Proteins shifting from the cytoplasm into the nuclei during early embryogenesis of Drosophila melanogaster

RNA tales – how embryos read and discard messages from mom

Following fertilization, embryos develop for a substantial amount of time with a transcriptionally silent genome. Thus, early development is maternally programmed, as it solely relies on RNAs and proteins that are provided by the female gamete. However, these maternal instructions are not sufficient to support later steps of embryogenesis and are therefore gradually replaced by novel products synthesized from the zygotic genome. This switch in the origin of molecular players that drive early development is known as the maternal-to-zygotic transition (MZT). MZT is a universal phenomenon among all metazoans and comprises two interconnected processes: maternal mRNA degradation and the transcriptional awakening of the zygotic genome. The recent adaptation of high-throughput methods for use in embryos has deepened our knowledge of the molecular principles underlying MZT. These mechanisms comprise conserved strategies for RNA regulation that operate in many well-studied cellular contexts but that have adapted differently to early development. In this Review, we will discuss advances in our understanding of post-transcriptional regulatory pathways that drive maternal mRNA clearance during MZT, with an emphasis on recent data in zebrafish embryos on codon-mediated mRNA decay, the contributions of microRNAs (miRNAs) and RNA-binding proteins to this process, and the roles of RNA modifications in the stability control of maternal mRNAs.

Methods for Acquisition of Quantitative Data from Confocal Images of Gene Expression in situ

In this review, we summarize original methods for the extraction of quantitative information from confocal images of gene-expression patterns. These methods include image segmentation, the extraction of quantitative numerical data on gene expression, and the removal of background signal and spatial registration. Finally, it is possible to construct a spatiotemporal atlas of gene expression from individual images recorded at each developmental stage. Initially all methods were developed to extract quantitative numerical information from confocal images of segmentation gene expression in Drosophila melanogaster. The application of these methods to Drosophila images makes it possible to reveal new mechanisms in the formation of segmentation gene expression domains, as well as to construct a quantitative atlas of segmentation gene expression. Most image processing procedures can be easily adapted to process a wide range of biological images.

Phenoloxidase-like activities and the function of virus-like particles in ovaries of the parthenogenetic parasitoid Venturia canescens

The ichneumonid endoparasitoid Venturia canescens successfully develops inside the hemocoel of another insect by using maternal protein secretions, including nucleic acid-free virus-like particles (VLPs), to manipulate host physiology. These VLPs consist of four major proteins, which are produced mainly in the calyx tissue and transferred into the host insect together with the egg. One of the protein-coding genes (vlp1), with similarities to phospholipid-hydroperoxide glutathione peroxidases (PHGPx), exists in allelic forms producing two protein variants with different protein properties. Here, we summarise observations indicating that oocytes and eggs are the source of reactive electrons, which potentially damage the lining and membranes of calyx tissues. We discuss the possible role of VLP1 in counteracting the damaging effects of oxidised phospholipids on membranes surrounding VLPs in the calyx lumen.

Transcription-dependent nucleocytoplasmic distribution of hnRNP A1 protein in early mouse embryos

A unique feature of certain members of the heterogeneous nuclear ribonucleoprotein (hnRNP) family of proteins is that they shuttle continuously between nucleus and cytoplasm and their accumulation in the nucleus is transcription-dependent. An extensively characterised protein of this group is hnRNP A1. To date, most studies addressing the transcription-dependent transport of hnRNP A1 have been performed on cultured cell lines treated with transcription inhibitors. Here we have analysed the nucleocytoplasmic distribution of hnRNP A1 in early mouse embryos, where the haploid pronuclei remain transcriptionally inactive for a period of several hours. Consistent with its small molecular size (36 kDa), the hnRNP A1 protein diffuses passively through the nuclear pores and equilibrates between the nucleus and the cytoplasm of transcriptionally inactive embryos. In contrast, following transcriptional activation the A1 protein becomes accumulated in the nucleus. This accumulation of the A1 protein in the nucleus is blocked by the lectin wheat germ agglutinin (WGA), which binds to nuclear pore proteins and prevents translocation of receptor-cargo complexes through the pores. This indicates that a carrier-mediated transport pathway is required for the concentration of A1 in transcriptionally active nuclei. To further analyse how transcription is coupled to nucleocytoplasmic transport, we transplanted transcriptionally inactive pronuclei into the cytoplasm of transcriptionally active embryos. The results show that the presence of newly synthesised RNAs in the cytoplasm is not sufficient to induce the accumulation of hnRNP A1 in the nucleus. Rather, the appearance of nascent transcripts in the nucleus appears to be the crucial event. Since hnRNP A1 is a shuttling protein, an increase in its steady state nuclear concentration could be the result of either faster nuclear import or slower export to the cytoplasm. We propose that binding of A1 to nascent transcripts retards its export to the cytoplasm and therefore contributes to its concentration in the nucleus.

