Transformation of Drosophila melanogaster with the wild-type myosin heavy-chain gene: rescue of mutant phenotypes and analysis of defects caused by overexpression

We have transformed Drosophila melanogaster with a genomic construct containing the entire wild-type myosin heavy-chain gene, Mhc, together with approximately 9 kb of flanking DNA on each side. Three independent lines stably express myosin heavy-chain protein (MHC) at approximately wild-type levels. The MHC produced is functional since it rescues the mutant phenotypes of a number of different Mhc alleles: the amorphic allele Mhc1, the indirect flight muscle and jump muscle-specific amorphic allele Mhc10, and the hypomorphic allele Mhc2. We show that the Mhc2 mutation is due to the insertion of a transposable element in an intron of Mhc. Since a reduction in MHC in the indirect flight muscles alters the myosin/actin protein ratio and results in myofibrillar defects, we determined the effects of an increase in the effective copy number of Mhc. The presence of four copies of Mhc results in overabundance of the protein and a flightless phenotype. Electron microscopy reveals concomitant defects in the indirect flight muscles, with excess thick filaments at the periphery of the myofibrils. Further increases in copy number are lethal. These results demonstrate the usefulness and potential of the transgenic system to study myosin function in Drosophila. They also show that overexpression of wild-type protein in muscle may disrupt the function of not only the indirect flight but also other muscles of the organism.     

Muscle-specific splicing enhancers regulate inclusion of the cardiac troponin T alternative exon in embryonic skeletal muscle.

The alternative exon 5 of the striated muscle-specific cardiac troponin T (cTNT) gene is included in mRNA from embryonic skeletal and cardiac muscle and excluded in mRNA from the adult. The embryonic splicing pattern is reproduced in primary skeletal muscle cultures for both the endogenous gene and transiently transfected minigenes, whereas in nonmuscle cell lines, minigenes express a default exon skipping pattern. Using this experimental system, we previously showed that a purine-rich splicing enhancer in the alternative exon functions as a constitutive splicing element but not as a target for factors regulating cell-specific splicing. In this study, we identify four intron elements, one located upstream,and three located downstream of the alternative exon, which act in a positive manner to mediate the embryonic splicing pattern of exon inclusion. Synergistic interactions between at least three of the four elements are necessary and sufficient to regulate splicing of a heterologous alternative exon and heterologous splice sites. Mutations in these elements prevent activation of exon inclusion in muscle cells but do not affect the default level of exon inclusion in nonmuscle cells. Therefore, these elements function as muscle-specific splicing enhancers (MSEs) and are the first muscle-specific positive-acting splicing elements to be described. One MSE located downstream from the alternative exon is conserved in the rat and chicken cTNT genes. A related sequence is found in a third muscle-specific gene, that encoding skeletal troponin T, downstream from an alternative exon with a developmental pattern of alternative splicing similar to that of rat and chicken cTNT. Therefore, the MSEs identified in the cTNT gene may play a role in developmentally regulated alternative splicing in a number of different genes.     

Sequence Requirements for Myosin Gene Expression and Regulation in Caenorhabditis Elegans

Four Caenorhabditis elegans genes encode muscle-type specific myosin heavy chain isoforms: myo-1 and myo-2 are expressed in the pharyngeal muscles; unc-54 and myo-3 are expressed in body wall muscles. We have used transformation-rescue and lacZ fusion assays to determine sequence requirements for regulated myosin gene expression during development. Multiple tissue-specific activation elements are present for all four genes. For each of the four genes, sequences upstream of the coding region are tissue-specific promoters, as shown by their ability to drive expression of a reporter gene (lacZ) in the appropriate muscle type. Each gene contains at least one additional tissue-specific regulatory element, as defined by the ability to enhance expression of a heterologous promoter in the appropriate muscle type. In rescue experiments with unc-54, two further requirements apparently independent of tissue specificity were found: sequences within the 3' non-coding region are essential for activity while an intron near the 5' end augments expression levels. The general intron stimulation is apparently independent of intron sequence, indicating a mechanistic effect of splicing. To further characterize the myosin gene promoters and to examine the types of enhancer sequences in the genome, we have initiated a screen of C. elegans genomic DNA for fragments capable of enhancing the myo-2 promoter. The properties of enhancers recovered from this screen suggest that the promoter is limited to muscle cells in its ability to respond to enhancers.     

