Myocardial Infarction Alters Adaptation of the Tethered Mitral Valve

BACKGROUND

In patients with myocardial infarction (MI), leaflet tethering by displaced papillary muscles induces mitral regurgitation (MR), which doubles mortality. Mitral valves (MVs) are larger in such patients but fibrosis sets in counterproductively. The investigators previously reported that experimental tethering alone increases mitral valve area in association with endothelial-to-mesenchymal transition.

OBJECTIVES

The aim of this study was to explore the clinically relevant situation of tethering and MI, testing the hypothesis that ischemic milieu modifies mitral valve adaptation.

METHODS

Twenty-three adult sheep were examined. Under cardiopulmonary bypass, the papillary muscle tips in 6 sheep were retracted apically to replicate tethering, short of producing MR (tethered alone). Papillary muscle retraction was combined with apical MI created by coronary ligation in another 6 sheep (tethered plus MI), and left ventricular remodeling was limited by external constraint in 5 additional sheep (left ventricular constraint). Six sham-operated sheep were control subjects. Diastolic mitral valve surface area was quantified by 3-dimensional echocardiography at baseline and after 58 ± 5 days, followed by histopathology and flow cytometry of excised leaflets.

RESULTS

Tethered plus MI leaflets were markedly thicker than tethered-alone valves and sham control subjects. Leaflet area also increased significantly. Endothelial-to-mesenchymal transition, detected as α-smooth muscle actin-positive endothelial cells, significantly exceeded that in tethered-alone and control valves. Transforming growth factor-β, matrix metalloproteinase expression, and cellular proliferation were markedly increased. Uniquely, tethering plus MI showed endothelial activation with vascular adhesion molecule expression, neovascularization, and cells positive for CD45, considered a hematopoietic cell marker. Tethered plus MI findings were comparable with external ventricular constraint.

CONCLUSIONS

MI altered leaflet adaptation, including a profibrotic increase in valvular cell activation, CD45-positive cells, and matrix turnover. Understanding cellular and molecular mechanisms underlying leaflet adaptation and fibrosis could yield new therapeutic opportunities for reducing ischemic MR.

Twelve-Hour Hypothermic Machine Perfusion for Donor Heart Preservation Leads to Improved Ultrastructural Characteristics Compared to Conventional Cold Storage

BACKGROUND Hypothermic machine perfusion of donor hearts has the theoretical advantage of continuous aerobic metabolism and washes out toxic metabolic byproducts. Here, we studied the effect of hypothermic machine perfusion on cardiac myocyte integrity when hearts are preserved for longer ischemic times (12 hours). MATERIAL AND METHODS Pig hearts were harvested and stored in Celsior® solution for 12 hours using either conventional cold storage on ice (12 h CS, n=3) or pulsatile perfusion with the Paragonix Sherpa Perfusion™ Cardiac Transport System at different flow rates (12 h PP, n=3 or 12 h PP low flow, n=2). After cold preservation, hearts were reperfused using an LV isovolumic Langendorff system. Controls (n=3) were reperfused immediately after organ harvest. Biopsies were taken from the apex of the left ventricle before storage, after storage and after reperfusion to measure ATP and endothelin-1 content in the tissue. TUNEL staining for signs of apoptosis and electron microscopy of the donor hearts were performed. RESULTS 12 h PP hearts showed significantly more weight gain than 12 h CS and controls after preservation. Pulsatile perfused hearts showed less ATP depletion, lower endothelin-1 levels and less apoptosis after preservation compared to CS. Electron microscopy showed damaged muscle fibers, endothelial cell rupture, and injury of mitochondria in the 12 h CS group, while machine perfusion could preserve the cell structures. CONCLUSIONS Hypothermic machine perfusion of donor hearts can preserve the cell structures better than conventional cold storage in prolonged ischemic times. Hypothermic pulsatile perfusion may therefore enable longer preservation times of donor hearts. Whether this method is able to avoid primary graft failure after orthotopic heart transplantation remains to be evaluated in further studies.

Preservation of donor hearts using hypothermic oxygenated perfusion

BACKGROUND

Hypothermic machine perfusion of donor hearts enables continuous aerobic metabolism and washout of toxic metabolic byproducts. We evaluated the effect of machine perfusion on cardiac myocyte integrity in hearts preserved for 4 h in a novel device that provides pulsatile oxygenated hypothermic perfusion (Paragonix Sherpa Perfusion™ Cardiac Transport System).

MATERIAL AND METHODS

Pig hearts were harvested and stored in Celsior® solution for 4 h using either conventional cold storage on ice (4-h CS, n=6) or the Sherpa device (4-h pulsatile perfusion (PP), n=6). After cold preservation, hearts were evaluated using a non-working heart Langendorff system. Controls (n=3) were reperfused immediately after organ harvest. Biopsies were taken from the apex of the left ventricle before storage, after storage, and after reperfusion to measure ATP content and endothelin-1 in the tissue. Ultrastructural analysis using electron microscopy was performed.

RESULTS

Four-hour CS, 4-h PP, and control group did not show any significant differences in systolic or diastolic function (+dP/dt, -dP/dt, EDP). Four-hour PP hearts showed significantly more weight gain than 4-h CS after preservation, which shows that machine perfusion led to myocardial edema. Four-hour CS led to higher endothelin-1 levels after preservation, suggesting more endothelial dysfunction compared to 4-h PP. Electron microscopy revealed endothelial cell rupture and damaged muscle fibers in the 4-h CS group after reperfusion, but the cell structures were preserved in the 4-h PP group.

CONCLUSIONS

Hypothermic pulsatile perfusion of donor hearts leads to a better-preserved cell structure compared to the conventional cold storage method. This may lead to less risk of primary graft failure after orthotopic heart transplantation.

Active adaptation of the tethered mitral valve: insights into a compensatory mechanism for functional mitral regurgitation

BACKGROUND

In patients with left ventricular infarction or dilatation, leaflet tethering by displaced papillary muscles frequently induces mitral regurgitation, which doubles mortality. Little is known about the biological potential of the mitral valve (MV) to compensate for ventricular remodeling. We tested the hypothesis that MV leaflet surface area increases over time with mechanical stretch created by papillary muscle displacement through cell activation, not passive stretching.

