Eric Fyrberg

Transcripts of the six Drosophila actin genes accumulate in a stage- and tissue-specific manner

We have surveyed expression of the six Drosophila actin genes during ontogeny. Unique portions of cloned actin genes were used to monitor levels of respective mRNAs in developmentally staged whole organisms and dissected body parts. We find that each gene is transcribed to form functional mRNA, which accumulates with a distinct pattern. Two of the genes, act5C and act42A, are expressed in undifferentiated cells and probably encode cytoplasmic actins. Act57A and act87E are expressed predominantly in larval, pupal, and adult intersegmental muscles; act88F in muscles of the adult thorax; and act79B in the thorax and leg muscles. These composite data define three main patterns of actin gene expression which are correlated with changing Drosophila morphology, particularly muscle differentiation and reorganization.

Arthrin, a myofibrillar protein of insect flight muscle, is an actin-ubiquitin conjugate

Flight muscles of some insects contain a myofibrillar protein termed arthrin, which is closely related to actin (mw 43,000). Here we demonstrate that arthrin (mw 55,000) is ubiquitinated actin. We show that in Act88FM342, a flightless Drosophila mutant wherein the Act88F actin gene specifies a glu93----lys replacement, isoelectric points of both actin III and arthrin are shifted, revealing that both are encoded by the same gene. Arthrin reacts with an anti-ubiquitin antibody, which demonstrates that its extra mass results from ubiquitin ligation. Approximately one-seventh of myofibrillar actin is stably ubiquitinated, suggesting that there may be one arthrin molecule per actin-tropomyosin-troponin cooperative unit. Arthrin formation lags several hours behind that of actin III, implying that ubiquitination coincides with some aspect of myofibril assembly.

Troponin of asynchronous flight muscle

Troponin has been prepared from the asynchronous flight muscle of Lethocerus (water bug) taking special care to prevent proteolysis. The regulatory complex contained tropomyosin and troponin components. The troponin components were Tn-C (18,000 Mr), Tn-T (apparent Mr 53,000) and a heavy component, Tn-H (apparent Mr 80,000). The troponin was tightly bound to tropomyosin and could not be dissociated from it in non-denaturing conditions. A complex of Tn-T, Tn-H and tropomyosin inhibited actomyosin ATPase activity and the inhibition was relieved by Tn-C from vertebrate striated muscle in the presence of Ca2+. However, unlike vertebrate Tn-I, Tn-H by itself was not inhibitory. Monoclonal antibodies were obtained to Tn-T and Tn-H. Antibody to Tn-T was used to screen an expression library of Drosophila cDNA cloned in lambda phage. The sequence of cDNA coding for the protein was determined and hence the amino acid sequence. The Drosophila protein has a sequence similar to that of vertebrate skeletal and cardiac Tn-T. The sequence extends beyond the carboxyl end of the vertebrate sequences, and the last 40 residues are acidic. Part of the sequence of Drosophila Tn-T is homologous to the carboxyl end of the Drosophila myosin light chain MLC-2 and one anti-Tn-T antibody cross-reacted with the light chain. Lethocerus Tn-H is related to the large tropomyosins of Drosophila flight muscle, for which the amino acid sequence is known, since antibodies that recognize this component also recognize the large tropomyosins. Tn-H is easily digested by calpain, suggesting that part of the molecule has an extended configuration. Electron micrographs of negatively stained specimens showed that Lethocerus thin filaments have projections at about 39 nm intervals, which are not seen on thin filaments from vertebrate striated muscle and are probably due to the relatively large troponin complex. Decoration of the thin filaments with myosin subfragment-1 in rigor conditions appeared not to be affected by the troponin. The troponin of asynchronous flight muscle lacks the Tn-I component of vertebrate striated muscle. Tn-H occurs only in the flight muscle and may be involved in the activation of this muscle by stretch.

A nonsense mutation within the act88f actin gene disrupts myofibril formation in Drosophila indirect flight muscles

We have investigated the molecular basis of muscle abnormalities in the flightless Drosophila mutant lfm(3)7. This EMS-induced, semi-dominant allele was isolated by Mogami and Hotta (1981) and was shown to disrupt the organization of myofibrils in indirect flight muscles. Here we demonstrate that lfm(3)7 contains a nonsense mutation within codon 355 of the act88F actin gene. A single G greater than A transition converts a tryptophan (TGG) codon to an opal (TGA) terminator, thus deleting the carboxy-terminal 20 amino acids of an actin isoform that accumulates only in thoracic flight muscles. The truncated actin polypeptide is stable, and retains antigenicity to at least two anti-Drosophila actin monoclonal antibodies. We suggest that abnormalities in lfm(3)7 flight muscles result from incorporation of the mutant actin isoform into assembling myofibrils.

Functional Nonequivalence of Drosophila Actin Isoforms

We show that different Drosophila actinisoforms are not interchangeable. We sequenced the sixgenes that encode conventional Drosophilaactins and found that they specify amino acidreplacements in 27 of 376 positions. To test the significance ofthese changes we used directed mutagenesis to introduce10 such conversions, independently, into the Act88Fflight muscle-specific actin gene. We challenged these variant actins to replace the nativeprotein by transforming germline chromosomes of aDrosophila strain lacking flight muscle actin.Only one of the 10 reproducibly perturbed myofibrillarfunction, demonstrating that most isoform-specific aminoacid replacements are of minor significance. In order toestablish the consequences of multiple amino acidreplacements, we substituted portions of theDrosophila Act88F actin gene with correspondingregions of genes encoding other isoforms. Only one offive constructs tested engendered normally functioningflight muscles, and the severity of myofibrillar defects correlated with the number of replacementswithin the chimeric genes. Finally, we completelyconverted the flight muscle actin-encoding gene to onespecifying a nonmuscle isoform, a change entailing atotal of 18 amino acid replacements. Transformationof flies with this construct resulted in disruption offlight muscle structure and function. We conclude thatactin isoform sequences are not equivalent and that effects of the amino acid replacements,while minor individually, collectively confer uniqueproperties.

