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CARDIAC LYSOSOMAL ENZYMES/Wildenihal 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. Downloaded from http://circres.ahajournals.org/ by guest on June 17, 2017 12. 13. -14. 15. 16. Hamilton, P Dow. Washington, D C , American Physiological Society, 1963, pp 1160-1161 Jones AW Altered ion transport in vascular smooth muscle from spontaneously hypertensive rats: influences of akiosterone, norepinephrine, and angiotensin. Circ Res 33: 563-572, 1973 Friedman SM: An ion-exchange approach to the problem of inlracellular sodium in the hypertensive process. Circ Res 34 (suppl I): 123-128, 1974 Jones AW, Hart RG: Altered ion transport in aortic smooth muscle during dcoxycorticosteronc acetate hypertension in the rat. Circ Res 37: 333-341, 1975 Friedman SM, Nakashima M, Friedman CL: Cell Na and K in the rat tail artery during the development of hypertension induced by desoxycorticosterone acetate Proc Soc Exp Biol Med 150: 171-176, 1975 Friedman SM: Lithium substitution and the distribution of sodium in the rat tail artery. Circ Res 34: 168-175, 1974 Friedman SM, Mar M, Nakashima M: Lithium substitution analysis of N» and K phases in a small artery. Blood Vessels 11: 55-64, 1974 Friedman SM: H + and cation analysis of biological fluids in the intact animal. In Glass Electrodes for Hydrogen and Other Cations, edited by G Eiscnman. New York, Marcel Dekkcr, 1967, pp 442-463 Friedman SM: Comparison of net fluxes of Li and Na in vascular smooth muscle. Blood Vessels 12: 219-235, 1975 Ronve G: Ionic composition of the rat aorta after incubation in saline Life Sciences (I) 8: 919-927, 1969 Palate V, Guslafson B, Friedman SM: Maintenance of the ionic composition of the the incubated artery. Can J Physiol Pharmacol 49: 106-112, 1971 Friedman SM, Nakashima M, Palaty V: Glass electrode measurement of ion transfers dunng rewarming of the single rat tail artery. Can J Physiol Pharmacol 47: 863-869, 1969 Kleinzeller A- Cellular transport of water. In Metabolic Transport, *d 3, vol 6, edited by WE Hokin New-York, Academic Press, 1972, pp 91-131 Friedman SM, Nakashima M, Palaty V, Walters BK: Vascular resistance and Na + -K + gradients in the perfused rat-tail artery. Can J Physiol Pharmacol 51: 410-417, 1973 Guignard J-P, Friedman SM: Intraluminal pressure and ionic distribution in the tail artery of rats Circ Res 27: 505-512, 1970 Jones AW: Altered transport in large and small arteries from spontaneously hypertensive rats and the influence of calcium Circ Res 34 (suppl I): 117-122, 1974 441 17. Guignard J-P, Friedman SM: Vascular ionic effects of angiotensin II in the rat Proc Soc Exp Biol Med 137: 147-150, 1971 18. Keatinge WR: Ionic requirements for arterial action potential. J Physiol (Lond) 194: 169-182, 1968 19. Somlyo AP, Somlyo AV: Vascular smooth muscle. I. Normal structure, pathology, biochemistry, and biophysics. Pharmacol Rev 20: 197-272, 1968 20. Morns DJ, Davis RP: AWosterone; current concepts. Metabolism 23: 473-494, 1974 21. Matthes KJ, Junge-HUlsing G, Schmitt G, Wagner H, Oberwitler W, Hauss WH: (Jber die Beziehung zwischen gesttJrtem Mesenchymstoffwechsel und VcrBnderungen der Lipidkonzentration in der Gefasswand bei arterieller Hypertension. J Atherosclerosis Res 9: 305-318, 1969 22. Villamil MF, Nachev P, Kleeman CR' Effect of prolonged infusion of angiotensin II on ionic composition of the arterial wall. Am J Physiol 218: 1281-1286, 1970 23. Hollander W, Kramsch DM, Farmelant M, MadofT IM- Arterial wall metabolism in experimental hypertension of coarctation of the aorta of short duration. J Clin Invest 47: 1221-1229, 1968 24. Todd ME, Friedman SM" The ultrastructure of peripheral arteries during the development of DOCA hypertension in the rat. Z Zellforsco Mikrosk Anat 128: 538-554, 1972 25. Palaty V, Gustafson B, Friedman SM: Sodium binding in the arterial wall. Can J Physiol Pharmacol 47: 763-770, 1969 26. Palaty V, Gustafson B, Friedman SM: The role of protein-polysaccharides in hydration of the arterial wall. Can J Physiol Pharmacol 48: 54-60, 1970 27. Edelman IS, Fimognari GM On the biochemical mechanism of action of aldostcrone. Recent Prog Horm Res 24: 1-44, 1968 28. Knox WH, Sen AK. Mechanism of action of aldosterone with particular reference to (Na + K)-ATPase. Ann NY Acad S;i 242: 471-488, 1974 29. Friedman