METHODS AND RESULTS

Under cardiopulmonary bypass, the papillary muscle tips in 6 adult sheep were retracted apically short of producing mitral regurgitation to replicate tethering without confounding myocardial infarction or turbulence. Diastolic leaflet area was quantified by 3-dimensional echocardiography over 61+/-6 days compared with 6 unstretched sheep MVs. Total diastolic leaflet area increased by 2.4+/-1.3 cm(2) (17+/-10%) from 14.3+/-1.9 to 16.7+/-1.9 cm(2) (P=0.006) with stretch with no change in the unstretched valves despite sham open heart surgery. Stretched MVs were 2.8 times thicker than normal (1.18+/-0.14 versus 0.42+/-0.14 mm; P<0.0001) at 60 days with an increased spongiosa layer. Endothelial cells (CD31(+)) coexpressing alpha-smooth muscle actin were significantly more common by fluorescent cell sorting in tethered versus normal leaflets (41+/-19% versus 9+/-5%; P=0.02), indicating endothelial-mesenchymal transdifferentiation. alpha-Smooth muscle actin-positive cells appeared in the atrial endothelium, penetrating into the interstitium, with increased collagen deposition. Thickened chordae showed endothelial and subendothelial alpha-smooth muscle actin. Endothelial-mesenchymal transdifferentiation capacity also was demonstrated in cultured MV endothelial cells.

CONCLUSIONS

Mechanical stresses imposed by papillary muscle tethering increase MV leaflet area and thickness, with cellular changes suggesting reactivated embryonic developmental pathways. Understanding such actively adaptive mechanisms can potentially provide therapeutic opportunities to augment MV area and reduce ischemic mitral regurgitation.

A stentless trileaflet valve from a sheet of decellularized porcine small intestinal submucosa

PURPOSE

The purpose of this study was to investigate the function of a trileaflet pulmonary valve constructed from a sheet of porcine small intestinal submucosa.

DESCRIPTION

In four sheep, the native pulmonary valve and a segment of the pulmonary trunk was excised and replaced with a trileaflet valve constructed from decellularized porcine small intestinal submucosa. The valve construct was created from a sheet of the xenograft material by a method of involuting flaps of tissue inside a cylinder of itself. The function of the valve was assessed by echocardiography, catheter pullback across the valve, and observation of an excised valve in a flow simulator.

EVALUATION

The valve constructs exhibited low gradients and symmetrical leaflet movement with good mobility when tested under physiologic conditions in an acute sheep model.

CONCLUSIONS

This method offers a means to create a functional trileaflet valve replacement from a sheet of tissue.

The use of a novel tissue sealant as a hemostatic adjunct in cardiac surgery

BACKGROUND

In spite of advances in the management of bleeding associated with cardiac surgery, hemorrhage remains a troublesome problem, particularly in complex cases and high risk patients. In minimally invasive cardiac surgery, limited exposure and tight quarters may make accurate suturing difficult, and increase the risk of surgical bleeding. A surgical sealant that effectively prevents suture line bleeding would be a valuable resource for cardiac surgeons and might help to facilitate minimal access cases.

METHODS

We undertook acute canine studies with a new polyethylene glycol-based tissue sealant (FocalSeal, Focal, Inc., Lexington, MA) to determine its effectiveness in controlling bleeding from graduated needle punctures sites in the arteries of heparinized animals. For chronic canine studies, the sealant was applied to the suture line of a left internal mammary artery (LIMA) to left anterior descending (LAD) anastomoses. The anastomoses were then evaluated for patency and tissue reaction after a three-month recovery period.

RESULTS

The sealant prevented bleeding from arterial puncture wounds up to 2.5 mm in diameter. Three months following the application of sealant to coronary anastomoses, no adverse tissue reaction was found on histologic examination. All anastomoses treated with the sealant remained patent.

CONCLUSION

When applied as a hemostatic adjunct to sutures at a coronary anastomosis, the sealant appears to be an effective means of preventing bleeding without adverse tissue reaction or scarring.

The temperature dependence of cardioplegic distribution in the canine heart

BACKGROUND

Cold cardioplegic arrest can produce cooling contracture and suboptimal myocardial protection. This study examines whether cooling contracture is associated with maldistribution of cardioplegic solution, particularly subendocardial hypoperfusion, which may impair recovery.

METHODS

Canine hearts were arrested by antegrade cold and warm blood cardioplegia in random order. Cardioplegic distribution was measured using radiolabeled microspheres before and just after induction of each period of arrest.

RESULTS

With cold cardioplegia, perfusion of left ventricular subepicardial and midwall regions decreased. Subendocardial to subepicardial perfusion ratios increased significantly in the left ventricle as a whole, the anterior and posterior regions of the left ventricular free wall, and the interventricular septum. With warm arrest, transmural flow distribution was not significantly altered from preceding prearrest values. At constant coronary flow, coronary perfusion pressure was initially similar after induction of arrest at both temperatures, but it rose subsequently during warm cardioplegia.

CONCLUSIONS

The data suggest that during normothermic arrest, vasomotor tone regulates cardioplegic distribution, and hyperkalemic vasoconstriction is of slow onset. In the absence of beating and with vasomotion inhibited by hypothermia, cardioplegic distribution during cold arrest appears to be primarily dependent on vascular anatomy. There was no evidence of subendocardial underperfusion during cooling contracture.

Cardioplegia and ischemia in the canine heart evaluated by 31P magnetic resonance spectroscopy

BACKGROUND

Warm continuous blood cardioplegia provides excellent protection, but must be interrupted by ischemic intervals to aid visualization. We hypothesized that (1) as ischemia is prolonged, the reduced metabolic rate offered by cooling gives the advantage to hypothermic cardioplegia; and (2) prior cardioplegia mitigates the deleterious effects of normothermic ischemia.

METHODS

Isolated cross-perfused canine hearts underwent cardioplegic arrest followed by 45 minutes of global ischemia at 10 degrees C or 37 degrees C, or 45 minutes of normothermic ischemia without prior cardioplegia. Left ventricular function was measured at baseline and during 2 hours of recovery. Metabolism was continuously evaluated by phosphorus-31 magnetic resonance spectroscopy.

RESULTS

Adenosine triphosphate was 71% +/- 4%, 71% +/- 7%, and 38% +/- 5% of baseline at 30 minutes, and 71% +/- 4%, 48% +/- 5%, and 39% +/- 6% at 42 minutes of ischemia in the cold ischemia, warm ischemia, and normothermic ischemia without prior cardioplegia groups, respectively. Left ventricular systolic function, left ventricular relaxation, and high-energy phosphate levels recovered fully after cold cardioplegia and ischemia. Prior cardioplegia delayed the decline in intracellular pH during normothermic ischemia initially by 9 minutes, and better preserved left ventricular relaxation during recovery, but did not ameliorate the severe postischemic impairment of left ventricular systolic function, marked adenosine triphosphate depletion, and creatine phosphate increase. Left ventricular distensibility decreased in all groups.