Organization of contractile protein genes within the 88F subdivision of the D. melanogaster third chromosome

We have investigated contractile protein gene arrangement within the 88F subdivision of the Drosophila melanogaster third chromosome. We show that at least five antigenically related myofibrillar proteins, three of which accumulate only within indirect flight muscles, are encoded by a 20 kilobase chromosome segment located 140 kilobases proximal to the act88F actin gene. The chromosome segment includes two transcribed regions, each of which directs the synthesis of multiple mRNAs. RNA blot-hybridization experiments and DNA sequencing suggest that overlapping transcripts are generated by differential RNA splicing. The nucleotide sequence also establishes that two of the encoded proteins are tropomyosin isoforms, and two are related to tropomyosin. The arrangement of myofibrillar genes parallels the distribution of third chromosome mutations that disrupt indirect flight muscle formation.

An insertion within a variably spliced Drosophila tropomyosin gene blocks accumulation of only one encoded isoform

We have characterized an aberrant allele of a variably spliced Drosophila tropomyosin gene. The allele was recovered from the flightless Ifm(3)3 strain, which has been shown to have structurally and functionally abnormal indirect flight muscles. The transcribed portion of the mutant gene is interrupted by an 8,8 kb insertion of middle repetitive DNA having a structure typical of copia-like Drosophila mobile elements. The insertion is positioned so as to interrupt an exon sequence in one splicing mode and, simultaneously, an intron in the alternate mode. As a consequence of the insertion the allele fails to direct synthesis of the flight muscle-specific tropomyosin isoform, but remains capable of specifying a second isoform, which accumulates in nonfibrillar Drosophila muscles.

The flightless drosophila mutant raised has two distinct genetic lesions affecting accumulation of myofibrillar proteins in flight muscles

We have used a combination of histological, molecular, and genetic techniques to investigate the flightless Drosophila mutant raised. Electron microscopy of indirect flight muscles of raised homozygotes confirms that they are grossly abnormal, lacking thin filaments and Z discs. These defects correspond to aberrant protein accumulation in thoraces, where several myofibrillar components are reduced or absent. Utilizing the germ-line transformation technique we demonstrate that one genetic lesion associated with the raised phenotype resides within the act88F actin gene, which, as a result, fails to specify normal mRNA accumulation during thoracic muscle differentiation. We also provide evidence for a distinct second genetic lesion, which apparently eliminates proper posttranslational modification of two myofibrillar proteins, one of which is actin.

Drosophila Projectin: Relatedness to Titin and Twitchin and Correlation with lethal(4)102 CDa and bent-Dominant Mutants

We have investigated projectin, a large protein of insect muscles, in Drosophila melanogaster. The 5.3 kilobases of coding sequence reported here contains Class I and Class II motifs characteristic of titin and twitchin, arranged in a three domain ...[II–I–I] [II–I–I]... pattern. Two mutants mapped to the location of the projectin gene in the 102C subdivision of chromosome 4, lethal(4)102 CDa and bent-Dominant, have DNA rearrangements within their projectin gene. The lethal{4) 102 CDa mutant has a 141 nucleotide insertion containing stop codons in all three reading frames within an exon sequence, showing that it cannot synthesize normal projectin. Both bent-Dominant and lethal(4) 102 CDa homozygotes die at the completion of embryogenesis because they are unable to escape the egg vitelline membrane. We propose that this hatching failure is due to muscle weakness caused by projectin defects.

Green fluorescent protein/beta-galactosidase double reporters for visualizing Drosophila gene expression patterns.

We characterized 120 novel yeast Ga14-targeted enhancer trap lines in Drosophila using upstream activating sequence (UAS) reporter plasmids incorporating newly constructed fusions of Aequorea victoria green fluorescent protein (GFP) and Escherichia coli beta-galactosidase genes. Direct comparisons of GFP epifluorescence and beta-galactosidase staining revealed that both proteins function comparably to their unconjugated counterparts within a wide variety of Drosophila tissues. Generally, both reporters accumulated in similar patterns within individual lines, but in some tissues, e.g., brain, GFP staining was more reliable than that of beta-galactosidase, whereas in other tissues, most notably tests and ovaries, the converse was true. In cases of weak enhancers, we occasionally could detect beta-galactosidase staining in the absence of discernible GFP fluorescence. This shortcoming of GFP can, in most cases, be alleviated by using the more efficient S65T GFP derivative. The GFP/beta-gal reporter fusion protein facilitated monitoring several aspects of protein accumulation. In particular, the ability to visualize GFP fluorescence enhances recognition of global static and dynamic patterns in live animals, whereas beta-galactosidase histochemistry affords sensitive high resolution protein localization. We present a catalog of Ga 14-expressing strains that will be useful for investigating several aspects of Drosophila melanogaster cell and developmental biology.