Ray, William K.Potters, Mark B.Haile, January D.Kennelly, Peter J.2017-09-202017-09-202015-05-15Ray, W.K.; Potters, M.B.; Haile, J.D.; Kennelly, P.J. Activation of SsoPK4, an Archaeal eIF2α Kinase Homolog, by Oxidized CoA. Proteomes 2015, 3, 89-116.http://hdl.handle.net/10919/79236The eukaryotic protein kinase (ePK) paradigm provides integral components for signal transduction cascades throughout nature<i>.</i> However, while so-called typical ePKs permeate the <i>Eucarya</i> and <i>Bacteria,</i> atypical ePKs dominate the kinomes of the <i>Archaea</i>. Intriguingly, the catalytic domains of the handful of deduced typical ePKs from the archaeon<i> Sulfolobus solfataricus</i> P2 exhibit significant resemblance to the protein kinases that phosphorylate translation initiation factor 2α (eIF2α) in response to cellular stresses. We cloned and expressed one of these archaeal eIF2α protein kinases, SsoPK4. SsoPK4 exhibited protein-serine/threonine kinase activity toward several proteins, including the <i>S. solfataricus</i> homolog of eIF2α, aIF2α. The activity of SsoPK4 was inhibited<i> in vitro </i>by 3ʹ,5ʹ-cyclic AMP (K_i of ~23 µM) and was activated by oxidized Coenzyme A, an indicator of oxidative stress in the <i>Archaea. </i>Activation enhanced the apparent affinity for protein substrates, K_m, but had little effect on V_max. Autophosphorylation activated SsoPK4 and rendered it insensitive to oxidized Coenzyme A.application/pdfenCreative Commons Attribution 4.0 Internationalprotein phosphorylationstress signalingcrenarchaeaArticle - Refereed2017-09-20https://doi.org/10.3390/proteomes3020089