Developmental regulation and complex organization of the promoter of the non-coding hsr(omega) gene of Drosophila melanogaster

The nucleus-limited large non-coding hsr(omega)-n RNA product of the 93D or the hsr(omega) gene of Drosophila melanogaster binds to a variety of RNA-binding proteins involved in nuclear RNA processing. We examined the developmental and heat shock induced expression of this gene by in situ hybridization of nonradioactively labelled riboprobe to cellular transcripts in intact embryos, larval and adult somatic tissues of wild type and an enhancer-trap line carrying the hsr(omega) 05241 allele due to insertion of a P-LacZ-rosy+ transposon at -130 bp position of the hsr(omega) promoter. We also examined LacZ expression in the enhancer-trap line and in two transgenic lines carrying different lengths of the hsr(omega) promoter upstream of the LacZ reporter. The hsr(omega) gene is expressed widely at all developmental stages; in later embryonic stages, its expression in the developing central nervous system was prominent. In spite of insertion of a big transposon in the promoter, expression of the hsr(omega) 05241 allele in the enhancer-trap line, as revealed by in situ hybridization to hsr(omega) transcripts in cells, was similar to that of the wild type allele in all the embryonic, larval and adult somatic tissues examined. Expression of the LacZ gene in this enhancer-trap line was similar to that of the hsr(omega) RNA in all diploid cell types in embryos and larvae but in the polytene cells, the LacZ gene did not express at all, neither during normal development nor after heat shock. Comparison of the expression patterns of hsr(omega) gene and those of the LacZ reporter gene under its various promoter regions in the enhancer-trap and transgenic lines revealed a complex pattern of regulation, which seems to be essential for its dynamically varying expression in diverse cell types.

P-TEFb kinase recruitment and function at heat shock loci

P-TEFb, a heterodimer of the kinase Cdk9 and cyclin T, was isolated as a factor that stimulates formation of productive transcription elongation complexes in vitro. Here, we show that P-TEFb is located at >200 distinct sites on Drosophila polytene chromosomes. Upon heat shock, P-TEFb, like the regulatory factor HSF, is rapidly recruited to heat shock loci, and this recruitment is blocked in an HSF mutant. Yet, HSF binding to DNA is not sufficient to recruit P-TEFb in vivo, and HSF and P-TEFb immunostainings within a heat shock locus are not coincident. Insight to the function of P-TEFb is offered by experiments showing that the direct recruitment of a Gal4-binding domain P-TEFb hybrid to an hsp70 promoter in Drosophilacells is sufficient to activate transcription in the absence of heat shock. Analyses of point mutants show this P-TEFb stimulation is dependent on Cdk9 kinase activity and on Cdk9's interaction with cyclin T. These results, coupled with the frequent colocalization of P-TEFb and the hypophosphorylated form of RNA polymerase II (Pol II) found at promoter-pause sites, support a model in which P-TEFb acts to stimulate promoter-paused Pol II to enter into productive elongation.

The levels of the bancal product, a Drosophila homologue of vertebrate hnRNP K protein, affect cell proliferation and apoptosis in imaginal disc cells

We have characterized the Drosophila bancal gene, which encodes a Drosophila homologue of the vertebrate hnRNP K protein. The bancal gene is essential for the correct size of adult appendages. Reduction of appendage size in bancal mutant flies appears to be due mainly to a reduction in the number of cell divisions in the imaginal discs. Transgenes expressing Drosophila or human hnRNP K are able to rescue weak bancal phenotype, showing the functional similarity of these proteins in vivo. High levels of either human or Drosophila hnRNP K protein in imaginal discs induces programmed cell death. Expression of the antiapoptotic P35 protein suppresses this phenotype in the eye, suggesting that apoptosis is the major cellular defect caused by overexpression of K protein. Finally, the human K protein acts as a negative regulator of bancal gene expression. We propose that negative autoregulation limits the level of Bancal protein produced in vivo.

The dynamic nuclear redistribution of an hnRNP K-homologous protein during Drosophila embryo development and heat shock. Flexibility of transcription sites in vivo

The Drosophila protein Hrb57A has sequence homology to mammalian heterogenous nuclear ribonucleoprotein (hnRNP) K proteins. Its in vivo distribution has been studied at high resolution by confocal laser scanning microscopy (CLSM) in embryos injected with fluorescently labeled monoclonal antibody. Injection of antibody into living embryos had no apparent deleterious effects on further development. Furthermore, the antibody-protein complex could be observed for more than 7 cell cycles in vivo, revealing a dynamic redistribution from the nucleus to cytoplasm at each mitosis from blastoderm until hatching. The evaluation of two- and three-dimensional CLSM data sets demonstrated important differences in the localization of the protein in the nuclei of living compared to fixed embryos. The Hrb57A protein was recruited to the 93D locus upon heat shock and thus serves as an in vivo probe for the activity of the gene in diploid cells of the embryo. Observations during heat shock revealed considerable mobility within interphase nuclei of this transcription site. Furthermore, the reinitiation as well as the down regulation of transcriptional loci in vivo during the recovery from heat shock could be followed by the rapid redistribution of the hnRNP K during stress recovery. These data are incompatible with a model of the interphase nucleus in which transcription complexes are associated with a rigid nuclear matrix.

The Drosophila TGF alpha homolog Spitz acts in photoreceptor recruitment in the developing retina

In vertebrates and Drosophila, the Epidermal Growth Factor Receptor (EGFR) signal transduction pathway is important in the regulation of cellular development. EGFR is bound by several activating ligands including Transforming Growth Factor-alpha in vertebrates, and its homolog Spitz in Drosophila. It has been shown that Spitz and EGFR act in the development of the Drosophila central nervous system and compound eye. Here we show that spitz function is required in developing ommatidia for the first cell recruitment step, and that Spitz pro-protein is expressed in the retinal neurons as they begin to differentiate. We propose a ‘two-key’ model for additive signal transduction from EGFR and other receptor tyrosine kinases, via the Ras pathway, in the developing eye.

