Expression of a novel tropomyosin isoform in axolotl heart and skeletal muscle.

TPM1kappa is an alternatively spliced isoform of the TPM1 gene whose specific role in cardiac development and disease is yet to be elucidated. Although mRNA studies have shown TPM1kappa expression in axolotl heart and skeletal muscle, it has not been quantified. Also the presence of TPM1kappa protein in axolotl heart and skeletal muscle has not been demonstrated. In this study, we quantified TPM1kappa mRNA expression in axolotl heart and skeletal muscle. Using a newly developed TPM1kappa specific antibody, we demonstrated the expression and incorporation of TPM1kappa protein in myofibrils of axolotl heart and skeletal muscle. The results support the potential role of TPM1kappa in myofibrillogenesis and sarcomeric function.

Variability in PET quantitation within a multicenter consortium.

PURPOSE: The purpose of this study was to evaluate the variability in quantitation of positron emission tomography (PET) data acquired within the context of a multicenter consortium. METHODS: PET quantitation phantoms designed by American Association of Physicists in Medicine/ Society of Nuclear Medicine Task Group 145 were sent to the ten member sites of the Pediatric Brain Tumor Consortium (PBTC), a NIH-funded research consortium investigating the biology and therapies for brain tumors in children. The phantoms were water-filled cylinders (18.6 cm inside height and 20.4 cm inside diameter) based on the standard ACR phantom with four small, "hot" cylinders of varying diameters (8, 12, 16, 25 mm, all with 38 mm height), consisting of an equilibrium mixture of 68Ge/68Ga in an epoxy matrix. At each site, the operator added the appropriate amount of 18F to the water in the background in order to attain a feature-to-background ratio of roughly 4:1. The phantom was imaged and reconstructed as if it were a brain PET scan for the PBTC. An approximately 12 mm circular region of interest (ROI) was placed over each feature and in a central area in the background. The mean and maximum pixel values for each ROI were requested from local sites in units of activity concentration (Bq/ml) and the standard uptake value (SUV) (g/mL) based on bodyweight. The activity concentration was normalized by the decay-corrected known activity concentration for the features, and reported as the absolute recovery coefficient (RC). In addition, central analyses were performed by two observers RESULTS: The ten sites successfully imaged the phantom within 5 months and submitted the quantitative results and the phantom image data to the PBTC Operations and Biostatistics Center. The local site-based and central analyses yielded similar mean values for RC. Local site-based SUV measurements of the hot cylindrical features yielded greater variability than central analysis (COV range of 29.9%-42.8% compared to 7.7%-23.2%). Correcting for miscalculations in the local site reported SUVs substantially reduced the variation to levels similar to the central analysis (COV range of 8.8%-18.4%) and also led to the local sites providing a similar mean of the SUV values to those from the central analysis. In the central analysis, the use of mean SUV in place of maximum SUV for an ROI of fixed size substantially reduced the variation in the SUV values (COV ranges of 7.7%-11.3% vs. 9.3%-23.2%). CONCLUSIONS: Based on this investigation, a SUV variability in the range of 10%-25% due solely to instrument and analysis factors can be expected in the context of a multicenter consortium if a central reading is used and quality assurance and quality control procedures are followed. The overall SUV variability can be expected to be larger than this due to biological and protocol factors.

Tropomyosin expression and dynamics in developing avian embryonic muscles.