CONCLUSIONS

When cardioplegia is followed by prolonged ischemia, better protection is provided by hypothermia than by normothermia. Prior cardioplegia confers little advantage on recovery after prolonged normothermic ischemia but delays initial ischemic metabolic deterioration, which would contribute to the safety of brief interruptions of warm cardioplegia.

Regional myocardial perfusion after experimental subarachnoid hemorrhage

BACKGROUND AND PURPOSE

The pathophysiology of cardiac injury after subarachnoid hemorrhage (SAH) remains controversial. Data from animal models suggest that catecholamine-mediated injury is the most likely cause of cardiac injury after SAH. However, researchers also have proposed myocardial ischemia to be the underlying cause, as a result of coronary artery disease, coronary artery spasm, or hypertension and tachycardia. To test the hypothesis that SAH-induced cardiac injury occurs in the absence of myocardial hypoperfusion, we developed an experimental canine model that reproduces the clinical and pathological cardiac lesions of SAH and defines the epicardial and microvascular coronary circulation.

METHODS

Serial ECG, hemodynamic measurements, coronary angiography, regional myocardial blood flow measurements by radiolabeled microspheres, 2D echocardiography, and myocardial contrast echocardiography were performed in 9 dogs with experimental SAH and 5 controls.

RESULTS

Regional wall motion abnormalities were identified in 8 of 9 SAH dogs and 1 of 5 controls (Fisher's Exact Test, P=0.02) but no evidence was seen of coronary artery disease or spasm by coronary angiography and of significant myocardial hypoperfusion by either regional myocardial blood flow or myocardial contrast echocardiography.

CONCLUSIONS

In this experimental model of SAH, a unique form of regional left ventricular dysfunction occurs in the absence of myocardial hypoperfusion. Future studies are justified to determine the cause of cardiac injury after SAH.

Recovery after cardioplegia in the hypertrophic rat heart

BACKGROUND

Enhanced recovery after cardioplegic arrest has been observed in rat hearts with hypertrophy induced by hemodynamic overload. We hypothesize that this is related to altered characteristics of hypertrophied myocardium-reflected by increased V(3) isomyosin and glycolytic potential-other than increased left ventricular mass.

MATERIALS AND METHODS

Isolated hearts from age-matched nonoperated and sham-operated control rats and from aortic-banded, hyperthyroid, and hypothyroid rats-groups in which hypertrophy and V(3) as a percentage of left ventricular myosin vary independently-underwent 2 h of multidose cardioplegic arrest at 8 degrees C followed by reperfusion at 37 degrees C. Left ventricular V(3) isomyosin was evaluated after separation by gel electrophoresis.

RESULTS

Moderate left ventricular hypertrophy was produced by aortic banding or hyperthyroidism and atrophy by hypothyroidism. V(3) isomyosin was increased in banded (28%) and hypothyroid (75%) rats compared to control (12%) and hyperthyroid rats (7%). Myocardial glycogen content closely paralleled %V(3). At 30 min of working reperfusion, functional recovery (assessed as percentage prearrest cardiac output) was 66 +/- 4 and 68 +/- 5% in control and hyperthyroid hearts and 81 +/- 2 and 80 +/- 5% in hearts from banded and hypothyroid rats (each P < 0.05 vs controls), respectively. At 30 min, hearts from banded and hypothyroid rats were also more efficient (as indexed by cardiac output at constant mean aortic pressure/myocardial oxygen consumption) than control and hyperthyroid hearts.

CONCLUSIONS

The data suggest that recovery is related not to increased mass but to other changes in overload hypertrophy. Increased percentage V(3) isomyosin and glycogen reflect these changes and may themselves contribute to improved functional recovery after cardioplegic arrest, as may increased postischemic efficiency.

Superior recovery of hypertrophied rat myocardium after cardioplegic arrest

BACKGROUND

Although cardioplegic protection of the hypertrophied heart remains a clinical challenge, we have previously observed enhanced recovery in rat hearts with pressure-overload hypertrophy induced by aortic banding. We investigated whether this unexpected result is found in other models of hypertrophy.

METHODS

Hearts with hypertrophy induced by aortic banding or administration of desoxycorticosterone acetate were each compared with age-matched sham-operated and nonoperated controls. Spontaneously hypertensive rats and Wistar-Kyoto controls were also compared. We evaluated left ventricular isomyosin distribution by gel electrophoresis and recovery of isolated working rat hearts arrested at 8 degrees C for 2 hours.

RESULTS

The percentage of V3 isomyosin in hearts with hypertrophy from aortic banding or administration of desoxycorticosterone acetate was increased compared with the control groups. Recovery of aortic flow in all three groups of hypertrophied hearts was at least as good or better than their respective controls. There were no significant differences in ATP or glycogen between hypertrophied and control hearts before or after arrest.

CONCLUSIONS

Enhanced recovery of hypertrophied hearts is not specific to a single model. This level of recovery may be supported by induction of a "fetal genetic program," exemplified in the rat by the shift in isomyosin from predominantly V1 to the more efficient V3 isoform, which occurs in pressure-overloaded hearts.

Ischemic intervals during warm blood cardioplegia in the canine heart evaluated by phosphorus 31-magnetic resonance spectroscopy

OBJECTIVE

Warm blood cardioplegia requires interruption by ischemic intervals to aid visualization. We evaluated the safety of repeated interruption of warm blood cardioplegia by normothermic ischemic periods of varying durations.

METHODS

In three groups of isolated cross-perfused canine hearts, left ventricular function was measured before and for 2 hours of recovery after arrest, which comprised four 15-minute periods of cardioplegia alternating with three ischemic intervals of 15, 20, or 30 minutes (I15, I20, and I30). Metabolism was continuously measured by phosphorus 31-magnetic resonance spectroscopy.

RESULTS

Adenosine triphosphate level fell progressively as ischemia was prolonged; after recovery, adenosine triphosphate was 99% +/- 6%, 90% +/- 1% (p = 0.0004 vs control), and 68% +/- 3% (p = 0.0002) of control levels in I15, I20, and I30, respectively. Intracellular acidosis with ischemia was most marked in I30. After recovery, left ventricular maximal systolic elastance at constant heart rate and coronary perfusion pressure was maintained in I15 but fell to 85% +/- 3% in I20, (p = 0.003) and to 65% +/- 6% (p = 0.003) of control values in I30, while relaxation (tau) was prolonged only in I30 (p = 0.007).

