Ligand-independent requirements of steroid receptors EcR and USP for cell survival.

The active form of the Drosophila steroid hormone ecdysone, 20-hydroxyecdysone (20E), binds the heterodimer EcR/USP nuclear receptor to regulate target genes that elicit proliferation, cell death and differentiation during insect development. Although the 20E effects are relatively well known, the physiological relevance of its receptors remains poorly understood. We show here that the prothoracic gland (PG), the major steroid-producing organ of insect larvae, requires EcR and USP to survive in a critical period previous to metamorphosis, and that this requirement is 20E-independent. The cell death induced by the downregulation of these receptors involves the activation of the JNK-encoding basket gene and it can be rescued by upregulating EcR isoforms which are unable to respond to 20E. Also, while PG cell death prevents ecdysone production, blocking hormone synthesis or secretion in normal PG does not lead to cell death, demonstrating further the ecdysone-independent nature of the receptor-deprivation cell death. In contrast to PG cells, wing disc or salivary glands cells do not require these receptors for survival, revealing their cell and developmental time specificity. Exploring the potential use of this feature of steroid receptors in cancer, we assayed tumor overgrowth induced by altered yorkie signaling. This overgrowth is suppressed by EcR downregulation in PG, but not in wing disc, cells. The mechanism of all these cell death features is based on the transcriptional regulation of reaper. These novel and context-dependent functional properties for EcR and USP receptors may help to understand the heterogeneous responses to steroid-based therapies in human pathologies.

Genes of the ecdysone biosynthesis pathway are regulated by the dATAC histone acetyltransferase complex in Drosophila.

Uncovering mechanisms that regulate ecdysone production is an important step toward understanding the regulation of insect metamorphosis and processes in steroid-related pathologies. We report here the transcriptome analysis of Drosophila melanogaster dAda2a and dAda3 mutants, in which subunits of the ATAC acetyltransferase complex are affected. In agreement with the fact that these mutations lead to lethality at the start of metamorphosis, both the ecdysone levels and the ecdysone receptor binding to polytene chromosomes are reduced in these flies. The cytochrome genes (spookier, phantom, disembodied, and shadow) involved in steroid conversion in the ring gland are downregulated, while the gene shade, which is involved in converting ecdysone into its active form in the periphery, is upregulated in these dATAC subunit mutants. Moreover, driven expression of dAda3 at the site of ecdysone synthesis partially rescues dAda3 mutants. Mutants of dAda2b, a subunit of the dSAGA histone acetyltransferase complex, do not share phenotype characteristics and RNA profile alterations with dAda2a mutants, indicating that the ecdysone biosynthesis genes are regulated by dATAC, but not by dSAGA. Thus, we provide one of the first examples of the coordinated regulation of a functionally linked set of genes by the metazoan-specific ATAC complex.

[Why so many synapses?]. / ¿Para que tantas sinapsis?

INTRODUCTION AND DEVELOPMENT: Synapses are the most abundant structures in the body of all animals. This number appears to be exceedingly large considering their apparent function: excite or inhibit the postsynaptic cell. In the few cases for which data are available, the number of synapses that two identified cells establish is reasonably constant between individuals although variable during development. Observations in a variety of sensory systems and animal species indicate that synapse number is important for normal physiology. Recent data from the olfactory system in Drosophila show that, if this number increases threefold, the sensitivity of perception increases up to three orders of magnitude. Similarly, the loss of perception sensitivity to a given odorant correlates with a loss of sensory synapses in selected neurons. These changes require proper regulation of the cAMP pathway. CONCLUSIONS: It seems reasonable to assume that the postsynaptic effects in the case of N versus N synapses should be different. Since the action potential parameters in the postsynaptic cell are the same in both cases, we can propose, as a working hypothesis, that the functional differences rely in the differential calcium dynamics throughout the postsynaptic dendritic branches.

¿Para qué tantas sinapsis? / Why so many synapses?

