Naoji Toyota

Isoform variants of troponin in skeletal and cardiac muscle cells cultured with and without nerves

Immunofluorescence microscopy shows that cultured skeletal and cardiac muscle cells of chicken embryos exhibit the same stainabilities with antibodies against skeletal and cardiac troponin components as do those in embryos. Muscle cells of each type cultured with motor or sympathetic nerves or in medium containing the nerve extract exhibit the same reactivities as do those in adult animals. Cardiac muscle cells incubated in the nerve-conditioned medium also change the form of troponin components to the adult type. It appears that the differentiation of individual muscle fibers to specific types is induced by nerves, and especially by the neurohumoral effect.

Isoforms of troponin during regeneration of chicken skeletal muscle fibers after cold injury

SummaryThe regeneration of skeletal muscle fibers of the adult chicken was examined after a focal injury brought about with a liquid-nitrogen cooled brass rod. Immunofluorescence microscopy with antibodies specific for troponin (TN) components (T, I, and C) from adult chicken breast and ventricular muscles showed the presence of different fiber types in both the anterior and posterior latissimus dorsi muscles. New fibers produced in the regions adjacent to the site of injury in both muscles exhibited the same immunoreactivities as those previously seen in embryonic skeletal muscles. As differentiation proceeded, regenerating cells lost their embryonic antigenicities and recovered their characteristic adult reactivities. These results indicate that, during regeneration from cold injury, skeletal muscles apparently pass again through an embryonic stage during which they synthesize embryonic-like TN isoforms.

Immunohistochemical studies on myoepithelial changes in breast tumors.

Specific rabbit antisera directed against human uterine myosin were prepared and used for immunohistochemical studies on myoepithelial cells (MECs) in some breast tumors. In Abroadenomas, MECs were observed confined to the periductal portions but not in the stroma. In infiltrating duct carcinomas, MECs were also present as a distinctive periductal layer. Moreover, they were also seen in the infiltrating area, either associated with a small nest of carcinoma cells or freely in the stroma. Larger nests of medullary carcinomas usually were not accompanied by any layer of MECs. No MECs were detected in lobular carcinomas as far as the infiltrating area was concerned. It is suggested from these results that the behavior of MECs is significantly different, depending upon the types of breast tumors. It also appears that the present method may be useful for further analysis of the origin and growth pattern in various breast tumors.

Differentiation of muscle-specific proteins in chicken somites as studied by immunofluorescence microscopy

Abstract Fluorescence microscopy of chicken cervical somites revealed that muscle-specific proteins began to appear at stage 11 (Hamburger and Hamilton numbering), and the onset of the expression of all the proteins examined in the present study had occurred by stage 17. Muscle proteins were classified into six groups according to the stage of their appearance. Since all these proteins were expressed before emergence of nerve fibers in myotomes, switching-on of their synthesis does not seem to require neuronal influence. However, since isoproteins other than adult muscle types disappeared and diversification of muscle fiber types occurred coordinately with the clustering of acetylcholine receptors in cervical muscles, switching-off of the synthesis of the nonadult isoforms might have been accelerated by the formation of functional neuromuscular junctions. The absence of nebulin and C-protein in early stages seems to indicate that these proteins are not required for the initial assembly of myofilaments and/or myofibrils. Further, this absence might be considered to facilitate exchangeabilities of proteins in nascent myofibrils, thereby changing the isoforms to adult types.

ASSEMBLY OF FORCE-EXPRESSED TROPONIN-I ISOFORMS IN MYOFIBRILS OF CULTURED CARDIAC AND FAST SKELETAL MUSCLE CELLS AS STUDIED BY EPITOPE TAGGING

The isoform-specific assembly of cardiac and skeletal muscle troponin-I (CTnI and FTnI, respectively) on to myofibrils (MFs) was investigated. Epitope tagging was used to monitor the intracellular localization of exogenously introduced constructs to myofibrillar structures in cultured chicken cardiac and fast skeletal (breast) muscle cells. Exogenous CTnI and FTnI were incorporated into endogenous MFs of cardiac and breast muscle cells with high affinity, respectively. In the case of CTnI and FTnI with breast and cardiac muscle cells respectively, CTnI was not incorporated into breast MFs but FTnI was assembled on to cardiac MFs. To determine which portion of TnI is responsible for incorporation into these MFs, we constructed chimeric TnIs with the head and tail of CTnI replaced by those of FTnI. The behaviour of these chimeras depends on the tail of TnIs. These results suggest that the tail regions of TnIs bind to cardiac and breast MFs, and that this affinity of TnI tails is responsible for the assembly of FTnI on to cardiac MFs.

Association of testicular undescent induced by prenatal flutamide treatment with thickening of the cremaster muscle in rats

Background and AimsPreviously, in cryptorchid rats, which were induced by prenatal exposure to flutamide, we found a thickening of the cremaster muscle. This study was undertaken to quantify the increase of the cremaster muscle thickness in the cryptorchid rats, and to examine its possible relationship with the proliferation of muscle cells.MethodsTo obtain cryptorchid rats, pregnant Wistar rats were subcutaneously injected with flutamide (100 mg/kg per day) during gestational days 16–17. Serial sections of the scrotum, containing the testis and cremaster muscle, were prepared from the control and cryptorchid rats that were 2–6 weeks of age, and stained with hematoxylin-eosin for morphometry, or stained with antibody against the proliferating cell nuclear antigen (PCNA) to analyze the cell proliferation ability.ResultsThe thickened cremaster muscle was always associated with cryptorchid testis and, in the case of unilateral cryptorchidism, the cremaster muscle of the contralateral (descended testis) side exhibited normal thickness. The average thickness of the affected cremaster muscle was 0.80 and 1.89 mm at 4 and 6 weeks of age, respectively, although that of the normal muscle was 0.28 and 0.33 mm at the same time period, respectively.ConclusionOur results showed that the cremaster muscle of the cryptorchid rats was significantly thicker than that of the control rats. The immunohistochemical analysis revealed that a thickened cremaster muscle contained many PCNA-positive nuclei even at 4 weeks of age, in contrast to the control, which had only a few positive nuclei. Our present study indicates that continuous proliferation of the muscle cells associated with cryptorchid testis increases the thickness of cremaster cells in rats exposed to flutamide prenatally.

