The transcription factor Xrp1 orchestrates both reduced translation and cell competition upon defective ribosome assembly or function

Ribosomal Protein (Rp) gene haploinsufficiency affects overall translation rate, leads to cell elimination by competition with wild type cells in mosaic tissues, and sometimes leads to accumulation of protein aggregates. The changes in ribosomal subunit levels observed are not sufficient for these effects, which all depend on the AT-hook, bZip domain protein Xrp1. In Rp^+/− cells, Xrp1 reduced global translation through PERK-dependent phosphorylation of eIF2α. eIF2α phosphorylation was sufficient to reduce translation in, and also enable cell competition of, otherwise wild type cells. Unexpectedly, however, many other defects reducing ribosome biogenesis or function (depletion of TAF1B, eIF2, eIF4G, eIF6, eEF2, eEF1α1, or eIF5A), also increased eIF2α phosphorylation and enabled cell competition. In all cases this was through the Xrp1 expression that was induced, placing Xrp1 as the downstream instigator of cell competition that also contributed to overall translation deficits. In the absence of Xrp1, translation differences between cells were not themselves sufficient to trigger cell competition. Thus, Xrp1, which is shown here to be a sequence-specific transcription factor, is the master regulator that triggers cell competition and other consequences of multiple ribosomal stresses.