SM, Scott GH, Nokasfiima M L Vascular morphology in hypertensive states in the rat. Anat Rec 171: 529-544, 1971 30. Friedman SM, Nakashima M, Mar M: Morphological assessment of vasoconstriction and vascular hypertrophy in sustained hypertension in the rat. Microvasc Res 3: 416-425, 1971 31. Folkow B, HallbSck M, Lundgren Y, Sivertsson R, Weiss L: Importance of adaptive changes in vascular design for establishment of primary hypertension, studied in man and in spontaneously hypertensive rats. Circ Res 32 (suppl I): 2-13, 1973 Hormonal and Nutritional Substrate Control of Cardiac Lysosomal Enzyme Activities KERN WILDENTHAL, M.D., SUMMARY Prolonged starvation is known to induce significant alterations in several cardiac lysosomal enzymes, particularly the acid proteinase cathepsin D. To determine what specific factors might mediate these changes, fetal mouse hearts in organ culture were maintained in media designed to simulate selected hormonal or nutritional substrate changes that accompany starvation. Reduced concentrations of glucose caused an increase in the activity of /9-acetylglucosaminidase but had no effect on cathepsin D or acid phosphatase activities (i.e., effects opposite from those of starvation). Also, high concentrations of free fatty acid, acetoacetate, and /S-OHbutyrate induced an increase in cathepsin D ( + 18%) and a simulta- PH.D. neous decrease in glucosaminidase ( - 1 9 % ) , with little change in add phosphatase. Furthermore, glucagon had no effect on any of the enzymes, whereas growth hormone caused a small (6%) increase in cathepsin D activity. In addition, insulin deprivation caused significant increases (7-25%) in the activities of all three enzymes. Insulin deprivation and excess ketones, but not tbe other interventions, increased the proportion of enzyme activity which was nonsedimentable. These results suggest the possibility that lysosomal alterations during starvation may be related in part to prolonged insulin deficiency and exposure to high concentrations of ketones and free fatty acids. PROLONGED starvation is accompanied by characteristic alterations in the activities and distribution of several cardiac lysosomal enzymes.'- 2 The specific activity of cathepsin D, the major acid proteinase in the heart, is increased by 20-40% after 3-6 days of food deprivation in mice, rats, and rabbits, and the proportion of activity that is present in the nonsedimentable (i.e., non-particulate-bound) fraction of the tissue homogenate becomes much greater From the Pauline and Adolph Weinberger Laboratory for Cardiopulmonary Research, Departments of Physiology and Internal Medicine, University of Texas Health Science Center at Dallas, Dallas, Texas. Supported by grants from the Moss Heart Fund and the National Heart and Lung Institute (HL 14706), and performed while Dr. Wildenihal held a U S . Public Health Service Research Career Development Award (HL 70125). Received March 23, 1976: accepted for publication May 24. 1976. 442 CIRCULATION RESEARCH Downloaded from http://circres.ahajournals.org/ by guest on June 17, 2017 than in hearts of fed animals. Immunohistochemical localization studies have revealed the changes to be confined specifically to cardiac myocytes rather than interstitial or endothelial cells. The myocytes display not only increased amounts of the enzyme but also alterations in its subcellular distribution that suggest an increased presence of cathepsin D outside secondary lysosomes.1 Some other enzymes of lysosomal origin are affected differently by starvation: acid phosphatase activity is increased minimally, whereas the activity of /S-acetylglucosaminidase remains constant or declines.1-2 Prolonged starvation is accompanied by a number of chronic metabolic changes that might play a role in causing the alterations in cardiac lysosomal function. Concentrations of fatty acids and ketones become elevated, while glucose is reduced. Levels of growth hormone and glucagon rise, and insulin falls. The present study was undertaken to test under controlled conditions which of these factors might possess the potential to play a role in mediating the effects of prolonged starvation on the heart. As a practical matter it would be impossible to test the chronic effects of these agents using conventional experimental models, in which the period of relative stability is limited to a few hours. Accordingly, an organ culture system was employed, in which intact hearts from fetal mice can be maintained in a reasonably stable functional state for several days under precisely controlled conditions in vitro. 