3D Domain Swapping Dimerization of the Receiver Domain of Cytokinin Receptor CRE1 From Arabidopsis thaliana and Medicago truncatula

Cytokinins are phytohormones regulating many biological processes that are vital to plants. CYTOKININ RESPONSE1 (CRE1), the main cytokinin receptor, has a modular architecture composed of a cytokinin-binding CHASE (Cyclases/Histidine kinases Associated Sensory Extracellular) domain, followed by a transmembrane fragment, an intracellular histidine kinase (HK) domain, and a receiver domain (REC). Perception of cytokinin signaling involves (i) a hormone molecule binding to the CHASE domain, (ii) CRE1 autophosphorylation at a conserved His residue in the HK domain, followed by a phosphorelay to (iii) a conserved Asp residue in the REC domain, (iv) a histidine-containing phosphotransfer protein (HPt), and (v) a response regulator (RR). This work focuses on the crystal structures of the REC domain of CRE1 from the model plant Arabidopsis thaliana and from the model legume Medicago truncatula. Both REC domains form tight 3D-domain-swapped dimers. Dimerization of the REC domain agrees with the quaternary assembly of the entire CRE1 but is incompatible with a model of its complex with HPt, suggesting that a considerable conformational change should occur to enable the signal transduction. Indeed, phosphorylation of the REC domain can change the HPt-binding properties of CRE1, as shown by functional studies.

Integrin degradation during postmortem cold storage and the level of drip loss in pork

Integrins are a family of transmembrane adhesion proteins. An integrin molecule is composed of two subunits called α and β, each of which has a large extracellular domain, a transmembrane fragment, and a short cytoplasmic sequence. The main function of integrin is to bind extracellular matrix proteins and the skeletal muscle cell membrane. In addition, integrin as a membrane receptor is involved in signal transduction and cell response to microenvironmental signals, by relaying information about the structure and composition of the cell environment. Postmortem integrin degradation has been the subject of several studies, mainly in pork, where the mechanisms of postmortem integrin degradation are not completely understood. Therefore, the aim of the study was to present current knowledge on the role of integrin in postmortem drip loss in pork. Research to date has shown that postmortem integrin degradation could contribute to the formation of drip channels between the cell body and cell membrane of muscle fibers, which increases the drip loss from pork.

Crystal structure of the complete integrin αVβ3 ectodomain plus an α/β transmembrane fragment

We determined the crystal structure of 1TM-αVβ3, which represents the complete unconstrained ectodomain plus short C-terminal transmembrane stretches of the αV and β3 subunits. 1TM-αVβ3 is more compact and less active in solution when compared with ΔTM-αVβ3, which lacks the short C-terminal stretches. The structure reveals a bent conformation and defines the α–β interface between IE2 (EGF-like 2) and the thigh domains. Modifying this interface by site-directed mutagenesis leads to robust integrin activation. Fluorescent lifetime imaging microscopy of inactive full-length αVβ3 on live cells yields a donor–membrane acceptor distance, which is consistent with the bent conformation and does not change in the activated integrin. These data are the first direct demonstration of conformational coupling of the integrin leg and head domains, identify the IE2–thigh interface as a critical steric barrier in integrin activation, and suggest that inside-out activation in intact cells may involve conformational changes other than the postulated switch to a genu-linear state.