CONCLUSIONS

Hearts recover fully after three 15-minutes periods of ischemia during warm blood cardioplegia, but deterioration, significant with 20-minute periods, is profound when the ischemic periods are lengthened to 30 minutes. This suggests that in the clinical setting warm cardioplegia can be safely interrupted for short intervals, but longer interruptions require caution.

Rapid cooling contracture with cold cardioplegia

BACKGROUND

Cold cardioplegia can induce rapid cooling contracture. The relations of cardioplegia-induced cooling contracture to myocardial temperature or myocyte calcium are unknown.

METHODS

Twelve crystalloid-perfused isovolumic rat hearts received three 2-minute cardioplegic infusions (1 mmol/L calcium) at 4 degrees, 20 degrees, and 37 degrees C in random order, each followed by 10 minutes of beating at 37 degrees C. Finally, warm induction of arrest by a 1-minute cardioplegic infusion at 37 degrees C was followed by a 1-minute infusion at 4 degrees C. Indo-1 was used to measure the intracellular Ca2+ concentration in 6 of these hearts. Additional hearts received hypoxic, glucose-free cardioplegia at 4 degrees or 37 degrees C.

RESULTS

After 1 minute of cardioplegia at 4 degrees, 20 degrees, and 37 degrees C, left ventricular developed pressure rose rapidly to 54% +/- 3%, 43% +/- 3%, and 18% +/- 1% of its prearrest value, whereas the intracellular Ca2+ concentration reached 166% +/- 23%, 94% +/- 4%, and 37% +/- 10% of its prearrest transient. Coronary flow was 5.7 +/- 0.2, 8.7 +/- 0.3, and 12.6 +/- 0.6 mL/min, respectively. Warm cardioplegia induction at 37 degrees C reduced left ventricular developed pressure and [Ca2+]i during subsequent 4 degrees C cardioplegia by 16% (p = 0.001) and 34% (p = 0.03), respectively. Adenosine triphosphate and phosphocreatine contents were lower after 4 degrees C than after 37 degrees C hypoxic, glucose-free cardioplegia.

CONCLUSIONS

Rapid cooling during cardioplegia increases left ventricular pressure, [Ca2+]i and coronary resistance, and is energy consuming. The absence of rapid cooling contracture may be a benefit of warm heart operations and warm induction of cardioplegic arrest.

Warm and cold blood cardioplegia. Comparison of myocardial function and metabolism using 31p magnetic resonance spectroscopy

BACKGROUND

Standard myocardial protection during cardiac surgery uses hypothermic arrest, but warm heart surgery, recently introduced, is now used in many centers. We hypothesized that warm continuous blood cardioplegia (WCBC) would provide better myocardial preservation than cold continuous blood cardioplegia (CCBC).

METHODS AND RESULTS

In isolated cross-perfused canine hearts, left ventricular (LV) function and myocardial O2 consumption (MVO2) were measured at constant LV volume, coronary perfusion pressure, and heart rate before and after 75 minutes of arrest at 37 degrees C or 10 degrees C. Metabolism was evaluated by 31P nuclear magnetic resonance spectroscopy. LV resting tone increased transiently after arrest by CCBC but not WCBC (38 +/- 3.9 versus 2.9 +/- 0.5 mm Hg, P < .0005). Myocardial ATP changed over time differently in the groups (P < .001), declining at the outset of CCBC and returning to control levels during the recovery period after CCBC or WCBC. Intracellular pH rose from 7.17 +/- 0.03 to 7.85 +/- 0.05 during CCBC (P < .0005 versus WCBC). MVO2 declined dramatically during arrest at either temperature but to a lower value during CCBC (P < .0005). LV pressure recovered to 86.1 +/- 5.1% of its prearrest value after CCBC and to 97.2 +/- 7.8% following WCBC (P = NS). After CCBC but not WCBC, there were small but significant increases in LV end-diastolic pressure (by 1.3 mm Hg, P < .05) and in the LV relaxation constant, tau (from 37.3 +/- 1.5 to 42.3 +/- 2.4 milliseconds, P < .05).

CONCLUSIONS

The increase in intracellular pH during CCBC is largely accounted for by physicochemical factors. Group differences in ATP over time may be related to rapid cooling contracture during CCBC. The data suggest that CCBC mildly impairs LV function but that WCBC preserves function and metabolism at or near prearrest levels.

Reversal of ventricular contracture during hypothermic cardioplegic arrest

Ventricular contracture was produced in isolated perfused rat hearts by a novel method using repeated administration of an anoxic cold hyperkalemic cardioplegia solution. Contracture could be reversed by reperfusion with the same solution, without calcium (Group 1), oxygenated (Group 2), or oxygenated and calcium free (Group 3). Group 1 hearts underwent partial reversal of contracture; in Group 2, contracture was reversed more completely, but the effect was transient. Hearts in Group 3 had contracture reversed completely to a level lower than prearrest end diastolic pressure. Hearts in contracture were profoundly depleted of high-energy phosphates (ATP, 9% of control; creatine phosphate, 27%) and the success of contracture reversal was paralleled by the extent to which each solution repleted ATP and PCr. Ventricular contracture produced by energy depletion is rapidly reversed by restoration of oxygen to the myocardium. Reducing extracellular calcium by acalcemic perfusion is ineffective as an isolated measure but is synergistic with reoxygenation and enhances contracture reversal.

Benefits of glucose and oxygen in multidose cold cardioplegia

We tested the effects of glucose and oxygen in cardioplegic solutions on myocardial protection in the isolated perfused working rat heart. Recovery from 2 hours' hypothermic (8 degrees C) cardioplegic arrest was examined in 93 hearts. Cardioplegic solution, which was delivered every 15 minutes, was supplemented with glucose 28 mmol/L as a substrate or sucrose 28 mmol/L as a nonmetabolizable osmotic control; it was equilibrated with either 98% oxygen or 98% nitrogen, both with 2% carbon dioxide. Four combinations of hyperkalemic cardioplegic solution were studied: nitrogen-sucrose, nitrogen-glucose, oxygen-sucrose, and oxygen-glucose. During hypothermic arrest, oxygenation of cardioplegic solution greatly reduced myocardial lactate production and prevented ischemic contracture as indicated by coronary vascular resistance. Glucose increased lactate production modestly but significantly only when the cardioplegic solution was nitrogenated. Although end-arrest myocardial adenosine triphosphate and creatine phosphate were greatly increased by oxygenation of cardioplegic solution (p less than 0.005), we could not detect improved preservation of these high-energy phosphates by glucose. Averaged over reperfusion, percent recovery of cardiac output for the nitrogen-sucrose, nitrogen-glucose, oxygen-sucrose, and oxygen-glucose solutions was 32.3% +/- 6.1%, 45.9% +/- 4.6%, 44.5% +/- 4.6%, and 62.2% +/- 4.5%, respectively. Oxygenation of the glucose solution or addition of glucose to the oxygenated solution significantly improved recovery of cardiac output. The benefits of glucose and oxygen were additive, so that the oxygen-glucose cardioplegic solution provided the best functional recovery. We conclude that the addition of glucose to the fully oxygenated multidose cold cardioplegic solution improves functional recovery without increasing lactate production during arrest.