3 The use of any in vitro model involves, of course, the dilemma of knowing to what extent it is legitimate to extrapolate results to related situations in vivo, and hearts in organ culture are no less subject to this problem than are traditional systems. The use of fetal hearts may compound the problem when attempts are made to relate results to adult hearts. Nevertheless, results in vitro may provide valuable hints about the potential ability of specific interventions to elicit analogous responses in vivo, so long as caution is used in drawing extrapolations. Methods Intact hearts of 18- to 20-day fetal mice were maintained in organ culture as described in detail previously.3 Briefly, the hearts, which weighed 2-4 mg and measured < 1 mm in thickness, were isolated under sterile conditions and explanted on stainless steel grids at the liquid-air interphase of shallow culture chambers. They were maintained at 37.5°C and exposed to an atmosphere of 95% O a -I- 5% COj. The basic nutritive solution was medium 199 or Earle's salt solution (Grand Island Biologicals); additions to or deletions from the basic medium were employed as required by the experimental protocol. Glucose was used in concentrations ranging from 50 to 400 mg/100 ml of solution. Other substrates added to the basic medium included sodium octanoate (2 mM), sodium acetoacetate (5 mM), and sodium /5-OH-butyrate (10 mM). Studies on effects of variations in glucose concentration were made with medium 199 supplemented with 2 mM octanoate to ensure that changes induced by low glucose could not be due to an inadequate energy supply per se. For tests of hormonal effects, crystalline bovine insulin (50 fig/m\; Sigma), glucagon (0.5-50 jig/ml; Lilly), and growth hormone (20-100 //g/ml; VOL. 39, No. 3, SEPTEMBER 1976 Miles) were added to the medium. For studies of effects of long chain fatty acid, hearts were cultured in medium 199 supplemented with 35% fetal calf serum (Colorado Serum Co.); oleic acid (final concentration = 1.7-2.0 mM) was saponified with NaOH and then combined slowly at 45°C with undiluted serum that had previously been chilled to 4°C, after which the serum was added to the chemically defined medium. After cultivation for 3 days, hearts were assayed for protein and for activities of creatine phosphokinase (a nonlysosomal enzyme which served as a general marker of cellular viability) and cathepsin D, /3-acetylglucosaminidase, and acid phosphatase (all of which are localized at least partially in lysosomes in heart). Preliminary experiments revealed that specific activities of the lysosomal enzymes rose gradually during the 3-day period of cultivation; thus, an agent which caused an increase in activity over matched controls would do so by stimulating enzyme activity over and above the normal effects of cultivation per se. For measurements of total enzyme activities, the hearts were homogenized vigorously in a 0.1% solution of Triton X-100 with a Polytron homogenizer to disrupt cells and organelles maximally. Cellular debris was sedimented at 350 g for 5 minutes, and assays were performed on the supernatant fluid. Protein was measured by the technique of Lowry et al.4 and creatine phosphokinase (CPK) by the technique of Szasz et al. s The lysosomal enzymes were assayed by modifications of the methods of Barrett 9 as described previously.1 Briefly, cathepsin D activity was determined from formation of Folin-reactive products from purified hemoglobin at pH 3.2 and 45°C (Barrett's method II); glucosaminidase, from cleavage of nitrophenol from p-nitrophenyl-/3-acetyl-D-glucosaminide at pH 4.3 and 37°C; and acid phosphatase, from cleavage of nitrophenol from /7-nitrophenyl phosphate at pH 4.5 and 37°C after inhibition of nonlysosomal phosphatases with sodium acetate.6 For measurements of sedimentable vs. nonsedimentable enzyme activity, the tissue was homogenized gently for 20 seconds in a Potter-Elvehjem homogenizer, using a buffered solution (pH 7.4) of 0.25 M KC1, to retain intact lysosomes insofar as possible.7 After initial centrifugation at 350 g to remove