Localization of proliferating cell nuclear antigen in the developing and mature rat heart cell.

BACKGROUND: The cardiac muscle cell ceases to divide shortly after birth; this cessation is followed by a limited period when DNA synthesis and karyokinesis occur without cytokinesis. The regulation of this process is not known. The purpose of this study is to explore the possible events that could lead to the cessation of cardiac muscle cell division. One protein requisite for DNA synthesis is proliferating cell nuclear antigen (PCNA). This protein is the auxiliary protein of DNA polymerase delta. METHODS: Rats of fetal age day 18 or days 0, 4, 8, 12, and 16 after birth were obtained. In addition, adult hearts were used for this study. Hearts from the fetal day-18 rats and the day-0 neonatal rats were digested. Cardiac myocytes were isolated and placed in culture for an analysis of DNA synthesis by using tridiated thymidine. Ventricular muscle tissue was isolated from hearts of all ages and frozen in liquid nitrogen for Northern and Western blot analyses. RESULTS: Tridiated thymidine analysis revealed that, although serum stimulation significantly increased the number of labeled fetal cardiac muscle cells, it did not have that effect on neonatal cardiac muscle cells in culture. Northern blot analysis revealed that the steady state levels of mRNA for PCNA remained constant from fetal day 18 through day 4 after birth. Steady state levels declined during the second postnatal week and then reached basal levels by day 16. PCNA message was still present in adult heart tissue. By using indirect immunofluorescence and Western blotting, PCNA protein could be located in the nucleus of cardiac muscle cells during the first 2 weeks after birth. At 16 days after birth, the protein was found in the cytoplasm in very low amounts but was not found in the nucleus. The protein was barely detectable by Western blotting in the cytoplasmic fraction from the adult myocardium. CONCLUSIONS: The results of this study suggest that the PCNA message and protein product declined after birth, but both were present at low levels in the adult myocardium. However, the PCNA protein was not translocated to the nucleus in adult myocardial cells. The events involving PCNA correlated closely with the time period when cell division and then DNA synthesis ceased in these cells.

Impairment of myocyte contractility following coronary artery narrowing is associated with activation of the myocyte IGF1 autocrine system, enhanced expression of late growth related genes, DNA synthesis, and myocyte nuclear mitotic division in rats.

To determine whether the alterations in ventricular loading and myocyte cellular contractile performance produced by short-term coronary artery constriction were associated with the activation of genes implicated in myocyte DNA synthesis including changes in the expression of insulin-like growth factor-1 (IGF1) and insulin-like growth factor-1 receptors (IGF1-R), nonocclusive coronary artery narrowing (CAN) was induced in rats. Animals were examined 2 and 7 days after coronary constriction. Following the in vivo documentation of severe impairment of ventricular performance, estimations of single-cell mechanics in vitro showed that peak shortening was decreased in left and right myocytes of coronary stenosed rats. Moreover, time to peak shortening was prolonged whereas velocity of shortening was decreased. These defects in myocyte contractility were accompanied by increases in cell length and width, indicative of myocyte enlargement biventricularly. In addition, CAN led to an enhanced expression of proliferating cell nuclear antigen (PCNA) and histone-H3 genes in myocytes at 2 and 7 days after surgery. PCNA protein was also detected in these stressed cells. These molecular responses were associated with increases in mRNA for IGF1 and IGF1-R in combination with enhanced DNA synthesis and appearance of myocyte nuclear mitotic division. In conclusion, cardiac myocytes may respond to the elevation in wall and myocyte stress by activating an IGF1-IGF1-R autocrine system which may modulate the induction of late growth related genes which are essential for DNA replication and myocyte cellular hyperplasia.

c-myb transactivates cdc2 expression via Myb binding sites in the 5'-flanking region of the human cdc2 gene.