Protection of the hypertrophied myocardium by crystalloid cardioplegia

Patients with left ventricular hypertrophy (LVH) have a worse outcome after cardiac surgery than those without hypertrophy. We studied protection of hearts with LVH in an isolated rat heart model using multidose, cold, oxygenated cardioplegia. LVH was produced by banding the abdominal aorta in young rats. Six weeks after banding, this produced a 31% increase in the left ventricular dry weight/body weight ratio compared to two age-matched control groups comprising sham-operated and nonoperated animals. The recovery of cardiac output after arrest was higher in LVH (82 +/- 4% of prearrest) than in sham-operated (69 +/- 4%) or nonoperated (66 +/- 3%) control groups. The improved functional recovery in LVH occurred although there were no differences among the groups in myocardial adenosine triphosphate (ATP) and phosphocreatine (PCr) prior to arrest, at the end of arrest, or after reperfusion. Glycogen levels were also similar among the three groups prior to arrest and after reperfusion but were highest in LVH after arrest. Myocardial oxygen consumption (MVO2) and efficiency, expressed as cardiac output/MVO2, were similar among the groups prior to arrest. Myocardial efficiency after reperfusion declined in all groups but was best preserved in LVH. We also compared the sensitivity of hypertrophied and control hearts to the deleterious effects of calcium in cardioplegia. Calcium in the cardioplegia increased myocardial lactate production during arrest in a dose-related fashion and depressed myocardial levels of ATP, PCr, and glycogen at end arrest in all groups. Cardiac output recovery was also depressed by calcium but was still best in LVH. We conclude that the hypertrophied myocardium is well protected by standard cardioplegia and that calcium in cardioplegia does not preferentially depress recovery in LVH.

Relation of myocardial protection to cardioplegic solution pH: modulation by calcium and magnesium

The relationship between myocardial preservation and cardioplegic solution pH was assessed in isolated, perfused rat hearts. A base solution without calcium or magnesium and the same solution containing 0.2 mmol/L ionized calcium or 16 mmol/L magnesium or both ions were studied at several values of pH between 6.8 and 8.7. Hearts were arrested at 8 degrees C by multidose infusions of these bicarbonate-buffered solutions bubbled with oxygen and a varying percentage of carbon dioxide to control pH. Diastolic tone (left ventricular balloon) and adenosine triphosphate (ATP) depletion during arrest both increased as the cardioplegic solution became more alkaline. Calcium increased these effects of pH. Magnesium weakened the effect of pH on diastolic tone, maintained ATP at all pH levels, and inhibited the effects of calcium on the relationships of pH to diastolic tone and ATP. When data from all solutions were considered together, ATP depletion was shown to be linearly related to diastolic tone. Calcium depressed functional recovery (left ventricular developed pressure during reperfusion expressed as a percentage of its prearrest value) at all pH levels. With the other solutions, recovery was similar and best within a broad and relatively alkaline pH range. With the solution containing calcium and magnesium, at pH levels of 8.28 +/- 0.02, 7.87 +/- 0.03, 7.58 +/- 0.02, 7.41 +/- 0.01, 7.06 +/- 0.02, and 6.80 +/- 0.01, recovery at 5 minutes of reperfusion was 101.4% +/- 3.7%, 102.9% +/- 2.8%, 107.3% +/- 3.7%, 102.8% +/- 2.9%, 91.8% +/- 3.6%, and 94.3% +/- 3.5%, respectively. This effect of alkalinity was short-lived. Extreme alkalinity of the base, acalcemic solution produced the calcium paradox, as reported previously. Good preservation of ATP by the most acid solutions did not predict good functional recovery. Magnesium increased the persistence of frequent extrasystoles during early reperfusion, but the effect was attenuated by calcium. The data support the inclusion of magnesium in cardioplegic solutions, particularly when they contain calcium, show that cardioplegic solution pH can have major effects on the arrested heart, and suggest that a relatively alkaline pH may modestly benefit functional recovery.

Oxygenated cardioplegia: the metabolic and functional effects of glucose and insulin

Reports differ as to the efficacy of glucose and insulin as cardioplegic additives. Although deliberate oxygenation of crystalloid cardioplegic solutions improves myocardial protection, little is known about the protection afforded by glucose and insulin in such oxygenated solutions. In the isolated working rat heart, we studied the addition of oxygen, glucose, and insulin, separately and together, to a cardioplegic solution. The solution was equilibrated with O2 or N2, with glucose added as a substrate or sucrose as a nonmetabolizable osmotic control, with or without insulin. Hearts were arrested for 2 hours at 8 degrees C by multidose infusions. Oxygenation decreased lactate production and improved high-energy phosphate and glycogen preservation during arrest, prevented ischemic contracture, and improved functional recovery. The addition of glucose to the oxygenated solution increased the level of adenosine triphosphate at end-arrest from 10.5 +/- 0.5 to 13.9 +/- 0.6 nmol/mg dry weight and glycogen stores from 18.7 +/- 2.5 to 35.7 +/- 5.5 nmol/mg dry weight. The further addition of insulin did not better preserve these metabolites. Improvements in functional recovery due to glucose or insulin in the oxygenated solution attained statistical significance when both additives were included. Glucose increased lactate production significantly only when the solution was nitrogenated. Insulin added to the nitrogenated glucose-containing solution increased adenosine triphosphate and glycogen levels after 1 hour of arrest; and, although insulin did not prevent ischemic contracture from developing during the latter part of arrest with profound depletion of these metabolites, functional recovery was improved. The mechanism of improved functional recovery by insulin is not clear.(ABSTRACT TRUNCATED AT 250 WORDS)

Increased Proteolysis of Senescing Rice Leaves in the Presence of NaCl and KCl

NaCl and KCl enhanced the degradation of chlorophylls and proteins in detached rice (Oryza sativa) leaves in a concentration-dependent manner. Ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) accounted for 73 to 80% of the protein lost by day 4 in the light. NaCl at 50 millimolar increased proteolysis by 21% over the control in 4 days, but the addition of cycloheximide reduced the increase to about one-half. Cycloheximide alone had no effect on proteolytic activity during this period. Leaf segments taken from 10-day-old seedlings contained the highest proteolytic activity. Both NaCl and KCl increased the activity of Rubisco-degrading endoproteinases (the amount of ninhydrin-positive compounds measured from HCl-hydrolyzates of trichloroacetic acid-soluble supernatant), but decreased the activity of hemoglobin- and Rubisco-degrading exoproteinases (the amount of ninhydrin-positive compounds measured directly from trichloroacetic acid-soluble supernatant). Efflux of amino acids from senescing leaf segments into the incubation media increased 7- and 12-fold in the presence of KCl and NaCl, respectively. The increased efflux resulted in a negative correlation between salt concentration and amino acid content of leaf segments at the later stage of senescence. It is concluded that, in addition to the induction of new proteinase synthesis, the increased efflux of protein hydrolyzates may play a significant role in increasing proteolysis of salt-treated leaves, especially at the later stages of senescence.