Introducción y desarrollo. La sinapsis es la estructura más abundante en el cuerpo de cualquier animal. Este número parece excesivamente grande al considerar su finalidad aparente: excitar o inhibir la célula postsináptica. Por otro lado, en los pocos casos de los que se dispone de datos, el número de sinapsis que dos células identificadas establecen entre sí suele ser razonablemente constante entre individuos, aunque varía durante el desarrollo. Observaciones procedentes de varios sistemas sensoriales y especies animales indican que el número de sinapsis es importante. En el sistema olfativo de Drosophila, si ese número aumenta tres veces, la sensibilidad de la percepción aumenta hasta tres órdenes de magnitud. Del mismo modo, la pérdida de sensibilidad de percepción olfativa a un determinado olor correlaciona con la pérdida de sinapsis sensoriales en determinadas neuronas. Esos cambios tienen lugar mediante la participación del AMPc y sus reguladores. Conclusiones. Parece lógico suponer que los efectos postsinápticos en el caso de N sinapsis con respecto al caso N' deben ser diferentes. Puesto que los parámetros del potencial de acción postsináptico en ambos casos son los mismos, cabe proponer, como hipótesis de trabajo, que la diferencia de significado biológico radica en la diferente dinámica del calcio a lo largo de la geometría de la célula postsináptica (AU)

Odor exposure causes central adaptation and morphological changes in selected olfactory glomeruli in Drosophila.

In an attempt to correlate behavioral and neuronal changes, we examined the structural and functional effects of odor exposure in Drosophila. Young adult flies were exposed to a high concentration of the selected odor, usually benzaldehyde or isoamyl acetate, for 4 d and subsequently tested for their olfactory response to a variety of odorants and concentrations. The behavioral response showed specific adaptation to the exposed odor. By contrast, olfactory transduction, as measured in electroantennograms, remained normal. In vivo volume measurements were performed on olfactory glomeruli, the anatomical and functional units involved in odor processing. Pre-exposed flies exhibited volume reduction of certain glomeruli, in an odor-selective manner. Of a sample of eight glomeruli measured, dorsal medial (DM) 2 and ventral (V) were affected by benzaldehyde exposure, whereas DM6 was affected by isoamyl acetate. Estimation of the number of synapses indicates that volume reduction involves synapse loss that can reach 30% in the V glomerulus of flies adapted to benzaldehyde. Additional features of odorant-induced adaptation, including concentration dependence and perdurance, also show correlation, because both effects are elicited by high odor concentrations and are long-lasting (>1 week). Finally, the dunce mutant fails to develop behavioral adaptation as well as morphological changes in the olfactory glomeruli after exposure. These neural changes thus appear to require the cAMP signaling pathway.

A tropomyosin-2 mutation suppresses a troponin I myopathy in Drosophila.

A suppressor mutation, D53, of the held-up(2) allele of the Drosophila melanogaster Troponin I (wupA) gene is described. D53, a missense mutation, S185F, of the tropomyosin-2, Tm2, gene fully suppresses all the phenotypic effects of held-up(2), including the destructive hypercontraction of the indirect flight muscles (IFMs), a lack of jumping, the progressive myopathy of the walking muscles, and reductions in larval crawling and feeding behavior. The suppressor restores normal function of the IFMs, but flight ability decreases with age and correlates with an unusual, progressive structural collapse of the myofibrillar lattice starting at the center. The S185F substitution in Tm2 is close to a troponin T binding site on tropomyosin. Models to explain suppression by D53, derived from current knowledge of the vertebrate troponin-tropomyosin complex structure and functions, are discussed. The effects of S185F are compared with those of two mutations in residues 175 and 180 of human alpha-tropomyosin 1 which cause familial hypertrophic cardiomyopathy (HCM).

Prodos is a conserved transcriptional regulator that interacts with dTAF(II)16 in Drosophila melanogaster.

