With heart failure leading the cause of death in the USA (Hunt), biomedical research is fundamental to advance medical treatments for cardiovascular diseases. Animal models that mimic human cardiac disease, such as myocardial infarction (MI) and ischemia-reperfusion (IR) that induces heart failure as well as pressure-overload (transverse aortic constriction) that induces cardiac hypertrophy and heart failure (Goldman and Tarnavski), are useful models to study cardiovascular disease. In particular, myocardial ischemia (MI) is a leading cause for cardiovascular morbidity and mortality despite controlling certain risk factors such as arteriosclerosis and treatments via surgical intervention (Thygesen). Furthermore, an acute loss of the myocardium following myocardial ischemia (MI) results in increased loading conditions that induces ventricular remodeling of the infarcted border zone and the remote non-infarcted myocardium. Myocyte apoptosis, necrosis and the resultant increased hemodynamic load activate multiple biochemical intracellular signaling that initiates LV dilatation, hypertrophy, ventricular shape distortion, and collagen scar formation. This pathological remodeling and failure to normalize the increased wall stresses results in progressive dilatation, recruitment of the border zone myocardium into the scar, and eventually deterioration in myocardial contractile function (i.e. heart failure). The progression of LV dysfunction and heart failure in rats is similar to that observed in patients who sustain a large myocardial infarction, survive and subsequently develops heart failure (Goldman). The acute myocardial infarction (AMI) model in rats has been used to mimic human cardiovascular disease; specifically used to study cardiac signaling mechanisms associated with heart failure as well as to assess the contribution of therapeutic strategies for the treatment of heart failure. The method described in this report is the rat model of acute myocardial infarction (AMI). This model is also referred to as an acute ischemic cardiomyopathy or ischemia followed by reperfusion (IR); which is induced by an acute 30-minute period of ischemia by ligation of the left anterior descending artery (LAD) followed by reperfusion of the tissue by releasing the LAD ligation (Vasilyev and McConnell). This protocol will focus on assessment of the infarct size and the area-at-risk (AAR) by Evan's blue dye and triphenyl tetrazolium chloride (TTC) following 4-hours of reperfusion; additional comments toward the evaluation of cardiac function and remodeling by modifying the duration of reperfusion, is also presented. Overall, this AMI rat animal model is useful for studying the consequence of a myocardial infarction on cardiac pathophysiological and physiological function. 2. All surgical instruments are to be sterilized with a hot bead sterilizer before surgery (and in between individual rat surgeries). These instruments include: surgical scissors (2), forceps (1), curved forceps (1), needle holder (2), and a chest rectract...
Gravin, an A-kinase anchoring protein, targets protein kinase A (PKA), protein kinase C (PKC), calcineurin and other signaling molecules to the beta2-adrenergic receptor (β2-AR). Gravin mediates desensitization/resensitization of the receptor by facilitating its phosphorylation by PKA and PKC. The role of gravin in β-AR mediated regulation of cardiac function is unclear. The purpose of this study was to determine the effect of acute β-AR stimulation on cardiac contractility in mice lacking functional gravin. Using echocardiographic analysis, we observed that contractility parameters such as left ventricular fractional shortening and ejection fraction were increased in gravin mutant (gravin-t/t) animals lacking functional protein compared to wild-type (WT) animals both at baseline and following acute isoproterenol (ISO) administration. In isolated gravin-t/t cardiomyocytes, we observed increased cell shortening fraction and decreased intracellular Ca2+ in response to 1 µmol/L ISO stimulation. These physiological responses occurred in the presence of decreased β2-AR phosphorylation in gravin-t/t hearts, where PKA-dependent β2-AR phosphorylation has been shown to lead to receptor desensitization. cAMP production, PKA activity and phosphorylation of phospholamban and troponin I was comparable in WT and gravin-t/t hearts both with and without ISO stimulation. However, cardiac myosin binding protein C (cMyBPC) phosphorylation site at position 273 was significantly increased in gravin-t/t versus WT hearts, in the absence of ISO. Additionally, the cardioprotective heat shock protein 20 (Hsp20) was significantly more phosphorylated in gravin-t/t versus WT hearts, in response to ISO. Our results suggest that disruption of gravin’s scaffold mediated signaling is able to increase baseline cardiac function as well as to augment contractility in response to acute β-AR stimulation by decreasing β2-AR phosphorylation and thus attenuating receptor desensitization and perhaps by altering PKA localization to increase the phosphorylation of cMyBPC and the nonclassical PKA substrate Hsp20.
It remains a challenge to achieve the stable and long‐term expression (in human cell lines) of a previously engineered hybrid enzyme [triple‐catalytic (Trip‐cat) enzyme‐2; Ruan KH, Deng H & So SP (2006) Biochemistry45, 14003–14011], which links cyclo‐oxygenase isoform‐2 (COX‐2) to prostacyclin (PGI2) synthase (PGIS) for the direct conversion of arachidonic acid into PGI2 through the enzyme’s Trip‐cat functions. The stable upregulation of the biosynthesis of the vascular protector, PGI2, in cells is an ideal model for the prevention and treatment of thromboxane A2 (TXA2)‐mediated thrombosis and vasoconstriction, both of which cause stroke, myocardial infarction, and hypertension. Here, we report another case of engineering of the Trip‐cat enzyme, in which human cyclo‐oxygenase isoform‐1, which has a different C‐terminal sequence from COX‐2, was linked to PGI2 synthase and called Trip‐cat enzyme‐1. Transient expression of recombinant Trip‐cat enzyme‐1 in HEK293 cells led to 3–5‐fold higher expression capacity and better PGI2‐synthesizing activity as compared to that of the previously engineered Trip‐cat enzyme‐2. Furthermore, an HEK293 cell line that can stably express the active new Trip‐cat enzyme‐1 and constantly synthesize the bioactive PGI2 was established by a screening approach. In addition, the stable HEK293 cell line, with constant production of PGI2, revealed strong antiplatelet aggregation properties through its unique dual functions (increasing PGI2 production while decreasing TXA2 production) in TXA2 synthase‐rich plasma. This study has optimized engineering of the active Trip‐cat enzyme, allowing it to become the first to stably upregulate PGI2 biosynthesis in a human cell line, which provides a basis for developing a PGI2‐producing therapeutic cell line for use against vascular diseases.
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