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

Sheep heart RNA stimulates myofibril formation and beating in cardiac mutant axolotl hearts in organ culture

In the Mexican axolotl, Ambystoma mexicanum, recessive mutant gene c, when homozygous, results in a failure of the heart to form sarcomeric myofibrils and contract normally. Previous studies have shown that purified RNA from normal anterior endoderm or from medium conditioned with anterior endoderm/pre-cardiac mesoderm has the capacity to rescue mutant hearts in organ culture. In the present study, RNA extracted from adult sheep heart was tested for its capacity to promote differentiation in the mutant axolotl hearts. Mutant hearts cultured in the presence of the sheep heart RNA in Steinberg's solution for 48 h displayed rhythmic contractions. Ultrastructural studies showed that the rescued mutant axolotl ventricular myocardial cells contained myofibrils of normal morphology. Mutant hearts cultured in Steinberg's solution alone did not beat throughout their lengths and myofibrils were not observable in the ventricles. Confocal microscopy confirmed the increase of Tropomyosin expression and formation of myofibrils in mutant hearts treated by sheep heart RNA. Thus, sheep heart RNA promotes myofibrillogenesis and the development of contractile function in embryonic cardiac mutant axolotl hearts

Protein Kinase C-Mediated Desmin Phosphorylation is Related to Myofibril Disarray in Cardiomyopathic Hamster Heart 1

The cardiomyopathic (CM) Syrian golden hamster (strain UM-X7.1) exhibits a hereditary cardiomyopathy, which causes premature death resulting from congestive heart failure. The CM animals show extensive cardiac myofibril disarray and myocardial calcium overload. The present study has been undertaken to examine the role of desmin phosphorylation in myofibril disarray observed in CM hearts. The data from skinned myofibril protein phosphorylation assays have shown that desmin can be phosphorylated by protein kinase C (PKC). There is no significant difference in the content of desmin between CM and control hamster hearts. However, the desmin from CM hearts has a higher phosphorylation level than that of the normal hearts. Furthermore, we have examined the distribution of desmin and myofibril organization with immunofluorescent microscopy and immunogold electron microscopy in cultured cardiac myocytes after treatment with the PKC-activating phorbol ester, 12-O-tetradecanylphorbol-13-acetate (TPA). When the cultured normal hamster cardiac cells are treated with TPA, desmin filaments are disassembled and the myofibrils become disarrayed. The myofibril disarray closely mimics that observed in untreated CM cultures. These results suggest that disassembly of desmin filaments, which could be caused by PKC-mediated phosphorylation, may be a factor in myofibril disarray in cardiomyopathic cells and that the intermediate filament protein, desmin, plays an Important role in maintaining myofibril alignment in cardiac cells

A point mutation in bioactive RNA results in the failure of mutant heart correction in mexican axolotls

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. The defect can be corrected by organ-culturing the mutant heart in the presence of RNA from anterior endoderm or endoderm/mesoderm-conditioned medium. By screening a cDNA library made of total conditioned medium RNA from normal axolotl embryonic endoderm, we isolated a single clone (MIR), the synthetic RNA from which corrects the mutant heart defect by promoting myofibrillogenesis and thus was named MIR (myofibrillogenesis inducing RNA). In the present study, we have examined MIR gene expression in mutant axolotl hearts at early pre-heart-beat developmental stages and found its quantitative expression, as detected by RT-PCR, to be the same as in normal hearts. However, careful analysis of sequence data revealed a G➙U point mutation in the mutant MIR RNA. Further computational analyses, using GENEBEE software to compare normal and mutant MIR RNAs show a significant alteration in RNA secondary structure of the point-mutated MIR RNA. The results from bioassay and confocal microscopy immunofluorescent studies demonstrate that, unlike MIR RNA derived from normal embryos, the mutated MIR RNA does not promote myofibrillogenesis in mutant embryonic hearts and fails to rescue/correct the mutant heart defect

Identification of a truncated form of methionine sulfoxide reductase a expressed in mouse embryonic stem cells

BACKGROUND: Methionine Sulfoxide Reductase A (MsrA), an enzyme in the Msr gene family, is important in the cellular anti-oxidative stress defense mechanism. It acts by reducing the oxidized methionine sulfoxide in proteins back to sulfide and by reducing the cellular level of reactive oxygen species. MsrA, the only enzyme in the Msr gene family that can reduce the S-form epimers of methionine sulfoxide, has been located in different cellular compartments including mitochondria, cytosol and nuclei of various cell lines. METHODS: In the present study, we have isolated a truncated form of the MsrA transcript from cultured mouse embryonic stem cells and performed eGFP fusion protein expression, confocal microscopy and real time RT-PCR studies. RESULTS: Results show a different expression response of this truncated transcript to oxygen deprivation and reoxygenation treatments in stem cells, compared to the longer full length form. In addition, a different subcellular localization pattern was noted with most of the eGFP fusion protein detected in the cytosol. CONCLUSION: One possibility for the existence of a truncated form of the MsrA transcripts could be that with a smaller protein size, yet retaining a GCWFG action site, this protein might have easier access to oxidize methionine residues on proteins than the longer form of the MsrA protein, thus having an evolutionary selection advantage. This research opens the door for further study on the role and function of the truncated MsrA embryonic mouse stem cells