The expression of striated muscle proteins occurs early in the developing embryo in the somites and forming heart. A major component of the assembling myofibrils is the actin-binding protein tropomyosin. In vertebrates, there are four genes for tropomyosin (TM), each of which can be alternatively spliced. TPM1 can generate at least 10 different isoforms including the striated muscle-specific TPM1alpha and TPM1kappa. We have undertaken a detailed study of the expression of various TM isoforms in 2-day-old (stage HH 10-12; 33 h) heart and somites, the progenitor of future skeletal muscles. Both TPM1alpha and TPM1kappa are expressed transiently in embryonic heart while TPM1alpha is expressed in somites. Both RT-PCR and in situ hybridization data suggest that TPM1kappa is expressed in embryonic heart whereas TPM1alpha is expressed in embryonic heart, and also in the branchial arch region of somites, and in the somites. Photobleaching studies of Yellow Fluorescent Protein-TPM1alpha and -TPM1kappa expressed in cultured avian cardiomyocytes revealed that the dynamics of the two probes was the same in both premyofibrils and in mature myofibrils. This was in sharp contrast to skeletal muscle cells in which the fluorescent proteins were more dynamic in premyofibrils. We speculate that the differences in the two muscles is due to the appearance of nebulin in the skeletal myocytes premyofibrils transform into mature myofibrils.

A reduction of tropomyosin limits development of sarcomeric structures in cardiac mutant hearts of the Mexican axolotl.

The cardiac lethal mutation in Mexican axolotl (Ambystoma mexicanum) results in a lack of contractions in the ventricle of mutant embryos. Previous studies have demonstrated that tropomyosin, a component of thin filaments, is greatly reduced in mutant hearts lacking myofibril organization. Confocal microscopy was used to examine the structure and comparative amount of tropomyosin at heartbeat initiation and at a later stage. The formation of functional sarcomeres coincided with contractions in normal hearts at stage 35. A-bands and I-bands were formed at stage 35 and did not change at stage 39. The widening of Z-bodies into z-lines was the main developmental difference between stage 35 and 39 normal hearts. Relative to normal hearts, a reduction of sarcomeric protein levels in mutant hearts at stage 35 was found, and a greater reduction occurred at later stages. The lower level of tropomyosin limited the areas where organized myofibrils formed in the mutant. The areas that had tropomyosin staining also had staining for alpha-actinin and myosin. Early myofibrils formed in these areas but the A-bands and I-bands were shorter than normal. At a later stage in the mutant, A-bands and I-bands remained shorter and importantly the Z-bodies also did not form wider z-lines.

Tropomodulin expression in developing hearts of normal and cardiac mutant Mexican axolotl.

In the axolotl, Ambystoma mexicanum, a simple, recessive cardiac-lethal mutation in gene "c" results in the hearts of c/c homozygous animals being deficient in sarcomeric tropomyosin (TM) and failing to form mature myofibrils. Subsequently, the mutant hearts do not beat. A three-step model of myofibril assembly recently developed in cell culture prompted a reassessment of the myofibril assembly process in mutant hearts using a relatively new late marker for thin filament assembly, tropomodulin (Tmod). This is, to the best of our knowledge, the first report of tropomodulin in an amphibian system. Tropomodulin antibodies were immunolocalized to the ends of the thin filaments. Tropomodulin was also found in discrete punctate spots in normal and mutant hearts, often in linear arrays suggestive of early myofibril formation. The tropomodulin spots assessed in stage 41/42 mutant hearts co-localized with antibodies to other myofibrillar proteins indicative of nascent myofibril formation. This suggests a failure of elongation/maturation of nascent myofibrils, which could be a consequence of decreased TM levels or increased Tmod/ TM ratio. Unlike tropomyosin, there is no apparent decrease in the level of Tmod expression in mutant hearts.

Expression of Nkx2.5 in wild type, cardiac mutant, and thyroxine-induced metamorphosed hearts of the Mexican axolotl.