undisrupted cells, nuclei, and debris, the supernatant fluid was recentrifuged at 40,000 g for 20 minutes. The supernatant fluid from this second centrifugation was assayed for enzyme activity (termed "nonsedimentable" activity); the pellet was rehomogenized vigorously in 0.1% Triton X-100 and also assayed for enzyme activity (termed "sedimentable" activity). The ratio of nonsedimentable to total (i.e., "sedimentable" plus "nonsedimentable") activity was calculated as an index of lysosomal fragility or of the presence of enzyme outside lysosomes, or both. Samples were maintained at 4°C at all times until assay. Three to eight hearts from a single litter were pooled to provide enough material for the assays. In all studies, results from hearts exposed to the experimental interventions were compared with results from control hearts from matched littermates that had been cultured and assayed at the same times under similar conditions. Statistical comparisons were made using Student's /-test for paired observations. Values CARDIAC LYSOSOMAL ENZYMES/Wildenthal 443 TABLE 1 Effect of Alterations in Hormones and Metabolic Substrates on Activities of Lysosomal Enzymes and Creatine Phosphokinase in Fetal Mouse Hearts Maintained in Organ Culture for 3 Days Cathepsin D activity Acid phosphatasc activity (%) 0-Acetylglucosaminidasc activity (%) A. Effect of reduced glucose (50 mg/100 ml) B. Effect of ketones (5 mM acetoacetate + 10 mM /3-OH butyrate) C. Effect of fatty acids (2 mM octanoate) D. Effect of glucagon (5 jig/ml) E. Effect of growth hormone (20 103 99 ± 2 106 ± 2* 100 ± 1 98 ± 2 98 ± 3 101 ± 3 F. Effect of insulin deprivation 125 ± 4 * 107 ± 2* 125 ±2* 2 101 ± 1 115 ± 3* 108 ± 3* 101 104 ± 2 ± 3 Crca.line phosphokinase activity (%) 112 ± 2 * 94 ± 4 101 ±2 106 ± 3 99±2 93 ±2* 104 ± 3 95 ± 3 85 ±2* Each value represents the mean ± 1 SEM of 8-12 samples (five hearts per sample), expressed as a percentage of values from matched littermate controls The control medium for comparison A contained glucose at a concentration of 200 mg/100 ml, the control medium for comparison F contained insulin at a concentration of 50 /ig/m\; all other control and experimental media contained glucose at 100 mg/100 ml and lacked insulin. • P < 0.05 compared to control media, by Student's l-test for paired observations. Downloaded from http://circres.ahajournals.org/ by guest on June 17, 2017 are expressed throughout the paper as the mean ± 1 SEM of each group of measurements. Results Spontaneous and rhythmic beating persisted throughout the 3-day culture periods in all hearts in all media. Except for hearts exposed to glucagon, which causes tachycardia at the higher concentrations used,8 beating rates were similar in all media. Variations in substrate composition failed to alter the specific activity of CPK but did exert selective effects on the three lysosomal enzymes that were assayed. Summary results are given in Table 1. Reductions in the concentration of glucose over a physiological range had no effect on cathepsin D or acid phosphatase activities, but produced a significant increase in the activity of j9-acetylglucosaminidase. This effect, which was progressive over a wide range of glucose concentrations (Table 2), was opposite to that which would have been expected if hypoglycemia participated in starvation-induced alterations in cardiac glucosaminidase activity in vivo.2 Addition of high concentrations of ketones to the culture medium produced effects which partially mimicked the net effect of starvation. Acetoacetate plus /S-OH-butyrate at levels of 5 mM and 10 mM, respectively (which simulate their relative concentrations during prolonged starvation), caused a 15% increase in the specific activity of cathepsin D (P < 0.01) and an 8% increase in acid phosphatase (P < 0.05). The activity of glucosaminidase was unaltered in the same Jiearts. Additional experiments jn whicfi the two ketones were added separately to the culture medium revealed that either alone was able to produce the observed increase in catheptic activity. Addition to the medium of a soluble free fatty acid (FFA), octanoate, produced no change in cathepsin D or acid phosphatase activity. However, it did induce a small, consistent decrease (7%) in glucosaminidase activity similar to that observed in vivo after starvation or high fat diets.2 A medium chain fatty acid such as octanoate is especially useful in studies of fetal hearts, which in many species, including mice, have not yet developed the capacity to utilize long chain fatty acids, presumably because of inadequate cardiac levels of carnitine and acylcarnitine transferase.