High-efficiency gene transfer into cardiac myocytes

Gene Transfer in Isolated Adult Cardiomyocytes

During the past few decades, gene delivery using recombinant virus has made tremendous progress. With a higher than 80 % transduction efficiency, even in non-dividing cells, viral transduction has become the method of choice for efficient gene transfer into cardiomyocytes. However, in vitro gene delivery is dependent on a robust cell isolation protocol, as prolonged cultivation is needed to initiate gene expression and target specific cellular processes. This chapter describes some of the important steps that need to be considered for successful in vitro gene transfer into adult cardiomyocytes. Included are detailed protocols for isolating cells, maintaining rod shaped cardiomyocytes in culture over several days, and employing adenovirus for gene transduction.

Methods in cardiomyocyte isolation, culture, and gene transfer

Since techniques for cardiomyocyte isolation were first developed 35 years ago, experiments on single myocytes have yielded great insight into their cellular and sub-cellular physiology. These studies have employed a broad range of techniques including electrophysiology, calcium imaging, cell mechanics, immunohistochemistry and protein biochemistry. More recently, techniques for cardiomyocyte culture have gained additional importance with the advent of gene transfer technology. While such studies require a high quality cardiomyocyte population, successful cell isolation and maintenance during culture remain challenging. In this review, we describe methods for the isolation of adult and neonatal ventricular myocytes from rat and mouse heart. This discussion outlines general principles for the beginner, but also provides detailed specific protocols and advice for common caveats. We additionally review methods for short-term myocyte culture, with particular attention given to the importance of substrate and media selection, and describe time-dependent alterations in myocyte physiology that should be anticipated. Gene transfer techniques for neonatal and adult cardiomyocytes are also reviewed, including methods for transfection (liposome, electroporation) and viral-based gene delivery.

Importance of divalent cations in nanolipoplex gene delivery

Gene therapy is a promising therapeutic strategy to combat genetic or acquired diseases at their root cause rather than just treating symptoms. It is well recognised that there is an urgent need for non-toxic and efficient gene delivery vectors to fully exploit the current potential of gene therapy in molecular medicine. Cell-specific targeting of bioactive nucleotides is a prerequisite to attain the concentration of nucleic acids required for therapeutic efficacy in the target tissue. Many metal ions such as Mg2+, Mn2+, Ba2+ and, most importantly, Ca2+ have been demonstrated to have significant roles in gene delivery. These inorganic cations show low toxicity, good biocompatibility and promise for controlled delivery properties, thus presenting a new alternative to toxic and immunogenic carriers. Recently, inorganic nanoparticles alone, or in combination with a colloidal particulate system such as nanoliposome, an advanced approach to gene delivery, were found to exert a positive effect on gene transfer. In this report, the role of the divalent cations in nucleic acid delivery, particularly with respect to the potential improvement of transfection efficiency of nanolipoplexes, is reviewed.

Differential interactions between transforming growth factor-beta3/TbetaR1, TAB1, and CD2AP disrupt blood-testis barrier and Sertoli-germ cell adhesion

The biochemical basis that regulates the timely and selective opening of the blood-testis barrier (BTB) to migrating preleptotene/leptotene spermatocytes at stage VIII of the epithelial cycle in adult rat testes is virtually unknown. Recent studies have shown that cytokines (e.g. transforming growth factor (TGF)-beta3) may play a crucial role in this event. However, much of this information relies on the use of toxicants (e.g. CdCl(2)), making it difficult to relay these findings to normal testicular physiology. Here we report that overexpression of TGF-beta3 in primary Sertoli cells cultured in vitro indeed perturbed the tight junction (TJ) barrier with a concomitant decline in the production of BTB constituent proteins as follows: occludin, N-cadherin, and ZO-1. Additionally, local administration of TGF-beta3 to testes in vivo was shown to reversibly perturb the BTB integrity and Sertoli-germ cell adhesion via the p38 MAPK and ERK signaling pathways. Most importantly, the simultaneous activation of p38 and ERK signaling pathways is dependent on the association of the TGF-beta3-TbetaR1 complex with adaptors TAB1 and CD2AP because if TbetaR1 was associated preferentially with CD2AP, only Sertoli-germ cell adhesion was perturbed without compromising the BTB. Collectively, these data illustrate that local production of TGF-beta3, and perhaps other TGF-betas and cytokines, by Sertoli and germ cells into the microenvironment at the BTB during spermatogenesis transiently perturbs the BTB and Sertoli-germ cell adhesion to facilitate germ cell migration when the activated TbetaRI interacts with adaptors TAB1 and CD2AP. However, TGF-beta3 selectively disrupts Sertoli-germ cell adhesion in the seminiferous epithelium to facilitate germ cell migration without compromising BTB when TbetaRI interacts only with adaptor CD2AP.

