H3K79 methylation directly precedes the histone-to-protamine transition in mammalian spermatids and is sensitive to bacterial infections

In both mammalian and Drosophila spermatids, the completely histone-based chromatin structure is reorganized to a largely protamine-based structure. During this histone-to-protamine switch, transition proteins are expressed, for example TNP1 and TNP2 in mammals and Tpl94D in Drosophila. Recently, we demonstrated that in Drosophila spermatids, H3K79 methylation accompanies histone H4 hyperacetylation during chromatin reorganization. Preceding the histone-to-protamine transition, the H3K79 methyltransferase Grappa is expressed, and the predominant isoform bears a C-terminal extension. Here, we show that isoforms of the Grappa-equivalent protein in humans, rats and mice, that is DOT1L, have a C-terminal extension. In mice, the transcript of this isoform was enriched in the post-meiotic stages of spermatogenesis. In human and mice spermatids, di- and tri-methylated H3K79 temporally overlapped with hyperacetylated H4 and thus accompanied chromatin reorganization. In rat spermatids, trimethylated H3K79 directly preceded transition protein loading on chromatin. We analysed the impact of bacterial infections on spermatid chromatin using a uropathogenic Escherichia coli-elicited epididymo-orchitis rat model and showed that these infections caused aberrant spermatid chromatin. Bacterial infections led to premature emergence of trimethylated H3K79 and hyperacetylated H4. Trimethylated H3K79 and hyperacetylated H4 simultaneously occurred with transition protein TNP1, which was never observed in spermatids of mock-infected rats. Upon bacterial infection, only histone-based spermatid chromatin showed abnormalities, whereas protamine-compacted chromatin seemed to be unaffected. Our results indicated that H3K79 methylation is a histone modification conserved in Drosophila, mouse, rat and human spermatids and may be a prerequisite for proper chromatin reorganization.

rolling pebbles(rols) is required inDrosophilamuscle precursors for recruitment of myoblasts for fusion

Mutations in the rolling pebbles (rols) gene result in severe defects in myoblast fusion. Muscle precursor cells are correctly determined, but myogenesis does not progress significantly beyond this point because recognition and/or cell adhesion between muscle precursor cells and fusion-competent myoblasts is disturbed. Molecular analysis of the rols genomic region reveals two variant transcripts of rols due to different transcription initiation sites, rols6 and rols7. rols6 mRNA is detectable mainly in the endoderm during differentiation as well as in malpighian tubules and in the epidermis. By contrast, rols7 expression is restricted to the mesoderm and later to progenitor descendants during somatic and pharyngeal muscle development. Transcription starts at the extended germ band stage when progenitor/founder cells are determined and persists until stage 13. The proteins encoded by the rols gene are 1670 (Rols6) and 1900 (Rols7) amino acids in length. Both forms contain an N-terminal RING-finger motif, nine ankyrin repeats and a TPR repeat eventually overlaid by a coiled-coil domain. The longer protein, Rols7, is characterized by 309 unique N-terminal amino acids, while Rols6 is distinguishable by 79 N-terminal amino acids. Expression of rols7 in muscle founder cells indicates a function of Rols7 in these cells. Transplantation assays of rols mutant mesodermal cells into wild-type embryos show that Rols is required in muscle precursor cells and is essential to recruit fusion-competent myoblasts for myotube formation.

The initiator element of the Drosophila beta2 tubulin gene core promoter contributes to gene expression in vivo but is not required for male germ-cell specific expression

The tissue-specific expression of the Drosophila beta 2 tubulin gene ( B2t ) is accomplished by the action of a 14-bp activator element (beta2UE1) in combination with certain regulatory elements of the TATA-less, Inr-containing B2t core promoter. We performed an in vivo analysis of the Inr element function in the B2t core promoter using a transgenic approach. Our experiments demonstrate that the Inr element acts as a functional cis -regulatory element in vivo and quantitatively regulates tissue-specific reporter expression in transgenic animals. However, our mutational analysis of the Inr element demonstrates no essential role of the Inr in mediating tissue specificity of the B2t promoter. In addition, a downstream element seems to affect promoter activity in combination with the Inr. In summary, our data show for the first time the functionality of the Inr element in an in vivo background situation in Drosophila.