The c-myb protooncogene is preferentially expressed in hematopoietic cells and is required for cell cycle progression at the G1/S boundary. Because c-myb encodes a transcriptional activator that functions via DNA binding, it is likely that c-myb exerts its biological activity by regulating the transcription of genes required for DNA synthesis and cell cycle progression. One such gene, cdc2, encodes a 34-kDa serine-threonine kinase that appears to be required for G1/S transition in normal human T-lymphocytes. To determine whether c-myb is a transcriptional regulator of cdc2 expression, we subcloned a segment of a cdc2 human genomic clone containing extensive 5'-flanking sequences and part of the first exon. Sequence analysis revealed the presence of two closely spaced Myb binding sites that interact with bacterially synthesized Myb protein within a region extending from nucleotides -410 to -392 upstream of the transcription initiation site. A 465-base pair segment of 5'-flanking sequence containing these sites was linked to the CAT gene and had promoter activity in rodent fibroblasts. Cotransfection of this construct with a full-length human c-myb cDNA driven by the early simian virus 40 promoter resulted in a 6-8-fold enhancement of CAT activity that was abrogated by mutations in the Myb binding sites. These data suggest that c-myb participates in the regulation of cell cycle progression by activating the expression of the cdc2 gene.

Proliferating cell nuclear antigen in developing and adult rat cardiac muscle cells.

During early development, rat cardiac muscle cells actively proliferate. Shortly after birth, division of cardiac muscle cells ceases, whereas DNA synthesis continues for approximately 2 weeks at a progressively diminishing rate. Little DNA synthesis or cell division occurs in adult cardiocytes. Thus, developing cardiac muscle cells are an ideal system in which to examine the expression of cell cycle-regulated genes during development. We chose to examine proliferating cell nuclear antigen (PCNA), a gene expressed at the G1/S phase boundary of the cell cycle. Northern blots of RNA from cardiac muscle cells from 18-day-old rat fetuses and from day 0, 5, and 14 neonatal as well as adult rat hearts revealed that the PCNA mRNA was found in cardiac muscle cells from all ages. However, because it was possible that this was a result of fibroblast PCNA gene expression, we used reverse transcription followed by polymerase chain reaction to see if it was possible to detect the message for PCNA in cardiac muscle cells from all ages. Because of the great sensitivity of this technique, RNA was recovered from 25 isolated adult cardiac muscle cells. Polymerase chain reaction amplification products for PCNA produced from the RNA isolated from these cells conclusively demonstrated that mRNA for this gene, which normally is associated with proliferating cells, is expressed in adult cardiac muscle cells that no longer divide. Furthermore, Western blot analysis demonstrated that the PCNA protein was found only in embryonic and neonatal cells and not in adult rat cardiac muscle cells. Therefore, it might be inferred from these data that PCNA might be regulated at the posttranscriptional level in adult cardiac muscle cells.

Norepinephrine-induced cardiac hypertrophy of the cat heart.

Norepinephrine administration causes progressive hypertrophy of the mammalian heart as measured by myocardial mass. The purpose of this study was to determine the growth response of the myocardial tissue components as well as the myocardial cell itself to norepinephrine. Young, adult cats were given low doses of norepinephrine in dextrose or dextrose alone twice daily for 15 days. On day 16, there were no changes in the animals body weight, right ventricular systolic pressure, right ventricular end-diastolic pressure, heart rate, cardiac index, or blood pressure. However, the right ventricle/body weight, the left ventricle/body weight and the total heart weight/body weight were increased significantly in the norepinephrine treated animals. The increase was on the order of 40%. The cardiac muscle cell was also significantly increased in size and both the right and left ventricular cardiac muscle cells exhibited a dramatic increase in size as measured by cross sectional area. Upon stereological examination it was found that the amount of hypertrophy as seen in the cardiac muscle cells was paralleled by the hypertrophy seen in the other tissue components of the myocardium. The volume density of the muscle cells, the interstitial components, as well as the blood vessel compartment were identical in the control and in the norepinephrine-treated groups. In conclusion, this study demonstrates that the response of the myocardium to norepinephrine is similar to that seen in response to a volume overload rather than that seen in response to pressure overload.

Mechanical properties of adult feline ventricular myocytes in culture.