Role of direct RhoA-phospholipase D1 interaction in mediating adenosine-induced protection from cardiac ischemia

Activation of adenosine A1 or A3 receptors protects heart cells from ischemia-induced injury. The A3 receptor signals via RhoA and phospholipase D (PLD) to induce cardioprotection. The objective of the study was to investigate how RhoA activates PLD to achieve the anti-ischemic effect of adenosine A3 receptors. In an established cardiac myocyte model of preconditioning using the cultured chick embryo heart cells, overexpression of the RhoA-noninteracting PLD1 mutant I870R selectively blocked the A3 agonist (Cl-IBMECA, 10 nM)-induced cardioprotection. I870R caused a significantly higher percentage of cardiac cells killed in A3 agonist-treated than in A1 agonist (CCPA, 10 nM)-treated myocytes (ANOVA and posttest comparison, P<0.01). Consistent with its inhibitory effect on the PLD activity, I870R attenuated the Cl-IBMECA-mediated PLD activation. Cl-IBMECA caused a 41 +/- 15% increase in PLD activity in mock-transfected myocytes (P<0.01, paired t test) while having only a slight stimulatory effect on the PLD activity in I870R-transfected cells. To further test the anti-ischemic role of a direct RhoA-PLD1 interaction, atrial cardiac myocytes were rendered null for native adenosine receptors by treatment with irreversible A1 antagonist m-DITC-XAC and were selectively transfected with the human adenosine A1 or A3 receptor cDNA individually or they were cotransfected with cDNAs encoding either receptor plus I870R. I870R preferentially inhibited the human A3 receptor-mediated protection from ischemia. The RhoA-noninteracting PLD1 mutant caused a significantly higher percentage of cardiac cells killed in myocytes cotransfected with the human A3 receptor than in those cells expressing the human A1 receptor (ANOVA and posttest comparison, P<0.01). The present data provided the first demonstration of a novel physiological role for the direct RhoA-PLD1 interaction, that of potent protection from cardiac ischemia. The study further supported the concept that a divergent signaling mechanism mediates the anti-ischemic effect of adenosine A1 and A3 receptors.

P2X4 receptor is a glycosylated cardiac receptor mediating a positive inotropic response to ATP

Although P2X receptors are suggested to play a role in synaptic neurotransmission, the specific physiological role of each P2X receptor subtype remains largely unknown. We used cultured chick embryo ventricular myocytes as a model to study a potential physiological role of the P2X(4) receptor in mediating the positive inotropic effect of ATP. The chick P2X4 receptor (cP2X(4)R) mRNA was expressed in the heart and the pharmacological features of the ATP-induced positive inotropic response were similar to those of the cP2X(4)R in terms of insensitivity to blockade by known P2 receptor antagonists and the ineffectiveness of adenosine 5'-(alpha,beta-methylene)triphosphate as an agonist. Treatment of myocytes with antisense oligonucleotides specific to the 5' region of cP2X(4)R abrogated the P2 agonist-stimulated (45)Ca influx. Similarly, antisense oligonucleotide treatment also blocked the 2-methylthio-ATP-stimulated increase in contractile amplitude. The data suggest that the native P2X(4) receptor is involved in mediating the P2 agonist-stimulated response in the heart. In characterizing the biochemical property of the P2X(4) receptor, antibody against cP2X(4)R detected a 44-kDa and a 58-kDa protein in the immunoblot. Inhibition of N-linked glycosylation by tunicamycin converted the 58-kDa protein to the 44-kDa protein, suggesting that the 58-kDa protein was a glycosylated P2X(4) receptor. The nonglycosylated 44-kDa P2X(4) receptor was resistant to various detergent/aqueous extraction, consistent with a role of glycosylation in maintaining its detergent solubility and hydrophilicity. Cross-linking the cell surface proteins with N-hydroxysuccinimide-SS-biotin followed by affinity precipitation with streptavidin-conjugated agarose and subsequent immunoblotting with anti-cP2X(4)R showed that only the glycosylated 58-kDa P2X(4) receptor was expressed on the cell surface, indicating an important role of glycosylation for the receptor's localization on the plasma membrane. These data revealed a novel physiologic function of the P2X(4) receptor and suggested the importance of N-linked glycosylation in its cell surface expression and detergent solubility.