Expression of the beta3 tubulin gene (beta Tub60D) in the visceral mesoderm of Drosophila is dependent on a complex enhancer that binds Tinman and UBX

The beta3 tubulin gene of Drosophila is expressed in the major mesodermal derivatives during their differentiation. The gene is subject to complex stage- and tissue-specific transcriptional control by upstream as well as downstream regions. Analysis of the vm1 enhancer, which is responsible for tissue-specific expression in the visceral mesoderm and is localized in the intron, revealed a complex modular arrangement of regulatory elements. In vitro and in vivo experiments uncovered two binding sites, termed UBX1 and UBX2, for the product of the homeotic gene Ultrabithorax (Ubx), which are required for high-level expression in pPS6 and PS7. Further analysis of the vm1 enhancer revealed that deletion of a specific element, termed element 7 (e7), abolishes transcription of the lacZ reporter gene in all parasegments except pPS6/PS7. Gel-retardation and footprint analysis identified a binding site for the homeodomain protein Tinman, which is essential for the specification of the dorsal mesoderm, within e7. Simultaneous deletion of two further sequence blocks in the vml enhancer, named elements 3 (e3), and 6 (e6), results in a reduction analogous to that caused by removal of e7. The e6 sequence contains conserved motifs also found in the visceral enhancer of the Ubx gene. Therefore we conclude that these elements act in concert with the Tinman binding site to achieve high expression levels. Thus the vm1 enhancer of the beta3 tubulin gene contains a complex array of elements that are involved in transactivation by a combination of tissue- and position-specific factors including Tinman and UBX.

Tinman regulates the transcription of the beta3 tubulin gene (betaTub60D) in the dorsal vessel of Drosophila

During Drosophila embryogenesis, the beta3 tubulin gene is expressed in the visceral and somatic mesoderm as well as in the dorsal vessel. Transcription of the gene is limited to four pairs of cardioblasts per segment. Here we show that its expression in the dorsal vessel (dv) is mediated by a 333-bp enhancer located upstream of the gene. The homeodomain protein Tinman is also expressed in these cardioblasts, implying that Tinman might be a key regulator of the beta3 tubulin gene. Gel retardation and footprint assays indeed revealed two Tinman binding sites within the dv-specific enhancer. We analyzed the relevance of the Tinman binding sites in a transgenic fly assay and observed distinct functions for both sites. The BS(Tin-1460) site is absolutely required for expression in cardioblasts, while BS(Tin-1425) is needed for high-level expression. Thus, these two Tinman binding sites act in concert to drive beta3 tubulin gene expression during heart development. Tinman initially functions in the specification of visceral mesoderm and heart progenitors, but remains expressed in cardioblasts until dorsal closure. Overall, our data demonstrate a late function for Tinman in the regulation of beta3 tubulin gene expression in the forming heart of Drosophila.

Essential genes for myoblast fusion in Drosophila embryogenesis

In Drosophila, as in vertebrates, each muscle is a syncytium and arises from mesodermal cells by successive fusion. This requires cell-cell recognition, alignment, formation of prefusion complexes, followed by electron-dense plaques and membrane breakdown. Because muscle development in Drosophila is rapid and well-documented, it has been possible to identify several genes essential for fusion. Molecular analysis of two of these genes revealed the importance of cytoplasmic components. One of these, Myoblast city, is expressed in several tissues and is homologous to the mammalian protein DOCK180. Myoblast city is presumably involved in cell recognition and cell adhesion. Blown fuse, the second cytoplasmic component, is selectively expressed in the mesoderm and essential in order to proceed from the prefusion complex to electron-dense plaques at opposed membranes between adjacent myoblasts. The rolling stone gene is transiently expressed during myoblast fusion. The Rost protein is located in the membrane and thus might be a key component for cell recognition. The molecular characterization of further genes relevant for fusion such as singles bar and sticks and stones will help to elucidate the mechanism of myoblast fusion in Drosophila.

Determination and development of the larval muscle pattern in Drosophila melanogaster

This review describes briefly what is known about the early steps of mesoderm differentiation in the fruitfly Drosophila melanogaster. After a summary of general aspects including mesoderm differentiation, mesoderm cell migration and subdivision of the mesoderm, more detail is given about the specification of muscle progenitor cells, due to their role as the earliest obvious landmarks in muscle fiber development in Drosophila. Particular focus is given to recent results on the role of asymmetric cell division in muscle differentiation. Furthermore a short summary of myoblast fusion is provided.

Flagellar mitochondrial association of the male-specific Don Juan protein in Drosophila spermatozoa

The Drosophila don juan gene encodes a basic protein (Don Juan protein), which is solely expressed postmeiotically during spermiogenesis in elongated spermatids and in mature sperm. Transgenic expression of a GFP-tagged Don Juan protein (DJ-GFP) in the male germ line showed an association of the fusion protein with the sperm tail. Detailed examination of DJ-GFP localization revealed novel insights into its distinct temporal and spatial distribution along the sperm tail during the last phase of spermatid maturation. Co-localization of DJ-GFP with actin-labeled cysts demonstrated its emergence in elongated spermatids during individualization. Additionally, the endogenous Don Juan protein was detected with epitope-specific antibodies in finally elongated nuclei of spermatids. After completion of nuclear shaping Don Juan is no longer detectable in the sperm heads with the onset of individualization. Mislocalization of the DJ-GFP protein in flagella of a mutant with defective mitochondrial differentiation provides evidence of mitochondrial association of the fusion protein with flagellar mitochondrial arrays. Ectopically expressed DJ-GFP in premeiotic germ cells as well as salivary gland cells confirmed the capability of the fusion protein to associate with mitochondria. Therefore we suppose that Don Juan is a nuclear-encoded, germ-cell specifically expressed mitochondrial protein, which might be involved in the final steps of mitochondrial differentiation within the flagellum.