The effects of calcium and magnesium in hyperkalemic cardioplegic solutions on myocardial preservation

Sustained left ventricular pressure development during each infusion of a cold calcium-containing hyperkalemic cardioplegic solution has been observed in rat hearts. The present study was undertaken to relate such contraction (i.e., increase in resting pressure) to myocardial preservation and to the calcium and magnesium contents of a crystalloid hyperkalemic cardioplegic solution. Isolated perfused rat hearts with a left ventricular isovolumic balloon were arrested at 8 degrees C by the fully oxygenated cardioplegic solution infused every 15 minutes for 2 hours. Cardioplegic solutions containing ionized calcium in concentrations of 0, 0.1, or 1.2 mmol/L were each studied with (groups 2, 4, and 6) and without (groups 1, 3, and 5) the addition of magnesium (16 mmol/L). Hearts arrested by the cardioplegic solution with no calcium or magnesium (group 1) developed a pressure (averaged over the second to eighth infusion and expressed as percent prearrest left ventricular pressure) of 6.0% +/- 0.4% during cardioplegic infusions. This solution maintained end-arrest myocardial adenosine triphosphate (13.1 +/- 1.0 nmol/mg dry weight) and phosphocreatine (21.7 +/- 2.8 nmol/mg dry weight) contents near the prearrest contents and preserved left ventricular function at 95% +/- 3% of prearrest developed left ventricular pressure at 15 minutes of reperfusion at 37 degrees C. Calcium (groups 3 and 5) increased pressure development during cardioplegic infusions (10.4% +/- 0.5% and 15.1% +/- 0.9%), depleted adenosine triphosphate (7.2 +/- 1.0 and 7.4 +/- 0.9) and phosphocreatine (13.3 +/- 1.8 and 10.7 +/- 1.5), and depressed left ventricular functional recovery (71% +/- 1% and 73% +/- 3%). Magnesium alone (group 2) decreased pressure development during cardioplegic infusions (3.0% +/- 0.3%), maintained adenosine triphosphate (15.6 +/- 0.9), augmented phosphocreatine (38.3 +/- 1.2), and preserved left ventricular function (99% +/- 4%). Magnesium added to calcium (groups 4 and 6) prevented the calcium-induced increased pressure development during cardioplegic infusions (4.0% +/- 0.5% and 6.7% +/- 0.6%), maintained adenosine triphosphate (13.6 +/- 1.4 and 14.9 +/- 0.7), augmented phosphocreatine (31.3 +/- 1.6 and 32.2 +/- 2.4), and ameliorated the depression of functional recovery (82% +/- 2% and 86% +/- 2%). These data suggest that left ventricular pressure development during arrest contributed to calcium-induced energy depletion and impairment of functional recovery and that these deleterious effects were inhibited by magnesium. The inhibitory effects of magnesium on left ventricular pressure development were rapidly reversed on reperfusion. The data support the addition

Myocardial preservation related to magnesium content of hyperkalemic cardioplegic solutions at 8 degrees C

This study investigates whether the addition of magnesium to a hyperkalemic cardioplegic solution containing 0.1 mM ionized calcium improves myocardial preservation, and whether there is an optimal magnesium concentration in this solution. Isolated perfused rat hearts were arrested for two hours by this cardioplegic solution, which was fully oxygenated and infused at 8 degrees C every 15 minutes to simulate clinical conditions. The cardioplegic solution contained either 0, 2, 4, 8, 16, or 32 mM magnesium. At end-arrest, the myocardial creatine phosphate concentration (nanomoles per milligram of dry weight) was 20.7 +/- 2.1, 22.9 +/- 1.7, 24.8 +/- 2.0, 31.3 +/- 1.4, 33.1 +/- 1.8, and 31.6 +/- 0.8, respectively, in hearts given cardioplegic solution containing these magnesium concentrations. Thus, the concentration of creatine phosphate was significantly higher at end-arrest when the cardioplegic solution contained 8, 16, or 32 mM than 0 or 2 mM magnesium (p less than 0.002) or 4 mM magnesium (p less than 0.02), and highest with 16 mM magnesium. Also, creatine phosphate was more sensitive to the magnesium concentration of the cardioplegic solution than was end-arrest adenosine triphosphate levels, which did not differ among the experimental groups. Aortic flow, expressed as a percentage of prearrest aortic flow, was 60.3 +/- 5.0, 70.2 +/- 5.5, 71.6 +/- 4.4, 71.8 +/- 4.8, 81.0 +/- 5.0, and 71.8 +/- 5.3, respectively. The addition of magnesium to the cardioplegic solution improved recovery of aortic flow (p less than 0.05, 16 mM versus 0 mM magnesium). We conclude from these data that with deep myocardial hypothermia and at an ionized calcium concentration of 0.1 mM, the addition of magnesium, over a broad concentration range, improved preservation of myocardial creatine phosphate and, at a concentration of 16 mM, improved aortic flow. The optimal magnesium concentration in the cardioplegic solution was 16 mM.

