Project description:Wound response programs are often activated during neoplastic growth in tumors. In both systems, cells respond to acute stress and balance the activation of multiple programs including apoptosis, proliferation, and cell migration. Central to this response are the JNK/MAPK and JAK/STAT signaling pathways. Yet, to what extent these signaling cascades interact at the cis-regulatory level, and how they orchestrate different phenotypic responses is still unclear. Here, we aim to characterize the cellular states that emerge and cooperate in the wound response, using the Drosophila melanogaster wing disc as a model system. We used single-cell multi-omics profiling to derive enhancer Gene Regulatory Networks (eGRNs) from chromatin accessibility, transcription factor binding motif and gene expression signals. We identify the eGRNs being activated following a transient wound induction, and compare them with the scRNA profiles obtained from a persistent induction of the rasv12 scrib-/- oncogenic driver. We detect a small cell population in the wound that activates a senescence program that is shared with cancer cells. This population is characterized by the C/EBP-like transcription factors Irbp18, Xrp1, slow-border and vrille. Our single-cell multiome and eGRNs resource offers a new perspective on gene regulation in the normal and wounded wing disc.

Project description:Wound response programs are often activated during neoplastic growth in tumors. In both systems, cells respond to acute stress and balance the activation of multiple programs including apoptosis, proliferation, and cell migration. Central to this response are the JNK/MAPK and JAK/STAT signaling pathways. Yet, to what extent these signaling cascades interact at the cis-regulatory level, and how they orchestrate different phenotypic responses is still unclear. Here, we aim to characterize the cellular states that emerge and cooperate in the wound response, using the Drosophila melanogaster wing disc as a model system. We used single-cell multi-omics profiling to derive enhancer Gene Regulatory Networks (eGRNs) from chromatin accessibility, transcription factor binding motif and gene expression signals. We identify the eGRNs being activated following a transient wound induction, and compare them with the scRNA profiles obtained from a persistent induction of the rasv12 scrib-/- oncogenic driver. We detect a small cell population in the wound that activates a senescence program that is shared with cancer cells. This population is characterized by the C/EBP-like transcription factors Irbp18, Xrp1, slow-border and vrille. Our single-cell multiome and eGRNs resource offers a new perspective on gene regulation in the normal and wounded wing disc.

Project description:We investigated the changes in gene expression in response to reduced levels of Ecdysoneless (Ecd), and the role of Xrp1 in induction of transcriptional changes upon loss of Ecd in the developing wing disc of Drosophila. To do this we utilized the GAL4/UAS system to express UAS-ecd-RNAi alone and in combination with UAS-xrp1-RNAi in the nubbin-domain (nub-Gal4, UAS-mRFP, UAS-ecd-RNAi and nub-Gal4, UAS-mRFP, UAS-ecd-RNAi, xrp1-RNAi) of the wing disc and used nub-Gal4, UAS-mRFP wing discs as controls.  We quantified transcriptomic expression analysis from four biological replicates for both experimental groups

Project description:Since the putative transcription factor Xrp1 gene is required for many aspects of Rp+/- phenotypes, we sought to define what transcriptional changes occur in Rp+/- wing discs and their dependence on Xrp1. We identified 257 genes whose transcripts were significantly altered in the same direction in two Rp+/- genotypes, most of which depended on Xrp1. The results show that Xrp1 regulates a significant transcriptional response in Rp+/- genotypes.

Project description:Drosophila mosaic eye-antennal discs from the listed genotypes generated using the MARCM system were dissected from 3rd instar larvae at day 5 after egg deposition. 20 pairs of discs for the Abrupt and scrib- + Abrupt samples and 50 pairs from FRT control, NACT scrib- +/- BskDN and RasACT scrib- +/- BskDN were used to prepare RNA. Samples were prepared in triplicate, and the RNA isolated using TRIZOL, before being column purified (Qiagen). Probes were hybridized to GeneChip Drosophila 2.0 Genome Arrays (Affymetrix). To compare the expression profile of Abrupt when overexpressed in the eye-antennal discs with tumours formed by Abrupt overexpression in scrib- clones, and to reveal JNK responsive genes in RasV12 (RasACT) scrib- versus NotchICD (NACT) scrib- eye-antennal mosaic discs

