Kaname Mogami scite author profile

A large number of dominant flightless mutants of Drosophila were chemically induced, and their thorax proteins were examined by chemically induced, and their thorax proteins were examined by means of two-dimensional gel electrophoresis (O'Farrell 1975). Among them, 26 lines were found to have deficiency or reduction of some of myofibrillar proteins in indirect flight muscle (IFM). The gel patterns of the mutants could be classified into eleven groups. In general, more than a few polypeptides were either absent or reduced in each mutant line. Although the mutations affect myofibrillar proteins in apparently complex and diverse ways, logical correlations were found among the changes. There are pairs of proteins which always change together when a number of mutants are compared. There are also many pairs in which presence of one protein is necessary, but not sufficient for presence of the other. This suggests that absence of one component leads to disappearance or reduction of others which are either spatially or functionally related to the former. The correlation is possibly due to a hierarchy of the proteins in the myofibrillar assembly processes. Chromosomal loci of eleven typical mutants were examined, and it was found that most of them are located in two small regions of the second and the third chromosomes. IFM myofibrils of these mutants are either abnormal or absent in homozygotes as well as in heterozygotes.

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Drosophila muscle myosin heavy chain encoded by a single gene in a cluster of muscle mutations

Bernstein

Mogami

Donady

et al. 1983

Nature

161

114

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Identification of Drosophila Indirect Flight Muscle Myofibrillar Proteins by Means of Two-Dimensional Electrophoresis1

Mogami

Fujita

Hotta

1982

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When proteins of whole Drosophila thorax were analyzed by two-dimensional gel electrophoresis, 186 spots were detected by protein staining with Coomassie brilliant blue R-250. Two methods were developed to identify proteins which exist in indirect flight muscle (IFM) and its myofibrils. 1) A whole fly was freeze-dried in a dry ice-acetone mixture, and indirect flight muscle fibers were cleanly dissected out from the thorax. The muscle cells and the rest of the thorax were analyzed separately. The muscle contained 146 polypeptides, of which 12 were not detected elsewhere. 2) Flies were frozen in liquid nitrogen and shaken vigorously so that their thoraces broke off from heads and abdomens. The thoraces were separated from the rest by sieving and centrifugation. After homogenization of the thorax, myofibrils were prepared by centrifugation in a discontinuous sucrose density gradient. The myofibril fraction contained at least 20 proteins. There were two types of actin (II and III), myosin heavy chain, tropomyosin and paramyosin. Nine of the other myofibrillar proteins were specific to this muscle.

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Ultrastructural and molecular analyses of homozygous-viable Drosophila melanogaster muscle mutants indicate there is a complex pattern of myosin heavy-chain isoform distribution.

O'Donnell¹,

Collier²,

Mogami³

et al. 1989

Genes Dev.

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We describe the ultrastructural and initial molecular characterization of four homozygous-viable, dominantflightless mutants of Drosophila melanogaster. Genetic mapping indicates that these mutations are inseparable from the known muscle myosin heavy-chain (MHC) allele Mhc^, and each mutation results in a muscle-specific reduction in MHC protein accumulation. The indirect flight muscles (IFMs) of each of these homozygous mutants fail to accumulate MHC, lack thick filaments, and do not display normal cylindrical myofibrils. As opposed to the null phenotype observed in the IFM, normal amounts of MHC accumulate in the leg muscles of three of these mutants, whereas the fourth mutant shows a 45% reduction in leg muscle MHC. The ultrastructure of the tergal depressor of the trochanter muscle (TDT, or jump muscle] is normal in one mutant, completely lacks thick filaments in a second mutant, and displays a reduction of thick filaments in two mutants. The thick filament reduction in this latter class of mutants is limited to the four smaller anterior cells of the TDT, indicating that the TDT is a mixed fiber-type muscle. Because all isoforms of muscle MHC are encoded by alternative splicing of transcripts from a single gene, our results suggest that there is a complex pattern of MHC isoform accumulation in Drosophila, The phenotypes of the homozygous-viable mutants provide evidence for the differential localization of MHC isoforms in different muscles, within the same muscle, and even within a single muscle cell. The mutant characteristics also suggest that the use of some alternative exons is shared among the IFM, TDT, and additional muscles whereas the use of others is unique to the IFM.[Key Words: Drosophila-, muscle mutants; myosin heavy chain; alternative RNA splicing]

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Mutations of the Drosophila myosin heavy-chain gene: effects on transcription, myosin accumulation, and muscle function.

Mogami¹,

O'Donnell²,

Bernstein³

et al. 1986

Proc. Natl. Acad. Sci. U.S.A.

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Mutations of the myosin heavy-chain (MHC) gene ofDrosophila melanogaster were identified among a group of dominant flightless and recessive lethal mutants (map position 2-52, 36A8-B1,2). One mutation is a 0.1-kilobase deletion in the 5' region of the MHC gene and reduces MHC protein in the leg and thoracic muscles of heterozygotes to levels found in 36AC haploids. Three mutations are insertions of 8-to 10-kilobase DNA elements within the MHC gene and produce truncated MHC transcripts. Heterozygotes of these insertional mutations possess levels of MHIC intermediate between those of haploids and diploids. An additional mutation has no gross alteration of the MHC gene or its RNA transcripts. Although leg and larval muscles function normally in each mutant heterozygote, indirect flight muscles are defective and possess disorganized myofibrils. Homozygous mutants die during embryonic or larval development and display abnormal muscle function prior to death. These flndings provide direct genetic evidence that the MHC gene at 36B (2L) is essential for both larval and adult muscle development and function. The results are consistent with the previous molecular evidence that Drosophila, unlike other organisms, has only a single muscle MHC gene per haploid genome. Quantitative expression of both copies of the MHC gene is required for function of indirect flight muscle, whereas expression of a single MHC gene is sufficient for function of larval muscles and adult tubular muscles.Analysis of muscle mutants of the fruit fly Drosophila melanogaster and the small soil nematode Caenorhabditis elegans offers a unique approach to understanding the genetic regulation of myogenesis and muscle function (1)(2)(3)(4)(5)(6)(7)(8)(9)(10)(11)(12)(13)(14). In C. elegans, mutations of myosin heavy-chain (MHC) (9-11), paramyosin (12)

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Kaname Mogami

Isolation of Drosophila flightless mutants which affect myofibrillar proteins of indirect flight muscle

Drosophila muscle myosin heavy chain encoded by a single gene in a cluster of muscle mutations

Identification of Drosophila Indirect Flight Muscle Myofibrillar Proteins by Means of Two-Dimensional Electrophoresis1

Ultrastructural and molecular analyses of homozygous-viable Drosophila melanogaster muscle mutants indicate there is a complex pattern of myosin heavy-chain isoform distribution.

Mutations of the Drosophila myosin heavy-chain gene: effects on transcription, myosin accumulation, and muscle function.

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