Oxygenation of cardioplegic solutions. Potential for the calcium paradox

Oxygenation of crystalloid cardioplegic solutions is beneficial, yet bicarbonate-containing solutions equilibrated with 100% oxygen become highly alkaline as carbon dioxide is released. In the isolated perfused rat heart fitted with an intraventricular balloon, we recently observed a sustained contraction related to infusion of cardioplegic solution. In the same model, to record these contractions, we studied myocardial preservation by multidose bicarbonate-containing cardioplegic solutions in which first the calcium content and then the pH was varied. An acalcemic cardioplegic solution (Group 1) and the same solution with calcium provided by adding calcium chloride (Group 2) or blood (Group 3) were equilibrated with 100% oxygen. Ionized calcium concentrations were 0, 0.10 +/- 0.06, and 0.11 +/- 0.07 mmol/L and pH values were 8.74 +/- 0.07, 8.54 +/- 0.08, and 8.40 +/- 0.07, all highly alkaline. Hearts were arrested for 2 hours at 8 degrees +/- 2.5 degrees C and reperfused for 1 hour at 37 degrees C. At end-arrest, myocardial adenosine triphosphate was depleted in all three groups, significantly in Groups 2 and 3. In Group 1 the calcium paradox developed upon reperfusion, with contracture (left ventricular end-diastolic pressure = 60 +/- 7 mm Hg), creatine kinase release up to 620 +/- 134 U/L, a profound further decrease in adenosine triphosphate to 1.9 +/- 1.7 nmol/mg dry weight, and either greatly impaired or no functional recovery (17% +/- 10% of prearrest developed pressure). Three hearts in this group released creatine kinase during arrest and did not resume beating during reperfusion. In Groups 2 and 3, the calcium paradox did not occur; functional recovery was 61% +/- 4% and 71% +/- 9% at 5 minutes of reperfusion. In two additional groups (4 and 5), the pH of the acalcemic cardioplegic solution was decreased by equilibration with 2% and 5% carbon dioxide in oxygen to 7.53 +/- 0.03 and 7.11 +/- 0.02. Contractions during arrest were smaller than in Groups 1, 2, and 3; adenosine triphosphate was maintained during arrest; functional recovery was 101% +/- 3% and 96% +/- 4% at 5 minutes of reperfusion. We conclude that acalcemic solutions with carbon dioxide are superior to highly alkaline calcium-containing solutions. If oxygenation of cardioplegic solutions, of proved value, causes severe alkalinity, then calcium paradox may result even with hypothermia. This hazard is prevented by adding calcium or blood to the solution or carbon dioxide to the oxygen used for equilibration.

Calcium-induced ventricular contraction during cardioplegic arrest

Cardiac arrest induced by hyperkalemic perfusion is generally considered to represent a state of complete electromechanical arrest. However, high-energy phosphate concentrations and ventricular function decrease with increasing cardioplegic calcium concentrations, possibly because of elevated resting muscle tone produced by calcium influx. We examined isolated rat hearts containing an isovolumic intraventricular balloon for the presence of contractile activity during the administration at 10 degrees C of a cardioplegic solution containing potassium, 20 mEq/L. Significant left ventricular pressure was developed (35.6% +/- 4.3% of prearrest systolic pressure) during administration of a solution containing a calcium concentration of 1.0 mmol/L and far less (9.7% +/- 1.6% of prearrest systolic pressure) with a calcium-free cardioplegic solution. The muscle contraction diminished with repeated doses, was increased by increasing cardioplegic calcium content, and was inhibited by magnesium. Adenosine triphosphate and creatine phosphate concentrations were 9.0 +/- 1.4 and 7.0 +/- 0.9 nmol/mg dry weight immediately after infusion of 15 ml of a hypoxic cardioplegic solution containing calcium, versus 13.3 +/- 1.3 (p less than 0.02) and 31.9 +/- 3.5 nmol/mg dry weight (p less than 0.0001) after a hypoxic acalcemic solution was given. When repeated doses of a hypoxic cardioplegic solution containing calcium in a concentration of 1.0 mmol/L were given at 15 minute intervals at 10 degrees C, ischemic contracture (a sustained development of ventricular pressure, mean 51% +/- 4% of prearrest systolic pressure) resulted within 1 hour. Coronary vascular resistance was increased during the muscle contractions induced by calcium-containing solutions, markedly so during contracture. Calcium-related mechanical activity was also observed during hypothermic cardioplegic arrest in five of six isolated isovolumic canine hearts. We conclude that hearts remain potentially active mechanically during cold hyperkalemic arrest and undergo energetically wasteful contraction when stimulated with calcium-containing hyperkalemic cardioplegic solutions.

Optimal myocardial preservation with an acalcemic crystalloid cardioplegic solution

The effect of the calcium and oxygen contents of a hyperkalemic glucose-containing cardioplegic solution on myocardial preservation was examined in the isolated working rat heart. The cardioplegic solution was delivered at 4 degrees C every 15 minutes during 2 hours of arrest, maintaining a myocardial temperature of 8 degrees +/- 2 degrees C. Hearts were reperfused in the Langendorff mode for 15 minutes and then resumed the working mode for a further 30 minutes. Groups of hearts were given the oxygenated cardioplegic solution containing an ionized calcium concentration of 0, 0.25, 0.75, or 1.25 mmol/L or the same solution nitrogenated to reduce the oxygen content and containing 0 or 0.75 mmol ionized calcium per liter. The myocardial adenosine triphosphate concentrations at the end of arrest in these six groups of hearts were 15.6 +/- 1.2, 9.5 +/- 0.5, 8.2 +/- 1.1, 4.9 +/- 1.8, 10.1 +/- 2.0, and 1.6 +/- 0.4 nmol/mg dry weight, respectively. At 5 minutes of working reperfusion, the percentages of prearrest aortic flow were 80 +/- 2, 62 +/- 4, 33 +/- 6, 37 +/- 5, 48 +/- 7 and 46 +/- 8, respectively. The differences among the groups in adenosine triphosphate concentrations and in functional recovery diminished during reperfusion. In hearts given the hypoxic calcium-containing solution, there was a marked increase in coronary vascular resistance during the administration of successive doses of cardioplegic solution, which was rapidly reversible upon reperfusion. These data indicate that hearts given the acalcemic oxygenated solution had better adenosine triphosphate preservation during arrest and better functional recovery than hearts in any other group. Addition of calcium to the oxygenated cardioplegic solution decreased adenosine triphosphate preservation and functional recovery. Oxygenation of the acalcemic solution increased adenosine triphosphate preservation and functional recovery. The lowest adenosine triphosphate levels at end arrest were observed in hearts given the hypoxic calcium-containing solution. In the setting of hypothermia and multidose administration, the addition of calcium to a cardioplegic solution resulted in increased energy depletion during arrest and depressed recovery.

