Divergence in transcriptional and regulatory responses to mating in male and female fruitflies

Mating induces extensive physiological, biochemical and behavioural changes in female animals of many taxa. In contrast, the overall phenotypic and transcriptomic consequences of mating for males, hence how they might differ from those of females, are poorly described. Post mating responses in each sex are rapidly initiated, predicting the existence of regulatory mechanisms in addition to transcriptional responses involving de novo gene expression. That post mating responses appear different for each sex also predicts that the genome-wide signatures of mating should show evidence of sex-specific specialisation. In this study, we used high resolution RNA sequencing to provide the first direct comparisons of the transcriptomic responses of male and female Drosophila to mating, and the first comparison of mating-responsive miRNAs in both sexes in any species. As predicted, the results revealed the existence of sex- and body part-specific mRNA and miRNA expression profiles. More genes were differentially expressed in the female head-thorax than the abdomen following mating, whereas the opposite was true in males. Indeed, the transcriptional profile of male head-thorax tissue was largely unaffected by mating, and no differentially expressed genes were detected at the most stringent significance threshold. A subset of ribosomal genes in females were differentially expressed in both body parts, but in opposite directions, consistent with the existence of body part-specific resource allocation switching. Novel, mating-responsive miRNAs in each sex were also identified, and a miRNA-mRNA interactions analysis revealed putative targets among mating-responsive genes. We show that the structure of genome-wide responses by each sex to mating is strongly divergent, and provide new insights into how shared genomes can achieve characteristic distinctiveness

New roles for apical secretion and extracellular matrix assembly in Drosophila epithelial morphogenesis

Branched tubular organs, such as the lung and vascular system fulfill the respiratory needs of most animals. Optimal tissue function relies on the uniform sizes and shapes of the constituting branches in each organ. The Drosophila tracheal airways provide a recognized genetic model system for identification and characterization of tube size regulators. We found that the programmed secretion and assembly of the apical extracellular matrix (ECM) is required for the expansion of the trachea and salivary glands (SG) tubes. We have characterized Vermiform (Verm) and Serpentine (Serp), two chitin-binding proteins with predicted polysaccharide deacetylase domains (ChLDs). Verm and Serp mutants show overelongated tubes, suggesting that luminal ECM modification restricts tracheal tube elongation. The luminal deposition of ChLDs, but not other secreted components, depends on paracellular septate junction integrity (SJs) in the tracheal epithelium. Deletion of the deacetylase domain renders Serp-GFP intracellular, arguing that the deacetylase domain harbors uncharacterized secretion signals. To explore this possibility we transferred the deacetylase domain from Serp to Gasp, another tracheal luminal protein, which requires the Emp24 adaptor for ER exit. The Gasp-Deac-GFP chimera was normally secreted in emp24 mutants indicating that the deacetylase domain contains potential ER-exit signals. To identify such signals we characterized conserved sequence motifs in the Serp deacetylase domain. Mutations of the N-glycosylation sites gradually reduced Serp-GFP luminal deposition suggesting that increased glycosylation enhances apical Serp secretion. By contrast, substitutions in three conserved amino acid stretches completely blocked the ER-exit of Serp-GFP. The mutated proteins were N-glycosylated suggesting that the motifs may be involved in a subsequent protein-folding step or facilitate ER exit through interactions with unidentified specific adaptors.At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 4: Manuscript

COPI vesicle transport is a common requirement for tube expansion in Drosophila.

BACKGROUND: Tube expansion defects like stenoses and atresias cause devastating human diseases. Luminal expansion during organogenesis begins to be elucidated in several systems but we still lack a mechanistic view of the process in many organs. The Drosophila tracheal respiratory system provides an amenable model to study tube size regulation. In the trachea, COPII anterograde transport of luminal proteins is required for extracellular matrix assembly and the concurrent tube expansion. PRINCIPAL FINDINGS: We identified and analyzed Drosophila COPI retrograde transport mutants with narrow tracheal tubes. gammaCOP mutants fail to efficiently secrete luminal components and assemble the luminal chitinous matrix during tracheal tube expansion. Likewise, tube extension is defective in salivary glands, where it also coincides with a failure in the luminal deposition and assembly of a distinct, transient intraluminal matrix. Drosophila gammaCOP colocalizes with cis-Golgi markers and in gammaCOP mutant embryos the ER and Golgi structures are severely disrupted. Analysis of gammaCOP and Sar1 double mutants suggests that bidirectional ER-Golgi traffic maintains the ER and Golgi compartments and is required for secretion and assembly of luminal matrixes during tube expansion. CONCLUSIONS/SIGNIFICANCE: Our results demonstrate the function of COPI components in organ morphogenesis and highlight the common role of apical secretion and assembly of transient organotypic matrices in tube expansion. Intraluminal matrices have been detected in the notochord of ascidians and zebrafish COPI mutants show defects in notochord expansion. Thus, the programmed deposition and growth of distinct luminal molds may provide distending forces during tube expansion in diverse organs

Sequential Pulses of Apical Epithelial Secretion and Endocytosis Drive Airway Maturation in Drosophila

SummaryThe development of air-filled respiratory organs is crucial for survival at birth. We used a combination of live imaging and genetic analysis to dissect respiratory organ maturation in the embryonic Drosophila trachea. We found that tracheal tube maturation entails three precise epithelial transitions. Initially, a secretion burst deposits proteins into the lumen. Solid luminal material is then rapidly cleared from the tubes, and shortly thereafter liquid is removed. To elucidate the cellular mechanisms behind these transitions, we identified gas-filling-deficient mutants showing narrow or protein-clogged tubes. These mutations either disrupt endoplasmatic reticulum-to-Golgi vesicle transport or endocytosis. First, Sar1 is required for protein secretion, luminal matrix assembly, and diametric tube expansion. Subsequently, a sharp pulse of Rab5-dependent endocytic activity rapidly internalizes and clears luminal contents. The coordination of luminal matrix secretion and endocytosis may be a general mechanism in tubular organ morphogenesis and maturation

Functional unknomics: Systematic screening of conserved genes of unknown function.

Acknowledgements: We thank Damian Crowther for loan of the iFly tracking system, Sara Imarisio for advice on proteostasis assays, Tobias Klöpper for help with gene selection for screens, the LMB workshops for help with the system for lifespan measurements, Anna Parish for fly stock maintenance, and Manu Hegde for comments on the manuscript.The human genome encodes approximately 20,000 proteins, many still uncharacterised. It has become clear that scientific research tends to focus on well-studied proteins, leading to a concern that poorly understood genes are unjustifiably neglected. To address this, we have developed a publicly available and customisable "Unknome database" that ranks proteins based on how little is known about them. We applied RNA interference (RNAi) in Drosophila to 260 unknown genes that are conserved between flies and humans. Knockdown of some genes resulted in loss of viability, and functional screening of the rest revealed hits for fertility, development, locomotion, protein quality control, and resilience to stress. CRISPR/Cas9 gene disruption validated a component of Notch signalling and 2 genes contributing to male fertility. Our work illustrates the importance of poorly understood genes, provides a resource to accelerate future research, and highlights a need to support database curation to ensure that misannotation does not erode our awareness of our own ignorance