Ribosomes perform protein synthesis but are also involved in signaling processes, the full extent of which are still being uncovered. We report that phenotypes of mutating ribosomal proteins (Rps) are largely due to signaling. Using Drosophila, we discovered that a bZip-domain protein, Xrp1, becomes elevated in Rp mutant cells. Xrp1 reduces translation and growth, delays development, is responsible for gene expression changes, and causes the cell competition of Rp heterozygous cells from genetic mosaics. Without Xrp1, even cells homozygously deleted for Rp genes persist and grow. Xrp1 induction in Rp mutant cells depends on a particular Rp with regulatory effects, RpS12, and precedes overall changes in translation. Thus, effects of Rp mutations, even the reductions in translation and growth, depend on signaling through the Xrp1 pathway and are not simply consequences of reduced ribosome production limiting protein synthesis. One benefit of this system may be to eliminate Rp-mutant cells by cell competition.
In Drosophila, the sine oculis (so) gene is important for the development of the entire visual system, including Bolwig's organ, compound eyes and ocelli. Together with twin of eyeless, eyeless, eyes absent and dachshund, sobelongs to a network of genes that by complex interactions initiate eye development. Although much is known about the genetic interactions of the genes belonging to this retinal determination network, only a few such regulatory interactions have been analysed down to the level of DNA-protein interactions. Previous work in our laboratory identified an eye/ocellus specific enhancer of the sine oculis gene that is directly regulated by eyeless and twin of eyeless. We further characterized this regulatory element and identified a minimal enhancer fragment of so that sets up an autoregulatory feedback loop crucial for proper ocelli development. By systematic analysis of the DNA-binding specificity of so we identified the most important nucleotides for this interaction. Using the emerging consensus sequence for SO-DNA binding we performed a genome-wide search and have thereby been able to identify eyeless as well as the signalling gene hedgehog as putative targets of so. Our results strengthen the general assumption that feedback loops among the genes of the retinal determination network are crucial for proper development of eyes and ocelli.
The homeobox gene orthodenticle (otd) controls the process of regional specification that takes place in the Drosophila eye-antennal disc during ocelli development. Mutations that reduce or abolish otd expression in the ocelli primordium give rise to ocelliless flies. We have identified the cis-regulatory sequence (ocelliless enhancer) that controls otd expression during ocelli development and studied its regulation at the molecular level. The ocelliless enhancer is initially activated by the combined action of Wingless (Wg) and Hedgehog (Hh) signaling pathways. Later, a positive autoregulatory feedback loop sets in to maintain otd expression. Moreover, we have analyzed the role of otd during ocelli primordium development and determined its involvement in the expression of the retinal determination gene eyes absent (eya). otd indirectly regulates eya in ocellar precursor cells through the inhibition of wg, an eya repressor, and the maintenance of hh expression in the ocelli primordium. Hh signaling is necessary for eya activation in ocellar precursor cells and this activation is mediated by the full-length activator form of the transcription factor Cubitus interruptus.
Background. Healthcare workers (HCWs) exposed to coronavirus 19 are at high risk of developing mental health concerns across several domains. The aim of this study is to determine the updated, global frequency of these outcomes. Methods. A multistep literature search was performed from database inception until March 1, 2021. PRISMA/MOOSE-compliant systematic review and PROSPERO protocol were used to identify studies reporting on depression, anxiety, acute stress, post-traumatic symptoms, insomnia, and burnout in HCWs exposed to COVID-19. A quantitative meta-analysis with random effects was conducted to analyze the proportion rate of the mental health disorders. Sensitivity analyses were performed to investigate the effect of the different continents and scales. Meta-regression analyses were conducted to examine the effect of gender, age, and work position.Results. 239 articles were included (n = 271,319 HCWs, mean age = 36.08 AE 8.33 (66.99% female). 33% HCWs exposed to COVID-19 reported depressive symptoms (95% confidence intervals [CI] = 28-38%), 42% anxiety features (95% CI = 35-48), 40% acute stress (95% CI = 32-47), 32% post-traumatic symptoms (95% CI = 26-37%), 42% insomnia (95% CI = 36-48), 37% burnout (95% CI = 31-42). Sensitivity analyses did not show statistically significant differences. Meta-regressions found a statistically significant lower prevalence of post-traumatic symptoms in Asia. Conclusions. HCWs exposed to COVID-19 were found to have a significant prevalence of mental health concerns in all domains analyzed. The effects of COVID-19 on HCWs' mental health could be underestimated and the future consequences dismissed.