*"" Despite their inability to be transported into mitochondria and oxidized by fetal heart cells, however, long chain fatty acids can be taken up and incorporated into triglycerides. Accordingly, to establish whether the effect of fatty acids was dependent on their oxidation or whether their uptake alone would suffice to produce the changes, studies were repeated using media containing oleate-enriched serum. The activity of glucosaminidase in hearts maintained for 3 days in media containing unenriched serum (FFA = 260 n») was 784 ± 55 TABLE 2 Effect of Glucose Concentration on the Activity of fi-Acetylglucosaminidase in Fetal Mouse Hearts Maintained in Organ Culture for 3 Days Glucose concentration /3-Acetylglucosaminidase activity (nmol nitrophenyl/hr x mg protein) % of activity at 400 mg/100 ml 4O0mg/100ml 200mg/100ml lOOmg/lOOml 50mg/l00ml 668 ±35 752±29*t 821±33*t 838 ± 36* 113% 123% 125% Hearts of littcrmatcs were compared by Student's (-test at four concentrations of glucose. Each value represents the mean ± 1 SEM of five matched samples (15 hearts). • P < 0.05, compared to value at 400 mg/100 ml. t P < 0.05, compared to preceding concentration. CIRCULATION RESEARCH 444 Katonu and Octanotc Acid Atnort 140 - Kctonn and Ocfanoic Add Pitisnt 120 g 100 J« 80 o •6 Ivlty Downloaded from http://circres.ahajournals.org/ by guest on June 17, 2017 nmol nitrophenol/hour x mg protein, and the activity in hearts of matched littermates exposed to increased oleate (FFA = 1840 MM) was 769 ± 39 (-2% ± 4%, P > 0.30), indicating that long chain fatty acids could not mimic the effect of octanoate in fetal mouse hearts. The effect of combined addition to the medium of fatty acids and ketones is shown in Figure 1. The individual effects of each alone were additive, and together they produced an 18 ± 6% increase in cathepsin D activity (from 88 ^g tyrosine/hour x mg protein in controls to 104 in hearts receiving the fatty substrates) and a simultaneous 19 ± 3% decrease in glucosaminidase activity (from 765 nmol nitrophenol/hour x mg protein to 619), while acid phosphatase was increased only minimally—i.e., changes analogous to those induced in vivo by starvation. Hormonal influences on cardiac lysosomal enzymes are also shown in Table 1. Glucagon in concentrations of 0.5-50 fig/m] produced no changes in cathepsin D, acid phosphatase, or glucosaminidase. Growth hormone had no effect on the latter two enzymes, but caused a small (6%) increase in the specific activity of cathepsin D. In contrast, insulin deprivation produced changes in the activities of all enzymes. Cathepsin D and glucosaminidase were affected similarly (+25% for both, P < 0.01), while acid phosphatase activity was increased less markedly (Fig. 2). In addition to its effects on total enzyme activities, each agent was tested for its effect on the distribution of enzyme activity between nonsedimentable and sedimentable fractions of the tissue homogenate. The proportion of activity which was nonsedimentable was unaltered by changes in glucose concentration or by the addition to the medium of glucagon or growth hormone. Oleic acid had no effect, but octanoate caused small decreases in the nonsedimentable 60 u 4 I 40 UJ 20 Cattwptln D Add PhosphatoM £-oe«tylgluco«amlnldOM FIGURE I Combined effects of ketones (5 mM acetoacetate + 10 /MM fi-OH-butyrate) and fatty acids (2 /MM octanoale) on specific activities of lysosomal enzymes in fetal mouse hearts maintained in organ culture for 3 days. Comparisons were made between hearts of matched littermates, and results are expressed as a percentage of control values. The data are derived from assays on 12 matched samples (60 heans in each group). Variance bars represent ± / SEM. • - P < 0.05, compared to values obtained in hearts cultured in the absence of ketones and fatty acids. Glucose concentration was 100 mg/IOO ml in control and experimental media. VOL. 39, No. 3, SEPTEMBER 140 1976 EJInuilin PrtMtit tntulin AbMfrt 120 100 80 60 40 20 0 Cattwpiin D Add Photpnatat* /9-octtytqluco»amintdoM