Distribution of polymorphic forms of troponin components in extra- and intrafusal fibers of an avian slow muscle

SummaryBy indirect immunofluorescence microscopy, the reactivities of extra- and intrafusal muscle fibers with antibodies against troponin (TN) components were studied in an avian slow muscle, the anterior latissimus dorsi (ALD) of the chicken. Serial cross sections of the muscle were exposed to antibodies specific to TN components (TN-T, -I, and -C) from adult chicken breast and ventricular muscles. In extrafusal fibers, four distinct categories were identified on the basis of differential reactivity with these antibodies. The predominant population of fibers (> 95%) reacted weakly only with antiventricular TN-C. The second type of fibers (< 5%) was stained with antibodies raised against breast TN components. The third group of fibers (< 1%) was labeled not only with antibreast TN components, but also with antiventricular TN-T and -C. The last class of fibers (< 1%) reacted with antibodies directed against ventricular TN-T and -C. These results were correlated with myofibrillar ATPase staining patterns of fibers. In intrafusal muscle fibers of this muscle, the same four types of fibers were observed; in these fibers, however, there appeared to be a longitudinal variation in the reactivity. In conclusion, the slow ALD muscle of the adult chicken contains populations of both extrafusal and intrafusal fibers which are heterogeneous in reactivity with TN component antibodies.

Alteration of androgen receptor immunoexpression by neonatal DES-treatment in mouse epididymis.

It has been shown that the use of DES is associated with urogenital tract abnormalities in female and male animals. Epididymis is an important male reproductive tract for maturing sperm and has been found as a sensitive organ for estrogen compounds including DES. In this study, we observed immunoexpression of androgen receptors in normal and neonatal DES-treatment mouse epididymis to investigate the influence of DES treatment on mouse epididymis.

Thin-filament-binding domains of cardiac and fast skeletal muscle troponin I isoforms as studied by epitope tagging.

We examined the binding domains of cardiac and fast skeletal muscle troponin I (CTnI and FTnI, respectively) to myofibrils (MFs). Deletion mutants containing CTnI amino acid residues 1–79, 43–207 and 80–207 (CTnI-head, CTnI-tail-1 and CTnI-tail-2, respectively) and FTnI amino acid residues 1–54 and 55–182 (FTnI-head and FTnI-tail, respectively) were transiently expressed in cardiac and fast skeletal muscle cells. To monitor the intracellular localization of these exogenously introduced truncated TnIs, epitope tagging was used. CTnI-tail-1 was incorporated into cardiac MFs specifically, but CTnI-tail-2 was not assembled onto any MFs examined. This suggests that there is no potent actin filament-binding site in CTnI-tail-2. Since CTnI-tail-1 has an amino acid extension (CTnI residues 43–79) whose sequence is longer than that of CTnI-head-2; it appears that this sequence extension is important in binding to cardiac MFs. FTnI-tail, containing the inhibitory domain of actomyosin ATPase, showed intensive and specific incorporation into fast MFs. FTnI-tail was a homologous fragment of CTnI-tail-2, but the binding patterns of these two domains differed greatly from each other. It is possible that the absence of potent binding affinity of CTnI-tail-2 corresponding to the inhibitory domain of actomyosin ATPase is advantageous for continuous cardiac muscle contraction, since a potent inhibitory activity is a serious obstacle to cardiac muscle contraction. It can be assumed that distinctive binding ability of functional domains of TnI-tails reflect unique adaptations to muscles with different physiological properties.

Morphological Modifications in Myofibrils by Suppressing Tropomyosin 4α in Chicken Cardiac Myocytes

Tropomyosin (TPM) localizes along F-actin and, together with troponin T (TnT) and other components, controls calcium-sensitive muscle contraction. The role of the TPM isoform (TPM4α) that is expressed in embryonic and adult cardiac muscle cells in chicken is poorly understood. To analyze the function of TPM4α in myofibrils, the effects of TPM4α-suppression were examined in embryonic cardiomyocytes by small interference RNA transfection. Localization of myofibril proteins such as TPM, actin, TnT, α-actinin, myosin and connectin was examined by immunofluorescence microscopy on day 5 when almost complete TPM4α-suppression occurred in culture. A unique large structure was detected, consisting of an actin aggregate bulging from the actin bundle, and many curved filaments projecting from the aggregate. TPM, TnT and actin were detected on the large structure, but myosin, connectin, α-actinin and obvious myofibril striations were undetectable. It is possible that TPM4α-suppressed actin filaments are sorted and excluded at the place of the large structure. This suggests that TPM4α-suppression significantly affects actin filament, and that TPM4α plays an important role in constructing and maintaining sarcomeres and myofibrils in cardiac muscle.