Regulated nuclear import of the Drosophila rel protein dorsal: structure-function analysis

The formation of a gradient of nuclear Dorsal protein in the early Drosophila embryo is the last step in a maternally encoded dorsal-ventral signal transduction pathway. This gradient is formed in response to a ventral signal, which leads to the dissociation of cytoplasmic Dorsal from the I kappa B homolog Cactus. Free Dorsal is then targeted to the nucleus. Dorsal is a Rel-family transcription factor. Signal-dependent nuclear localization characterizes the regulation of Rel proteins. In order to identify regions of Dorsal that are essential for its homodimerization, nuclear targeting, and interaction with Cactus, we have performed an in vivo structure-function analysis. Our results show that all these functions are carried out by regions within the conserved Rel-homology region of Dorsal. The C-terminal divergent half of Dorsal is dispensable for its selective nuclear import. A basic stretch of 6 amino acids at the C terminus of the Rel-homology region is necessary for nuclear localization. This nuclear localization signal is not required for Cactus binding. Removal of the N-terminal 40 amino acids abolished the nuclear import of Dorsal, uncovering a potentially novel function for this highly conserved region.

A novel nuclear inhibitor I-92 regulates DNA binding activity of octamer binding protein p92 during the cell cycle

Nuclear DNA binding protein p92 is a sequence specific octamer binding protein with identical molecular weight as the ubiquitous octamer binding protein Oct-1. It binds to octamer related sequences from the enhancer of human papillomavirus type 18. The activity and intracellular distribution of p92 is regulated by extracellular signals. In serum starved Hela-fibroblast hybrid cells p92 is localized to the cytosol. Serum stimulation leads to nuclear import of p92. In fractions of asynchronously growing cells, which were separated according to cell cycle phases into G1, S, and G2 populations by centrifugal elutriation, p92 DNA binding is confined to S phase. In binding site blots however, p92 DNA binding activity is also present in G1 and G2. In G1 and G2 DNA binding activity of p92 is masked by a novel nuclear inhibitor I-92. The cyclic association of p92 with its inhibitor I-92 provides a new mechanism of regulating S phase dependent activity of a sequence specific DNA binding protein.

Chromosome tangling and breakage at anaphase result from mutations in lodestar, a Drosophila gene encoding a putative nucleoside triphosphate-binding protein

We describe a Drosophila maternal-effect gene, lodestar, mutations in which cause chromatin bridges at anaphase. lodestar maps to cytological position 84D13-14, and we identified the lodestar gene in germ-line transformation experiments by the ability of a genomic fragment to restore fertility to females homozygous for lodestar mutations. lodestar encodes a potential nucleoside triphosphate binding protein, which is a novel member of the D-E-A-H box family of proteins. Antibodies raised against the lodestar gene product detect a protein that undergoes cell cycle-dependent changes in distribution in the embryo. The protein is cytoplasmic at interphase, and rapidly enters the nucleus early in prophase. It is restricted to the region enclosed by the spindle envelope during metaphase and anaphase; but by telophase, the lodestar protein is contained entirely within the reforming nucleus.

The discs-large tumor suppressor gene of Drosophila encodes a guanylate kinase homolog localized at septate junctions

Mutations of the lethal(1)discs large-1 (dlg) tumor suppressor gene of Drosophila cause neoplastic overgrowth of the imaginal discs. Sequencing of a near full-length cDNA predicts a protein containing a domain homologous to yeast guanylate kinase and a region homologous to SH3, a putative regulatory motif in nonreceptor protein tyrosine kinases and other signal transduction proteins. Immunofluorescence analysis using antibodies directed against fusion peptides shows that the dlg gene product is localized in an apical belt of the lateral cell membrane, at the position of the septate junction. The results suggest that a signal transduction process involving guanine nucleotides occurs at the septate junction and is necessary for cell proliferation control in Drosophila epithelia.

Nuclear localization of c-Fos, but not v-Fos proteins, is controlled by extracellular signals

We report here that transport of the protein product of the c-fos proto-oncogene from the cytoplasm, where it is synthesized, into the nucleus, where it operates as part of the AP-1 transcription complex, is not spontaneous but depends on the continuous stimulation of cells by serum factors. A labile protein inhibitor of transport, the effect of which is reversed by cAMP, is responsible for retention of c-Fos protein within the cytoplasm of serum-starved fibroblasts. In contrast, v-Fos proteins transduced by the murine retroviruses FBJ and FBR, which remain nuclear in the absence of serum, evade the translocation control, which therefore appears to contribute to their tumorigenic potential.

Visualization of transport-related configurations of the nuclear pore transporter

The transport of macromolecules between the cytoplasm and nucleus of the cell is mediated by the nuclear pore complex (NPC). In this study, details of the central transporter assembly within NPCs have been examined by cryoelectron microscopy, image processing, and classification analysis. The NPC transporter in isolated amphibian nuclei appears to adopt a minimum of four transport-related configurations including: (a) a putative closed form with a 90-100 A diameter central pore, (b) a docked form with material aligned over the pore, (c) an open form with substrates apparently caught "in transit," and (d) an open form with an enlarged pore. This data confirms previous observations on NPC transporters labeled with nucleoplasmin-gold (Akey, C.W., and D.S. Goldfarb. 1989. J. Cell Biol. 109:971-982) and allows a working model of the central NPC transporter to be proposed. The model is comprised of two supramolecular irislike assemblies which open asynchronously to provide an expanded pore for translocation while maintaining transport fidelity.

