confocal study characterizes the expression of one of these myosin binding proteins, C-protein (MyBP-C) in wild-type and cardiac lethal mutant embryos of the axolotl, Ambystoma mexicanum. C-protein isoforms are also detected in distinct temporal patterns in whole-mounted heart tubes and thoracic skeletal muscles. Confocal analysis of axolotl embryos shows both cardiac and skeletal muscles to regulate the expression of C-protein isoforms over a specific developmental window. Although the CPROAxslow isoform is present during the initial heartbeat stage, its expression is not retained in the adult heart. C-protein isoforms are simultaneously expressed in both cardiac and skeletal muscle during embryogenesis.