FIGURE 2 Effect of insulin deprivation on specific activities of lysosomal enzymes in fetal mouse hearts maintained in organ culture for 1 days. Comparisons were made between hearts of matched littermates, and results are expressed as a percentage of control values. The data are derived from assays on nine matched samples (45 hearts in each group). Variance bars represent ±1 SEM. * = P < 0.05, compared to values obtained in hearts cultured in the presence of insulin (50 fig/ ml). fraction (i.e., changes opposite to those induced by starvation). As shown in Table 3, both insulin deficiency and excess ketones produced increases in the nonsedimentable fraction. The changes were slightly more pronounced for cathepsin D than for glucosaminidase (as is true for hearts of starved animals), but the changes were small compared to those encountered in vivo.1 2 Discussion Starvation-induced alterations in lysosomal enzymes have been demonstrated in heart,1- ' skeletal muscle, 11 and liver. " • " Unlike liver, changes in heart and skeletal muscle are not "pan-lysosomal" but rather are quite distinct for different enzymes: 1 - 212 the specific activities of some enzymes of lysosomal origin increase during prolonged starvation (e.g., cathepsin D and, to a lesser extent, acid phosphatase), while the activities of others may remain constant or even decrease (e.g., /3-acetylglucosaminidase). These alterations, along with simultaneous changes in the lability of the enzymes, develop gradually, and significant changes are not demonstrable for a day or more after starvation has begun.1 2- l2 Interestingly, starvation-induced increases in the degradation rates of cardiac and skeletal muscle proteins also appear only after a lag period of a day or more, despite earlier alterations in rates of protein synthesis,1" which suggests the possibility that increases in lysosomal proteolytic activity or enzyme "availability" or both may be causally linked with increases in muscle protein degradation during starvation, possibly in concert with increased activities of nonlysosomal proteinases.11- I7 "' e The metabolic basis for starvation-induced lysosomal changes has been uncertain. Both insulin deprivation and glucagon excess are known to alter lysosomal function and protein degradation in perfused liver,20 and the hypoinsulinemia and nyperglucagonemia of starvation have therefore seemed likely candidates for mediating hepatic changes. CARDIAC LYSOSOMAL ENZYMES/Wildenthal 445 TABLE 3 Effects of Insulin Deprivation and of Acetoacetate (5 /MM) and fi-OH-butyraie (10 mM) on the Proportion of Lysosomal Enzyme Activities Present in the Nonsedimentable Fraction of Cardiac Homogenates % nonsedimentable calhepsin D activity (100 x nonsedimentablc/ total activity) % nonsedimentable 0-acetylglucosaminidase activity (100 x nonsedimentable/ total activity) A. Medium 199 (n = 8) Medium 199 + ketones (n - 8 ) Difference P 46 ± 1.9 49 ± 1.7 + 3 ± 0.8 <0.01 50 ± 1.7 51 ± 1.6 + 1 ±0.5 >0.05 B. Medium 199 with insulin (n = 12) Medium 199 without insulin (n - 12) Difference 41 ± 1 . 6 45 ± 1.7 +4 ± 1.4 47 ± 1.3 50 ± 1.4 P <0.0l + 3 ± 1.1 <0.05 Downloaded from http://circres.ahajournals.org/ by guest on June 17, 2017 For each intervention, hearts of matched littermates (eight hearts per sample) were compared by Student's (-test for paired observations Each value represents the mean ± I SEM Lack of insulin has been shown in cultured hearts to increase the activity of cathepsin D, particularly in the nonsedimentable fraction of the tissue homogenate,*1- 12 and this change can be correlated with concomitant increases in the rate of protein degradation.12 On the other hand, short-term studies of perfused rat hearts 23 - 2t have suggested that insulindependent alterations in lysosomal function and protein degradation develop rapidly, unlike the delayed appearance of starvation-induced changes. Furthermore, in short-term studies of perfused hearts glucosaminidase is affected in a similar way and to a similar degree as cathepsin D.2< The present experiments confirm that insulin deficiency in vitro is a potent stimulator of lysosomal enzyme activity and demonstrate that in cultured hearts, as in perfused hearts, glucosaminidase is altered in the same way as cathepsin D, even after several days. Thus, cardiac lysosomal alterations