A sequence-specific protease cleaves a maternal, cortical protein during early embryogenesis in Sciara coprophila (Diptera)

One of the first events of egg activation in Sciara coprophila (Diptera) is the disappearance of an abundant maternal 38-kDa protein (p38) and the simultaneous emergence of an abundant 35-kDa protein (p35). Western blotting experiments using monoclonal antibodies directed against p38 reveal that p38 and p35 are serologically related and indicate that maternal p38 is transformed into p35 during early development. This transition is possibly accompanied by a conformational change in the part of the protein that is common to both protein species. The processing of p38 to p35 can be mimicked by trypsin treatment in vitro, suggesting that a trypsin-like protease is responsible for this conversion in vivo. Immunostaining indicates that the p38 class of antigens is evenly distributed in the periplasm of early cleavage embryos. After the arrival of nuclei in the periplasm, the antigens become associated with the infolding cellular membranes. A similar membrane association of actin can be observed with anti-actin antibodies. Nevertheless, p38 and actin are clearly distinct from each other. We presume that p38 is a product of a maternal effect gene necessary for early dipteran development.

Different requirements for l(1) giant in two embryonic domains of Drosophila melanogaster

l(1) giant is a zygotic lethal mutation which affects the embryonic development of both the labial/thoracic segments and a subset of posterior abdominal segments. Using antibodies specific for proteins encoded by several Drosophila genes to identify the compartmental origin of the defects, we show that the requirement of giant activity is different in these two embryonic domains. Anteriorly, the posterior compartment of the labial segment is missing at the blastoderm stage. Posteriorly, cells are specifically deleted by cell death within the anterior compartments of abdominal segments 5-7 during germ band elongation. In mature embryos, posterior compartment structures of the peripheral nervous system of A5-7 are fused. In addition to a different pattern of defect in the two parts of the embryo, the kind of action appears different. Anteriorly, giant resembles a gap mutation in that a particular region is missing from the blastoderm fate map, whereas in the abdominal domain, giant affects the development of anterior compartment-specific structures.

Nucleus-specific and temporally restricted localization of proteins in Tetrahymena macronuclei and micronuclei

Labeled nuclear proteins were microinjected into the cytoplasm of Tetrahymena thermophila. Macronuclear H1, calf thymus H1, and the SV40 large T antigen nuclear localization signal linked to BSA accumulated specifically in macronuclei, even if cells were in micronuclear S phase or were nonreplicating. The way in which histone H4 localized to either the macronucleus or the micronucleus suggested that it accumulates in whichever nucleus is replicating. The inability of the micronucleus to accumulate Tetrahymena H1 or heterologous nuclear proteins, even at a period in the cell cycle when it is accumulating H4, suggests that it has a specialized transport system. These studies demonstrate that although the mechanism for localizing proteins to nuclei is highly conserved among eukaryotes, it can differ between two porecontaining nuclei lying in the same cytoplasm.

Isolation of two tissue-specific Drosophila paired box genes, Pox meso and Pox neuro

Two new paired domain genes of Drosophila, Pox meso and Pox neuro, are described. In contrast to the previously isolated paired domain genes, paired and gooseberry, which contain both a paired and a homeo-domain (PHox genes), Pox meso and Pox neuro possess no homeodomain. Evidence suggesting that the new genes encode tissue-specific transcriptional factors and belong to the same regulatory cascade as the other paired domain genes includes (i) tissue-specific expression of Pox meso in the somatic mesoderm and of Pox neuro in the central and peripheral nervous system, (ii) nuclear localization of their proteins, (iii) dependence on prd activity and (iv) presence of the paired domain in genes of known regulatory activity. While no mutant phenotypes of Pox meso and Pox neuro have yet been discovered, a murine gene with a paired domain closely homologous to that of Pox meso has recently been identified with the undulated mutant. Both Pox meso and undulated are expressed in tissues derived from the somatic mesoderm. The five known Drosophila paired domains fall into three classes: (i) the prd,gsb-class, (ii) the Pox meso, undulated-class and (iii) the Pox neuro-class which probably includes the paired domain of the murine gene Pax 2.

The glass gene encodes a zinc-finger protein required by Drosophila photoreceptor cells

Null mutations of glass specifically remove photoreceptor cells, leaving other cell types intact. We have isolated the glass gene and have shown that its transcript encodes a putative protein of 604 amino acids with five zinc-fingers. The glass product may be a transcription factor required for the development of a single neuronal cell type.

Embryonic expression pattern of a family of Drosophila proteins that interact with a central nervous system regulatory element

The protein Elf-1 interacts with a cis-acting element that is required specifically for the neuronal expression of the Drosophila dopa decarboxylase gene Ddc. Using protein purified from Drosophila embryos, we raised Elf-1-specific monoclonal antibodies. The expression of Elf-1 during embryogenesis is restricted to nuclei of tissues derived from ectoderm, predominantly the central nervous system (CNS) and the epidermis. Within the CNS, Elf-1 is present in only a small fraction of nuclei, and the pattern of expressing nuclei changes dramatically during development. Elf-1 and Ddc are coexpressed in primary cultures of neural cells. However, we do not detect Elf-1 in Ddc-expressing neurons in vivo, leading to the suggestion that Elf-1 activity is required in vivo for initiation of Ddc expression but not for its maintenance. The antibodies also were used to isolate cDNA clones encoding Elf-1. Alternate forms of Elf-1 mRNA result in at least three protein isoforms.