A novel cardioprotective role of RhoA: new signaling mechanism for adenosine

Adenosine exerts a potent cardioprotective effect that is mediated by adenosine A1 and A3 receptors. The signaling pathways activated by the A1 and A3 receptors are distinct and involve selective coupling to phospholipases C and D, respectively. The objective of our study was to elucidate the signaling mechanism that mediates the coupling of each receptor to its respective phospholipase and to test the role of RhoA as a novel mediator leading from adenosine receptors to cardioprotection. C3 transferase and dominant negative RhoA (RhoAT19N) blocked the A3 receptor-mediated phospholipase D activation and cardioprotection but had no effect on A1 receptor-mediated phospholipase C activation or cardioprotection. In contrast, pertussis toxin treatment caused a greater inhibition of the diacylglycerol accumulation induced by the A1 agonist than by the A3 agonist, and it completely abrogated the A1 agonist-mediated cardioprotection. Thus, adenosine A1 and A3 receptors are linked to different G-proteins. The A3 receptor is coupled via RhoA to activate phospholipase D in exerting its cardioprotective effect, whereas the A1 receptor is linked via Gi to phospholipase C to produce cardioprotective responses. The present study identifies a novel role for RhoA and further suggests its importance in regulating cardiac cellular function.

SERCA2A overexpression decreases the incidence of aftercontractions in adult rabbit ventricular myocytes

K. Davia, E. Bernobich, H. K. Ranu, F. del Monte, C. M. N. Terracciano, K. T. MacLeod, D. L. Adamson, B. Chaudhri, R. J. Hajjar and S. E. Harding. SERCA2a Overexpression Decreases the Incidence of Aftercontractions in Adult Rabbit Ventricular Myocytes. Journal of Molecular and Cellular Cardiology (2001) 33, 1005-1015. Slow relaxation and poor contractile response to increasing stimulation frequency in failing human heart have been strongly linked to a decrease in the activity of the sarcoplasmic reticulum (SR) Ca(2+)-ATPase (SERCA2a). Restoration of SERCA2a levels using gene transfer has beneficial effects on contractile function but, like beta -adrenoceptor stimulation, could potentially produce excess SR Ca(2+), arrhythmias and cell death. We have examined the effects of SERCA2a overexpression in adult rabbit cardiac myocytes, and compared changes in relaxation with those following beta -adrenoceptor stimulation. Myocytes were infected with an adenovirus carrying both SERCA2a and green fluorescent protein (GFP) for positive identification of infected cells. Myocyte survival was significantly enhanced in the infected cultures. There was a reduction in both time-to-peak contraction and time-to-50% relaxation (R50) 48 h after infection. Time-to-90% relaxation (R90) was particularly improved (non-infected 516+/-41 ms, AD.SERCA2a-GFP 230+/-23 ms, n=7 preparations, P<0.001). There was also a decreased incidence of aftercontractions in Ad.SERCA2a-GFP infected myocytes (21+/-5%v 41+/-4% in controls, P<0.01). This contrasts with beta -adrenoceptor stimulation, which reduced R50 but prolonged R90 by 158+/-76 ms (P<0.02, n=16). At higher stimulation frequencies (2-3 Hz) contraction amplitude and SR calcium content were increased and diastolic contracture was reduced following SERCA2a overexpression. Overall, increasing levels of SERCA2a resulted in an improvement in systolic and diastolic function and a reduction in cell death and arrhythmic aftercontractions. SERCA2a overexpression therefore lacks the detrimental effects associated with some other inotropic interventions.

