HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Add to Personal Folders Download to citation manager Permission Requests Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Narula, J. Articles by Baliga, R. Search for Related Content PubMed PubMed Citation Articles by Narula, J. Articles by Baliga, R. Related Collections Cerebral protection

Ann Thorac Surg 2001;72:1454-1456
© 2001 The Society of Thoracic Surgeons

---

Editorial

What’s in a name? Would that which we call death by any other name be less tragic?

^a MCP-Hahnemann University Medical School, Philadelphia, Pennsylvania, USA
^b University of Michigan Health Systems, Ann Arbor, Michigan, USA

* Address reprint requests to Dr Narula, Hahnemann University Hospital, Broad & Vine, MS115-NT742, Philadelphia, PA 19102-1192, USA
e-mail: jagat.narula{at}drexel.edu

Open-heart surgery, particularly coronary artery bypass grafting (CABG) for coronary artery disease, is one of the great success stories in modern cardiovascular therapeutics, with more than 500,000 bypass procedures performed in the United States each year [1]. It not only improves survival but also relieves angina and improves exercise tolerance. This success story, however, has its trade-offs, including injury to the myocardium and central nervous system during circulatory arrest or low-flow bypass [2, 3]. Surgeons and researchers have grappled with different techniques to minimize neurologic dysfunction after open-heart surgery. The incidence of adverse cerebral outcomes after CABG ranges from 0.4% to approximately 80%. Perioperative cerebral injury has been divided into major deficits, which include focal neurologic deficits, coma, delirium and stupor; or relatively minor deficits, which include deterioration in short-term and long-term cognitive functions such as intellectual function and memory [1]. These cognitive changes may be subtle and may include problems with following directions, mental arithmetic, and planning complex actions [4]. In addition, family members and colleagues may observe that the patient is more prone to be short-tempered, is less able to withstand frustration, and has wider mood swings. The deterioration in cognitive function may demonstrate a biphasic temporal pattern with an immediate postoperative decline and then a late decline on long-term follow-up [5]. The pathogenesis of neurologic deficits after CABG has been ascribed to hypoxia, recurrent emboli, hemorrhage and metabolic abnormalities. The cellular and molecular mechanisms that result in neurologic deficits, particularly the decline in late cognitive function, continue to be defined. In a very elegant article in this issue of The Annals, Hagl and associates [6] have investigated the role of cell death in neurologic injury after hypothermic circulatory arrest. In addition to temporal characterization of cell death and significant revelations that lower temperatures (approximately 10°C) and use of antiapoptotic intervention (such as cyclosporin A) may lead to prevention of neuronal cell loss, the morphologic description of a spectrum of cell death provides a landmark observation. The types of cell death represented classic apoptosis, orthodox necrosis, and a state that most likely combines the features of both types (referred to as type 1 death). Because death by any means is a loss of functional tissue, should morphologic nuances in the type of cell death be at all important?

It is being increasingly recognized that the cells may defect from necrotic to apoptotic process and vice versa based on the available intracellular energy content [7]. This may be especially true during acute insults and particularly in terminally differentiated cells. The cells during the process of apoptosis may exhaust energy stores and die by necrosis. Unlike necrosis, apoptosis is an active energy requiring process and energy consumption increases enormously if repair of the apoptotic DNA is undertaken, such as by the help of poly-ADP-ribose polymerase (PARP) [8]. PARP utilizes NAD as a substrate to transfer ADP-ribose groups to nuclear proteins during DNA repair. On the other hand, the cells may be exposed to necrotogenic stimuli (such as during acute myocardial infarction), but interruption of injury (such as by reperfusion) may prevent the necrotic process and partially damaged cells may progress to death through the apoptotic cascade [9]. Similarly, milder necrotogenic stimuli may also induce cell death by apoptosis [10]. It is conceivable that the pendular process of cell death may produce various morphologic hybrids of the two cell death types. It may be logical to propose that interventions to abrogate any one process may produce preventative benefits that exceed expectations. The cell death, at least in terminally differentiated cells, may therefore allow multiple avenues of intervention.

