Summary
Combinatorial action of transcription factors (TFs) with partially overlapping expression is a widespread strategy to generate novel gene-expression patterns and, thus, cellular diversity. Known mechanisms underlying combinatorial activity require co-expression of TFs within the same cell. Here, we describe the mechanism by which two TFs that are never co-expressed generate a new, intersectional expression pattern in
C. elegans
embryos: lineage-specific priming of a gene by a transiently expressed TF generates a unique intersection with a second TF acting on the same gene four cell divisions later; the second TF is expressed in multiple cells but only activates transcription in those where priming occurred. Early induction of active transcription is necessary and sufficient to establish a competent state, maintained by broadly expressed regulators in the absence of the initial trigger. We uncover additional cells diversified through this mechanism. Our findings define a mechanism for combinatorial TF activity with important implications for generation of cell-type diversity.
Muscle function requires unique structural and metabolic adaptations that can render muscle cells selectively vulnerable, with mutations in some ubiquitously expressed genes causing myopathies but sparing other tissues. We uncovered a muscle cell vulnerability by studying miR-1, a deeply conserved, muscle-specific microRNA whose ablation causes various muscle defects. Using Caenorhabditis elegans, we found that miR-1 represses multiple subunits of the ubiquitous vacuolar adenosine triphosphatase (V-ATPase) complex, which is essential for internal compartment acidification and metabolic signaling. V-ATPase subunits are predicted miR-1 targets in animals ranging from C. elegans to humans, and we experimentally validated this in Drosophila. Unexpectedly, up-regulation of V-ATPase subunits upon miR-1 deletion causes reduced V-ATPase function due to defects in complex assembly. These results reveal V-ATPase assembly as a conserved muscle cell vulnerability and support a previously unknown role for microRNAs in the regulation of protein complexes.
Muscles are not only essential for force generation but are also key regulators of systemic energy homeostasis1. Both these roles rely heavily on mitochondria and lysosome function as providers of energy and building blocks, but also as metabolic sensors2-4. Perturbations in these organelles or their crosstalk lead to a wide range of pathologies5. Here, we uncover a deeply conserved regulon of mitochondria and lysosome homeostasis under control of the muscle-specific microRNA miR-1. Animals lacking miR-1 display a diverse range of muscle cell defects that have been attributed to numerous different targets6. Guided by the striking conservation of miR-1 and some of its predicted targets, we identified a set of direct targets that can explain the pleiotropic function of miR-1. miR-1-mediated repression of multiple subunits of the vacuolar ATPase (V-ATPase) complex, a key player in the acidification of internal compartments and a hub for metabolic signaling7,8, and of DCT-1/BNIP3, a mitochondrial protein involved in mitophagy and apoptosis9,10, accounts for the function of this miRNA in C. elegans. Surprisingly, although multiple V-ATPase subunits are upregulated in the absence of miR-1, this causes a loss-of-function of V-ATPase due to altered levels or stoichiometry, which negatively impact complex assembly. Finally, we demonstrate the conservation of the functional relationship between miR-1 and the V-ATPase complex in Drosophila.
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