Evolved to be active: sulfate ions define substrate recognition sites of CK2alpha and emphasise its exceptional role within the CMGC family of eukaryotic protein kinases

CK2alpha is the catalytic subunit of protein kinase CK2 and a member of the CMGC family of eukaryotic protein kinases like the cyclin-dependent kinases, the MAP kinases and glycogen-synthase kinase 3. We present here a 1.6 A resolution crystal structure of a fully active C-terminal deletion mutant of human CK2alpha liganded by two sulfate ions, and we compare this structure systematically with representative structures of related CMGC kinases. The two sulfate anions occupy binding pockets at the activation segment and provide the structural basis of the acidic consensus sequence S/T-D/E-X-D/E that governs substrate recognition by CK2. The anion binding sites are conserved among those CMGC kinases. In most cases they are neutralized by phosphorylation of a neighbouring threonine or tyrosine side-chain, which triggers conformational changes for regulatory purposes. CK2alpha, however, lacks both phosphorylation sites at the activation segment and structural plasticity. Here the anion binding sites are functionally changed from regulation to substrate recognition. These findings underline the exceptional role of CK2alpha as a constitutively active enzyme within a family of strictly controlled protein kinases.     

Do we consent to rules of consent and confidentiality?

Confidentiality and informed consent are important concepts enabling the sharing of sensitive data. In a paper on this topic of this issue, Williams and Pigeot ( 2017 ) discuss that these have to be balanced with openness to ensure research standards. In this opinion paper, we give some background on how the paper by Williams and Pigeot evolved, reflect on their concepts, and provide some examples of the application of these concepts in various settings relevant to biostatisticians working in health research.     

Structures of dimeric nonstandard nucleotide triphosphate pyrophosphatase from Pyrococcus horikoshii OT3: functional significance of interprotomer conformational changes

Nonstandard nucleotide triphosphate pyrophosphatase (NTPase) can efficiently hydrolyze nonstandard purine nucleotides in the presence of divalent cations. The crystal structures of the NTPase from Pyrococcus horikoshii OT3 (PhNTPase) have been determined in two unliganded forms and in three liganded forms with inosine 5′-monophosphate (IMP), ITP and Mn²⁺, which visualize the recognition of these ligands unambiguously. The overall structure of PhNTPase is similar to that of previously reported crystal structures of the NTPase from Methanococcus jannaschii and the human ITPase. They share a similar protomer folding with two domains and a similar homodimeric quaternary structure. The dimeric interface of NTPase is well conserved, and the dimeric state might be important to constitute the active site of this enzyme. A conformational analysis of the five snapshots of PhNTPase structures using the multiple superposition method reveals that IMP, ITP and Mn²⁺ bind to the active site without inducing large local conformational changes, indicating that a combination of interdomain and interprotomer rigid-body shifts mainly describes the conformational change of PhNTPase. The interdomain and interprotomer conformations of the ITP liganded form are essentially the same as those observed in the unliganded form 1, indicating that ITP binding to PhNTPase in solution may follow the selection mode in which ITP binds to the subunit that happens to be in the conformation observed in the unliganded form 1. In contrast to the human ITPase inducing a large domain closure upon ITP binding, the interdomain active site cleft is generally closed in PhNTPase and only the IMP binding form shows a remarkable domain opening by 14° only in the B subunit. The interprotomer rigid-body rotation of PhNTPase has a tendency to keep the dimeric 2-fold symmetry, which is also true in human ITPase, thereby suggesting its relevance to the positive cooperativity of the dimeric NTPases. The exception of this rule is observed in the IMP liganded form in which the dimeric 2-fold symmetry is broken by a 3° interprotomer rotation in an unusual direction. A combination of the exceptional interdomain and interprotomer relocations is most likely the reason for the observed asymmetric IMP binding that might be necessary for PhNTPase to release the reaction product IMP.