Anoxia, acidosis, and intergenic interactions selectively regulate methionine sulfoxide reductase transcriptions in mouse embryonic stem cells

Methionine sulfoxide reductases (Msr) belong to a gene family that contains one MsrA and three MsrBs (MsrB1, MsrB2, and MsrB3). We have identified all four of the genes that are expressed in mouse embryonic stem cell cultures. The vital cellular functions of the Msr family of genes are to protect cells from oxidative damage by enzymatically reducing the oxidized sulfide groups of methionine residues in proteins from the sulfoxide form (--SO) back to sulfide thus restoring normal protein functions as well as reducing intracellular reactive oxygen species (ROS). We have performed studies on the Msr family genes to examine the regulation of gene expression. Our studies using real-time RT-PCR and Western blotting have shown that expression levels of the four Msr family genes are under differential regulation by anoxia/reoxygenation treatment, acidic culture conditions and interactions between MsrA and MsrB. Results from these in vitro experiments suggest that although these genes function as a whole in oxidative stress protection, each one of the Msr genes could be responsive to environmental stimulants differently at the tissue level

Cellular, Molecular, and Developmental Studies on Heart Development in Normal and Cardiac Mutant Axolotls, Ambystoma mexicanum

The Mexican axolotl (Ambystoma mexicanum) provides an excellent model for studying heart development because it carries a simple recessive cardiac lethal mutation that results in a failure of the mutant embryonic myocardium to contract. In cardiac mutant axolotls, the hearts do not beat, apparently due to an absence of organized myofibrils. The mutant hearts can be rescued by coculturing them with normal anterior endoderm/mesoderm tissue, by a medium conditioned with normal anterior endoderm/mesoderm, or by an RNA isolated from the conditioned medium. We have previously isolated a single cDNA clone from a library prepared with total RNA from conditioned medium; this 166-nt-long in vitro synthesized RNA, directed by the unique cDNA clone (Clone #4), has the ability to correct the heart defect and promote myofibrillogenesis in mutant hearts. The criteria for rescue include contraction of mutant hearts throughout their lengths, an increase in sarcomeric tropomyosin arrays as shown by immunofluorescent confocal microscopy, and the ultrastructural appearance of organized sarcomeric myofibrils. More recently, we carried out RT-PCR with total RNAs extracted from normal or mutant axolotl embryos. A point mutation (G-T) was found in Clone #4 RNA derived from the mutant embryos at stages 20 and 30 as compared to normal axolotls at the same stages. Furthermore, we searched for the full-length Clone #4 gene in an axolotl genomic library. Primer extension yielded a product of —500 by at the 5’ end of the Clone #4 gene. The nucleotide sequence of the extended Clone #4 (Ext-Clone #4) was determined and was found to be unique because there was no significant homology with other known sequences available from the gene databases. Interestingly, T7 sense RNA from the Ext-Clone #4 (-500-nt RNA) showed a higher efficiency in rescuing mutant hearts than the T7 RNA from original Clone #4 (166-nt RNA). Our working hypothesis is that the bioactive RNA is a regulatory RNA that may directly or indirectly upregulate tropomyosin production in the axolotl heart

Role of myofibril-inducing RNA in cardiac TnT expression in developing Mexican axolotl

The Mexican axolotl, Ambystoma mexicanum, has been a useful animal model to study heart development and cardiac myofibrillogenesis. A naturally-occurring recessive mutant, gene ``c”, for cardiac non-function in the Mexican axolotl causes a failure of myofibrillogenesis due to a lack of tropomyosin expression in homozygous mutant (c/c) embryonic hearts. Myofibril-inducing RNA (MIR) rescues mutant hearts in vitro by promoting tropomyosin expression and myofibril formation thereafter. We have studied the effect of MIR on the expression of various isoforms of cardiac troponin T (cTnT), a component of the thin filament that binds with tropomyosin. Four alternatively spliced cTnT isoforms have been characterized from developing axolotl heart. The expression of various cTnT isoforms in normal, mutant, and mutant hearts corrected with MIR, is evaluated by real-time RT-PCR using isoform specific primer pairs; MIR affects the total transcription as well as the splicing of the cTnT in axolotl heart