produced by insulin deprivation in vitro do not mimic exactly those observed after prolonged starvation. Therefore, although hypoinsulinemia may well contribute to some of the delayed effects of starvation, it seems unlikely to be the sole explanation for the complex lysosomal alterations that are observed in vivo. On the basis of the present experiments, glucagon seems unlikely to play a vital role in lysosomal function in fetal mouse hearts, in contrast to its probable importance for lysosomal function in liver. It is impossible from these data alone to know whether this is a universal distinction between cardiac and hepatic responses or whether it is species-specific. Like guinea pig hearts" but unlike liver and unlike hearts of many other species, mouse hearts apparently lack the capacity to respond to glucagon with increases in adenylate cyclase activity and cyclic AMP. 1 ' " Thus, if glucagoninduced lysosomal alterations are mediated through the adenylate cyclase-cyclic AMP system, it might be expected that mouse hearts (and, presumably, guinea pig hearts as well) would fail to be affected, even though hearts of other, responsive species could react the way liver does. Nevertheless, since starvation alters cardiac lysosomes similarly in the mouse as in other species, 1 ' it seems doubtful that glucagon is of primary importance in causing cardiac changes in any species during starvation. Growth liormone in very targe concentrations causes only a minimal increase in cardiac cathepsin D activity, with no change in the distribution of the enzyme. Thus, on the basis of its effects in fetal hearts in vitro, its role in mediating lysosomal changes in vivo therefore seems likely to be negligible. Substrate-dependent lysosomal changes are more complex. The effects of high concentrations of ketones and free fatty acids result in directional changes in the activities of cathepsin D, acid phosphatase, and glucosaminidase that resemble those during starvation. Increases in cathepsin D and, to a lesser extent, acid phosphatase are induced by ketones, whereas metabolizable fatty acids produce a decrease in glucosaminidase. Since these substrates cause a reduction in the uptake and utilization of glucose and, since reciprocal decreases in circulating levels of glucose often occur simultaneously with increases in fatty acids and ketones in vivo, it might have been expected that reduced concentrations of glucose in vitro would cause effects similar to those of ketones or fatty acids, or both. Paradoxically, this was not the case, and decreased glucose availability was accompanied by increased glucosaminidase activity over a wide range of concentrations; thus, hypoglycemia seems unlikely to play a direct role in causing the lysosomal alterations that accompany starvation. The demonstration that several of the interventions can influence individual lysosomal enzymes in different ways confirms in vitro the observation in several tissues in vivo, including heart, that lysosomal enzyme respond to some stimuli in a heterogeneous m a n n e r . ' 1 1 ' " In at least some instances in vivo this could be due to an influx of migratory cells and a resultant alteration in the cellular origin of the lysosomes.11 " Such an influx is clearly impossible in an organ culture system. One possible explanation is that there are separate effects on the several subsets of distinct lysosomal populations that are known to exist in heart."" 3 ' Alternatively, it remains possible that the synthesis or degradation 446 CIRCULATION RESEARCH of certain enzymes within a given lysosomal population may be altered independently from other enzymes in the same lysosomes. Finally, it should be reiterated that changes observed in a relatively unphysiological system such as organ culture should be extrapolated to hearts in vivo only with caution; factors important in this highly catabolic model may be different in some regards from those important in adult hearts in vivo.22 and confirmatory studies in intact animals would be valuable. It also should be noted that the relatively small changes in hydrolytic enzyme activities and distribution noted here do not necessarily imply that concomitant alterations in cellular catabolism must occur in all instances, and actual measurements of the rate of proteolysis are required before