Independent regulatory elements in the upstream region of the Drosophila beta 3 tubulin gene (beta Tub60D) guide expression in the dorsal vessel and the somatic muscles

The beta 3 tubulin gene (beta Tub60D) is a structural gene expressed during mesoderm development from the extended germ band stage onward. Expression within the individual mesodermal derivatives is guided by different control elements. The upstream regions allow expression in the dorsal vessel and the somatic mesoderm while enhancers localized in the first intron guide expression in the visceral mesoderm. Deletion analysis carried out in transgenic flies revealed independent regulatory elements for the dorsal vessel and the somatic mesoderm. For expression in the somatic mesoderm, a 279-bp region is absolutely essential. This region contains a binding site for the Drosophila myocyte-specific enhancer binding factor 2 (D-MEF2), a MADS-box transcription factor known to be essential for mesoderm development. Deletion or mutation of this D-MEF2 binding site strongly reduces transcription. This pattern is consistent with the strongly reduced expression of beta 3 tubulin in D-mef2 mutant embryos. This analysis furthermore reveals that the D-MEF2 binding site acts in concert with nearby cis regulatory elements. These data show that the upstream control region of the beta 3 tubulin gene is an early target of the D-MEF2 transcriptional activator.

Somatic mesoderm differentiation and the development of a subset of pericardial cells depend on the not enough muscles (nem) locus, which contains the inscuteable gene and the intron located gene, skittles

Not enough muscles (nem) mutants of Drosophila reveal defects in the development of embryonic muscles, a subset of pericardial cells, the CNS and derivatives of the PNS (Burchard, S., Paululat, A., Hinz, U. and Renkawitz-Pohl, R. (1995) The mutant not enough muscles (nem) reveals reduction of the Drosophila embryonic muscle pattern. J. Cell. Sci. 108, 1443-1454). The molecular analysis of the nem locus shows a complex genomic structure. One transcription unit was identified as inscuteable (insc). Within the first intron of insc we find another independent gene, skittles (sktl), which is not affected in nem mutants. insc transcripts are localised apically in neuroblasts and may prefigure the localisation of the protein. The skittles mRNA is ubiquitously distributed during early embryogenesis due to maternal contribution. Later, some enrichment of sktl is observed in the nervous system and the mesoderm. The muscle phenotype shows deletions as well as duplication of specific muscles which is reflected in a change of even-skipped (eve) and Krüppel (Kr) expressing cells. Our data suggest a role for insc in the specification process of a subset of muscle progenitors/founders. Furthermore, in insc mutants the eve expressing pericardial cells of the developing heart are significantly reduced in numbers.

The mesodermal expression of rolling stone (rost) is essential for myoblast fusion in Drosophila and encodes a potential transmembrane protein

In homozygous rolling stone embryos, the fusion of myoblasts to syncytial myotubes is diminished. Nevertheless, the visceral mesoderm, the heart mesoderm, and few somatic muscles are properly formed. Thus, we postulate a central role of rolling stone for the fusion process within the somatic mesoderm. We have cloned the rolling stone gene, and the deduced protein sequence is in accordance with a transmembrane protein, which agrees with the enrichment of Rost in the membrane fraction of Drosophila embryos. No homologous genes have been described so far. rolling stone is expressed in the embryonic nervous system and cells of the somatic mesoderm, most notable in muscle founder cells. To elucidate the function of rolling stone for myoblast fusion, we applied a knock-out strategy. The expression of an antisense rolling stone transcript specifically within the mesoderm of wild-type embryos results in fusion defects of myoblasts, proving that the rolling stone expression in the mesoderm is responsible for the rolling stone phenotype. We suggest that rolling stone is a member of a group of genes that are necessary for the fusion process during myogenesis.

The Drosophila don juan (dj) gene encodes a novel sperm specific protein component characterized by an unusual domain of a repetitive amino acid motif

We identified and characterized the don juan gene (dj) of Drosophila melanogaster. The don juan gene codes for a sperm specific protein component with an unusual repetitive six amino acid motif (DPCKKK) in the carboxy-terminal part of the protein. The expression of Don Juan is limited to male germ cells where transcription of the dj gene is initiated during meiotic prophase. But Western blot experiments indicate that DJ protein occurs just postmeiotically. Examination of transgenic flies bearing a dj-promoter-lacZ reporter construct revealed lacZ mRNA distribution resembling the expression pattern of the endogenous dj mRNA in the adult testes, whereas beta-galactosidase expression is exclusively present in postmeiotic germ cells. Thus, these observations strongly suggest that dj transcripts are under translational repression until in spermiogenesis. To study the function and subcellular distribution of DJ in spermiogenesis we expressed a chimaeric dj-GFP fusion gene in the male germline exhibiting strong GFP fluorescence in the liver testes, where only elongated spermatids are decorated. With regard to the characteristic expression pattern of DJ protein and its conspicuous repeat units possible functional roles are discussed.