CUG-initiated FGF-2 induces chromatin compaction in cultured cardiac myocytes and in vitro

Fibroblast growth factor-2 (FGF-2) is a mitogen found in CUG-initiated 21-25 kDa ("hi") or AUG-initiated 16-18 kDa ("lo") forms. Previously we demonstrated that "hi"-but not "lo"-FGF-2 caused a distinct nuclear phenotype characterized by apparently condensed chromatin present as separate clumps in the nucleus of cardiac myocytes. In this manuscript we investigated whether these effects were related to apoptosis or mitosis and whether they reflected a direct effect of "hi" FGF-2 on chromatin. Myocytes overexpressing "hi" FGF-2 and presenting the clumped chromatin phenotype: (i) were not labeled above background with antibodies to phosphorylated histones H1 and H3 used as indicators of mitotic chromatin condensation; (ii) did not stain positive for TUNEL; (iii) their nuclear lamina, visualized by anti-laminB immunofluorescence, appeared intact; (iv) neither caspase inhibitors, nor Bcl-2 or "lo" FGF-2 overexpression prevented the manifestation of the compacted nuclear phenotype. Purified recombinant "hi" FGF-2 was more potent than "lo" FGF-2 in promoting the condensation/aggregation of chick erythrocyte chromatin partially reconstituted with histone H1 in vitro. We conclude that the DNA phenotype induced by "hi" FGF-2 in cardiac myocytes likely reflects a direct effect on chromatin structure that does not require the engagement of mitosis or apoptosis. By affecting chromatin compaction "hi" FGF-2 may contribute to the regulation of gene expression.

Distinct cardioprotective effects of adenosine mediated by differential coupling of receptor subtypes to phospholipases C and D

Adenosine released during cardiac ischemia exerts a marked protective effect in the heart that is mediated by the A(1) and A(3) subtypes of adenosine receptors. The signaling pathways activated by these adenosine receptors have now been characterized in a chick embryo ventricular myocyte culture model of cardioprotection against ischemia. Selective A(1) and A(3) receptor agonists were shown to activate phospholipases C and D, respectively, to achieve their distinct cardioprotective effects. The specificity of the A(3) receptor-phospholipase D interaction was also demonstrated in chick embryo atrial myocytes (which do not express endogenous A(3) receptors) that had been transfected with a vector encoding the human A(3) receptor. Activation of both endogenous A(1) and A(3) receptors in ventricular myocytes resulted in a protective response greater than that induced by stimulation of either receptor alone. Agonists that activate both adenosine A(1) and A(3) receptors may thus prove beneficial for the treatment of myocardial ischemia.

Ca(2+) channel modulation by recombinant auxiliary beta subunits expressed in young adult heart cells

L-type Ca(2+) channels contribute importantly to the normal excitation-contraction coupling of physiological hearts, and to the functional derangement seen in heart failure. Although Ca(2+) channel auxiliary beta(1-4) subunits are among the strongest modulators of channel properties, little is known about their role in regulating channel behavior in actual heart cells. Current understanding draws almost exclusively from heterologous expression of recombinant subunits in model systems, which may differ from cardiocytes. To study beta-subunit effects in the cardiac setting, we here used an adenoviral-component gene-delivery strategy to express recombinant beta subunits in young adult ventricular myocytes cultured from 4- to 6-week-old rats. The main results were the following. (1) A component system of replication-deficient adenovirus, poly-L-lysine, and expression plasmids encoding beta subunits could be optimized to transfect young adult myocytes with 1% to 10% efficiency. (2) A reporter gene strategy based on green fluorescent protein (GFP) could be used to identify successfully transfected cells. Because fusion of GFP to beta subunits altered intrinsic beta-subunit properties, we favored the use of a bicistronic expression plasmid encoding both GFP and a beta subunit. (3) Despite the heteromultimeric composition of L-type channels (composed of alpha(1C), beta, and alpha(2)delta), expression of recombinant beta subunits alone enhanced Ca(2+) channel current density up to 3- to 4-fold, which argues that beta subunits are "rate limiting" for expression of current in heart. (4) Overexpression of the putative "cardiac" beta(2a) subunit more than halved the rate of voltage-dependent inactivation at +10 mV. This result demonstrates that beta subunits can tune inactivation in the myocardium and suggests that other beta subunits may be functionally dominant in the heart. Overall, this study points to the possible therapeutic potential of beta subunits to ameliorate contractile dysfunction and excitability in heart failure.

