Despite efforts to promote diversity in the biomedical workforce, there remains a lower rate of funding of National Institutes of Health R01 applications submitted by African-American/black (AA/B) scientists relative to white scientists. To identify underlying causes of this funding gap, we analyzed six stages of the application process from 2011 to 2015 and found that disparate outcomes arise at three of the six: decision to discuss, impact score assignment, and a previously unstudied stage, topic choice. Notably, AA/B applicants tend to propose research on topics with lower award rates. These topics include research at the community and population level, as opposed to more fundamental and mechanistic investigations; the latter tend to have higher award rates. Topic choice alone accounts for over 20% of the funding gap after controlling for multiple variables, including the applicant’s prior achievements. Our findings can be used to inform interventions designed to close the funding gap.
The recruitment model for gene activation presumes that DNA is a platform on which the requisite components of the transcriptional machinery are assembled. In contrast to this idea, we show here that Rap1͞Gcr1͞Gcr2 transcriptional activation in yeast cells occurs through a large anchored protein platform, the Nup84 nuclear pore subcomplex. Surprisingly, Nup84 and associated subcomplex components activate transcription themselves in vivo when fused to a heterologous DNA-binding domain. The Rap1 coactivators Gcr1 and Gcr2 form an important bridge between the yeast nuclear pore complex and the transcriptional machinery. Nucleoporin activation may be a widespread eukaryotic phenomenon, because it was first detected as a consequence of oncogenic rearrangements in acute myeloid leukemia and related syndromes in humans. These chromosomal translocations fuse a homeobox DNA-binding domain to the human homolog (hNup98) of a transcriptionally active component of the yeast Nup84 subcomplex. We conclude that Rap1 target genes are activated by moving to contact compartmentalized nuclear assemblages, rather than through recruitment of the requisite factors to chromatin by means of diffusion. We term this previously undescribed mechanism ''reverse recruitment'' and discuss the possibility that it is a central feature of eukaryotic gene regulation. Reverse recruitment stipulates that activators work by bringing the DNA to an nuclear pore complex-tethered platform of assembled transcriptional machine components.chromatin boundaries ͉ leukemia ͉ silencing ͉ synthetic genetic array ͉ gene regulation A n underlying assumption of both the stepwise and preassembly alternatives (1) of the recruitment model of in vivo gene activation (2-6) is that activators work by bringing the transcriptional machinery to the DNA, i.e., that the machinery itself diffuses relatively freely within the nuclear compartment. We have been studying the repressor͞activator protein Rap1 of Saccharomyces cerevisiae, which recognizes identical motifs in mediating either transcriptional activation (of glycolytic genes and ribosomal protein genes; refs. 7-9) or repression (of silent mating type loci and telomeres; refs. 10-15) and with its coactivators Gcr1 and Gcr2 participates in coordination of growth with cell-cycle progression (16,17). Numerous aspects of Rap1 activation have conformed poorly with the ''free diffusion'' aspect of the recruitment model for transcriptional activation. One such aspect is the presence of an unusually large activation domain that is easily inactivated by means of mutations throughout the N-terminal 280 residues of Gcr1, spanning four distinct hypomutable regions (8,17,18); two of these hypomutable regions overlap with putative transmembrane domains.We report here independent approaches demonstrating that the Rap1͞Gcr1͞Gcr2 activation assemblage (7-9, 19), like its silencing counterpart, is anchored at the nuclear periphery. For example, synthetic genetic array (SGA) analysis identified a robust genetic network that connects the Ra...
Regulation of gene transcription is a key feature of developmental, homeostatic, and oncogenic processes. The reverse recruitment model of transcriptional control postulates that eukaryotic genes become active by moving to contact transcription factories at nuclear substructures; our previous work showed that at least some of these factories are tethered to nuclear pores. We demonstrate here that the nuclear periphery is the site of key events in the regulation of glucose-repressed genes, which together compose one-sixth of the Saccharomyces cerevisiae genome. We also show that the canonical glucoserepressed gene SUC2 associates tightly with the nuclear periphery when transcriptionally active but is highly mobile when repressed. Strikingly, SUC2 is both derepressed and confined to the nuclear rim in mutant cells where the Mig1 repressor is nuclear but not perinuclear. Upon derepression all three subunits (a, b, and g) of the positively acting Snf1 kinase complex localize to the nuclear periphery, resulting in phosphorylation of Mig1 and its export to the cytoplasm. Reverse recruitment therefore appears to explain a fundamental pathway of eukaryotic gene regulation.
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