The Drosophila gene alien is expressed in the muscle attachment sites during embryogenesis and encodes a protein highly conserved between plants, Drosophila and vertebrates

We have found a novel gene (alien) that is expressed exclusively in the muscle attachment sites (apodemes) during embryogenesis in Drosophila. Antibodies raised against the Alien protein enable us to follow the developing attachments from state 11/12 until stage 16/17. The coding region of the Drosophila alien gene is highly conserved to a gene of unknown function, isolated from a plant (Loo et at., 1995), and to the human TRIP15 gene (Lee et al., 1995). Searching for thyroid receptor interacting proteins, TRIP15 was isolated as a negative regulator. Whether there is a functional correlation to Alien remains to be analyzed. Alien expression is independent of muscle formation, as shown in rolling stone mutant embryos. Even in twist and snail mutants, lacking mesodermal development, alien expression is fairly normal, showing a rather autonomous development of the apodemes. The conservation of alien suggests an important role in differentiation.

Muscle development and attachment to the epidermis is accompanied by expression of beta 3 and beta 1 tubulin isotypes, respectively

In Drosophila beta tubulins are encoded by a small gene family whose members are differentially expressed in a highly cell and tissue specific manner. Here we focus on the expression of the beta 3 tubulin isotype during mesoderm differentiation and beta 1 tubulin expression in the apodemes during embryonic development. The beta 3 tubulin isotype is first detectable at the extended germband stage shortly before the separation of somatic and visceral derivatives. Comparing the distribution of the beta 3 mRNA and the beta 3 isotype shows that the transcription of the beta 3 tubulin gene is cell type specifically repressed during differentiation of individual mesodermal derivatives, from which the dorsal vessel remains transcriptionally active until shortly before hatching. In contrast the beta 3 tubulin protein is detectable in all mesodermal derivatives. The beta 3 tubulin is an excellent marker to study mesoderm differentiation on a regulatory and cellular level using both genetics and molecular biology. In the visceral mesoderm, the expression of the beta 3 tubulin gene is regulated by homeotic gene products, while other transactivators regulate expression in the dorsal vessel and the body wall musculature. In the somatic mesoderm, the beta 3 tubulin allows to visualize myotube formation and insertion into the epidermis. This contact to the epidermal attachment sites (apodemes) induces beta 1 tubulin expression, as can be seen in double staining experiments. We determined a 14bp cis-regulatory enhancer element guiding expression of the beta 1 tubulin gene in these attachment sites. Using the beta 1 and beta 3 tubulin isotypes as markers we started to isolate mutants which are disturbed in muscle formation.

Fusion from myoblasts to myotubes is dependent on the rolling stone gene (rost) of Drosophila

The development and differentiation of the body wall musculature in Drosophila are accompanied by changes in gene expression and cellular architecture. We isolated a Drosophila gene, termed rolling stone (rost), which, when mutated, specifically blocks the fusion of mononucleated cells to myotubes in the body wall musculature. beta 3 tubulin, which is an early marker for the onset of mesoderm differentiation, is still expressed in these cells. Gastrulation and mesoderm formation, as well as the development of the epidermis and of the central and peripheral nervous systems, appear quite normal in homozygous rolling stone embryos. Embryonic development stops shortly before hatching in a P-element-induced mutant, as well as in 16 EMS-induced alleles. In mutant embryos, other mesodermal derivatives such as the visceral mesoderm and the dorsal vessel, develop fairly normally and defects are restricted to the body wall musculature. Myoblasts remain as single mononucleated cells, which express muscle myosin, showing that the developmental program of gene expression proceeds. These myoblasts occur at positions corresponding to the locations of dorsal, ventral and pleural muscles, showing that the gene rolling stone is involved in cell fusion, a process that is independent of cell migration in these mutants. This genetic analysis has set the stage for a molecular analysis to clarify where the rolling stone action is manifested in the fusion process and thus gives insight into the complex regulating network controlling the differentiation of the body wall musculature.

The mutant not enough muscles (nem) reveals reduction of the Drosophila embryonic muscle pattern

In a search for mutations affecting embryonic muscle development in Drosophila we identified a mutation caused by the insertion of a P-element, which we called not enough muscles (nem). The phenotype of the P-element mutation of the nem gene suggests that it may be required for the development of the somatic musculature and the chordotonal organs of the PNS, while it is not involved in the development of the visceral mesoderm and the dorsal vessel. Mutant embryos are characterized by partial absence of muscles, monitored by immunostainings with mesoderm-specific anti-beta 3 tubulin and anti-myosin heavy chain antibodies. Besides these muscle distortions, defects in the peripheral nervous system were found, indicating a dual function of the nem gene product. Ethyl methane sulfonate-induced alleles for the P-element mutation were created for a detailed analysis. One of these alleles is characterized by unfused myoblasts which express beta 3 tubulin and myosin heavy chain, indicating the state of cell differentiation.