Cardiac myocytes rendered ischemia resistant by expressing the human adenosine A1 or A3 receptor

Adenosine is an important mediator of the endogenous defense against ischemia-induced injury in the heart. Adenosine can achieve cardioprotection by mediating the effect of ischemic preconditioning and by protecting against myocyte injury when it is present during the infarct-producing ischemia. A novel adenosine A3 receptor can mediate this protective function. One approach to achieve cardioprotection is to enhance myocardial sensitivity to the endogenous adenosine by increasing the number of adenosine receptors instead of administering an adenosine receptor agonist. The objective of the present study was to investigate whether genetic manipulation of the cardiac myocyte, achieved by gene transfer and overexpression of the human A3 receptor cDNA, renders the myocytes resistant to the deleterious effect of ischemia. Prolonged hypoxia with glucose deprivation, causing myocyte injury and adenosine release, was used to simulate ischemia in cultured chick embryo ventricular myocytes. During simulated ischemia, cultured myocytes with enhanced expression of the human A3 receptor and showed significantly higher ATP content, fewer cells killed, and less creatine kinase released into the medium than either control or mock-transfected myocytes. Also, increased expression of the A3 receptor caused an enhanced cardioprotective effect by the preconditioning ischemia. Overexpressing the adenosine A1 receptor also led to increased protection against ischemia-induced myocyte injury as well as an enhanced preconditioning effect. Thus, increasing the receptor level improves the myocyte sensitivity to the endogenous adenosine, which in turn causes all of the cardioprotective effects found for exogenously administered adenosine agonists. The study provides the first proof for the new concept that an increased expression of the human A3 receptor in the cardiac myocyte can be an important cardioprotective therapeutic approach.

Ectopic expression of tropomyosin promotes myofibrillogenesis in mutant axolotl hearts

Expression of tropomyosin protein, an essential component of the thin filament, has been found to be drastically reduced in cardiac mutant hearts of the Mexican axolotl (Ambystoma mexicanum) with no formation of sarcomeric myofibrils. Therefore, this naturally occurring cardiac mutation is an appropriate model to examine the effects of delivering tropomyosin protein or tropomyosin cDNA into the deficient tissue. In this study, we describe the replacement of tropomyosin by using a cationic liposome transfection technique applied to whole hearts in vitro. When mouse alpha-tropomyosin cDNA under the control of a cardiac-specific alpha-myosin heavy chain promoter was transfected into the mutant hearts, tropomyosin expression was enhanced resulting in the formation of well-organized sarcomeric myofibrils. Transfection of a beta-tropomyosin construct under control of the same promoter did not result in enhanced organization of the myofibrils. Transfection of a beta-galactosidase reporter gene did not result in the formation of organized myofibrils or increased tropomyosin expression. These results demonstrate the importance of alpha-tropomyosin to the phenotype of this mutation and to normal myofibril formation. Moreover, we have shown that a crucial contractile protein can be ectopically expressed in cardiac muscle that is deficient in this protein, with the resulting formation of organized sarcomeres.