Project description:Investigation of intratumor heterogeneity in the scrib¹ mutant wing imaginal discs. Method: Staged scrib¹ wing imaginal discs were dissected and transferred to DPBS. The wing imaginal discs were dissociated in 0.25% Trypsin-EDTA solution at 37 ℃ for 10 min. Cells were then washed in DPBS and passed through 35μm filter before library preparation. Construction of 10x single cell libraries and sequencing on Illumina platform were performed by Novogene.

Project description:The systemic response to injury in Drosophila melanogaster is characterized by the activation of specific signaling pathways that facilitate the regeneration of wounded tissue and help coordinate wound healing with organism growth. The mechanisms by which damaged tissues influence the development and function of peripheral non-injured tissues is not fully understood. Injury was induced in early third instar larvae via temperature-dependent cell death in wing imaginal discs. Microarray analysis using RNA isolated from injured and control was used to identify genes underlying the systemic injury response. We identified 150 genes which were differentially expressed in response to localized cell death in wing imaginal discs. Upregulated genes were associated biological processes including carnitine biosynthesis, signal transduction and regulation of oxidoreductase activity while terms associated with downregulated genes included wound healing, imaginal disc-derived wing hair outgrowth, and regulation of glutamatergic synaptic transmission. Pathway analysis revealed that wing disc damage led to changes in fatty acid, cysteine, and carnitine metabolism. One gene, 14-3-3ζ, which encodes a known regulator of Ras/MAPK signaling was identified as a potential regulator of transdetermination during tissue regeneration. Our results raise the possibility that immune function and cell proliferation during wing disc repair and regeneration in Drosophila may require the sulfur amino acid cysteine and its’ metabolites, taurine and glutathione, similar to what has been reported during tissue repair in mammals. Further, it seems likely that imaginal disc damage stimulates the mobilization of fatty acids to support the energetically demanding process of tissue regeneration. The roles of additional genes that are differentially regulated following imaginal disc injury remain to be elucidated.

Project description:Expressing constitutive active Ras (RasV12) in combination with loss of function mutations in cell polarity determinants such as scrib, dlg or lgl results in large tumors in Drosophila eye imaginal discs. We found that the transcription factor Ets21C critically affects neoplastic growth of RasV12 dlgRNAi tumors. In order better understand this phenomenon, we aimed to identify Ets21C dependent target genes. For this purpose, we did microarrays of RasV12 dlgRNAi tumors that were depleted for Ets21C or overexpressed Ets21C and compared the transcriptional profiles to control tumors.

Project description:Abrupt scrib- vs. Abrupt and RasV12 (RasACT) scrib-, NotchICD (NACT) scrib- +/- JNK (Bsk) expression profiles

Project description:mRNA Seq analysis of Drosophila wing imaginal discs from Rp mutants and controls in the presence and absence of RpS12 mutations RpS12 is a regulatory gene required for Xrp1-mediated control of translation and growth in mutants for other ribosomal protein genes Loss of function mutations in Ribosomal Protein (Rp) genes are generally lethal, but heterozygous mutant phenotypes increasingly reveal previously cryptic functions of Rps in growth control and tumor suppression. Here we report that RpS12 in particular is a regulatory gene that controls its own expression levels and also signals to control hundreds of gene expression changes in mutants for haploinsufficient Rp genes, acting through the bZip protein Xrp1. Through Xrp1, RpS12 reduces the bulk translation rate of Rp mutant cells and increases the developmental rate of Rp mutant genotypes. RpS12 also has an Xrp1-independent, positive contribution to normal development, so that the effects of RpS12 mutations in different genetic backgrounds reflects the sum of the Xrp1-dependent and Xrp1-independent effects. Our findings outline a regulatory response to mutations affecting essential Rp genes that controls overall translation and growth.