Browsing by Subject "Veterinary Physiology"
Now showing 1 - 4 of 4
- Results Per Page
- Sort Options
Item Differential Gene Expression Profiling in a Small Animal Model of Progressively Pacing-Induced Heart Failure(2006-06-01) Selby, Donald Evan; Stephen R. Grant; Patricia A. Gwirtz; Dan DimitrijevichDonald Evan Selby, Differential Gene Expression Profiling in a Small Animal Model of Progressively Pacing-Induced Heart Failure. Doctor of Philosophy (Biomedical Sciences), July 2006, 235 pp, 4 tables, 35 illustrations, references, 328 titles. Pacing induced tachycardia (PIT), in mammals, is known to cause a change from normal heart function to early left ventricular dysfunction. Progression to heart failure in experimental animals, such as dogs, pigs, and sheep, takes place in a relatively short period of time compared to the disease development observed in humans. Due to the cost and nature of using such animals, there is a need for a small animal model of PIT, which would delineate the etiology of the disease state by impairing the systolic function. The mode of action of overpacing inducement of cardiomyopathy, as the data suggests, may be through a sarcomere stretch sensor and its length-dependent signaling mechanism. In this study, an internal electrical-overpacing of an isogenic rabbit strain over a 52-day period was used to initiate a pathology consistent with human CHF. The data presented demonstrated that PIT causes alterations in the systolic ability of the heart, observed as reduced fractional shortening of the heart. This is seen in changes of the message pool population for proteins of the contractile architecture. Initially the heart is being paced rapidly and therefore there is insufficient time to get blood into the chamber. Thus, the data suggests that a mechanical stretch sensor is the process by which overpacing the heart leads to changes in gene expression which ultimately cause a compounding cellular condition which exists during heart failure. The data shows that there are gene isoform ratio changes that occur as the disease develops these include changes in differential expression of cardiac titin alternative splicing isoforms. The data suggests that there is also isoform switching occurring with alternative splicing of the gene encoding for SERCA2a, the probe 1587641_at shows a moderate decrease in expression and using BLAST for this probe this sequence is homologous to an alternative splicing variant of SERCA2a of the rabbit accession number J04703. The data shows that ferritin heavy chain also has an alternative splicing variant that are differentially regulated, this dysregulation of the isoform ratio may be linked to ADAMSTS1, a disintegrin and metalloproteinase isoform 1, which is seen to be downregulated in the data, these play a role in negative regulation of cellular proliferation. In addition to these detected isoform changes in the ratios of alternative splice variants changes are seen in genes linked to sarcomere integrity such as dystrophin probe 1582958_at is significantly increased in its expression, also integrin beta-1 probe 1584175)at shows a marginal increase in expression. The protease calpain probe 1604384)at, which uses a substrate the aforementioned integrin, dystrophin, and titin is also significantly upregulated in the data. Interestingly calpastatin, probe 1591603_at the inhibitor of calpain is marginally increased in its expression. Only recently has titin become to be appreciated as the protein that is responsible for the Frank Starling law as it undergoes an isoform ratio change as heart failure develops. These changes are initially caused by changes in ion concentration and stress upon the contractile proteins but as seen in the study, leads to altered gene expression. In this model, these gene alterations lead to diastolic dysfunction and the compounded problems constitute heart failure. This work shows that heart failure induced by over-pacing creates physical demands upon the framework of the heart and these physical stresses are transmitted through mechanical sensors leading to differential expression of the message pools for proteins involved in the way the heart contracts, and fills upon relaxation which ultimately ends in a heart that can do neither, thus leading to death.Item Functional Heterogeneity in Canine Coronary Resistance Arteries(1994-06-01) Parker, James Bruce; Peter B. Raven; Patricia A. Gwirtz; James CaffreyParker, James B., Functional Heterogeneity in Canine Coronary Resistance Arteries. Doctor of Philosophy (Biomedical Sciences), June, 1994, 89 pages, 21 illustrations, bibliography, 82 titles. Two thirds of the coronary vascular resistance resides in the smallest arteries and investigators have hypothesized that they may respond differently to endogenous vasoactive substances. The arterial responses to norepinephrine, acetylcholine, and adenosine were evaluated in large ([greater than] 700 μm, n=24), intermediate (400 600 μm, n=24), and small arteries (μm, n=24). Maximal vessel lumen diameter (Dmax) was determined in CA++ free medium. A reference diameter (84 ± 4.3% of Dmax) was established by re-equilibration in medium containing 2.0 mM Ca++. Arterial maximal responses as a percentage of Dmax to norepinephrine, acetylcholine, and adenosine are given in table 1: Table 1; Large % of Dmax; Inter. % of Dmax; Small % of Dmax; Norepinephrine; 41 ± 2.3; 50 ± 4.2; 83 ± 2.4; Acetylcholine; 96 ± 2.7; 88 ± 3.9; 78 ± 1.9; Adenosine; 71 ± 1.8; 81 ± 4.2; 96 ± 1.4. The sensitivity of canine coronary arteries to