Expression of beta 1 tubulin (beta Tub56D) in Drosophila testis stem cells is regulated by a short upstream sequence while intron elements guide expression in somatic cells

Stem cell differentiation to mature spermatozoa is a morphogenetic process that is highly dependent on microtubular arrays. In the early, mitotically active stages of spermatogenesis, only the beta 1 tubulin isotype is expressed. Analysis of transgenic flies containing beta 1-lacZ gene fusions revealed that this expression is regulated by sequences located between positions -45 and -191 upstream of the transcription initiation site. Furthermore, beta 1 tubulin is a major component of cyst cells. Expression in these cells is driven by enhancer elements located in the beta 1 tubulin gene intron. These enhancer elements also guide expression in combination with the hsp70 basal promoter. In addition, redundant enhancer elements in the intron drive expression in the testis wall. Our data show that within a single tissue, the male gonad, expression of the beta 1 tubulin gene is under cell-type-specific control mediated by independent cis-acting elements. Therefore in the germ line, control of beta 1 tubulin expression is strictly governed by promoter-proximal elements, while for the somatic parts of the testis, enhancer elements confer less stringent expression control.

An 18-bp element in the 5' untranslated region of the Drosophila beta 2 tubulin mRNA regulates the mRNA level during postmeiotic stages of spermatogenesis

During Drosophila spermatogenesis transcriptional activity is mainly restricted to premeiotic stages. Translation during sperm morphogenesis, however, proceeds for several days, requiring a high stability for mRNAs translated postmeiotically. We studied expression of the Drosophila beta 2 tubulin gene, which is expressed solely in the male germ line from the primary spermatocyte stage onwards. Cis-acting elements involved in the regulation of mRNA levels were investigated in transgenic fly strains. In adult testes, mRNA amounts from beta 2-lacZ fusion genes in the presence of an 18-bp AT-rich element, termed beta 2DE1, are elevated about threefold. The element is present at about the same position in the 5' untranslated regions of the beta 2 tubulin genes of the distantly related species Drosophila melanogaster and Drosophila hydei. Changing the position of the element on the mRNA reduces the stabilizing effect, while inversion of the beta 2DE1 abolishes its function. The element also acts in a combination with the beta 1 tubulin transcription start site, and the beta 2UE1, which is required to achieve tissue-specific expression. In all experiments done, the comparison of premeiotic with postmeiotic stages strongly implies that this element is involved in regulating mRNA stability. This mRNA stabilizing element acts in a position-independent manner and also on a heterologous mRNA, showing its autonomous functional activity.

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.

Further sequence requirements for male germ cell-specific expression under the control of the 14 bp promoter element (beta 2UE1) of the Drosophila beta 2 tubulin gene

We have investigated a 14 bp promoter element (beta 2UE1) that is required for testis-specific expression of the Drosophila beta 2 tubulin gene. To further elucidate the role of the 14 bp element, we fused different promoter constructs to the E. coli lacZ gene and established transgenic strains with the aid of the Drosophila P-element transformation system. Germ line transformation experiments with constructs in which the element in the beta 2 tubulin gene promoter was exchanged for a related sequence from the promoter region of the Drosophila beta 3 tubulin gene led to a dramatic reduction in the expression of the lacZ gene in the testis. Exchanging the 14 bp promoter element for a similar sequence from the distal promoter of the Drosophila alcohol dehydrogenase gene abolished expression. This might indicate that the sequence differences between the beta 2UE1 and the beta 2UE1-related elements reflect functional differences between these elements. Constructs in which the beta 2UE1 was fused to the hsp70 promoter revealed that testis-specific expression of a marker gene is obtained only when the element is located at the correct distance from the transcription initiation site. However, constructs in which the beta 2UE1 was inserted at about the correct position (between -41 and -54 bp) upstream of a truncated beta 3 tubulin gene promoter did not show any expression. By making beta 2-beta 3 gene promoter fusions it was found that both the region surrounding the beta 3 transcription initiation site as well as the first 116 b of beta 3 leader sequences independently reduce testis-specific expression. These findings suggest that the testis-specific expression of the Drosophila beta 2 tubulin gene underlies a unique regulatory mechanism.

