The lipid ties of α1-antitrypsin: Structural and functional aspects.

α1-antitrypsin (AAT) is an acute-phase protein that functions as an inhibitor of serine proteases, such as neutrophil elastase. A significant body of evidence shows that AAT has a pivotal role in protecting tissues from neutrophil-induced damage, preserving endothelial function, and improving outcomes of cardiovascular and cerebrovascular diseases, though the mechanism of its activity is not fully elucidated. In terms of several significant anti-inflammatory and immunomodulatory properties, AAT's capacity to inhibit elastase has been determined to be non-essential. With the discovery of a role for diverse binding partners in AAT biology, it is intriguing to learn that AAT attaches to cholesterol, fatty acids, lipid rafts, and lipoproteins and conformational changes in its hydrophobic binding site affect its activity. The complex formation of fatty acids or lipoproteins with native or modified AAT impacts its protease inhibitory action as well as its anti-inflammatory properties. As such, AAT-enriched HDL particles exhibit improved anti-inflammatory action. These findings contribute to our understanding of AAT's mechanism of action and may provide a fresh platform for investigating the therapeutic significance of AAT therapy in an informed manner outside of genetic AAT deficiency.

Dock10 Regulates Cardiac Function under Neurohormonal Stress.

Dedicator of cytokinesis 10 (Dock10) is a guanine nucleotide exchange factor for Cdc42 and Rac1 that regulates the JNK (c-Jun N-terminal kinase) and p38 MAPK (mitogen-activated protein kinase) signaling cascades. In this study, we characterized the roles of Dock10 in the myocardium. In vitro: we ablated Dock10 in neonatal mouse floxed Dock10 cardiomyocytes (NMCMs) and cardiofibroblasts (NMCFs) by transduction with an adenovirus expressing Cre-recombinase. In vivo, we studied mice in which the Dock10 gene was constitutively and globally deleted (Dock10 KO) and mice with cardiac myocyte-specific Dock10 KO (Dock10 CKO) at baseline and in response to two weeks of Angiotensin II (Ang II) infusion. In vitro, Dock10 ablation differentially inhibited the α-adrenergic stimulation of p38 and JNK in NMCM and NMCF, respectively. In vivo, the stimulation of both signaling pathways was markedly attenuated in the heart. The Dock10 KO mice had normal body weight and cardiac size. However, echocardiography revealed mildly reduced systolic function, and IonOptix recordings demonstrated reduced contractility and elevated diastolic calcium levels in isolated cardiomyocytes. Remarkably, Dock10 KO, but not Dock10 CKO, exaggerated the pathological response to Ang II infusion. These data suggest that Dock10 regulates cardiac stress-related signaling. Although Dock10 can regulate MAPK signaling in both cardiomyocytes and cardiofibroblasts, the inhibition of pathological cardiac remodeling is not apparently due to the Dock10 signaling in the cardiomyocyte.

Plekhm2 acts as an autophagy modulator in murine heart and cardiofibroblasts.

Plekhm2 is a protein regulating endosomal trafficking and lysosomal distribution. We recently linked a recessive inherited mutation in PLEKHM2 to a familial form of dilated cardiomyopathy and left ventricular non-compaction. These patients' primary fibroblasts exhibited abnormal lysosomal distribution and autophagy impairment. We therefore hypothesized that loss of PLEKHM2 impairs cardiac function via autophagy derangement. Here, we characterized the roles of Plekhm2 in the heart using global Plekhm2 knockout (PLK2-KO) mice and cultured cardiac cells. Compared to littermate controls (WT), young PLK2-KO mice exhibited no difference in heart function or autophagy markers but demonstrated higher basal AKT phosphorylation. Older PLK2-KO mice had body and heart growth retardation and increased LC3II protein levels. PLK2-KO mice were more vulnerable to fasting and, interestingly, impaired autophagy was noted in vitro, in Plekhm2-deficient cardiofibroblasts but not in cardiomyocytes. PLK2-KO hearts appeared to be less sensitive to pathological hypertrophy induced by angiotensin-II compared to WT. Our findings suggest a role of Plekhm2 in murine cardiac autophagy. Plekhm2 deficiency impaired autophagy in cardiofibroblasts, but the autophagy in cardiomyocytes is not critically dependent on Plekhm2. The absence of Plekhm2 in mice appears to promote compensatory mechanism(s) enabling the heart to manage angiotensin-II-induced stress without detrimental consequences.