The contractile and electrophysiological properties of cultured adult feline ventricular myocytes were studied. Cells were field stimulated and contraction was measured using a video-based edge detector. The magnitude of contraction decreased by 36% and the rate of contraction decreased by 52% 2 h after the cells were plated on laminin-coated cover slips. The magnitude and rate of contraction then remained stable for 1 wk. The duration of contraction prolonged and a second component to the twitch frequently, but not invariably, developed after 5 days in culture. This was associated with prolongation of the action potential duration. After 7 days in culture, cells could be divided into two groups based on resting membrane potential. Norepinephrine increased the magnitude of contraction for 5 days after plating. Cultured ventricular myocytes became unresponsive to the effects of norepinephrine after 7 days. Adult cardiac myocytes maintained in primary culture continue to respond to field stimulation and retain many contractile properties for up to 7 days; however, the functional characteristics of these cells do not remain uniform during this time period.

Effects of norepinephrine on neonatal rat cardiocyte growth and differentiation.

Norepinephrine stimulates the growth in size of nondividing neonatal cardiocytes. During this time the neonatal cardiocyte is in a period of transition in which the cell can synthesize DNA and yet does not divide. Because the cell undergoes karyokinesis without cytokinesis the objective of this study was to determine whether the norepinephrine-induced growth in size of the neonatal cardiocyte was accompanied by an increase in a) the number of cardiocytes synthesizing DNA, b) the number of binucleate cardiocytes, and c) organized myofibrils. One- to four-d-old neonatal rat heart cells were isolated and placed in serum-free medium which was then supplemented with serum, norepinephrine, norepinephrine plus propranolol, or isoproterenol. After 4 d the number and size of the cells was determined using a Coulter counter. In other cultures cardiocytes were fixed on Days 0, 1, 2, and 4, and an increase in the number of binucleate cardiocytes was found in all treatment groups including controls. However, the rate of binucleation was faster in the norepinephrine group. It was also determined by proliferating cell nuclear antigen (PCNA) antibody staining that by Day 4, over 50% of the cardiocytes were in the cell cycle. The percentage of cells in which PCNA could be detected was higher in the norepinephrine and norepinephrine plus propranolol groups. Furthermore, there was a concomitant increase in the amount and organization of myofibrils in the catecholamine-treated cardiocytes.

Effects of catecholamines on fetal rat cardiocytes in vitro.

Norepinephrine stimulates the growth in size of non-dividing, neonatal cardiac muscle cells, and it can stimulate the growth in numbers of dividing hepatocytes and endothelial cells in culture. The objective of this study was to test the hypothesis that in dividing fetal cardiocytes, norepinephrine would stimulate growth in cell number rather than in cell size. Fourteen-day fetal heart cells were placed in serum-free or serum-supplemented cultures in the presence or absence of norepinephrine (NE), NE plus propranolol, or isoproterenol for 4 days. Almost 90% of the cardiocytes in serum-supplemented medium were in the cell cycle as determined by proliferating cell nuclear antigen (PCNA) antibody staining during this period. In addition, between days 2 and 4 of culture, 35% and 40% of these cardiocytes were labeled with 3H-thymidine. After 4 days the cardiocytes increased in cell number in the serum-supplemented NE cultures as compared to serum-free cultures. In contrast, there was no significant change in cardiocyte volume between any of the groups examined. It was concluded that in dividing muscle cell populations the effect of norepinephrine was to enhance cell proliferation rather than to stimulate cell growth in size.

Role of contraction in the structure and growth of neonatal rat cardiocytes.

The aim of this study was to determine the role of contraction in the regulation of neonatal rat cardiocyte growth in size. To accomplish this objective, experiments were done on four groups of cardiocytes: 1) quiescent cardiocytes attached to a substrate, 2) contracting cardiocytes attached to a substrate, 3) quiescent cardiocytes not attached to a substrate, adn 4) contracting cardiocytes not attached to a substrate. The cardiocytes were grown in both serum-free and serum-supplemented media for up to 1 wk, and cardiocyte surface area, volume, number, and fine structure were evaluated. The most important result of this study was that cardiocytes, which are attached to a substrate and stimulated to contract, grow in size. However, neither contraction alone nor attachment to a substrate by itself resulted in neonatal cardiocyte growth in size in defined serum-free medium. Another important finding was that other nonspecific growth promoters, such as those found in serum, stimulated more substantial growth in cardiocyte size in contracting cardiocytes that were attached to a substrate.