The domain model for eukaryotic DNA organization. 2: A molecular basis for constraints on development and evolution

A model for eukaryotic DNA organization has been proposed in which DNA regulatory processes depend on multiple site-specific DNA-nuclear matrix interactions throughout a DNA domain. In this model gene regulation depends on combinations of a few control factors in a cell to activate cell type-specific genes. This model suggests simple molecular mechanisms for organismal development which can account for sequential activation of appropriate groups of genes throughout development and for specific constraints on developmental pathways. Additionally, these suggested developmental pathways are consistent with mechanisms of evolution in which gradualism and punctuated equilibrium are not exclusive of one another and are interrelated mechanisms of evolution that are both induced by specific chromosomal mutations.

Experimental phenocopy of a minute maternal-effect mutation alters blastoderm determination in embryos of Drosophila melanogaster

Maternal haploinsufficiency for a third chromosome Minute, M(3)i55, lowers rates of protein synthesis by approximately 30% during the syncytial nuclear cycles of early embryogenesis. The maternal effect of Mi55 also produces segmentation defects (denticle belt fusions) in the posterior abdomen of larvae. Furthermore, embryos from Minute mothers show abnormal expression patterns of the segmentation gene fushi tarazu (ftz) at the cellular blastoderm stage of embryogenesis. We developed a computer-aided analysis to describe the deviations in ftz expression which demonstrates that abnormally narrow ftz stripes occur in segment primordia that become fused in the larva. Unexpectedly, an abnormally wide ftz stripe occurs in segment primordia which do not develop abnormally. In addition, Mi55 produces a general narrowing of all ftz- interstripes. We phenocopied the Minute mutation by injecting wild-type embryos with cycloheximide concentrations which decreased protein synthesis rates to levels comparable with those of Minute embryos. Thus, a general decrease in protein synthesis during early embryogenesis leads to abnormal determination of posterior abdominal segment primordia.

Major nucleolar proteins shuttle between nucleus and cytoplasm

Nucleolin is a 92 kd nucleolar protein implicated in regulating polymerase I transcription and binding of preribosomal RNA. Another abundant nucleolar protein of 38 kd (B23/No38) is thought to be involved in intranuclear packaging of preribosomal particles. Although both proteins have previously been detected only in nuclei, we conclude that they shuttle constantly between nucleus and cytoplasm. This conclusion is based on monitoring the equilibration of these proteins between nuclei present in interspecies heterokaryons, and on observing the antigen-mediated nuclear accumulation of cytoplasmically injected antibodies. Our unexpected results suggest a role for these major nucleolar proteins in the nucleocytoplasmic transport of ribosomal components. Moreover, they suggest that transient exposure of shuttling proteins to the cytoplasm may provide a mechanism for cytoplasmic regulation of nuclear activities.

Two proteins from Drosophila nuclei are bound to chromatin and are detected in a series of puffs on polytene chromosomes

Immunizing chromatin protein fractions from Drosophila melanogaster embryos, monoclonal antibodies have been generated against two nuclear proteins of different molecular weight. These proteins are present in a chromatin fraction of Drosophila Kc-cell nuclei and both proteins could be shown to cosediment with nucleosomes following separation on sucrose gradients. Early in development both proteins are located in the embryo cytoplasm. Later, at times when transcription starts at blastoderm, they become redistributed into the nuclei. On salivary gland chromosomes both proteins are detected in a series of developmentally active puffs. The number of sites where these antigens can be detected, as well as the qualitative properties of the antigens at these sites differ between both proteins.

The maternal effect of lethal(1)discs-large-1: a recessive oncogene of Drosophila melanogaster

The maternal effect phenotypes of recessive mutations at the Drosophila zygotic lethal gene l(1)discs-large-1 (l(1)dlg-1) are described. L(1)dlg-1 is located in 10B7-8 on the salivary gland chromosome map. A complex complementation pattern is observed among the nine characterized alleles. Larvae missing zygotic l(1)dlg-1+ gene activity die due to aberrant growth of imaginal cells at the larval-pupal transition. Embryos lacking both maternal and zygotic activity of l(1)dlg-1+, i.e., embryos derived from homozygous l(1)dlg-1 germ line clones for null alleles, show neurogenesis and morphogenesis defects that result in very abnormal embryos. Although differentiated, most tissues are morphologically misshapen. This maternal effect is rescuable to some extent. One allele, l(1)dlg-1HF321, is a temperature-sensitive mutation for the zygotic lethality. Embryos derived from homozygous l(1)dlg-1HF321 females at 18 degrees C exhibit defects associated with dorsal closure and head involution. More extreme phenotypes are observed when females are shifted to higher temperatures and include defective dorsal closure, collapse of the somatic musculature, and an oversized central nervous system. The possible involvement of the recessive oncogene l(1)dlg-1 in cell adhesion is discussed.

Changes in the synthesis and intracellular localization of nuclear proteins during embryogenesis in the sea urchin Strongylocentrotus purpuratus

A rapid, gentle technique is described for the isolation of nuclei from sea urchin embryos. Using this technique, we have analyzed the synthesis and accumulation of nonhistone nuclear proteins during sea urchin development by two-dimensional gel electrophoresis. Most nuclear proteins fall into one of three patterns of synthesis, which are distinguished by maximal rates of accumulation at early (prior to hatching blastula), middle (hatching blastula/gastrula), or late (prism/pluteus) stages of development. Over 60% of observed nuclear proteins undergo apparent qualitative changes in synthesis and accumulation between the 64-cell and pluteus stages. Most of these changes represent appearances of new proteins. A large number of qualitative changes occur very early in development; the period of greatest change is between the 64-cell and 200-cell stages. Over half of the proteins which first appear in the nucleus subsequent to the 64-cell stage are synthesized at stages prior to the time of their initial appearance in nuclei, but are excluded from nuclei for some time.