Adenosine Receptor Subtypes and Cardioprotection

Brief ischemia prior to a sustained period of ischemia reduces myocardial infarct size, a phenomenon known as preconditioning. A cardiac ventricular myocyte model has been developed to investigate the role and signaling mechanism of adenosine receptor subtypes in cardiac preconditioning. A 5-min exposure of cardiac myocytes to simulated ischemia, termed preconditioning ischemia, prior to a subsequent 90-min period of ischemia protected them against injury incurred during the 90-min ischemia. Preconditioning ischemia preserved ATP content, reduced percentage of cells killed, and decreased release of creatine kinase into the medium. Activation of the adenosine A1 receptor with CCPA or the A3 receptor with IB-MECA can replace preconditioning ischemia and mimic the protective effect of preconditioning ischemia. Blockade of the A1 receptor with its selective antagonist DPCPX or of the A3 receptor with the A3 selective antagonist MRS1191 during the preconditioning ischemia resulted in only a partial attenuation of the subsequent protection. Incubation with both DPCPX and MRS1191 or with the nonselective antagonist 8-SPT during the preconditioning ischemia completely abolished the protective effect of preconditioning ischemia. The KATP channel opener pinacidil caused a large activation of the KATP channel current and was able to precondition the myocyte. The KATP channel antagonist glibenclamide blocked the cardioprotective effect of preconditioning ischemia when it was included during myocyte exposure to the preconditioning ischemia, indicating that KATP channel is a requisite effector in mediating preconditioning. A receptor-mediated stimulation of phospholipase C or phospholipase D, with consequent activation of protein kinase C and KATP channel, appears to be the signaling mechanism linking adenosine A1 and A3 receptors to the induction of preconditioning. A model of how ischemic preconditioning is triggered and mediated is proposed. Evidence is accumulating to support its validity.

A physiological role of the adenosine A3 receptor: sustained cardioprotection

Adenosine released during cardiac ischemia exerts a potent, protective effect in the heart. A newly recognized adenosine receptor, the A3 subtype, is expressed on the cardiac ventricular cell, and its activation protects the ventricular heart cell against injury during a subsequent exposure to ischemia. A cultured chicken ventricular myocyte model was used to investigate the cardioprotective role of a novel adenosine A3 receptor. The protection mediated by prior activation of A3 receptors exhibits a significantly longer duration than that produced by activation of the adenosine A1 receptor. Prior exposure of the myocytes to brief ischemia also protected them against injury sustained during a subsequent exposure to prolonged ischemia. The adenosine A3 receptor-selective antagonist 3-ethyl 5-benzyl-2-methyl-6-phenyl-4-phenylethynyl-1, 4-(+/-)-dihydropyridine-3,5-dicarboxylate (MRS1191) caused a biphasic inhibition of the protective effect of the brief ischemia. The concomitant presence of the A1 receptor antagonist 8-cyclopentyl-1,3-dipropylxanthine (DPCPX) converted the MRS1191-induced dose inhibition curve to a monophasic one. The combined presence of both antagonists abolished the protective effect induced by the brief ischemia. Thus, activation of both A1 and A3 receptors is required to mediate the cardioprotective effect of the brief ischemia. Cardiac atrial cells lack native A3 receptors and exhibit a shorter duration of cardioprotection than do ventricular cells. Transfection of atrial cells with cDNA encoding the human adenosine A3 receptor causes a sustained A3 agonist-mediated cardioprotection. The study indicates that cardiac adenosine A3 receptor mediates a sustained cardioprotective function and represents a new cardiac therapeutic target.

Enhanced expression of p53 and apoptosis induced by blockade of the vacuolar proton ATPase in cardiomyocytes

Activation of the vacuolar proton ATPase (VPATPase) has been implicated in the prevention of apoptosis in neutrophils and adult cardiac myocytes. To determine the role of the VPATPase in apoptosis of cardiac myocytes, we used a potent and specific inhibitor of the VPATPase, bafilomycin A1. Bafilomycin A1 alone caused increased DNA laddering of genomic DNA and increased nuclear staining for fragmented DNA in neonatal cardiomyocyte apoptosis in a dose- and time-dependent manner. Intracellular acidification in cardiac myocytes was also observed after 18 h of bafilomycin A1 treatment. Accordingly, bafilomycin A1-treated myocytes also showed increased accumulation of p53 protein and p53-dependent transactivation of gene expression, including a persistent upregulation of p21/wild-type p53 activated fragment 1/cyclin kinase inhibitor protein-1 mRNA. The bafilomycin A1-induced increase in p53 protein levels was accompanied by a marked increase in p53 mRNA accumulation. In contrast, cardiac fibroblasts treated with bafilomycin A1 showed no change in p53 protein expression or pHi and did not undergo apoptosis even after 24 h of treatment. Our data suggest that blockade of the VPATPase induces apoptotic cell death of cardiac myocytes and that this may occur through a p53-mediated apoptotic pathway.

