We exploited the high Ras activity induced differentiation of supernumerary R7 cells in Drosophila eyes to examine if hsrω lncRNAs influence active Ras signaling. Surprisingly, either down-or up-regulation of hsrω lncRNAs in sev-GAL4>Ras V12 expressing eye discs resulted in complete pupal lethality and substantially greater increase in R7 photoreceptor number at the expense of cone cells. Enhanced nuclear p-MAPK and presence of sev-GAL4 driven Ras V12 bound RafRBDFLAG in cells not expressing the sev-GAL4 driver indicated non-cell autonomous spread of Ras signaling when hsrω levels were co-altered. RNAsequencing revealed that down-and up-regulation of hsrω transcripts in sev-GAL4>Ras V12 expressing eye discs elevated transcripts of positive or negative modulators, respectively, of Ras signaling so that either condition enhances it. Altered hsrω transcript levels in sev-GAL4>Ras V12 expressing discs also affected sn/sno/sca RNAs and some other RNA processing transcript levels. Post-transcriptional changes due to the disrupted intra-cellular dynamicity of omega speckle associated hnRNPs and other RNA-binding proteins that follow down-or up-regulation of hsrω lncRNAs appear to be responsible for the further elevated Ras signaling. Cell autonomous and non-autonomous enhancement of Ras signaling by lncRNAs like hsrω has implications for cell signaling during high Ras activity commonly associated with some cancers. HighlightsOur findings highlight roles of hsrω lncRNAs in conditionally modulating the important Ras signaling pathway and provide evidence for cell non-autonomous Ras signaling in Drosophila eye discs..
To examine role of hsrω nuclear lncRNAs in Ras signaling cascade, we down-or up-regulated these transcripts in eye discs of Drosophila expressing sev-GAL4 driven activated ras V12 transgene. The sev-GAL4 driven Ras V12 transgene expression dependent late pupal lethality and extra R7 photoreceptors in ommatidia, were significantly enhanced when levels of hsrω lncRNA were down/up-regulated. This was associated with enhanced p-MAPK expression, reduced Yan levels, and greater association of RafRBDFLAG with Ras, indicating elevated Ras activation which was both cell autonomous and non-autonomous. RNAseq analysis revealed significant increase in expression of certain sno/sn/scaRNAs and some RNA processing genes in sevGAL4>Ras V12 which was further modulated when hsrωRNA levels were co-altered. Downregulation of hsrωRNAs elevated positive modulators of Ras signaling while their up-regulation reduced expression of negative modulators of Ras signaling, and thus both conditions have similar outcome. Further enhancement of activity of hyperactive Ras following changes in hsrω lncRNA levels in cell autonomous as well as non-autonomous manner emphasizes roles of lncRNAs in cell signaling during development and disease conditions associated with hyperactive Ras pathway mutants. SummaryOur findings highlight roles of hsrω lncRNA in conditionally modulating the important Ras signaling pathway and provide evidence for cell non-autonomous Ras signaling in Drosophila eye discs.
Currently, maize (Zea mays L.) production is under threat from climate change, drought, and pests such as fall armyworm (FAW) [Spodoptera frugiperda (J.E. Smith) (Lepidoptera: Noctuidae)]. Since its first detection outside of its native range in 2016, FAW has spread into 76 nations across Africa and Asia adversely affecting maize production and, in turn, the livelihoods of millions of smallholder farmers. Thus, there is a strong need for the development of cost-effective and biologically based integrated pest management (IPM) practices including host-plant resistance (HPR). However, most of the commercial maize cultivars have lost some defensive traits through selective breeding for yield during domestication. The majority of the commercially cultivated hybrids and cultivars in Asia and Africa are highly susceptible to FAW. Therefore, this review summarizes information about various maize landraces, native germplasm, and crop wild relatives (CWRs) possessing FAW resistance traits and about their potential resistance mechanisms, namely antibiosis, antixenosis, and tolerance. There is clear evidence of FAW resistance acting through diverse mechanisms in several maize landraces, germplasm lines, native populations, and CWRs such as Antigua race, FAW Tuxpeno, Zapalote Chico 2451F, Doce Flor da Serra, FAWCC (C5), CMS 14C, PopG (C2), Mp708, Mp 704, CML 67, and FAW 7050, as well as a few species of teosinte and Tripsacum L. Further, a scheme that outlines strategies and approaches for prebreeding and their introgression into elite cultivars for developing FAW-resistant maize is proposed as a possible way forward.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.