During Drosophila spermatogenesis beta 1, beta 2 and beta 3 tubulin isotypes are cell-type specifically expressed but have the potential to coassemble into the axoneme of transgenic flies

alpha and beta Tubulins exist in a number of different isotypes with distinct expression patterns during development. We have shown by immunofluorescent staining that beta 1, beta 2 and beta 3 tubulins are distributed very specifically in the testes of Drosophila. beta 3 Tubulin is present exclusively in cytoplasmic microtubules of cells somatic in origin, while the beta 1 isotype is localized in the somatic cells and in early germ cells of both the microtubules of the cytoskeleton as well as in the mitotic spindle. In contrast, beta 2 tubulin is present in all microtubular arrays (cytoskeleton, meiotic spindles, axoneme) of germ cells from meiotic prophase onward, though not detectable in somatic cells. Thus, a switch of beta tubulin isotypes from beta 1 to beta 2 occurs during male germ cell differentiation. This switch is also observed in the distantly related species Drosophila hydei. By fusing beta 1 or beta 3 amino acid coding regions to the control region of the beta 2 tubulin gene and performing germ line transformation experiments, we have examined the copolymerization properties of the different tubulin isotypes. Neither beta 1 nor beta 3 are detectable in the axoneme in the wild-type situation. Analysis of transgenic flies carrying beta 2-beta 1 fusion genes or beta 2-beta 3 fusion genes revealed that both beta 1 and beta 3 tubulin isotypes have the potential to co-incorporate with beta 2 tubulin into microtubules of the sperm axoneme. Male flies homozygous for the fusion genes (beta 2-beta 1 or beta 2-beta 3) remain fertile, despite the mixture of beta tubulin isotypes in the axoneme.

During Drosophila embryogenesis the beta 1 tubulin gene is specifically expressed in the nervous system and the apodemes

We determined the in vivo distribution of the beta 1 tubulin from D. melanogaster using isotype specific antibodies. Maternally expressed beta 1 tubulin is incorporated into mitotic spindles. Later in development a strong expression in the CNS is observed. Furthermore, all chordotonal organs and the apodemes are marked by beta 1 tubulin. Nuclear run-on assays and stage specific in vitro transcription showed a zygotic expression of the beta 1 tubulin gene from the extended germ-band stage onwards. Using the P-element system, we identified several elements; upstream between -2.2 kb and the transcription initiation site, elements for low level expression in the CNS are present. In the intron between +0.44 kb and +2.5 kb enhancer elements are located that drive the expression in the chordotonal organs and the apodemes. Between the start site and +0.44 kb (273 bp) and +2.5 kb and the second exon (315 bp), maternal and CNS enhancers result in full level expression of a lacZ-beta 1 reporter gene. We show, that the beta 1 tubulin gene is very early effector gene starting its expression shortly after the commitment of neuroblast cell fate. This gene offers an excellent model system for the identification of neural and apodeme specific transcription factors.

Intron and upstream sequences regulate expression of the Drosophila beta 3-tubulin gene in the visceral and somatic musculature, respectively

The morphogenetic programs involved in the differentiation of internal organs, such as the muscle system, during Drosophila embryogenesis have remained largely obscure. beta 3-tubulin has proved to be a good marker for mesoderm development as this tubulin isotype is detectable soon after mesoderm formation and during the process of mesoderm differentiation. The beta 3-tubulin gene is expressed in the somatic and pharyngeal musculature, the dorsal vessel, and the visceral musculature. To learn more about the programs underlying mesodermal differentiation, we have started to dissect the regulatory elements of the beta 3-tubulin gene by means of P-element-mediated transformation experiments. We show that expression of the beta 3-tubulin gene in the somatic muscles, the pharyngeal muscles, and the dorsal vessel is mediated by far upstream sequences. We also demonstrate that the first intron of the beta 3-tubulin gene bears a tissue-specific enhancer element that is required for expression in the visceral muscles and that also functions efficiently when cloned downstream of an indicator gene. The separability of elements driving beta 3-tubulin expression in the somatic and visceral mesoderm facilitates the investigation of the different programs involved in regulating the early differentiation of this germ layer.

A 14 bp promoter element directs the testis specificity of the Drosophila beta 2 tubulin gene

To analyze the regulation of gene expression during male germ cell development, we investigated the testis-specific expression of the Drosophila beta 2 tubulin gene. Germ line transformation experiments with the upstream region of the D.melanogaster beta 2 tubulin gene fused to the Escherichia coli lacZ gene resulted in the correct tissue specific expression of the reporter gene. Furthermore, we showed that the upstream sequences of the beta 2 tubulin gene of the distantly related species D.hydei can drive the expression of the lacZ gene testis specifically in D.melanogaster flies. A detailed deletion analysis showed that 53 bp of upstream and 23 bp (D.melanogaster) or 29 bp (D.hydei) of leader sequences are sufficient to confer tissue specificity. The short promoter regions contain a 14 bp motif at identical positions in both species, which acts as a position-dependent promoter element. In vitro mutagenesis and subsequent germline transformation experiments revealed that this sequence is the only element necessary for the testis-specific transcription of the beta 2 tubulin gene in Drosophila.