Characterization and localization of the even-skipped protein of Drosophila

On the basis of homeo box cross-homology we have isolated the pair-rule gene even-skipped (eve) of Drosophila. The eve transcription unit appears to be less than 1.5 kb in length, and encodes a single mRNA of approximately 1.4 kb. The nucleotide sequence of genomic and cDNA clones indicates that the eve protein is composed of 376 amino acid residues, and that its homeo domain shares only approximately 50% amino acid identity with the homeo domains of previously characterized genes. Using antibodies raised against a beta-galactosidase fusion protein we show that the eve protein is distributed in a series of seven transverse stripes at the cellular blastoderm stage, and is localized primarily within the nuclear regions of those embryonic cells that express the gene. After gastrulation, seven weakly stained stripes of eve expression appear, resulting in a transient pattern that consists of a total of 14 evenly spaced stripes. Both the original and new stripes gradually disappear during germ band elongation. A second expression pattern emerges during neurogenesis, whereby eve protein is detected in discrete subsets of neurons in each of the ventral ganglia.

Expression of the caudal gene in the germ line of Drosophila: formation of an RNA and protein gradient during early embryogenesis

The caudal (cad) gene of Drosophila encodes a maternal and a zygotic transcript which have different promoters. Both mRNAs contain the same open reading frame, including a homeo box. In situ hybridization and antibody staining show that the maternal RNA and protein are localized in an anteroposterior gradient during the syncytial blastoderm stage. The protein is found mainly in the nuclei and is also present in the pole cells. Zygotic RNA and protein are localized in the primordia of the terminal abdominal segment, the hindgut, and in the posterior midgut rudiment. In third instar larvae, cad is expressed in the gut, the gonads, and parts of the genital discs. It is the first homeo box-containing gene expressed in the germ line of Drosophila.

Multiple functions of segment polarity genes in Drosophila

l(1)dishevelled (l(1)dsh) is a late zygotic lethal mutation that exhibits a rescuable maternal effect lethal phenotype. l(1)dsh/Y embryos, derived from females possessing a homozygous l(1)dsh germline clone, exhibit a segment polarity embryonic phenotype. Analysis of the development of these embryos indicates: (1) that segmental boundaries do not form although the correct number of tracheal pits is formed; (2) that pockets of cell death occur between the tracheal pits; and (3) that engrailed expression becomes abnormal during germ band shortening. We propose that, in the absence of both maternal and zygotic expression of l(1)dsh+, cells from each posterior compartment die. Subsequently, cells from the anterior compartment must rearrange their positional values to generate the segment polarity phenotype. We have compared the phenotype of five other segment polarity loci: four embryonic lethals [l(1)armadillo, l(2)gooseberry, l(2)wingless, and l(3)hedgehog]; and the late zygotic lethal, l(1)fused. Only l(2)wingless embryos exhibit early segmentation defects similar to those found in l(1)dsh/Y embryos derived from homozygous germline clones. In contrast, segmentation is essentially normal in l(1)armadillo, l(2)gooseberry, l(3)hedgehog, and l(1)fused embryos. The respective maternal and zygotic contribution and the roles of the segment polarity loci for the patterning of the embryo and the adult are discussed.

Monoclonal antibodies against Drosophila ovaries: their reaction with ovarian and embryonic antigens

A library of monoclonal antibodies (MAbs) against Drosophila ovarian antigens was established. Each of the MAbs was characterized by its immunohistochemical binding pattern to sections from egg chambers at various stages of oogenesis. Sixteen of the 18 MAbs were found to bind to antigens in mature oocytes. Among the 16 antigens, two were also located in cytoplasm of cell types in the egg chamber other than the oocyte, at all stages of oogenesis. Four made their appearance in nurse cell cytoplasm at mid-vitellogenic stages and shifted to oocyte cytoplasm at a later stage, and ten appeared at the vitellogenic stage and confined their distribution to oocyte cytoplasm. All these antigens were distributed evenly in cytoplasm of mature oocytes. However, some of these antigens were noticed to change their distribution during early embryogenesis as to be localized in a specific region of embryos.

Region-specific defects in l(1)giant embryos of Drosophila melanogaster

Lack of zygotic expression of the l(1)giant locus (l(1)gt;3A1), produces embryos with defects in abdominal A5, 6, and 7 and within the head. Scanning electron microscopy at the time of segment formation reveals two regions of defects in the segmentation pattern: anteriorly the labial lobe and thoracic segments T1 and T2 are fused; posteriorly, abdominal segments A5-7 are disrupted. The mature embryo shows incomplete head involution and defects within A5-7; fusion of T1 and T2 is no longer observed. Localized cell death within neural and mesodermal tissues is observed at 7 hr of development; later ventral ganglia, A5-7, are missing. Double-mutant analyses of l(1)gt with maternal effect lethal mutations and mutations that generate homeotic, segment number, gap, or segment polarity phenotypes indicate that normal activity of l(1)gt is required for differentiation of two embryonic domains: one corresponding to labial, T1 and T2 segments, and the second corresponding to abdominal segments 5, 6, and 7.