Induction of the cholesterol metabolic pathway regulates the farnesylation of RAS in embryonic chick heart cells: a new role for ras in regulating the expression of muscarinic receptors and G proteins

We propose a novel mechanism for the regulation of the processing of Ras and demonstrate a new function for Ras in regulating the expression of cardiac autonomic receptors and their associated G proteins. We have demonstrated previously that induction of endogenous cholesterol synthesis in cultured cardiac myocytes resulted in a coordinated increase in expression of muscarinic receptors, the G protein alpha-subunit, G-alphai2, and the inward rectifying K+ channel, GIRK1. These changes in gene expression were associated with a marked increase in the response of heart cells to parasympathetic stimulation. In this study, we demonstrate that the induction of the cholesterol metabolic pathway regulates Ras processing and that Ras regulates expression of G-alphai2. We show that in primary cultured myocytes most of the RAS is localized to the cytoplasm in an unfarnesylated form. Induction of the cholesterol metabolic pathway results in increased farnesylation and membrane association of RAS. Studies of Ras mutants expressed in cultured heart cells demonstrate that activation of Ras by induction of the cholesterol metabolic pathway results in increased expression of G-alphai2 mRNA. Hence farnesylation of Ras is a regulatable process that plays a novel role in the control of second messenger pathways.

p53 and the hypoxia-induced apoptosis of cultured neonatal rat cardiac myocytes

Myocyte cell loss is a prominent and important pathogenic feature of cardiac ischemia. We have used cultured neonatal rat cardiac myocytes exposed to prolonged hypoxia as an experimental system to identify critical factors involved in cardiomyocyte death. Exposure of myocytes to hypoxia for 48 h resulted in intranucleosomal cleavage of genomic DNA characteristic of apoptosis and was accompanied by increased p53 transactivating activity and protein accumulation. Expression of p21/WAF-1/CIP-1, a well-characterized target of p53 transactivation, also increased in response to hypoxia. Hypoxia did not cause DNA laddering or cell loss in cardiac fibroblasts. To determine whether the increase in p53 expression in myocytes was sufficient to induce apoptosis, normoxic cultures were infected with a replication-defective adenovirus expressing wild-type human p53 (AdCMV.p53). Infected cells expressed high intracellular levels of p53 protein and exhibited the morphological changes and genomic DNA fragmentation characteristic of apoptosis. In contrast, no genomic DNA fragmentation was observed in myocytes infected with the control virus lacking an insert (AdCMV.null) or in cardiac fibroblasts infected with AdCMV.p53. These results suggest that the intracellular signaling pathways activated by p53 might play a critical role in the regulation of hypoxia-induced apoptosis of cardiomyocytes.

Direct preconditioning of cultured chick ventricular myocytes. Novel functions of cardiac adenosine A2a and A3 receptors