postulations about the ultimate metabolic effect of the observed lysosomal changes should be entertained.22-30-" Downloaded from http://circres.ahajournals.org/ by guest on June 17, 2017 Acknowledgments I am grateful to J R Wakeland, P.C. Morton, S C. Jasinski, A Vasil, and M. Kennedy for invaluable technical assistance. References 1. Wildcnthal K, Poole AR, Dingle JT- Influence of starvation on the activities and localization of cathepsin D and other lysosomal enzymes in hearts of rabbits and mice. J M o l Cell Cardiol 7: 841-855, 1975 2. Wildenthal K, Poole AR, Glauert A M , Dingle JT Dietary control of cardiac lysosomal enzymes In Recent Advances in Studies on Cardiac Structure and Metabolism, vol 8, edited by P-E Roy, P Harris. Baltimore, University Park Press, 1975, pp 519-529 3. Wildenlhal K: Long-term maintenance of spontaneously beating mouse hearts in organ culture. J Appl Physiol 30: 153-157, 1971 4. Lowry O H , Roscbrough NJ, Farr A L , Randall RJ Protein measurement with the Folin phenol reagent. J Biol Chem 193: 265-275, 1951 5 Szasz G. Busch E-W, Farohs H-B: Serum-Kreatinkinase. I. Mcthodischc erfahrungen und normalwcrtc mtt einem neucn handelsUblichen Test. Dtsch Med Wochenschr 95: 829-835, 1970 6 Barrett A J : Lysosomal enzymes. In Lysosomes: A Laboratory Handbook, edited by JT Dingle. Amsterdam, North-Holland, 1972, pp 46-135 7. Kao R, Rannels DE, Morgan H: Preparation of homogenates of heart muscle for the assay of lysosomal enzyme activities. In Lysosomes in Biology and Pathology, vol 4, edited by JT Dingle, RT Dean. Amsterdam, North-Holland, 1975, pp 184-187 8. Wildenthal K, Allen DO. Karlsson J, Wakeland JR. Clark C M J r Responsiveness to glucagon in fetal hearts: species variability and apparent disparities between changes in beating, adenylale cyclase activation, and cyclic A M P concentration. J Clin Invest 57: 551-558, 1976 9. Wildenthal K: Foetal maturation of cardiac metabolism. In Foetal and Neonatal Physiology, edited by RS Comline ct al Cambridge, Cambridge University Press, 1973, pp 181-185 10. Wittels B, Brcssler R: Lipid metabolism in the newborn heart J Clin Invest 44: 1639-1646, 1965 11. Warshaw JB, Terry M L : Cellular energy metabolism during fetal development. I I . Fatly acid oxidation by the developing heart J Cell Biol 44: 354-360, 1970 12. Bird JWC Skeletal muscle lysosomes. In Lysosomes in Biology and Pathology, vol 4, edited by JT Dingle, RT Dean. Amsterdam. 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Noguchi T, Miyazawa E, Kametaka M: Protease and protease inhibitor activity in rat skeletal muscle during growth, protein deficiency and fasting Agr Biol Chem (Tokyo) 38: 253-257. 1974 19. Banno Y, Shiotam T, Towatan T, Yoshikawa D, Kalsunuma T, Afting E-G, Kalunuma N: Studies on new intracellular proteases in various organs of rat. I I I . Control of group-specific protease under physiological conditions. Eur J Biochem 52: 59-64, 1975 20. Mortimore GE, Neely A N Regulatory effects of insulin, glucagon and amino acids on hepatic protein turnover in association with alterations of the lysosomal system. In Intracellular Protein Turnover, edited by RT Schimke, N Katunuma. New York. Academic Press, 1975, pp 265-279 21. Wildenthal K Inhibition by insulin of cardiac cathepsin D activity. 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K Wildenthal Downloaded from http://circres.ahajournals.org/ by guest on June 17, 2017 Circ Res. 1976;39:441-446 doi: 10.1161/01.RES.39.3.441 Circulation Research is published by the American Heart Association, 7272 Greenville Avenue, Dallas, TX 75231 Copyright © 1976 American Heart Association, Inc. All rights reserved. Print ISSN: 0009-7330. Online ISSN: 1524-4571 The online version of this article, along with updated information and services, is located on the World Wide Web at: http://circres.ahajournals.org/content/39/3/441 Permissions: Requests for permissions to reproduce figures, tables, or portions of articles originally published in Circulation Research can be obtained via RightsLink, a service of the Copyright Clearance Center, not the Editorial Office. Once the online version of the published article for which permission is being requested is located, click Request Permissions in the middle column of the Web page under Services. 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