A conserved family of nuclear proteins containing structural elements of the finger protein encoded by Krüppel, a Drosophila segmentation gene

Krüppel (Kr), a segmentation gene of Drosophila, encodes a protein sharing structural features of the DNA-binding "finger motif" of TFIIIA, a Xenopus transcription factor. Low-stringency hybridization of the Kr finger coding sequence revealed multiple copies of homologous DNA sequences in the genomes of Drosophila and other eukaryotes. Molecular analysis of one Kr-homologous DNA clone identified a developmentally regulated gene. Its product, a finger protein, relates to Kr by the invariant positioning of crucial amino acid residues within the finger repeats and by a stretch of seven amino acids connecting the finger loops, the "H/C link." This H/C link is conserved in several nuclear and chromosome-associated proteins of Drosophila and other eukaryotic organisms including mammals. Our results demonstrate a new subfamily of evolutionarily conserved nuclear and possibly DNA-binding proteins that again relate to a Drosophila segmentation gene as in the case of the homeo domain.

l(1)hopscotch, A larval-pupal zygotic lethal with a specific maternal effect on segmentation in Drosophila

The maternal and zygotic effect phenotypes of mutations at the l(1)hopscotch (l(1)hop) locus are described. l(1)hop is located in 10B6-8 on the salivary gland chromosome map and 17 alleles have been characterized. A complex complementation pattern is observed among the 17 alleles. The lethal phase of null alleles of l(1)hop occurs at the larval-pupal interface associated with a small disc phenotype. Embryos produced from homozygous l(1)hop germline clones show segment specific defects. The extent of these defects depends upon both the strength of the allele and the paternal contribution. In the most extreme case embryos exhibit defects associated with five segments T2, T3, A4, A5, and A8. In the less extreme phenotype defects are only associated with A5. Thus, activity of l(1)hop+ is required both for the maintenance and continued cell division of diploid imaginal precursors and for the establishment of the full array of segments.

The dissociation of nuclear and centrosomal division in gnu, a mutation causing giant nuclei in Drosophila

We describe a recessive, maternal-effect lethal mutation of Drosophila, gnu. gnu uncouples nuclear division from many cytoplasmic events of mitosis in the Drosophila embryo. Embryos from homozygous females are defective in nuclear division, but not in DNA replication, and therefore develop a small number of giant nuclei. Centrosomes divide independently of nuclear division and migrate to the surface of the syncytial blastoderm. There they nucleate microtubules into asters, which appear normal at first but become very large. Only later, when the giant nuclei begin to break down, are spindles sometimes formed. The cortical actin of these embryos develops into a characteristic network.

Developmental analysis of the torso-like phenotype in Drosophila produced by a maternal-effect locus

The segmental plan of the Drosophila embryo is already established at the blastoderm stage through the action of maternal effect genes which determine the polarity of the embryo and zygotically active genes involved in segmentation. We have analyzed the first example of a group of maternally acting genes which are necessary for establishing the developmental potential of the posterior 25% of the blastoderm. Females, homozygous for the X-linked maternal-effect mutation female sterile(1)Nasrat211 [fs(1)N211], produce embryos, characterized as torso-like, which lack all posterior endodermal derivatives as well as structures characteristic of abdominal segments 8 to 10. In addition, anterior endodermal derivatives are deficient and the absence of pharyngeal musculature causes a collapse of the cephalopharyngeal apparatus. The columnar blastoderm cell layer is defective at the posterior tip below the pole cells in these embryos. This defect, however, is presumably secondary to some abnormal feature of pole cell formation since in double mutants of fs(1)Nasrat211; tudor3 the blastoderm is normal but the embryos still show the torso-like phenotype. In situ hybridization with RNA probes derived from the fushi tarazu gene establishes that the cellular determination of the posterior blastoderm of embryos produced by fs(1)N211 is changed. This represents the first direct demonstration that a maternal-effect mutation alters the spatial distribution of a zygotic gene product involved in the segmental patterning of the embryo.

Organization of the cytoskeleton in early Drosophila embryos

The cytoskeleton of early, non-cellularized Drosophila embryos has been examined by indirect immunofluorescence techniques, using whole mounts to visualize the cortical cytoplasm and sections to visualize the interior. Before the completion of outward nuclear migration at nuclear cycle 10, both actin filaments and microtubules are concentrated in a uniform surface layer a few micrometers deep, while a network of microtubules surrounds each of the nuclei in the embryo interior. These two filament-rich regions in the early embryo correspond to special regions of cytoplasm that tend to exclude cytoplasmic particles in light micrographs of histological sections. After the nuclei in the interior migrate to the cell surface and form the syncytial blastoderm, each nucleus is seen to be surrounded by its own domain of filament-rich cytoplasm, into which the cytoskeletal proteins of the original surface layer have presumably been incorporated. At interphase, the microtubules seem to be organized from the centrosome directly above each nucleus, extending to a depth of at least 40 microns throughout the cortical region of cytoplasm (the periplasm). During this stage of the cell cycle, there is also an actin "cap" underlying the plasma membrane immediately above each nucleus. As each nucleus enters mitosis, the centrosome splits and the microtubules are rearranged to form a mitotic spindle. The actin underlying the plasma membrane spreads out, and closely spaced adjacent spindles become separated by transient membrane furrows that are associated with a continuous actin filament-rich layer. Thus, each nucleus in the syncytial blastoderm is surrounded by its own individualized region of the cytoplasm, despite the fact that it shares a single cytoplasmic compartment with thousands of other nuclei.

