PERSPECTIVE SERIES responses to

SERIES INTRODUCTION Tissue ischemia: and therapeutics

Gregg L. Semenza

Institute of Genetic Medicine, The Johns Hopkins University School of Medicine, CMSC-1004, 600 North Wolfe Street, Baltimore, Maryland 21287-3914, USA. Phone: (410) 955-1619; Fax: (410) 955-0484; E-mail: [email protected].

This issue of the JCI contains the first articles in a Per- has been the preconditioning phenomena that have spective series that focuses on ischemia, the major been demonstrated in virtually every , including cause of mortality in the developed world. The specific the and brain. Thus, exposure of an organ or tis- mechanisms and consequences of ischemia differ in sue to one or more brief episodes of ischemia will pro- each tissue or organ, which reflects differences in vide protection against subsequent prolonged ischemia anatomy and physiology. For this reason, the series has that would otherwise result in . The precon- been organized to include articles on cerebral (Dennis ditioning stimulus provides an immediate but short- Choi and colleagues), myocardial (Sandy Williams and lived “first window” of protection, which occurs over a Ivor Benjamin), and skeletal muscle (Jeff Isner) period of minutes to hours and requires the altered ischemia, as well as discussions of ischemia in epithe- activity of pre-existing proteins, as well as a delayed but lial tissues (Sanjay Nigam and colleagues) and hypox- sustained “second window” of protection, which per- ia-induced pulmonary vascular remodeling (Norbert sists over a period of hours to days and depends on new Voelkel and Rubin Tuder). In each case, the authors protein synthesis. Considerable progress has been present a balanced overview of the field and focus on made in elucidating the signal transduction pathways an area of particular interest, such as the contribution that mediate these adaptive responses, as described in of excitatory neurotransmitter release to the patho- the Perspectives by Choi’s group and by Williams and genesis of , the protective effect of Benjamin. A pharmacologic agent capable of activating heat proteins (HSPs) in myocardial ischemia, the a preconditioning pathway would, of course, have role of VEGF in ischemia-induced , the tremendous therapeutic potential. disruptive effects of ischemia on epithelial barrier func- A third approach is to target for inhibition or induc- tion, or the effects of on pulmonary vascular tion a specific gene or protein product that is known biology. Most of the research discussed employs tissue to promote ischemia or to protect against infarction. culture or small animal model systems and reflects the The analysis of knockout and transgenic mice has expectation that insights into basic pathophysiology will offer a foundation for designing therapeutics. Despite the variability of responses to ischemia in var- ious tissues, several general therapeutic strategies can Ischemia arises when tissue demand for be considered regardless of the anatomical site of energy substrates (primarily O2 and ischemia. Ischemia arises when tissue demand for ener- gy substrates (primarily O2 and glucose) is not matched glucose) is not matched by supply... by supply, usually due to impaired . Thus, ischemia can be prevented or eliminated, in principle, by decreasing demand or increasing supply. As dis- cussed by Williams and Benjamin, decreased demand provided a wealth of data regarding genes that, when occurs in the case of , in which inactivated or activated, either promote or protect the ATP-consuming process of contractility is inhibit- against cerebral or . The inter- ed to minimize O2 and glucose consumption. Global pretation of these data, however, is not always entire- inhibition of myocardial or cerebral function is unlike- ly straightforward. For example, the Nos2 gene encod- ly to represent a viable therapeutic strategy, but the ing inducible nitric oxide synthase is required for alternative of increasing supply to these tissues seems late-phase cardiac preconditioning, but NOS2-defi- feasible, for example, by therapeutic angiogenesis (see cient mice develop smaller cerebral than Perspective by Isner). DNA- or protein-based clinical their wild-type littermates in response to cerebral arte- trials involving VEGF, other angiogenic factors, or rial occlusion. Thus, NOS2 may help to protect pre- mediators of their production are currently underway. conditioned animals and also, paradoxically, promote Another approach is to prevent the death of ischemic infarction in non-preconditioned animals. Transgenic tissue, i.e., infarction. A major focus of investigation models have demonstrated that overexpression of

The Journal of Clinical Investigation | September 2000 | Volume 106 | Number 5 613 Tissue responses to ischemia PERSPECTIVE SERIES

HSPs, such as HSP70, provides protection against The present Perspective series on ischemia has ischemia in the myocardium (as described by notable parallels to the excellent JCI Perspective series Williams and Benjamin) and in epithelial tissues (as on cancer therapy that was recently edited by Bill discussed by Nigam and colleagues). Examples of Kaelin (December 1999–January 2000). For both potentially useful pharmacologic inhibitors have ischemic and neoplastic disorders, we are accumulat- come from animal models of hypoxia-induced pul- ing an impressive fund of knowledge regarding patho- monary hypertension, in which treatment with physiology. Although the articles in the present series angiotensin-converting inhibitors or on ischemia demonstrate the enormous complexity of endothelin receptor ETA antagonists can prevent or the processes under investigation, the challenge reverse vascular remodeling. However, as Voelkel and to each investigator and reader of the JCI remains to Tuder explain, it is not entirely clear to which clinical build this growing investment into clinical dividends, conditions the rodent model is relevant. in the form of novel and effective therapeutics.

614 The Journal of Clinical Investigation | September 2000 | Volume 106 | Number 5