β3 tubulin expression characterizes the differentiating mesodermal germ layer during Drosophila embryogenesis

During embryogenesis, the β3 tubulin gene of Drosophila is transcribed predominantly in the mesoderm. We have raised antibodies specific to the C-terminal domain of the β3 tubulin and analysed by immunostaining the distribution of this tubulin isotype during Drosophila embryogenesis. The protein is first detectable in the cephalic mesoderm at maximal germband extension. Shortly afterwards, β3 tubulin is expressed in single cells at identical positions of the thoracic and abdominal segments. We suggest that these cells represent muscle pioneer cells of Drosophila. During later embryonic development the somatic musculature, musculature, visceral musculature, dorsal vessel and macrophages contain β3 tubulin. In dorsalizing mutants dorsal, snail and twist, which do not form a ventral furrow during gastrulation, β3 expression is greatly reduced but not completely abolished. Our analysis shows that β3 tubulin immunostaining characterizes the differentiation of mesodermal derivatives during embryogenesis

The expression of beta 1 and beta 3 tubulin genes of Drosophila melanogaster is spatially regulated during embryogenesis

In Drosophila beta tubulins are encoded by a small gene family and the four members of this family are differentially expressed. mRNAs transcribed from two of these genes, namely the beta 1 and beta 3 tubulin genes, are abundant during embryogenesis. While the beta 1 tubulin gene is constitutively expressed during development, beta 3 mRNA is restricted to two distinct phases: mid embryogenesis and metamorphosis. The transcription initiation sites are identical in both these stages and comparison of presumptive promoter regions reveals no extensive homologies between the genes. In situ localization shows beta 1 tubulin mRNA to be maternally expressed in the nurse cells of the egg chambers and evenly distributed during early embryogenesis. In contrast, during later stages of embryogenesis beta 1 tubulin transcripts are predominantly expressed in neural derivatives. The beta 3 tubulin gene expression is also spatially regulated, beta 3 mRNA being restricted to the mesoderm.

Testis-specific beta 2 tubulins are identical in Drosophila melanogaster and D. hydei but differ from the ubiquitous beta 1 tubulin

In Drosophila as in many organisms beta tubulins are encoded by a gene family. We have determined the complete nucleotide sequences coding for the beta 1 and beta 2 tubulins of Drosophila melanogaster and the beta 2 tubulin of D. hydei, and found these insect beta tubulins to be highly conserved and like beta tubulins of other organisms. This is discussed with reference to the possible functional domains of these proteins. The beta 1 tubulin gene of Drosophila is constitutively expressed, whereas the beta 2 tubulin is expressed specifically in the testes. In D. melanogaster the amino acid sequences of these proteins are 95% homologous, differing at only 25 positions. In the testes the beta 2 tubulin participates in different microtubules as shown by genetic analysis (Kemphues et al. 1982). Interestingly, all of the amino acids characteristic of the testis-specific beta 2 tubulin are also present in the corresponding gene of D. hydei. Of special interest is the high degree of conservation of the carboxy-terminal domain in these functionally equivalent beta tubulins.

Cloning and identification of the gene coding for the 140-kd subunit of Drosophila RNA polymerase II

Genomic clones of Drosophila melanogaster were isolated from a lambda library by cross-hybridization with the yeast gene coding for the 150-kd subunit of RNA polymerase II. Clones containing a region of approximately 2.0 kb with strong homology to the yeast gene were shown to code for a 3.9-kb poly(A)-RNA. Part of the coding region was cloned into an expression vector. A fusion protein was obtained which reacted with an antibody directed against RNA polymerase II of Drosophila. Peptide mapping of the fusion protein yielded a number of spots identical with spots derived from the 140-kd subunit of Drosophila RNA polymerase II. Sequence comparison of a segment of the Drosophila and the corresponding yeast clone yielded a high degree of homology at the protein level also, suggesting that we had isolated the gene coding for the 140-kd subunit of RNA polymerase II from Drosophila. In situ hybridization localized the DmRP140 gene at 88 A/B on chromosome 3 while the DmRP215 gene has previously been localized at 10 C on the X chromosome. Analysis of the transcripts (7.0 and 3.9 kb) in female and male flies shows dosage compensation for the transcription of the DmRP215 gene.

Characterization and developmental expression of beta tubulin genes in Drosophila melanogaster

Genomic clones containing beta tubulin sequences were isolated from a lambda library of Drosophila melanogaster. In situ hybridization localized three genes to 56D and 60B on chromosome 2 as well as to 85D on chromosome 3. The latter was known through genetic analysis to be specifically expressed during spermatogenesis. The genomic clone, pTu85, derived from this region contains one complete beta tubulin coding region as well as the 3' end of an additional so far unidentified beta tubulin gene. Genomic Southern hybridizations reveal a total of five fragments with beta tubulin homology. Clone pTu56 codes for an RNA of 1.8 kb which is expressed in all developmental stages. Clone pTu60 codes for a 2.5-kb RNA expressed during embryogenesis and pupation. In testes RNA we detected a 2.2-kb message homologous to pTu85.

