Abstract
Developmental switching between life-cycle stages is a common feature among parasitic pathogens to facilitate disease transmission and pathogenesis. The protozoan parasite Entamoeba switches between invasive trophozoites and dormant cysts, but the encystation process remains poorly understood despite being central to amoebic biology. We identify a transcription factor, Encystation Regulatory Motif-Binding Protein (ERM-BP), that regulates encystation. Down-regulation of ERM-BP decreases encystation efficiency resulting in abnormal cysts with defective cyst walls. We demonstrate that direct binding of NAD+ to ERM-BP affects ERM-BP conformation and facilitates its binding to promoter DNA. Additionally, cellular NAD+ levels increase during encystation and exogenous NAD+ enhances encystation consistent with the role of carbon source depletion in triggering Entamoeba encystation. Furthermore, ERM-BP catalyzes conversion of nicotinamide to nicotinic acid, which might have second messenger effects on stage conversion. Our findings link the metabolic cofactors nicotinamide and NAD+ to transcriptional regulation via ERM-BP and provide the first mechanistic insights into Entamoeba encystation.
Highlights
Modulation of gene expression plays a crucial role during stage conversion in all organisms (Gomez et al, 2010; Morf et al, 2010; Kramer, 2012)
The Encystation Regulatory Motif-Binding Protein (ERM-BP) has a nicotinamidase domain; we identified that NAD+ levels increase during encystation and mediate ERM-BP binding to DNA, and that increased NAD+ augments encystation efficiency
We identified a novel transcription factor ERM-BP as a key regulator of stage conversion in the protozoan parasite Entamoeba
Summary
Modulation of gene expression plays a crucial role during stage conversion in all organisms (Gomez et al, 2010; Morf et al, 2010; Kramer, 2012). Regulated genes can be controlled by multiple pathways including transcriptional control, post-transcriptional modification, and RNA transport, stability, or translation efficiency (Day and Tuite, 1998; Spitz and Furlong, 2012). Transcriptional regulatory networks have been extensively studied in model organisms, our understanding of transcriptional regulation in protozoan parasites is relatively limited. Studies in Plasmodium (Cai et al, 2012), Toxoplasma (Bougdour et al, 2008; Joyce et al, 2013), Giardia (Einarsson et al, 2015), Trypanosome (Clayton, 2014) and Entamoeba (Ehrenkaufer et al, 2013) hint at unique pathways that are exploited by parasitic protozoa to regulate their developmental cascades.
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