Oncocytic cardiomyopathy of infancy with Wolff-Parkinson-White syndrome and ectopic foci causing tachydysrhythmias in children.

Two female infants, ages 6 months and 13 months, were first seen in the newborn period with supraventricular tachycardia associated with Wolff-Parkinson-White syndrome. One infant had echocardiographic and angiographic evidence of diffuse cardiomyopathy and died suddenly at home. The other infant was seen initially at 13 months of age with refractory ventricular tachycardia and died following surgical resection of arrhythmogenic foci on the left and right ventricles. Autopsy showed diffuse patchy oncocytic cardiomyopathy in both instances. Serial histologic sections of the cardiac conduction system showed oncocytic involvement of the atrioventricular (AV) node, His bundle, and bundle branches. Both infants had interruption of the anulus fibrosus by oncocytic cells at several sites, resulting in multiple accessory AV and nodoventricular connections. Additionally, patient No. 1 had an accessory AV connection by oncocytic cells in the fatty fibrous tissue of the left AV sulcus. To our knowledge, this is the first report of multiple accessory AV connections of oncocytic cells seen during histologic study. In addition, both infants had oncocytic involvement of the exocrine and endocrine glands. This report discusses the clinicopathologic correlations in these two patients, the literature on oncocytic cardiomyopathy, and the types of dysrhythmias found in these patients and their management.

Control of myocardial tissue components and cardiocyte organelles in pressure-overload hypertrophy of the cat right ventricle.

Previous studies have demonstrated that there is a disproportionate increase in connective tissue in right ventricular myocardium subjected to pressure-overload hypertrophy associated with depressed cardiac contractility. While the myocardium is primarily responsive to load, the aim of the present study was to determine whether catecholamines also modulate the response of myocardial tissue components and cardiocyte organelles in pressure-overload-induced cardiac hypertrophy. Four experimental groups of cats were examined: a sham-operated control group, a group which had their pulmonary arteries banded in order to induce a pressure overload, a group which had been subjected to the same pressure overload, but in addition had beta-adrenoceptor blockade produced prior to and during the pressure overloading, and a group which had been subjected to the same pressure overload, but in addition had alpha-adrenoceptor blockade produced prior to and maintained during the pressure overloading. As in our previous study, there was a significant and equivalent degree of right ventricular hypertrophy in all experimental groups with pressure overload when assessed either as the ratio of right ventricular weight to body weight or as cardiocyte cross-sectional area. At the light microscopic level, the disproportionate increase in the volume density of myocardial connective tissue seen in banded animals was completely prevented by either alpha- or beta-adrenoceptor blockade. At the electron microscopic level, there was a reduction in the mitochondrial and myofibrillar volume fractions following beta-adrenoceptor blockade. The results of this study provide evidence for a modulatory role of catecholamines in the control of myocardial connective-tissue proliferation in pressure-overload-induced cardiac hypertrophy. There is also evidence to support the role of the adrenergic nervous system in regulating cardiocyte subcellular organelles, independent of the regulation of cardiocyte size.

Load regulation of the properties of adult feline cardiocytes. The role of substrate adhesion.

We have recently described rapid and reversible changes in cardiac structure, function, and composition in response to surgical load alteration in vivo. In the present study, we used a simple, well-defined in vitro experimental model system, consisting of terminally differentiated quiescent adult cat ventricular cardiocytes maintained in serum-free culture medium, to assess more definitively the role of loading conditions in regulating these same biological properties of heart muscle. Cardiocytes considered to be externally loaded were adherent throughout their length to a protein substrate, such that the tendency for the ends of the cells to retract was prevented. Cardiocytes considered to be unloaded were not adherent to a substrate and, thus, were free to assume a spherical shape. Cardiocyte structure and surface area were assessed, in initially identified cells, both by serial light microscopy and by terminal electron microscopy. Cardiocyte function was assessed in terms of the ability to exclude trypan blue, to remain quiescent with relaxed sarcomeres containing I-bands, and to shorten in response to electrical stimulation. Cardiocyte composition was first assessed by quantitative gel electrophoresis of proteins and then by microfluorimetric measurement of ribonucleic acid, protein, and deoxyribonucleic acid. In addition, cardiocyte incorporation of [3H]thymidine into deoxyribonucleic acid and [3H]uridine into ribonucleic acid were measured. Loading via substrate adhesion was found to be very effective in terms of each of these measurements in retaining the differentiated features of adult cardiocytes for up to 2 weeks in culture; unattached and thus unloaded cardiocytes quickly dedifferentiated. Conditions thought to stimulate cardiac growth, including catecholamine stimulation, were found to be ineffective. These experiments demonstrate that external load has a primary role in the maintenance of the basic differentiated properties of adult mammalian cardiocytes.