Microtubule arrays present during the syncytial and cellular blastoderm stages of the early Drosophila embryo

The organization of microtubules within the surface caps of Drosophila embryos is described for the mitotic cycles of the syncytial blastoderm stage (particularly cycle 10), and for the subsequent cellularization process. Tubulin was labelled with the well characterized monoclonal antibody YL 1/2 (Kilmartin et al., J cell biol 93 (1982) 576). Each surface cap was found to contain an array of microtubules running around the nucleus. The microtubules originated at prominent centrosomes located close to the apical surface of each cap nucleus. During mitosis the spindle microtubules stained strongly for tubulin. A novel finding was that the spindle microtubules of the interzone region appeared to reduce their connections with the centrosomes at the end of anaphase. The spindle remnant remained in position during telophase but then became smaller in size, disappearing by interphase. At this phase of the cell cycle duplication of the aster centrosomes occurred. The cellular blastoderm stage was marked by a change in the main axis of microtubule orientation. The centrosomes of each cap separated somewhat and formed initiation centres for the development of a well developed basket of microtubules around each nucleus, but now perpendicular to the surface. The microtubule baskets were seen to extend in parallel with nuclear elongation, but not in concert with growth of the cell membranes, which extended some way beneath the bases of the nuclei.

Cell surface antigen of human neuroblastomas is related to nuclear antigen of normal cells

The localization of MC25, an antigen first detected on the surface of human neuroblastoma cells, was determined in cultured cells and tissues. Neuroblastoma cell lines (15/17) express the antigen on the surface and in the cytoplasm (scMC25+), whereas 156/160 cell lines derived from other normal and malignant human cell types are scMC25-. However, MC25 is found in the nucleus of scMC25- cells (nMC25+), presenting a discrete granular pattern. In scMC25+/nMC25- neuroblastoma lines, apparent antigen shifting from the cell surface/cytoplasm to the nucleus accompanies variant formation, which represents a transition in the neuronal differentiation program of these cells. Results of immunohistochemical studies with human tissues parallel the findings with cultured cells. Almost all cell types are scMC25-/nMC25+; basal cells of the epidermis are the only cells constitutively expressing cMC25; and a population of neurons are the only scMC25-/nMC25- cells. Alternative localization of MC25 to different cellular compartments and antigen shifting are reminiscent of the behavior of certain developmentally regulated antigens in Drosophila and Xenopus.

Early specification for body position in mes-endodermal regions of an amphibian embryo

Specification for development of the body pattern in the amphibian embryo has usually been thought of as a prolonged process, initiated from an ooplasmic localisation of some kind in what will become the dorsal-anterior midline. The evidence has been interpreted as suggesting that this initial localisation is centred in what will become anterior endoderm, but gives rise by an inductive process in early blastula stages to an overlying organising centre which eventually controls the genesis of mesodermal pattern. Neurectodermal development (especially, the position and pattern of the central nervous system) is seen as controlled considerably later, by inductive signals from submigrating mesoderm at gastrulation. Current work tends to confirm that this sequence of inductive influences can occur at least in experimental situations. It also suggests, however, that in the normal development of the rather small egg of Xenopus, genesis of positional cues that specify the body pattern contributions within the more vegetal material (mes-endoderm) is a rather rapid, widespread and direct consequence of events occurring in the interval between fertilisation and cleavage. Possible molecular bases of early nuclear responses to position within egg material, and the more problematic nature of the positional system itself, are discussed.

Monoclonal antibodies to lampbrush chromosome antigens of Pleurodeles waltlii

Germinal vesicles of oocytes from Pleurodeles waltlii were used for immunization of BALB/c mice to obtain hybridomas secreting monoclonal antibodies. The hybridomas were screened for reactivity of their antibodies against lampbrush chromosomes of oocytes, as revealed by indirect immunostaining. Antibodies labelling the lampbrush chromosomes were also tested on histological sections of oocytes, embryos, and larvae of Pleurodeles. Characterization of the antigens was accomplished through immunoblotting of two-dimensional electrophoretic gels of germinal vesicle proteins. The ten monoclonal antibodies giving a positive reaction were classed into five groups. Group 1, exemplified by antibody A33, recognizes all the lampbrush chromosome transcribing sites (loops). Moreover, it differentially labels the cell nuclei during embryonic and larval development. Group 2, antibody B71, also stains all the loops of the lampbrush chromosomes, but does not react with cell nuclei of embryos and larvae. Group 3, antibody A1, labels specific loops, some of which are heterozygous in the strain of P. waltlii used. These heterozygosities have allowed us to localize and to characterize a chromosomal segment on bivalent IV which is heteromorphic in the two partners of the bivalent. We suggest that this heteromorphism represents a morphological distinction between Z and W heterochromosomes. Moreover, this antibody reacts with only one transcription unit along a loop that contains several units. Group 4, antibody B24, stains the only two structures in the lampbrush chromosomes of P. waltlii that do not have a loop organization, the mass "M" and the spheres. Group 5, antibody A35, reacts with the chromomeres. The antigens corresponding to antibodies A33 and B24 have been identified as proteins, which have apparent molecular weights of 80 and 104 kilodaltons, respectively. They correspond to proteins abundant in the germinal vesicles. All the antibodies described here cross-react with the lampbrush chromosomes of five other species of Urodeles.