A DNA sequence of Drosophila melanogaster with a differential telomeric distribution

A DNA sequence (8-19T) of 2.3 kilobase pairs (kb) of Drosophila melanogaster was localized by in situ hybridization to the extreme ends of polytene chromosomes and to the chromocenter. The relative abundance of this sequence at the ends of polytene chromosomes X:2L:2R:3L:3R is 1:3.4:1.9:0:2.7. This differential distribution is probably due to different copy numbers at the individual telomeric regions. Restriction enzyme analysis of genomic DNA shows that 8-19T sequences are interspersed with other sequences. The clone 8-19T, which contains most of this interspersed repetitive sequence, is itself not internally repetitive but has a complex sequence composition. Some of these sequences are transcribed into poly(A)+RNA. We suggest that the ends of Drosophila chromosomes are of a complex arrangement with some sequences common to all ends.

Two distinct intervening sequences in different ribosomal DNA repeat units of Sciara coprophila

We have prepared a partial gene library of sheared DNA from the fungus fly, Sciara coprophila, by dA-T tailing and insertion into pBR322. Two ribosomal DNA clones which differ from the usual ribosomal DNA organization in this organism were studied in detail. Clone pBc 1L-1 has an intervening sequence of 1.4 kb, and clone pBc 6D-6 has an intervening sequence of 0.9 kb. These intervening sequences occur in about the same position in 28S rDNA, but do not appear to share sequence homology with one another. Previously we found that 90% of Sciara ribosomal DNA is homogenous and lacks an intervening sequence, and our present data explains the size heterogeneity found in most of the remaining 10%. We have found no evidence of size heterogeneity in the nontranscribed spacer.

Distribution of spacer length classes and the intervening sequence among different nucleolus organizers in Drosophila hydei

Drosophila hydei rRNA genes from different chromosomes and from different stocks have been studied by restriction enzyme analysis. In DNA from wild-type females, about half of the X chromosomal rRNA genes are interrupted by an intervening sequence within the 28S coding region. In contrast to D. melanogaster, the intervening sequences belong to a single size class of 6.0 kb. Although there are two nucleolus organizers on the Y chromosome, genes containing the intervening sequence seem to be restricted to the X chromosome. -- As shown in four cloned rDNA fragments, the nontranscribed spacers differ in length by having varying numbers of a 242 base pair sequence located in tandem in the right section of the spacer. In genomic rDNA, the spacers also differ in length by a regular 0.25 kb interval. Spacers with between 5 and 15 subrepeats occur frequently within the X and Y chromosomal nucleolus organizers in different D. hydei stocks; shorter and longer spacers are also present but are relatively rare. -- Although each genotype is characterized by different frequencies of some spacer classes, the prominent spacer length heterogeneity pattern is similar among the different nucleolus organizers and, therefore, seems to be conserved during evolution.

Characterization of cloned ribosomal DNA from Drosophila hydei

The structure of ribosomal genes from the fly Drosophila hydei has been analyzed. EcoRI fragments, cloned in a plasmid vector, were mapped by restriction enzyme analysis. The lengths of the regions coding for 18S and 28S rRNA were defined by R-loop formation. From these data a physical map of the rRNA genes was constructed. There are two major types of rDNA units in D. hydei, one having a size of 11 kb and the other a size of 17 kb. The 17 kb unit results from an intervening sequence (ivs) of 6.0 kb, interrupting the beta-28S rRNA coding region. Some homology between th D. hydei ivs and D. melanogaster type 1 ivs has been described previously (1). However, the restriction sites within these ivs show considerable divergence. Whereas D. hydei rDNA D. melanogaster rDNA, the nontranscribed spacer has little, if any, sequence homology. Despite difference in sequence, D. hydei and D. melanogaster spacers show structural similarities in that both contain repeated sequence elements of similar size and location.

Proportional polyploidization of 5S RNA genes in the ovary of Drosophila melanogaster mutants containing three 5S RNA gene loci

The 5S RNA gene content of polyploid cells of the ovary of Drosophila melanogaster has been compared in animals with two or three gene clusters. The amount of 5S RNA genes is exactly proportional to the number of gene clusters as determined by DNA-RNA filter hybridization. In contrast, the number of rDNA genes in endomitotic cells remains constant regardless of different numbers of nucleolus organizer regions (Spear, 1974).

Underreplication of satellite dnas in polyploid ovarian tissue of Drosophila virilis

The satellite DNAs of Drosophila virilis have been examined in diploid and polyploid tissues by isopycnic ultracentrifugation and thermal denaturation experiments. Previous work has established that the satellite DNAs are underreplicated in the polytene chromosomes of the salivary glands of D. virilis. The results of the present experiments demonstrate that this underreplication also takes place in the ovaries which contain nurse cells and follicle cells. These tissues are polyploid but do not show polytene chromosomes.