Association of Radial Artery Access with Reduced Incidence of Acute Kidney Injury.

Objectives: To determine if radial artery (RA) access compared with femoral artery (FA) access for percutaneous coronary intervention (PCI) is associated with a lower incidence of acute kidney injury (AKI). Background: AKI results in substantial morbidity and cost following PCI. Prior studies comparing the occurrence of AKI associated with radial artery (RA) versus femoral artery (FA) access have mixed results. Methods: Using a large state-wide database, 14,077 patients (8,539 with RA and 5,538 patents with FA access) were retrospectively compared to assess the occurrence of AKI following PCI. To reduce selection bias and balance clinical data across the two groups, a novel machine learning method called a Generalized Boosted Model was conducted on the arterial access site generating a weighted propensity score for each variable. A logistic regression analysis was then performed on the occurrence of AKI following PCI using the weighted propensity scores from the Generalized Boosted Model. Results: As shown in other studies, multiple variables were associated with an increase in AKI after PCI. Only RA access (OR 0.82; 95% CI 0.74-0.91) and male gender (OR 0.80; 95% CI 0.72-0.89) were associated with a lower occurrence of AKI. Based on the calculated Mehran scores, patients were stratified into groups with an increasing risk of AKI. RA access was consistently found to have a lower risk of AKI compared with FA access across these groups of increasing risk. Conclusions: Compared with FA access, RA access is associated with an 18% lower rate of AKI following PCI. This effect was observed among different levels of risk for developing AKI. Although developed from a retrospective analysis, this study supports the use of RA access when technically possible in a diverse group of patients.

Functional characterization of the guanine nucleotide exchange factor (GEF) motif of GIV protein reveals a threshold effect in signaling.

Heterotrimeric G proteins are critical signal-transducing molecules controlled by a complex network of regulators. GIV (a.k.a. Girdin) is a unique component of this network and a nonreceptor guanine nucleotide exchange factor (GEF) that functions via a signature motif. GIV's GEF motif is involved in the regulation of critical biological processes such as phosphoinositide 3 kinase (PI3K)-Akt signaling, actin cytoskeleton remodeling, cell migration, and cancer metastasis. Here we investigated how the GEF function of GIV affects the wiring of its signaling pathway to shape different biological responses. Using a structure-guided approach, we designed a battery of GIV mutants with different Gαi-binding and -activating properties and used it to dissect the specific impact of changes in GIV's GEF activity on several cellular responses. In vivo signaling assays revealed a threshold effect of GEF activity for the activation of Akt by GIV in different cell lines and by different stimuli. Akt signaling is minimal at low GEF activity and is sharply increased to reach a maximum above a threshold of GEF activity, suggesting that GIV is a critical signal amplifier and that activation of Akt is ultrasensitive to changes in GIV's GEF activity. A similar threshold dependence was observed for other biological functions promoted by GIV such as remodeling of the actin cytoskeleton and cell migration. This functional characterization of GIV's GEF motif provides insights into the molecular interactions between nonreceptor GEFs and G proteins and the mechanisms that govern this signal transduction pathway.

Transcatheter Mitral Valve Therapies in Patients with Mitral Annular Calcification.

Mitral annular calcification is a chronic process involving degeneration and calcium deposition within the fibrous skeleton of the mitral valve annulus, which can lead to mitral valve dysfunction. It can be asymptomatic, or it can have pathologic sequelae leading to cardiovascular morbidity and mortality. Mitral annular calcification is increasingly recognized with the advancement of diagnostic imaging modalities, especially in an era with a growing elderly population. Its presence poses considerable challenges in terms of surgical and transcatheter management. Multiple surgical and transcatheter techniques have been developed to overcome these challenges. New transcatheter technologies are under investigation to tackle this problem.

G Protein binding sites on Calnuc (nucleobindin 1) and NUCB2 (nucleobindin 2) define a new class of G(alpha)i-regulatory motifs.

Heterotrimeric G proteins are molecular switches modulated by families of structurally and functionally related regulators. GIV (Gα-interacting vesicle-associated protein) is the first non-receptor guanine nucleotide exchange factor (GEF) that activates Gα(i) subunits via a defined, evolutionarily conserved motif. Here we found that Calnuc and NUCB2, two highly homologous calcium-binding proteins, share a common motif with GIV for Gα(i) binding and activation. Bioinformatics searches and structural analysis revealed that Calnuc and NUCB2 possess an evolutionarily conserved motif with sequence and structural similarity to the GEF sequence of GIV. Using in vitro pulldown and competition assays, we demonstrate that this motif binds preferentially to the inactive conformation of Gα(i1) and Gα(i3) over other Gα subunits and, like GIV, docks onto the α3/switch II cleft. Calnuc binding was impaired when Lys-248 in the α3 helix of Gα(i3) was replaced with M, the corresponding residue in Gα(o), which does not bind to Calnuc. Moreover, mutation of hydrophobic residues in the conserved motif predicted to dock on the α3/switch II cleft of Gα(i3) impaired the ability of Calnuc and NUCB2 to bind and activate Gα(i3) in vitro. We also provide evidence that calcium binding to Calnuc and NUCB2 abolishes their interaction with Gα(i3) in vitro and in cells, probably by inducing a conformational change that renders the Gα(i)-binding residues inaccessible. Taken together, our results identify a new type of Gα(i)-regulatory motif named the GBA motif (for Gα-binding and -activating motif), which is conserved across different proteins throughout evolution. These findings provide the structural basis for the properties of Calnuc and NUCB2 binding to Gα subunits and its regulation by calcium ions.