The transcription factor TFIID is a multiprotein complex that includes the TATA box binding protein (TBP) and a number of associated factors, TAF(II). Prodos (PDS) is a conserved protein that exhibits a histone fold domain (HFD). In yeast two-hybrid tests using PDS as bait, we cloned the Drosophila TAF(II), dTAF(II)16, as a specific PDS target. dTAF(II)16 is closely related to human TAF(II)30 and to another recently discovered Drosophila TAF, dTAF(II)24. PDS and dTAF(II)24 do not interact, however, thus establishing a functional difference between these dTAFs. The PDS-dTAF(II)16 interaction is mediated by the HFD motif in PDS and the N terminus in dTAF(II)16, as indicated by yeast two-hybrid assays with protein fragments. Luciferase-reported transcription tests in transfected cells show that PDS or an HFD-containing fragment activates transcription only with the help of dTAF(II)16 and TBP. Consistent with this, the eye phenotype of flies expressing a sev-Ras1 construct is modulated by PDS and dTAF(II)16 in a gene dosage-dependent manner. Finally, we show that PDS function is required for cell viability in somatic mosaics. These findings indicate that PDS is a novel transcriptional coactivator that associates with a member of the general transcription factor TFIID.

Cellular and molecular features of axon collaterals and dendrites.

Neural geometry is the major factor that determines connectivity and, possibly, functional output from a nervous system. Recently some of the proteins and pathways involved in specific modes of branch formation or maintenance, or both, have been described. To a variable extent, dendrites and axon collaterals can be viewed as dynamic structures subject to fine modulation that can result either in further growth or retraction. Each form of branching results from specific molecular mechanisms. Cell-internal, substrate-derived factors and functional activity, however, can often differ in their effect according to cell type and physiological context at the site of branch formation. Neural branching is not a linear process but an integrative one that takes place in a microenvironment where we have only a limited experimental access. To attain a coherent mechanism for this phenomenon, quantitative in situ data on the proteins involved and their interactions will be required.

Ariadne-1: a vital Drosophila gene is required in development and defines a new conserved family of ring-finger proteins.

We report the identification and functional characterization of ariadne-1 (ari-1), a novel and vital Drosophila gene required for the correct differentiation of most cell types in the adult organism. Also, we identify a sequence-related gene, ari-2, and the corresponding mouse and human homologues of both genes. All these sequences define a new protein family by the Acid-rich, RING finger, B-box, RING finger, coiled-coil (ARBRCC) motif string. In Drosophila, ari-1 is expressed throughout development in all tissues. The mutant phenotypes are most noticeable in cells that undergo a large and rapid membrane deposition, such as rewiring neurons during metamorphosis, large tubular muscles during adult myogenesis, and photoreceptors. Occasional survivors of null alleles exhibit reduced life span, motor impairments, and short and thin bristles. Single substitutions at key cysteines in each RING finger cause lethality with no survivors and a drastic reduction of rough endoplasmic reticulum that can be observed in the photoreceptors of mosaic eyes. In yeast two-hybrid assays, the protein ARI-1 interacts with a novel ubiquitin-conjugating enzyme, UbcD10, whose sequence is also reported here. The N-terminal RING-finger motif is necessary and sufficient to mediate this interaction. Mouse and fly homologues of both ARI proteins and the Ubc can substitute for each other in the yeast two-hybrid assay, indicating that ARI represents a conserved novel mechanism in development. In addition to ARI homologues, the RBR signature is also found in the Parkinson-disease-related protein Parkin adjacent to an ubiquitin-like domain, suggesting that the study of this mechanism could be relevant for human pathology.

[Survey of infant mortality in Mirebalais, Haiti]. / Enquête sur la mortalité infantile à Mirebalais, Haïti.

Infant mortality remains high in Haiti, at 74 deaths per 1,000 live births. In this study, we aimed to assess infant mortality in Mirebalais and to identify the associated risk factors. We carried out a census of pregnant women in Mirebalais, at the beginning of the study, over a three-week period. Twelve researchers visited the homes of the newborns to enroll the families in the study and to collect demographic data. Further visits were scheduled for two, four, six, nine and twelve months after birth. If the child died during this time, the investigator asked the mother about all the steps taken to prevent the death of the child, and an autopsy was carried out. The survey began on July 12 1994 and ended on December 31 1995. During that time, about 2,151 pregnant women were enrolled. Seven of these women died and 16 had abortions. In total, 2,069 children were born to the enrolled women. We enrolled 515 other children after birth or following referral by health workers or midwives. We therefore followed 2,584 children. We found that 10% of the mothers were aged between 15 and 19 years, 66.3% had had one to three pregnancies and 73% were entirely uneducated. The early neonatal mortality rate was 4.64 per 1,000 live births, late neonatal mortality was 6.96 per thousand and post-neonatal mortality was 45.6 per thousand live births. Diarrhea was responsible for 60% of the deaths and acute respiratory infections for 11%, these two causes accounting for 71% of the deaths of children aged 1 to 12 months. Thus, although infant mortality has decreased it remains high in Mirebalais, largely due to diarrhea and acute respiratory infections in the post-neonatal period.