norepinephrine, acetylcholine, and adenosine in terms of ED50’s are given in table 2: Table 2; Agonists; Large ED50 μM; Inter. ED50 μM; Small ED50 μM; Norepinephrine; 0.037 ± 0.002; 0.078 ± 0.004; no response; acetylcholine; 0.028 ± 0.003; 0.087 ± 0.005; 0.309 ± 0.03; Adenosine; 0.295 ± 0.002; 0.095 ± 0.004; 0.035 ± 0.03. These data indicate that canine arterial responses to the native agonists norepinephrine, acetylcholine, and adenosine are heterogeneous and that neural control predominates in the larger “transport” arteries while local control predominates in the smaller “distributive” arteries. Responses of small and intermediate isolated canine coronary arteries (lumen diameter 147±42μm, and 531±37μm respectively) to norepinephrine were evaluated after pharmacological or mechanical interruption of endothelial relaxing activity. Following with the nitric oxide synthase inhibitor N-Nitro-L-Arginine Methylester (L-NAME) 10^-5 M the small and intermediate vessels spontaneously constricted to 73±4.1% of Dmax indicating a significant basal release of nitric oxide. After L-NAME or endothelial disruption graded additions of norepinephrine now reduced the vessel diameter in previously unresponsive small arteries. These data suggest that the weak and equivocal response of coronary resistance arteries to norepinephrine results from the competitive dilatory influence of endothelial derived nitric oxide production and not to the absence of norepinephrine receptors.Item Role of Adenosine in Acute Hibernation of Guinea-Pig Myocardium(1995-08-01) Gao, Zhi-Ping; H. Fred Downey; James L. Caffrey; Patricia A. GwirtzGao, Zhi-Ping, Role of Adenosine in Acute Hibernation of Guinea-Pig Myocardium Doctor of Philosophy (Biomedical Sciences), August, 1995; 111 pp; 3 tables; 15 figures, bibliography, 158 titles. Myocardial hibernation is a state of depressed contractile function and energy demand during chronic ischemia. When coronary flow is restored, depressed contractile function can partially or completely recover to the pre-ischemic level, and ischemic injury of the myocardium in not evident. This project tested the hypothesis that endogenous adenosine mediates hibernation in guinea-pig myocardium. Isolated working guinea-pig hearts, perfused with glucose fortified Krebs-Henseleit buffer, were subjected to global low-flow ischemia. Left ventricular performance and cytosolic energy level were assessed. Lactate and purine nucleotides were measured in venous effluent. Heart were perfused with [U-14C]glucose to investigate the role of adenosine on glucose metabolism in myocardium. Left ventricular function in untreated hearts decreased by 80% and remained stable during ischemia, and completely recovered upon reperfusion. Neither adenosine receptor blockade with 8-p-sulfophenyl theophylline (8-SPT; 20 μM) nor ecto 5’-nucleotidase inhibitor αβ-methylene adenosine 5’-diphosphonate (AOPCP; 50μM) affected left ventricular function either ischemia or during reperfusion. Cytosolic energy level fell by 67% at 10 min ischemia in untreated hearts, but subsequently recovered to the pre-ischemic level despite continued ischemia. Adenosine receptor blockade increased cytosolic energy level at 10 min ischemia relative to untreated hearts, but blunted the subsequent rebound of phosphorylation potential. Moreover, 8-SPT doubled ischemic lactate release. Adenosine receptor blockade also increased glucose uptake during pre-ischemia and hypoperfusion, but did not stimulate glucose oxidation. Crossover plots of glycolytic intermediates revealed that phosphofructokinase, a key rate-controlling step in glycolysis, was activated by adenosine receptor blockade in both pre-ischemic and hibernating myocardium. We conclude that 1) activation of adenosine receptors results in recovery of cytosolic energy level of moderately ischemic working myocardium, but this energetic recover is not solely responsible for post-ischemic contractile recovery; 2) endogenous adenosine attenuates anaerobic glycolysis during myocardial hibernation by blunting phosphofructokinase activity.Item The Effects of Hyperlipidemia and Hypoglycemia on Myocardial Contractile Function and Oxygen Utilization During Coronary Hypoperfusion(1998-08-01) Hart, Bradley Joe; Downey, H. Fred; Mallet, Robert T.; Smith, Michael B.Hart, Bradley Joe, The Effects of Hyperlipidemia and Hypoglycemia on Myocardial Contractile Function and Oxygen Utilization During Coronary Hypoperfusion Master of Science (Biomedical Sciences), August, 1998, 85 pp., 1 table, 5 figures, references, 51 titles. This study was designed to determine the effects of elevated fatty acid and lowered glucose concentrations on myocardial contractile function and substrate selection during hypoperfusion. Coronary perfusion pressure (CPP) was lowered in the left anterior descending coronary artery of open-chest anesthetized dogs. Glucose uptake, fatty acid uptake, and percent segment shortening (%SS) were determined with normal arterial FFA concentrations (Group 1) or with elevated concentrations (Groups 2 and 3). When glucose was removed by dialysis in Group 3, FFA uptake increased and glucose uptake decreased relative to Group 1 at 40 mmHg CPP (p [less than] 0.05). Oxygen consumption significantly increased (p [less than] 0.05); however, %SS was unchanged. Thus, although the myocardium switches from fatty acid to glucose metabolism to increase oxygen utilization efficiency during hypoperfusion, blocking this switch does not contribute to a further decrease in myocardial contractile function.