AbstractmicroRNAs (miRNAs), the tiny but stable regulatory RNAs in metazoan cells, can undergo selective turnover in presence of specific internal and external cues to control cellular response against the changing environment. We have observed reduction in cellular miR‐122 content, due to their accelerated extracellular export in human hepatic cells starved for small metabolites including amino acids. In this context, a new role of human ELAV protein HuR has been identified. HuR, a negative regulator of miRNA function, accelerates extracellular vesicle (EV)‐mediated export of miRNAs in human cells. In stressed cells, HuR replaces miRNPs from target messages and is both necessary and sufficient for the extracellular export of corresponding miRNAs. HuR could reversibly bind miRNAs to replace them from Ago2 and subsequently itself gets freed from bound miRNAs upon ubiquitination. The ubiquitinated form of HuR is predominantly associated with multivesicular bodies (MVB) where HuR‐unbound miRNAs also reside. These MVB‐associated pool of miRNAs get exported out via EVs thereby delimiting cellular miR‐122 level during starvation. Therefore, by modulating extracellular export of miR‐122, HuR could control stress response in starved human hepatic cells.
Leishmania donovani, the causative agent of visceral leishmaniasis, infects and resides within tissue macrophage cells. It is not clear how the parasite infected cells crosstalk with the noninfected cells to regulate the infection process. During infection, Leishmania adopts a dual strategy for its survival by regulating the intercellular transport of host miRNAs to restrict inflammation. The parasite, by preventing mitochondrial function of host cells, restricts the entry of liver cell derived miR-122–containing extracellular vesicles in infected macrophages to curtail the inflammatory response associated with miR-122 entry. On contrary, the parasite up-regulates the export of miR-146a from the infected macrophages. The miR-146a, associated with the extracellular vesicles released by infected cells, restricts miR-122 production in hepatocytes while polarizing neighbouring naïve macrophages to the M2 state by affecting the cytokine expression. On entering the recipient macrophages, miR-146a dominates the miRNA antagonist RNA-binding protein HuR to inhibit the expression of proinflammatory cytokine mRNAs having HuR-interacting AU-rich elements whereas up-regulates anti-inflammatory IL-10 by exporting the miR-21 to polarize the recipient cells to M2 stage.
MicroRNAs, the tiny regulators of gene expression, can be transferred between neighbouring cells via Extracellular Vesicles (EV) to control the expression of genes in both donor and recipient cells. How the EV-derived miRNAs get internalized and become functional in target cells is an unresolved question. We have expressed liver specific microRNA, miR-122, in non-hepatic cells for packaging in the released EVs. With these EVs, we have followed the trafficking of miR-122 to recipient HeLa cells that otherwise don't express this miRNA. We found that EV-associated miR-122 are primarily single stranded and, to become functional, get loaded onto the recipient cell Ago proteins without requiring host Dicer1. Following endocytosis, EV-associated miR-122 get loaded onto the host cell Ago on the endosomal membrane where the release of internalized miRNAs occurs in a pH-dependent manner facilitating the formation of the exogenous miRNP pool in the recipient cells. Endosome maturation defect affects EV-mediated entry of exogeneous miRNAs in mammalian cells.
MicroRNAs are small regulatory RNAs of relatively long half-life in non-proliferative human cells. However, in cancer cells the half-lives of miRNAs are comparatively short. To understand the mechanism of rapid miRNA turn over in cancer cells, we explored the effect of target mRNAs on the abundance of the miRNA that repress them. We have noted an accelerated extracellular vesicle (EV) mediated export of miRNAs in presence of their target mRNAs in mammalian cells and this target driven miRNA-export process gets retarded by Ago2 interacting protein GW182B. The GW182 group of proteins are localized to GW182 Bodies or RNA Processing Bodies in mammalian cells and GW182B dependent retardation of miRNA export depends on GW-body integrity and is independent of HuR protein mediated auxiliary pathway of miRNA export. Our data thus support the existence of a HuR independent pathway of miRNA export in human cells that can be targeted in MDA-MB-231 cancer cells, to increase the level of cellular let-7a, a known negative regulator of cancer growth.
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