A genetic approach to detect muscle protein interactions in vivo.

An organism is required to identify biologically relevant protein interactions. We propose Drosophila and its indirect flight muscles as a suitable experimental system for genetic screenings for muscle protein interactions. The first attempt focused on troponin I (TnI) in view of the key role in thin filament regulation that this protein performs. Suppressors of a defined Tn I allele have been isolated as mutations in the heavy chain of myosin (MhC). This unsuspected functional interaction between TnI and MhC serves to illustrate one of the benefits of the approach. Four of the suppressors identified to date reside in the MhC head, around the actin-binding site and near the lips of the pocket where ATP is hydrolyzed. Two other suppressors correspond to a second site mutation in TnI and a mutation in the conserved region of Tropomyosin II (TmII), respectively. All the identified suppressors are mutations in constituents of the sarcomere, and most of them are structurally similar to human mutations causing familial hypertrophic cardiomyopathy (FHC). At least seven sarcomere proteins can lead to FHC and, consequently, the disease is heterogeneous and difficult to diagnose. In addition, putative natural suppressors may help obscure the origin of FHC. The genetic procedure, used here for muscle proteins, could help diagnose FHC and other myopathies, and extend to proteins of clinical interest in other tissues, including the nervous and circulatory systems.

Presynaptic calcium-channel currents in normal and csp mutant Drosophila peptidergic terminals.

The study of regulated vesicle exocytosis, which underlies neurotransmitter and neuropeptide release, has benefited from a convergence of several independent approaches. These include the use of genetically tractable organisms and model preparations that allow a direct characterization of presynaptic ionic currents. Aiming for a comprehensive analysis of release, we had already developed a Drosophila preparation in which electrophysiological recordings from peptidergic terminals are feasible. Here, we report on the characterization of the Ca2+-channel currents present in these terminals. With Ba2+ as the charge carrier, the presynaptic membrane expresses a current type with high-activation threshold and little inactivation. This current is blocked by verapamil and diltiazem at micromolar concentrations, it is relatively insensitive to nifedipine and completely resistant to non-L-type Ca2+-channel antagonists. As a comparison, we also analysed the pharmacology of high-threshold Ba+2 currents on muscle fibres. A high-activation threshold Ca2+-channel current is also present in muscle fibres, albeit with a distinct pharmacological profile. Thus, peptidergic terminals and muscle fibres exhibit different subtypes of voltage-gated Ca2+ channels. The putative role of cysteine string protein (CSP) as a neuronal Ca2+-channel modulator was tested by examining the peptidergic presynaptic current in csp null mutants. We show that CSP is expressed in peptidergic boutons and abolished in the mutant. Direct recordings, under conditions that inhibit calcium influx into glutamatergic terminals, show that Ca2+-currents in peptidergic csp terminals are entirely normal. This result indicates that CSP is not a generic Ca2+-channel modulator and it might perform different functions in fast versus slow forms of release.

Specific myosin heavy chain mutations suppress troponin I defects in Drosophila muscles.