Reversibility of the structural effects of pressure overload hypertrophy of cat right ventricular myocardium.

The purpose of the present quantitative structural study was to determine whether the histological alterations seen in pressure overloaded myocardium return to normal, as in vitro contractile function does, upon removal of the pressure overload stimulus. Three experimental groups of four cats each were studied: a group with pulmonary artery banding to create a pressure overload, a group that had been subjected to an equivalent duration of pressure overload and then had that pressure overload removed, and a group of sham-operated controls. Seven to 10 weeks after each operative procedure, the right ventricular pressure was elevated only in the pulmonary artery-banded group. The right ventricle/body weight ratio was significantly increased in the pressure overloaded group only. The body weight at sacrifice, the left ventricle/body weight ratio, and the right ventricular end-diastolic pressure did not differ significantly in the three groups. The striking histological changes in the right ventricular myocardium hypertrophing in response to a pressure overload were the decrease in the volume density of cardiocytes and the increase in connective tissue in papillary muscles. These were reversed when the pressure overload was removed. This study demonstrates that when a pressure overload is removed, myocardial structure returns to normal as the function returns to normal. Given the critical importance of the proportion of cardiocytes and connective tissue components to both systolic and diastolic cardiac function, these data support the hypothesis that the abnormal proportions of these structures provide a potential morphological basis for at least some of the functional abnormalities observed in pressure overload hypertrophy of the cat right ventricle.

Structural analysis of pressure versus volume overload hypertrophy of cat right ventricle.

Pressure overload of cat right ventricle causes progressive abnormalities of in vitro contractile function at a time when in vivo contractile function is normal. In marked contrast, the same degree and duration of volume overload of cat right ventricle results in neither in vitro nor in vivo contractile dysfunction. The purpose of the present quantitative structural study was to determine whether there were any histological alterations in pressure-overloaded myocardium that might be causally related to the contractile dysfunction found only in this model. Four experimental groups of eight cats each were studied: a group with pulmonary arterial banding to create a pressure overload, sham-operated controls for this group, a group with atrial septal defects to create a volume overload, and sham-operated controls for this group. Seven to ten weeks after each operative procedure, right ventricular pressure was elevated only in the pressure-overloaded group, pulmonary-to-systemic blood flow ratio was increased only in the volume-overloaded group, and right ventricle-to-body weight ratio was significantly and comparably increased in both the pressure- and the volume-overloaded groups. There was a single striking histological distinction between myocardium hypertrophying in response to pressure as opposed to volume overload: the volume density of cardiocytes in papillary muscles from pressure-overloaded right ventricles was decreased significantly with a proportional increase in connective tissue. Given the critical importance of these two myocardial components to both systolic and diastolic cardiac function, these data provide a potential structural basis for at least some of the functional abnormalities observed in pressure but not in volume overload hypertrophy of the cat right ventricle.

Hemodynamic versus adrenergic control of cat right ventricular hypertrophy.