Reduced copy number of ribosomal protein (Rp) genes adversely affects both flies and mammals. Xrp1 encodes a reportedly Drosophila-specific AT-hook, bZIP protein responsible for many of the effects including the elimination of Rp mutant cells by competition with wild type cells. Irbp18, an evolutionarily conserved bZIP gene, heterodimerizes with Xrp1 and with another bZip protein, dATF4. We show that Irbp18 is required for the effects of Xrp1, whereas dATF4 does not share the same phenotype, indicating that Xrp1/Irbp18 is the complex active in Rp mutant cells, independently of other complexes that share Irbp18. Xrp1 and Irbp18 transcripts and proteins are upregulated in Rp mutant cells by auto-regulatory expression that depends on the Xrp1 DNA binding domains and is necessary for cell competition. We show that Xrp1 is conserved beyond Drosophila, although under positive selection for rapid evolution, and that at least one human bZip protein can similarly affect Drosophila development.
Whereas complete loss of Rp function is generally lethal, most heterozygous Rp mutants grow more slowly and are subject to competitive loss from mosaics tissues that also contain wild type cells. The rpS12 gene has a special role in the cell competition of other Ribosomal Protein (Rp) mutant cells in Drosophila. Elimination by cell competition is promoted by higher RpS12 levels and prevented by a specific rpS12 mis-sense mutation, identifying RpS12 as a key effector of cell competition due to mutations in other Rp genes. Here we show that RpS12 is also required for other aspects of Rp mutant phenotypes, including hundreds of gene expression changes that occur in ‘Minute’ Rp heterozygous wing imaginal discs, overall translation rate, and the overall rate of organismal development, all through the bZip protein Xrp1 that is one of the RpS12-regulated genes. Our findings outline the regulatory response to mutations affecting essential Rp genes that controls overall translation, growth, and cell competition, and which may contribute to cancer and other diseases.
Wild-type Drosophila cells can remove cells heterozygous for ribosomal protein mutations (known as "Minute" mutant cells) from genetic mosaics, a process termed cell competition. The ribosomal protein S12 was unusual because cells heterozygous for rpS12 mutations were not competed by wild-type, and a viable missense mutation in rpS12 protected Minute cells from cell competition with wild-type cells. Furthermore, cells with Minute mutations were induced to compete with one another by altering the gene dose of rpS12, eliminating cells with more rpS12 than their neighbors. Thus RpS12 has a special function in cell competition that defines the competitiveness of cells. We propose that cell competition between wild-type and Minute cells is initiated by a signal of ribosomal protein haploinsufficiency mediated by RpS12. Since competition between cells expressing different levels of Myc did not require RpS12, other kinds of cell competition may be initiated differently.
A variety of extracellular factors regulate morphogenesis during development. However, coordination between extracellular signaling and dynamic morphogenesis is largely unexplored. We address the fundamental question by studying posterior crossvein (PCV) development in Drosophila as a model, in which long-range BMP transport from the longitudinal veins plays a critical role during the pupal stages. Here, we show that RhoGAP Crossveinless-C (Cv-C) is induced at the PCV primordial cells by BMP signaling and mediates PCV morphogenesis cell-autonomously by inactivating members of the Rho-type small GTPases. Intriguingly, we find that Cv-C is also required non-cell-autonomously for BMP transport into the PCV region, while a long-range BMP transport is guided toward ectopic wing vein regions by loss of the Rho-type small GTPases. We present evidence that low level of ß-integrin accumulation at the basal side of PCV epithelial cells regulated by Cv-C provides an optimal extracellular environment for guiding BMP transport. These data suggest that BMP transport and PCV morphogenesis are tightly coupled. Our study reveals a feed-forward mechanism that coordinates the spatial distribution of extracellular instructive cues and morphogenesis. The coupling mechanism may be widely utilized to achieve precise morphogenesis during development and homeostasis.
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