We show that specific mutations in the head of the thick filament molecule myosin heavy chain prevent a degenerative muscle syndrome resulting from the hdp2 mutation in the thin filament protein troponin I. One mutation deletes eight residues from the actin binding loop of myosin, while a second affects a residue at the base of this loop. Two other mutations affect amino acids near the site of nucleotide entry and exit in the motor domain. We document the degree of phenotypic rescue each suppressor permits and show that other point mutations in myosin, as well as null mutations, fail to suppress the hdp2 phenotype. We discuss mechanisms by which the hdp2 phenotypes are suppressed and conclude that the specific residues we identified in myosin are important in regulating thick and thin filament interactions. This in vivo approach to dissecting the contractile cycle defines novel molecular processes that may be difficult to uncover by biochemical and structural analysis. Our study illustrates how expression of genetic defects are dependent upon genetic background, and therefore could have implications for understanding gene interactions in human disease.

The haplolethal region at the 16F gene cluster of Drosophila melanogaster: structure and function.

Extensive aneuploid analyses had shown the existence of a few haplolethal (HL) regions and one triplolethal region in the genome of Drosophila melanogaster. Since then, only two haplolethals, 22F1-2 and 16F, have been directly linked to identified genes, dpp and wupA, respectively. However, with the possible exception of dpp, the actual bases for this dosage sensitivity remain unknown. We have generated and characterized dominant-lethal mutations and chromosomal rearrangements in 16F and studied them in relation to the genes in the region. This region extends along 100 kb and includes at least 14 genes. The normal HL function depends on the integrity of a critical 4-kb window of mostly noncoding sequences within the wupA transcription unit that encodes the muscle protein troponin I (TNI). All dominant lethals are breakpoints within that window, which prevent the functional expression of TNI and other adjacent genes in the proximal direction. However, independent mutations in these genes result in recessive lethal phenotypes only. We propose that the HL at 16F represents a long-range cis regulatory region that acts upon a number of functionally related genes whose combined haploidy would yield the dominant-lethal effect.

Enhanced neurotransmitter release is associated with reduction of neuronal branching in a Drosophila mutant overexpressing frequenin.

Frequenin is a Drosophila Ca2+ binding protein whose overexpression causes a chronic facilitation of transmitter release at the larval neuromuscular junction and multiple firing of action potentials. These functional abnormalities are similar to those found in other hyperexcitable mutants (Shaker, ether-a-gogo, Hyperkinetic) which, in turn, exhibit increased branching at the motor nerve endings. We report here that mutants which overexpress frequenin have motor nerve terminals with reduced number and length of branches as well as number of synaptic boutons. Similar defects are observed in transgenic flies which have additional copies of the frequenin gene indicating that the phenotype can be adscribed to the overexpression of the protein. The ultrastructure of boutons, however, appears indistinguishable from wild type. In addition, we show here that frequenin overexpression leads also to a down regulation of Shaker proteins expression. The contrast between the observations in frequenin and the other hyperexcitable mutants indicates that nerve terminal morphology and enhanced transmitter release do not have a direct causal relationship.

Cloning, chromosome mapping and expression analysis of the HIRA gene from Drosophila melanogaster.

The human HIRA gene was identified as a putative transcriptional regulator mapping within the DiGeorge syndrome critical region at 22q11. HIRA-related proteins have been described in a number of species, but functional information concerning family members is only available in Saccharomyces cerevisiae, where the Hir1p and Hir2p proteins are known to be transcriptional corepressors. In order to analyse conservation of HIRA-related genes and to provide resources for functional studies in another model organism we have isolated the HIRA gene from Drosophila melanogaster (dhira). The 3374 nucleotide cDNA encodes a protein of 1047 aa, showing 42% identity with the human protein. Alignment with the predicted HIRA proteins from human, mouse, chick and pufferfish reveals strong conservation within the N-terminal region which contains seven WD domains, with less conservation of C-terminal sequences. In situ hybridisation to salivary gland chromosomes indicates that the gene resides in region 7B2-3 of the X chromosome. Dhira is expressed through embryonic development and at lower levels during larval and pupal development. The expression of dhira is dramatically increased in early embryos and in females, suggesting that the dhira mRNA could be maternally deposited in the embryos.

scully, an essential gene of Drosophila, is homologous to mammalian mitochondrial type II L-3-hydroxyacyl-CoA dehydrogenase/amyloid-beta peptide-binding protein.