Preconditioning with brief ischemia before a sustained period of ischemia reduces infarct size in the perfused heart. A cultured chick ventricular myocyte model was developed to investigate the role of adenosine receptor subtypes in cardiac preconditioning. Brief hypoxic exposure, termed preconditioning hypoxia, prior to prolonged hypoxia, protected myocytes against injury induced by the prolonged hypoxia. Activation of the adenosine A1 receptor with CCPA or the A3 receptor with C1-IB-MECA can replace preconditioning hypoxia and simulate preconditioning, with a maximal effect at 100 nM. While activation of the A2a receptor by 1 microM CGS21680 could not mimic preconditioning, its stimulation during preconditioning hypoxia, however, attenuated the protection against hypoxia-induced injury. Blockade of A2a receptors with the selective antagonist CSC (1 microM) during preconditioning hypoxia enhanced the protective effect of preconditioning. Nifedipine, which blocked the A2a receptor-mediated calcium entry, abolished the A2a agonist-induced attenuation of preconditioning. Isoproterenol, forskolin, and BayK 8644, which stimulated calcium entry, also attenuated preconditioning. Nifedipine blocked the increase in calcium uptake by these agents as well as their attenuating effect on preconditioning. The present study provides the first evidence that the adenosine A3 receptor is present on ventricular myocytes and can mediate simulation of preconditioning. The data demonstrate, for the first time, that activation of the A2a receptor antagonizes the preconditioning effect of adenosine, with increased calcium entry during the preconditioning stimuli as a novel mechanism.

A new cyclic AMP-independent, Gs-mediated stimulatory mechanism via the adenosine A2a receptor in the intact cardiac cell

The objectives of this study were to investigate the mechanism underlying the adenosine A2a receptor (A2aR)-mediated positive inotropic response and to define its contractile function using chick embryo ventricular cells as a model. Activation of the A2aR caused a marked stimulation of calcium entry and cell contractility, which were blocked by verapamil or nifedipine. The effects elicited by maximal concentrations of the A2aR agonist 2-[4-(2-carboxyethyl)phenylethylamino]-5'-N-ethylcarboxamidoadenos ine and the beta-adrenergic agonist isoproterenol were additive, indicating that the two receptors do not share a common stimulatory mechanism. The cAMP antagonist (Rp)-adenosine cyclic 3':5'-monophosphorothioate was ineffective in inhibiting the A2aR-mediated stimulation of contractility or the L-type calcium channel, while it completely abolished the isoproterenol effects. Activation of the A2aR had no effect on Na+/Ca2+ exchange or inositol 1,4,5-trisphosphate accumulation. Blocking of the A2aR resulted in unopposed A1 receptor-mediated inhibitory effects and led to an inhibition of basal contractility and an enhanced anti-adrenergic effect by A1 agonist. The adenosine A2a receptor mediates a new cyclic AMP-independent mechanism and a new contractile function in the cardiac cell.

High and low molecular weight fibroblast growth factor-2 increase proliferation of neonatal rat cardiac myocytes but have differential effects on binucleation and nuclear morphology. Evidence for both paracrine and intracrine actions of fibroblast growth factor-2

Basic fibroblast growth factor (FGF-2) plays a vital role in the growth and differentiation of cardiac myocytes. It exists in high and low molecular weight forms because of the use of alternative initiation codons in the same mRNA. Higher levels of high molecular weight forms (molecular mass of 22 and 21.5 kD) are present in the rat heart during the neonatal stage, whereas the low molecular weight form (molecular mass of 18 kD) is predominant in the adult heart, suggesting different roles in development. Rat FGF-2 cDNAs that can preferentially express high or low molecular weight forms were introduced into neonatal rat ventricular myocyte cultures. Significant and comparable increases in overall cardiac myocyte DNA synthesis and proliferation were seen with 22/21.5- and 18-kD FGF-2 expression. A significantly higher mitotic index was seen in the vicinity of cardiac myocytes overexpressing high or low molecular weight forms of FGF-2 compared with nonoverexpressing cells. This increase was inhibited in the presence of neutralizing antibodies to FGF-2, pointing to a proximity-dependent paracrine effect of 22/21.5- and 18-kD FGF-2 on mitosis. By contrast, overexpression of high but not low molecular weight FGF-2 was associated with a significant increase in binucleation (approximately 36% of cardiac myocytes overexpressing 22/21.5-kD FGF-2 were binucleated compared with 9% of cardiac myocytes overexpressing 18-kD FGF-2), which was not affected by neutralizing antibodies to FGF-2. These results suggest that 22/21.5-kD FGF-2 and 18-kD FGF-2 have similar paracrine effects on proliferation but that 22-21.5-kD FGF-2 exerts a distinct intracrine effect on binucleation.