Functional nonequivalence of Drosophila actin isoforms.

We show that different Drosophila actin isoforms are not interchangeable. We sequenced the six genes that encode conventional Drosophila actins and found that they specify amino acid replacements in 27 of 376 positions. To test the significance of these changes we used directed mutagenesis to introduce 10 such conversions, independently, into the Act88F flight muscle-specific actin gene. We challenged these variant actins to replace the native protein by transforming germline chromosomes of a Drosophila strain lacking flight muscle actin. Only one of the 10 reproducibly perturbed myofibrillar function, demonstrating that most isoform-specific amino acid replacements are of minor significance. In order to establish the consequences of multiple amino acid replacements, we substituted portions of the Drosophila Act88F actin gene with corresponding regions of genes encoding other isoforms. Only one of five constructs tested engendered normally functioning flight muscles, and the severity of myofibrillar defects correlated with the number of replacements within the chimeric genes. Finally, we completely converted the flight muscle actin-encoding gene to one specifying a nonmuscle isoform, a change entailing a total of 18 amino acid replacements. Transformation of flies with this construct resulted in disruption of flight muscle structure and function. We conclude that actin isoform sequences are not equivalent and that effects of the amino acid replacements, while minor individually, collectively confer unique properties.

Characterization of lethal Drosophila melanogaster alpha-actinin mutants.

We have partially characterized four Drosophila melanogaster alpha-actinin gene mutants, I(1)2Cb1, I(1)2Cb2, I(1)2Cb4, and I(1)2Cb5. We demonstrate that in each case the mutation is caused by a chromosomal rearrangement that precludes normal protein synthesis. In the absence of alpha-actinin, flies complete embryogenesis and develop into flaccid larvae that die within approximately 24 hr. These larvae have noticeable muscle dysfunction at hatching, although they, nevertheless, are capable of escaping from the egg membranes and of subsequent crawling movements. During larval development muscles degenerate, progressively limiting mobility and ultimately causing death. Electron microscopy of mutant muscle fibers reveals that myofibrils are grossly disrupted in one day old larvae and that electron-dense structures reminiscent of those seen in human nemaline myopathies are present throughout larval life. Our work rigorously demonstrates that alpha-actinin deficiencies are the cause of I(1)2Cb muscle defects. We anticipate that the alpha-actinin mutants described herein will facilitate in vivo tests of spectrin superfamily protein domain functions using a combination of directed mutagenesis and germline transformation.

Molecular organization and alternative splicing in zipper, the gene that encodes the Drosophila non-muscle myosin II heavy chain.

Genomic sequence of the entire zipper gene, that encodes non-muscle myosin II heavy chain (MHC) in Drosophila melanogaster, reveals a new, differentially spliced exon in this essential locus and identifies a molecular lesion that is responsible for a severe embryonic lethal zipper allele. There are two alternative splices in the head domain. The first is present in the 5' untranslated sequence which, when employed, produces an N-terminal extension of 45 amino acids (aa). This splicoform produces a protein that is stable in flies but less prevalent than the isoform that lacks the extension. The second alternative exon (40 aa) is close to the nucleotide binding pocket. The position, size and sequence of this exon is conserved in D. simulans and putative alternative exons of different size (7 to 16 aa) but identical position have been reported for other myosins throughout phylogeny. The functional significance of neither alternative splice is clear. Sequence analysis of genomic DNA identifies the lesion responsible for zipIIF107, one of the original severe embryonic lethal zipper alleles. Our primary structural data confirm and correct our previous sequence of the cDNA, establish the spatial relationship between zipper and unzipped (the gene originally thought to have been disrupted in zipper mutations), and provide a high resolution template for the precise mapping of mutations.

Morphogenesis in Drosophila requires nonmuscle myosin heavy chain function.

We provide the first link between a known molecular motor and morphogenesis, the fundamental process of cell shape changes and movements that characterizes development throughout phylogeny. By reverse genetics, we generate mutations in the Drosophila conventional nonmuscle myosin (myosin II) heavy chain gene and show that this gene is essential. We demonstrate that these mutations are allelic to previously identified, recessive, embryonic-lethal zipper mutations and thereby identify nonmuscle myosin heavy chain as the zipper gene product. Embryos that lack functional myosin display defects in dorsal closure, head involution, and axon patterning. Analysis of cell morphology and myosin localization during dorsal closure in wild-type and homozygous mutant embryos demonstrates a key role for myosin in the maintenance of cell shape and suggests a model for the involvement of myosin in cell sheet movement during development. Our experiments, in conjunction with the observation that cytokinesis also requires myosin, suggest that the processes of cell shape change in morphogenesis and cell division are intimately and mechanistically related.

Complete sequence of the Drosophila nonmuscle myosin heavy-chain transcript: conserved sequences in the myosin tail and differential splicing in the 5' untranslated sequence.

We have sequenced a cDNA that encodes the nonmuscle myosin heavy chain from Drosophila melanogaster. An alternatively spliced exon at the 5' end generates two distinct heavy-chain transcripts: the longer transcripts inserts an additional start codon upstream of the primary translation start site and encodes a myosin heavy chain with a 45-residue extension at its amino terminus. The remainder of the coding sequence reveals extensive homology with other conventional myosins, especially metazoan nonmuscle and smooth muscle myosin isoforms. Comparisons among available myosin heavy-chain sequences establish that characteristic differences in sequence throughout the length of both the globular myosin head and extended rod-like tail readily distinguish nonmuscle and smooth muscle myosins from striated muscle isoforms and predict a basis for their functional diversity.

Contractile proteins in Drosophila development.

In summary, we have used a multidisciplinary approach to the analysis of actomyosin-based motility during Drosophila embryogenesis. We have documented the movements of early embryogenesis with modern, video methods. We have characterized the cytoplasmic myosin polypeptide, made specific polyclonal antisera to the molecule, studied its distribution during early embryogenesis, cloned and partially characterized the gene that encodes it, and have recently completed the nucleotide sequence of a nearly full length cDNA that encodes the entire protein-coding region. We have initiated studies on myosin function in living embryos both by direct microinjection of antibodies and through classical genetics. To better understand how myosin function is regulated, we have begun analysis of its light chains. Finally, to investigate the molecular mechanism by which its function is integrated into a labile cytoskeleton, whose architecture is constantly changing, we have also investigated Drosophila spectrins. Together, these studies are designed to shed light on the dynamics of biologic form at the cellular level, with current focus on such complex processes as cytokinesis and morphogenesis.

Identification of the gene for fly non-muscle myosin heavy chain: Drosophila myosin heavy chains are encoded by a gene family.

In contrast to vertebrate species Drosophila has a single myosin heavy chain gene that apparently encodes all sarcomeric heavy chain polypeptides. Flies also contain a cytoplasmic myosin heavy chain polypeptide that by immunological and peptide mapping criteria is clearly different from the major thoracic muscle isoform. Here, we identify the gene that encodes this cytoplasmic isoform and demonstrate that it is distinct from the muscle myosin heavy chain gene. Thus, fly myosin heavy chains are the products of a gene family. Our data suggest that the contractile function required to power myosin based movement in non-muscle cells requires myosin diversity beyond that available in a single heavy chain gene. In addition, we show, that accumulation of cytoplasmic myosin transcripts is regulated in a developmental stage specific fashion, consistent with a key role for this protein in the movements of early embryogenesis.