The boundaries of apoptotic and necrotic cell death may be even hazier in chronic cardiac and neurologic disorders, such as CHF and Alzheimer’s disease. Studies of the apoptotic cascade in these disorders have been very informative. Activation of caspase 3 is a central step in apoptosis and eventually leads to cytoplasmic proteolysis and DNA fragmentation [11]. Activation of caspase 3 may result from two distinct (but not mutually exclusive) pathways (Fig 1). The pathway initiated by stress stimuli, such as ischemia, reactive oxygen radicals, and intracellular calcium overload, is mediated by cytochrome c release from mitochondria and its interaction with Apaf-1, caspase 9, and dATP [12]. The other pathway is cytokine based and cascades through activation of caspases 1 and 8 [13]. Processing of caspase 8 further amplifies the caspase 3 activation by mitochondrial release of cytochrome c via mitochondrial translocation of truncated Bid [14]. There are natural repressors of caspases, including IAPs for caspase 3 [15], ARC for caspase 8 [16], and ICEBERG for caspase 1 [17], which retard the apoptotic process. Similarly, BCl2 family proteins, including BCl2 and BClxL, prevent cytochrome c release and hence apoptosis [15]. Other BCl2 family members such as Bax potentiate apoptosis. Narula and associates [18] have demonstrated that cytochrome c is released from mitochondria in end-stage heart failure, and is associated with caspases 8, 9, and 3 upregulation and activation. Secondary to caspase 3 activation, cytoplasmic contents such as contractile proteins are cleaved to an extent [19], but the apoptosis is not completed and nuclei remain intact, leading to a state referred to as apoptosis interruptus [20]. The resistance to apoptosis is not clearly understood but is likely associated with loss of DNAses (unpublished observations), upregulation of antiapoptotic proteins, and downregulation of apoptotic factors [21]. Whereas loss of cytochrome c may contribute to systolic dysfunction, lack of completion of apoptosis maintains these cells in the state of suspended animation. The cells may exist until recovery or until depletion of energy allows them to die by necrosis. Because the interrupted apoptotic process leaves nuclear blue print intact, it may allow recovery of the cells with reconstitution of the cytoplasmic protein compartment. The revitalized cells have been termed as "zombie myocytes" [20]. The apoptotic process may therefore lead to death by necrosis or recovery of dysfunctional cells in chronic disease states. This is in contrast with acute diseases wherein proapoptotic proteins may overwhelm the protective response due to a shorter time for compensatory accumulation of antiapoptotic factors.

View larger version (54K): [in this window] [in a new window]   Fig 1. Activation of caspase 3 may result from two distinct, but not mutually exclusive, pathways.

As various mechanisms by which cells are able to halt apoptosis "midstream" continue to unravel, our understanding of the pathogenesis of chronic conditions such as heart failure and chronic cognitive decline are only beginning to be understood. A growing understanding of cellular processes should eventually result in the development of more effective therapeutic strategies for management of cardiac and neurologic disorders, which were once considered invincible. Defining diverse cidal pathways in terminally differentiated cells, as described by Hagl and associates, is of paramount importance. And if these pathways are truly interrelated, we should be able to substantially minimize the tragedy of cell death.