The purpose of this study was to determine whether cardiac hypertrophy in response to hemodynamic overloading is a primary result of the increased load or is instead a secondary result of such other factors as concurrent sympathetic activation. To make this distinction, four experiments were done; the major experimental result, cardiac hypertrophy, was assessed in terms of ventricular mass and cardiocyte cross-sectional area. In the first experiment, the cat right ventricle was loaded differentially by pressure overloading the ventricle, while unloading a constituent papillary muscle; this model was used to ask whether any endogenous or exogenous substance caused uniform hypertrophy, or whether locally appropriate load responses caused ventricular hypertrophy with papillary muscle atrophy. The latter result obtained, both when each aspect of differential loading was simultaneous and when a previously hypertrophied papillary muscle was unloaded in a pressure overloaded right ventricle. In the second experiment, epicardial denervation and then pressure overloading was used to assess the role of local neurogenic catecholamines in the genesis of hypertrophy. The degree of hypertrophy caused by these procedures was the same as that caused by pressure overloading alone. In the third and fourth experiments, beta-adrenoceptor or alpha-adrenoceptor blockade was produced before and maintained during pressure overloading. The hypertrophic response did not differ in either case from that caused by pressure overloading without adrenoceptor blockade. These experiments demonstrate the following: first, cardiac hypertrophy is a local response to increased load, so that any factor serving as a mediator of this response must be either locally generated or selectively active only in those cardiocytes in which stress and/or strain are increased; second, catecholamines are not that mediator, in that adrenergic activation is neither necessary for nor importantly modifies the cardiac hypertrophic response to an increased hemodynamic load.

Cardiac atrioventricular junctional tissues in hearts from infants who died suddenly.

The cause of sudden infant death syndrome is not known at present. Most agree that in the majority of cases it involves primary apnea. However, cardiac abnormalities probably account for a subset of these deaths. An investigation into the structure of the atrioventricular (AV) junctional tissues of the heart would provide insight into the frequency of sudden death in infants that might result from abnormal cardiac morphology. The hearts of seven infants who died from diagnosed sudden infant death syndrome were examined by serially sectioning and studying this critical region of the heart. The hearts of these infants could be divided into three groups on the basis of their morphologic features. In the first group, represented by two cases, there were marked variations from normal, the most striking feature being the presence of accessory pathways. In the second group, represented by four cases, the AV junctional tissues were not fully mature and clusters of AV nodal and bundle cells were dispersed throughout the anulus fibrosus. In the third group, the structure of the junctional tissues was normal. There remains a distinct subset of infants who might have died suddenly and unexpectedly from cardiac abnormalities that needs to be more completely defined.

Biochemical and structural correlates in unloaded and reloaded cat myocardium.

Cardiocytes of unloaded myocardium rapidly lose structural and functional integrity through a combined loss of myofibrils and contractile activity; both changes are reversible with load restoration. The present study correlates the biochemical composition of unloaded and reloaded myocardium with these alterations in structure and function. Cardiac muscle was unloaded by transecting the chordae tendineae of a cat right ventricular papillary muscle and was reloaded by suturing these same chordae tendineae to the ventricular wall at the base of the valve; an adjacent intact muscle served as the control. Muscles unloaded for 1 to 14 days were assayed for DNA, protein, total creatine and hydroxyproline content. The ratios of wet weight/DNA and creatine/DNA decreased by 30 and 22% respectively, in parallel with a 38% reduction in cardiocyte cross-sectional area. Protein/unit wet weight was decreased by 50% after 14 days of unloading, so that both protein/DNA and protein/creatine were markedly reduced. Reloading of the muscle restored cardiocyte size, protein per unit wet weight and protein/DNA to normal. Parallel reductions in both contractile filaments and contractile proteins after unloading and parallel increases in each following load restoration were demonstrated by morphometric analysis of electron micrographs and analysis of actin and myosin by gel electrophoresis. In summary, the myocardium undergoes marked, parallel changes in structure, function and biochemical composition in response to the removal and restoration of load.

Atrophy reversal and cardiocyte redifferentiation in reloaded cat myocardium.