The characterization of scully, an essential gene of Drosophila with phenocritical phases at embryonic and pupal stages, shows its extensive homology with vertebrate type II L-3-hydroxyacyl-CoA dehydrogenase/ERAB. Genomic rescue demonstrates that four different lethal mutations are scu alleles, the molecular nature of which has been established. One of them, scu3127, generates a nonfunctional truncated product. scu4058 also produces a truncated protein, but it contains most of the known functional domains of the enzyme. The other two mutations, scu174 and scuS152, correspond to single amino acid changes. The expression of scully mRNA is general to many tissues including the CNS; however, it is highest in both embryonic gonadal primordia and mature ovaries and testes. Consistent with this pattern, the phenotypic analysis suggests a role for scully in germ line formation: mutant testis are reduced in size and devoid of maturing sperm, and mutant ovarioles are not able to produce viable eggs. Ultrastructural analysis of mutant spermatocytes reveals the presence of cytoplasmic lipid inclusions and scarce mitochondria. In addition, mutant photoreceptors contain morphologically aberrant mitochondria and large multilayered accumulations of membranous material. Some of these phenotypes are very similar to those present in human pathologies caused by beta-oxidation disorders.

Single neuron mosaics of the drosophila gigas mutant project beyond normal targets and modify behavior.

gigas is a lethal mutant that differentiates enlarged cells, including the nucleus. This trait manifests only after the completion of the mitotic program. We have taken advantage of this phenotype to test in vivo the capacity of normal target cells to arrest the growth of mutant sensory axons. Single neuron connectivity changes have been analyzed in mosaics after horseradish peroxidase retrograde tracings. A mutant mechanoreceptor neuron, growing over a genetically normal substrate, contacts its normal target, and in addition projects to novel areas of the CNS. The mutant axon does terminate its growth eventually, and the new additional targets that are reached correspond to mechanoreceptor domains in other ganglia, indicating that this territorial constraint is operational in the mutant. gigas neurons maintain their stereotyped profile and represent an expanded version of the normal branching pattern. The ultrastructure of the invading projections does not reveal gliotic or necrotic reactions from the new cell contacts. The functional consequences of the connectivity changes produced by the mutant mechanoreceptors have been studied in grooming behavior. Mosaic flies carrying a single gigas mechanoreceptor show modified, albeit context-coherent, grooming responses after stimulation of the mutant bristle, whereas the response from neighboring normal sensory neurons remains unchanged. All of these experiments indicate that target recognition and growth arrest are two dissectible processes of neural development, and they highlight the autonomous features of the growth cone during pathfinding.

Presynaptic recordings from Drosophila: correlation of macroscopic and single-channel K+ currents.

We have performed direct electrophysiological recordings from Drosophila peptidergic synaptic boutons in situ, taking advantage of a mutation, ecdysone, which causes an increase in size of these terminals. Using patch-clamp techniques, we have analyzed voltage-dependent potassium currents at the macroscopic and single-channel level. The synaptic membrane contained at least two distinct voltage-activated potassium currents with different kinetics and voltage sensitivity: an IA-like current with fast activation and inactivation kinetics and voltage-dependent steady-state inactivation; a complex delayed current that includes a slowly inactivating component, resembling the IK described in other preparations; and a noninactivating component. The IA-like current in these peptidergic boutons is not encoded by the gene Shaker, because it is not affected by null mutations at this locus. Rather, synaptic IA has properties similar to those of the Shal-encoded IA. Single-channel recordings revealed the presence in synaptic membranes of three different potassium channel types (A2, KD, KL), with biophysical properties that could account for the macroscopic currents and resemble those of the Shal, Shab, and Shaw channels described in heterologous expression systems and Drosophila neuronal somata. A2 channels (6-9 pS) have brief open times, and like the macroscopic IA they exhibited voltage-dependent steady-state inactivation and a rapidly inactivating ensemble average current profile. KD channels (13-16 pS) had longer open times, activate and inactivate with much slower kinetics, and may account for the slowly inactivating component of the macroscopic current. KL (44-54 pS) channels produced a noninactivating ensemble average and may contribute to the delayed macroscopic current observed.