Upstream and intronic regulatory sequences interact in the activation of the glutamine synthetase promoter.

Glutamine synthetase (GS) is expressed at high levels in subsets of cells in some tissues and at low levels in all cells of other tissues, suggesting that the GS gene is surrounded by multiple regulatory elements. We searched for such elements in the 2.5-kb upstream region and in the 2.6-kb first intron of the GS gene, using FTO-2B hepatoma and C2/7 muscle cells as representatives of both cell types and transient transfection assays as our tools. In addition to the entire upstream region and entire intron, an upstream enhancer module at -2.5 kb, and 5', middle and 3' modules of the first intron were tested. The main effects of the respective modules and their combinatorial interactions were quantified using the analysis of variance (anova) technique. The upstream enhancer was strongly stimulatory, the middle intron module strongly inhibitory, and the 3'-intron module weakly stimulatory in both hepatoma and muscle cells. The 5'-intron module was strongly stimulatory in muscle cells only. The major new finding was that in both cell types, the upstream enhancer and 5'-intron module needed to be present simultaneously to fully realize their transactivational potencies. This interaction was responsible for a pronounced inhibitory effect of the 5'-intron module in the absence of the upstream enhancer in hepatoma cells, and for a strong synergistic effect of these two modules, when present simultaneously in muscle cells. The main difference between hepatoma and muscle cells therefore appeared to reside in tissue-specific differences in activity of the respective regulatory elements due to interactions rather than in the existence of tissue-specific regulatory elements.     

Ultrabithorax is a regulator of beta 3 tubulin expression in the Drosophila visceral mesoderm.

beta 3 tubulin expression accompanies the specification and differentiation of the Drosophila mesoderm. The genetic programs involved in these processes are largely unknown. Our previous studies on the regulation of the beta 3 tubulin gene have shown that upstream sequences guide the expression in the somatic musculature, while regulatory elements in the first intron are necessary for expression in the visceral musculature. To further analyse this mode of regulation, which reflects an early embryonic specification program, we undertook a more detailed analysis of the regulatory capabilities of the intron. The results reveal not only a certain degree of redundancy in the cis-acting elements, which act at different developmental stages in the same mesodermal derivatives, but they also demonstrate in the visceral mesoderm, which forms a continuous epithelium along the body axis of the embryo, an early action of regulators guiding gene expression along the anterior-posterior axis of the embryo: an enhancer element in the intron leads to expression in a subdomain restricted along the anterior-posterior axis. This pattern is altered in mutants in the homeotic gene Ultrabithorax (Ubx), whereas ectopic Ubx expression leads to activity of the enhancer in the entire visceral mesoderm. So this element is likely to be a target of homeotic genes, which would define the beta 3 tubulin gene as a realisator gene under the control of selector genes.     

Tissue-specific expression of the alternately processed Drosophila myosin heavy-chain messenger RNAs

The myosin heavy-chain (Mhc) gene of Drosophila is a single-copy gene from which four messenger RNAs are transcribed. Two of these mRNAs, CA-1 and CA-2, are expressed in all stages of development when Mhc mRNA is detected. The 3' ends of these mRNAs differ by alternate choice of poly(A) addition sites. Two additional Mhc mRNAs, CBA-1 and CBA-2, are detected only in midpupal to adult stages of development. The 3' ends of these mRNAs are alternately polyadenylated as the above mRNAs; however, these mRNAs contain an additional alternately spliced exon. We have used in situ hybridization to tissue sections to determine the tissue-specific expression of the alternately processed Mhc mRNAs. Four probes were used in the in situ hybridization experiments: one that detects all Mhc mRNAs, one that is specific for mRNA molecules polyadenylated at the downstream site 2, one that is specific for alternately spliced mRNAs containing the B exon, and one that is specific for Mhc mRNAs Ca-1 and CA-2. This last probe is an oligodeoxynucleotide, while the others are single-stranded RNA molecules synthesized in vitro. Our results demonstrate that the alternate splicing of Mhc mRNAs is muscle-cell-type-specific during pupal development, while the polydenylation site usage at the downstream site 2 is not muscle-cell-type-specific during either embryonic or pupal development.