We have recently described rapid cardiac atrophy in response to decreased load. The present study was designed to determine whether this atrophy is solely a degenerative response of damaged myocardium or is, instead, an adaptive response of viable myocardium. A discrete portion of cat myocardium was unloaded by severing the chordae tendinae of a single right ventricular papillary muscle. One week later, the muscle was reloaded by attachment of its apex to the ventricular free wall. This allowed the load to be removed and restored without altering the blood supply, innervation, or frequency of contraction of the tissue. In myocardium unloaded for 1 week, the cardiocyte cross-sectional area and the volume densities of mitochondria and myofibrils decreased significantly. Large areas of cytoplasm were devoid of organelles, and the few remaining myofilaments were oriented in a variety of directions rather than longitudinally within the cell. Upon reloading for 1 week, the cardiocyte cross-sectional area, volume density of mitochondria, and ultrastructural organization all returned to normal. The volume density of the myofibrils increased toward control, and they reoriented with respect to the long axis of the cardiocyte. The contractile function of the papillary muscles, which was depressed as early as 1 day after unloading and almost absent at times later than 3 days after unloading, returned to normal after 2 weeks of reloading. This study demonstrates that adult mammalian myocardium responds to unloading with a marked loss of cellular differentiation, organization, and function which is fully reversible with reloading. This plasticity in response to load may well be the basic mechanism responsible for the development and maintenance of normal cardiac structure and function.

Complete reversibility of cat right ventricular chronic progressive pressure overload.

Chronic, progressive pressure overload of the cat right ventricle produces persistent, ongoing abnormalities of contractile, energetic, and biochemical function in vitro at a time when in vivo pump function is still normal. The present study tested the reversibility of the in vitro changes in this clinically relevant hypertrophy model. Fourteen sham-operated and 14 reversal cats were studied. After banding the animals as 1-kg kittens, right ventricular pressures were normal. Before band removal (25.2 +/- 0.5 weeks later for the control group and 25.5 +/- 0.3 weeks later for the hypertrophy reversal group), systolic right ventricular pressures were 24 +/- 1 mm Hg for controls and 71 +/- 5 mm Hg for the hypertrophy reversal group (P less than 0.05). At study, 19.5 +/- 1.1 weeks after a second sham operation for controls or 18.7 +/- 0.7 weeks after band removal for the hypertrophy reversal group, these pressures were 24 +/- 1 mm Hg for controls and 23 +/- 1 mm Hg for the hypertrophy reversal group (P = NS); cardiac output was 0.18 +/- 0.01 liters/kg per min for controls and 0.19 +/- 0.01 liters/kg per min for the hypertrophy reversal group (P = NS). The ratio of right ventricle to body weight was normal in both groups, as was the right ventricular papillary muscle myocyte cross-sectional area and the myocardial collagen concentration. A right ventricular papillary muscle from each cat was studied at 29 degrees C in a polarographic myograph. Preloaded shortening velocity was 0.79 +/- 0.04 muscle lengths/sec for controls and 0.86 +/- 0.03 muscle lengths/sec for the hypertrophy reversal group (P = NS); extent of shortening was 0.15 +/- 0.01 muscle lengths for controls and 0.16 +/- 0.01 muscle lengths for the hypertrophy reversal group (P = NS).(ABSTRACT TRUNCATED AT 250 WORDS)

Early morphological alterations of pressure-overloaded cat right ventricular myocardium.

Pressure overload of the right ventricle results in an increase in ventricular mass. It also results in abnormal in vitro contractile function in advance of the onset of congestive heart failure as determined in papillary muscles removed from these ventricles. To correlate these functional abnormalities with any early underlying morphological changes, a band was placed around the proximal pulmonary artery of cats. This band restricted the lumen to 20% of normal and was left in place for 2 weeks. At that time, hemodynamic variables were measured to insure that right ventricular pressure overload had been produced. The hearts were then perfusion fixed, and papillary muscles from the right ventricle were prepared for light and transmission electron microscopy. Quantitative morphological data were obtained for the volume density both of several tissue components and of several organelles. It was found that there are significant increases in myocyte cross-sectional area and diameter in hypertrophied tissue with a concurrent increase in the volume density of interstitial tissue. There are no alterations in the volume density of organelles in the hypertrophied myocytes. We suggest that the substantial increase in the proportion of connective tissue and the decrease in the surface area to volume ratio that accompany pressure overload cardiac hypertrophy may be early underlying structural changes that relate directly to the abnormal contractile function found in this type of hypertrophy.