Nkx2.5, a homeodomain-containing transcription factor, is known to be necessary for normal heart development in vertebrates. It is one of the earliest lineage-restricted genes expressed in cardiovascular progenitor cells and knowledge of its expression patterns has important therapeutic implications for damaged cardiomyocytes. Mexican axolotl is a unique system to study heart development for two reasons: the presence of a mutant phenotype lacking organized myofibrils due to sarcomeric tropomyosin deficiency and the ability to induce metamorphosis by administration of exogenous thyroid hormone. In this study, we cloned and sequenced the as yet uncharacterized Nkx2.5 cDNA from normal and cardiac mutant axolotl heart RNA. Comparison of cDNA sequences of Nkx2.5 from normal and mutant axolotl hearts did not show differences suggesting that loss of function mutation in Nkx2.5 is not responsible for the mutant phenotype. However, quantitative studies show higher expression of Nkx2.5 in mutant hearts raising the possibility that increased expression of Nkx2.5 may contribute to the mutant phenotype. We also evaluated quantitative changes in expression of Nkx2.5 in axolotl hearts during embryonic and postembryonic heart development induced by exogenous thyroid hormone. There is an apparent increase in Nkx2.5 transcript levels in metamorphosed hearts.

Ectopic expression and dynamics of TPM1alpha and TPM1kappa in myofibrils of avian myotubes.

From the four known vertebrate tropomyosin genes (designated TPM1, TPM2, TPM3, and TPM4) over 20 isoforms can be generated. The predominant TPM1 isoform, TPM1alpha, is specifically expressed in both skeletal and cardiac muscles. A newly discovered alternatively spliced isoform, TPM1kappa, containing exon 2a instead of exon 2b contained in TPM1alpha, was found to be cardiac specific and developmentally regulated. In this work, we transfected quail skeletal muscle cells with green fluorescent proteins (GFP) coupled to chicken TPM1alpha and chicken TPM1kappa and compared their localizations in premyofibrils and mature myofibrils. We used the technique of fluorescence recovery after photobleaching (FRAP) to compare the dynamics of TPM1alpha and TPM1kappa in myotubes. TPM1alpha and TPM1kappa incorporated into premyofibrils, nascent myofibrils, and mature myofibrils of quail myotubes in identical patterns. The two tropomyosin isoforms have a higher exchange rate in premyofibrils than in mature myofibrils. F-actin and muscle tropomyosin are present in the same fibers at all three stages of myofibrillogenesis (premyofibrils, nascent myofibrils, mature myofibrils). In contrast, the tropomyosin-binding molecule nebulin is not present in the initial premyofibrils. Nebulin is gradually added during myofibrillogenesis, becoming fully localized in striated patterns by the mature myofibril stage. A model of thin filament formation is proposed to explain the increased stability of tropomyosin in mature myofibrils. These experiments are supportive of a maturing thin filament and stepwise model of myofibrillogenesis (premyofibrils to nascent myofibrils to mature myofibrils), and are inconsistent with models that postulate the immediate appearance of fully formed thin filaments or myofibrils.

Differential expression of tropomyosin during segmental heart development in Mexican axolotl.

The Mexican axolotl, Ambystoma mexicanum, serves as an intriguing model to investigate myofibril organization and heart development in vertebrates. The axolotl has a homozygous recessive cardiac lethal gene "c" which causes a failure of ventricular myofibril formation and contraction. However, the conus of the heart beats, and has organized myofibrils. Tropomyosin (TM), an essential component of the thin filament, has three known striated muscle isoforms (TPM1alpha, TPM1kappa, and TPM4alpha) in axolotl hearts. However, it is not known whether there are differential expression patterns of these tropomyosin isoforms in various segments of the heart. Also, it is not understood whether these isoforms contribute to myofibril formation in a segment-specific manner. In this study, we have utilized anti-sense oligonucleotides to separately knockdown post-transcriptional expression of TPM1alpha and TPM4alpha. We then evaluated the organization of myofibrils in the conus and ventricle of normal and cardiac mutant hearts using immunohistochemical techniques. We determined that the TPM1alpha isoform, a product of the TPM1 gene, was essential for myofibrillogenesis in the conus, whereas TPM4alpha, the striated muscle isoform of the TPM4 gene, was essential for myofibrillogenesis in the ventricle. Our results support the segmental theory of vertebrate heart development.