References

1. Eagle K.A., Guyton R., et al. ACC/AHA guidelines for CABG surgery. J Am Coll Cardiol 1999;34:1262-1347.[Free Full Text]
2. Greeley W.J., Ungerleider R.M. Assessing the effect of cardiopulmonary bypass on the brain. Ann Thorac Surg 1991;52:417-419.[Medline]
3. Sotaniemi K.A., Juolasmaa A., Hokkanen E.T. Neuropsychologic outcomes after open heart surgery. Arch Neurol 1991;38:2-8.
4. Selenes O.A., McKhann G.M. Coronary artery bypass surgery and the brain. N Engl J Med 2001;344:451-452.[Free Full Text]
5. Newman M.F., Kirchner J.L., Phillips-Bute B., et al. Longitudinal assessment of neurocognitive function after coronary artery bypass grafting. N Engl J Med 2001;344:395-402.[Abstract/Free Full Text]
6. Hagl C., Tatton N.A., Khaladj N., et al. Involvement of apoptosis in neurological injury after hypothermic circulatory arrest: a new target for therapeutic intervention. Ann Thorac Surg 2001;72:1457-1464.[Abstract/Free Full Text]
7. Leist M., Single B., Castoldi A.F., Kuhnle S., Nicotera P. Intracellular adenosine triphosphate (ATP) concentration: a switch in the decision between apoptosis and necrosis. J Exp Med 1997;185:1481-1486.[Abstract/Free Full Text]
8. Blankenberg F., Narula J., Strauss H.W. In vivo detection of apoptotic cell death: a necessary measurement for evaluating therapy for myocarditis, ischemia and failure. J Nucl Cardiol 1999;6:531-539.[Medline]
9. Gottlieb R.A., Burleson K.O., Kloner R.A., Babior B.D., Engler R.L. Reperfusion injury induces apoptosis in rabbit cardiomyocytes. J Clin Invest 1994;94:1621-1628.
10. Tanaka M., Itoh H., Adachi S., et al. Hypoxia induces apoptosis with enhanced expression of Fas antigen messenger RNA in cultured neonatal rat cadiomyocytes. Circ Res 1994;75:426-433.[Abstract/Free Full Text]
11. Stegh A.H., Peter M.E. Apoptosis and caspases. Cardiol Clinics 2001;19:13-29.[Medline]
12. Liu X., Kim C.N., Yang J., Jemmerson R., Wang X. Induction of apoptotic program in cell free extracts: requirement of dATP and cytochrome-C. Cell 1996;60:147-158.
13. Vicenz C. Death receptors and apoptosis. Cardiol Clinics 2001;19:31-43.[Medline]
14. Luo X., Budihardjo I., Zou H., Slaughter C., Wang X. Bid, a Bcl interacting protein, mediates cytochrome c release from mitochondria in response to activation of cell surface death receptors. Cell 1998;94:481-490.[Medline]
15. Deveraux Q.L., Reed J.C. IAP family proteins: suppressors of apoptosis. Genes Dev 1999;13:239-252.[Free Full Text]
17. Humke E.W., Shriver S.K., Starovasnik M.A., Fairbrother W.J., Dixit V.M. ICEBERG: a novel inhibitor of interleukin-1ß generation. Cell 2000;103:99-111.[Medline]
16. Koseki T., Inohara N., Chen S., Nunez G. ARC, an inhibitor of apoptosis expressed in skeletal muscle and heart that interacts selectively with caspases. Proc Natl Acad Sci USA 1998;95:5156-5160.[Abstract/Free Full Text]
18. Narula J., Pandey P., Arbustini E., et al. Apoptosis in heart failure: release of cytochrome-c and activation of caspase-3 in human cardiomyopathy. Proc Natl Acad Sci USA 1999;96:8144-8149.[Abstract/Free Full Text]
19. Haider N., Kharbanda S.K., Chandrashekhar Y., et al. Caspase-3 mediated cleavage of troponin-C at evolutionarily-conserved calcium binding site: relevance of apoptosis in heart failure. Circulation 1999;100:I283.
20. Narula J., Arbustini E., Chandrashekhar Y., Schwaiger M. Apoptosis and left ventricular systolic dysfunction. Cardiol Clinics 2001;19:113-126.[Medline]
21. Olivetti G., Abbi R., Quaini F., et al. Apoptosis in the failing human heart. N Engl J Med 1997;336:1131-1141.[Abstract/Free Full Text]
22. Yuan J., Yankner B.A. Apoptosis in the nervous system. Nature 2000;407:802-809.[Medline]
23. Perry G., Zhu Z., Smith M.A. Do neurons have a choice in death?. Am J Pathol 2001;158:1-2.[Free Full Text]
24. Spearnadio S., de Belle I., Bredesen D.E. An alternative, non-apoptotic form of programmed cell death. Proc Natl Acad Sci USA 2000;97:14376-14381.[Abstract/Free Full Text]
25. Raina A.K., Hochman A., Zhu X., et al. Abortive apoptosis in Alzheimer’s disease. Acta Neuropathol 2001;101:305-310.[Medline]
26. Kuida K., et al. Reduced apoptosis and cytochrome-c mediated caspase activation in mice lacking caspase-9. Cell 1998;94:325-327.[Medline]
27. Green D.R., Beere H.M. Mostly dead. Nature (Lond) 2001;412:133-134.[Medline]

This article has been cited by other articles:

				Y. Chandrashekhar and J. Narula Death Hath a Thousand Doors To Let Out Life... Circ. Res., April 18, 2003; 92(7): 710 - 714. [Full Text] [PDF]

This Article Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in PubMed Alert me to new issues of the journal Add to Personal Folders Download to citation manager Permission Requests Citing Articles Citing Articles via HighWire Citing Articles via Google Scholar Google Scholar Articles by Narula, J. Articles by Baliga, R. Search for Related Content PubMed PubMed Citation Articles by Narula, J. Articles by Baliga, R. Related Collections Cerebral protection