Effect of preload on ischaemic and non-ischaemic left ventricular regional function

The response to preload of ischaemic and non-ischaemic regions of the left ventricle was studied in 14 dogs undergoing right heart bypass with mean aortic pressure and heart rate held constant. Regional function was measured by sonomicrometry before and after coronary artery occlusion. In the ischaemic region, as expected, there was paradoxical systolic lengthening (that is, systolic shortening was negative) but as stroke volume was progressively increased end diastolic length increased, whereas end systolic length changed little; thus systolic lengthening decreased (systolic shortening increased). Ischaemic regions that were dyskinetic at low stroke volumes were virtually akinetic at high stroke volumes. Additional studies showed that this response was not attributable to increased regional blood flow at high preloads and occurred over a wide range of heart rates and mean aortic pressures. Plots of systolic shortening against end diastolic length, expressing the regional Frank-Starling relation, were well described by linear regression in both ischaemic and non-ischaemic regions, although a few of these relations were better described by higher order polynomials. The slopes of these relations in the ischaemic region were 0.86(0.05) before and 0.83(0.06) after ligation, reflecting a small effect of preload on end systolic length. The data suggest that when contractility and afterload are constant preload determines the magnitude and in certain instances the sign of systolic shortening. In any ischaemic regions incapable of developing force the positive slope of the Frank-Starling relation is attributable to myocardial passive elastic properties. Paradoxical lengthening does not, however, necessarily indicate the absence of active force development; positive and negative values of systolic shortening describe a continuous spectrum of regional contractility. Thus the effects of preload and contractility on systolic shortening in ischaemic as well as non-ischaemic myocardium require differentiation.

Characteristics and Activity Changes of Proteolytic Enzymes in Apple Leaves during Autumnal Senescence

At least four different proteinases are present in senescing apple leaves (Malus domestica Borkh. cv. Golden Delicious) as determined by their pH optima, substrate specificity, and their reactivity to proteinase inhibitors. An enzyme active at pH 4.5 to 5.0 appears to be a sulfhydryl-dependent (iodoacetamide and phenylmercuric acetate-sensitive) endoproteinase, and degradation of the large subunit of ribulose bisphosphate carboxylase was observed only with this enzyme. It is tentatively concluded that this endoproteinase is responsible for the breakdown of ribulose bisphosphate carboxylase in vivo. However, the presence of more than one endoproteinase in apple leaves is suggested by the broad range of pH optima of the SH-dependent enzyme. Another enzyme active at pH 6.0 appears to be a carboxypeptidase, and was sensitive to phenylmethylsulfonylfluoride. This enzyme showed a strong hydrolytic activity against carbobenzoxyphenylalanylalanine. A sulfhydryl-dependent aminopeptidase and a second hydroxyl-dependent carboxypeptidase were active at pH 7.5Total autolytic activity (the sulfhydryl-dependent endoproteinase) as measured by the disappearance of proteins decreased during the period of protein decline. Evidence is presented that the measured proteinase activity can be dependent on assay methods and substrates. While the disappearance of protein measures most of endo-type activity, the ninhydrin assay appears to measure exo-type activity preferentially.

Isolation and partial characterization of an Acid endoprotease present in dormant apple shoot bark

A major protease present in dormant bark tissues of the apple (Malus domestica Borkh. cv. "Golden Delicious") was partially purified by hemoglobin-coupled Sepharose column chromatography. The protease active at pH 4.6 and at temperatures of 30 to 50 C was found to be sulfhydryl-dependent. Phenylmercuric acetate inhibited the enzyme approximately 50% at 2 millimolar, whereas phenylmethylsulfonyl fluoride inhibited less than 30% even at 10 millimolar. Substrate specificity and the separation of the enzyme reaction products indicated that the enzyme is likely to be an endoprotease. We suggest that the storage proteins in apple bark tissue undergo some modification prior to their eventual hydrolysis to amino acids, which requires a multi-enzyme system(s). Evidence is presented that the apple bark protein extracts enzymically release ninhydrin-positive compounds upon storage at 5 C. It is concluded that the activation of the sulfhydryl-dependent acid endoprotease is associated with the rapid metabolism of storage proteins which accompanies bud break upon regrowth.

The occurrence and nature of ornithine carbamoyltransferase in senescing apple leaf tissue

Ornithine carbamoyltransferase (EC 2.1.3.3) activity was detected in apple (Pyrus malus L.) leaf tissue from early June to November. Total activity remained relatively constant at 4.1 mumoles citrulline produced per hour per 10 cm(2) until mid-October when it sharply doubled. Following the first frost of the autumn, the enzyme lost about 80% of its former activity. The enzyme from apple leaf exhibited two pH optima, one at pH 8.6 and the other at pH 7.8, indicating the presence of isozymes or two forms of the enzyme. At pH 8.6, a partially-purified enzyme preparation had binding contrasts for its substrates of 6 mm for carbamyl-phosphate and 4.8 mm for ornithine. At pH 7.8, the Km for carbamyl-phosphate was 1.9 mm and the Km for ornithine was 1.22 mm.

Biochemical and Enzymatic Changes in Apple Leaf Tissue during Autumnal Senescence

The biochemical changes occurring during the natural senescence of apple leaf tissue (Pyrus malus L., Golden Delicious) coincided with specific changes in the environment. Protein, sugars, and total nitrogen began declining in leaf tissue when the daylength first became less than 14 hours in the second week of August. The activity of triose phosphate dehydrogenase declined shortly afterwards, while the activities of malate dehydrogenase, glutamic dehydrogenase, and aspartate aminotransaminase increased. Chlorophyll, DNA, RNA, and fresh weight began declining when the daylength first became less than 12 hours at the end of September. At the same time sugars and the activities of RNase, polyphenol oxidase, and proteolytic enzymes began increasing. Protein synthesis, total nitrogen, and the activities of malate dehydrogenase, glutamic dehydrogenase, and aspartate aminotransaminase began declining rapidly and amino acids began to accumulate after the first frost of the year. RNase, polyphenol oxidase, and proteolytic activity reached their highest specific activities after the first frost.

Metabolism of alpha-Ketoglutarate by Roots of Woody Plants

The uptake and metabolism of alpha-ketoglutarate-5-(14)C by peach, apple, and privet root tissues were studied over various time intervals. As much as 80% of the absorbed (14)C appeared as (14)CO(2) in 320 minutes in peach roots. Apple and privet roots were less effective in this conversion with the bulk of the (14)C found in the organic acid fraction. This indicates differences in organic acid metabolism among species of woody plants.The (14)C accumulated in malate earlier and in larger quantities than in citrate. Both glutamate and aspartate were labeled in 10 minutes and glutamate was labeled as early as 3 minutes. The labeling pattern does not clearly distinguish between the synthesis of glutamate by glutamic dehydrogenase or by transamination with oxaloacetate.The rapid metabolism of alpha-ketoglutarate to glutamate by the 3 species studied indicates the presence of enzyme systems important in amino acid synthesis in the roots of woody plants.