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(Circulation Research. 2002;90:749.)
© 2002 American Heart Association, Inc.

Editorials

Vascular Biology

Look What We Staggered Into

Frank M. Faraci

From the Departments of Medicine and Pharmacology, Cardiovascular Center, University of Iowa College of Medicine, Iowa City, Iowa.

Correspondence to Frank M. Faraci, PhD, Department of Internal Medicine, University of Iowa College of Medicine, Iowa City, Iowa 52242-1081. E-mail frank-faraci{at}uiowa.edu

Key Words: genetically altered mice • inflammation • blood pressure • vascular muscle

The nuclear receptor superfamily, which includes receptors for steroid hormones, eicosanoids, and retinoic acid, is a group of ligand-dependent transcription factors.¹ Included in this family are "orphan" receptors for which regulatory ligands have yet to be defined (Figure). One such group is the retinoid-related orphan receptor (ROR) subfamily, which has three known members (ROR, RORß, and ROR). Previous work has suggested that RORs are involved in diverse processes including embryonic development as well as cell differentiation, cell proliferation, and cancer.¹

View larger version (21K): [in this window] [in a new window]   Schematic summary of known influences of ROR in vascular biology. The transcription factor ROR is activated by ligands that are presently unknown. Stimuli that regulate expression of ROR are only beginning to be defined (see text). It is also possible that ROR may be constitutively active in some cell types. ROR interacts and binds with ROR-response elements (RORE), which then influence transcriptional activity of ROR-sensitive target genes. Studies to date, including the present study by Besnard et al,5 suggest that ROR target genes influence several prominent vascular phenotypes including vascular inflammation and development of atherosclerosis, expression of contractile proteins, and regulation of vascular tone (vasodilation and vasoconstriction).

Much less is known regarding potential roles for RORs in the cardiovascular system. ROR mRNA is expressed constitutively in human endothelium and vascular muscle in culture as well as within the wall of intact arteries.^2,3 The constitutive levels of ROR mRNA are reduced in human atherosclerotic plaques.³ Several proinflammatory stimuli—interleukin-1ß, TNF, and lipopolysaccharide—all increase ROR mRNA expression in endothelium and vascular muscle. ROR can inhibit inflammatory responses in vascular muscle including TNF-induced production of cytokines and expression of cyclooxygenase-2.² These effects seem to be mediated by increased expression of IB,² the primary inhibitor of NF-B signaling. Activation of NF-B has a significant effect on expression of many inflammatory-related genes. Thus, a major role for ROR may be to limit inflammation in blood vessels (Figure).

Pharmacological tools to study the functional importance of selective ROR members are limited. Fortunately, there are two genetic models available for the study of ROR. First, there is an animal with a natural mutation that makes it ROR deficient—the staggerer mouse (sg/sg).¹ Staggerer mice have neurological degeneration including cerebellar ataxia. In relation to vascular biology, it has already been established that sg/sg mice have lower levels of IB mRNA in blood vessels under normal conditions and develop greater atherosclerosis when fed a high-fat diet compared with wild-type controls.^2,4 These results are interesting in relation to the finding that ROR mRNA levels are reduced in human atherosclerotic lesions. Second, a ROR-deficient mouse has been produced using standard gene-targeting technology.

In the study by Besnard et al,⁵ the role of ROR in blood vessels was examined using the sg/sg mouse. Several functional responses were examined using aorta, carotid artery, and small mesenteric arteries in vitro. In addition, arterial pressure was measured directly in anesthetized mice. The study has several major findings. First, arterial pressure was lower and the pressor response to intravenous phenylephrine was reduced in sg/sg mice compared with wild-type controls (C57BL/6J mice). Second, myogenic tone and flow-mediated vasodilation were less in mesenteric arteries (but not carotid arteries) in sg/sg mice. Third, contractile responses to serotonin and phenylephrine were selectively reduced in the mesenteric arteries from sg/sg mice. Fourth, depending on the blood vessel, relaxation in response to acetylcholine (the classic endothelium-dependent agonist), nitroprusside (a nitric oxide [NO] donor), and isoproterenol was impaired in the sg/sg mouse. Fifth, Western blotting suggested that levels of endothelial NO synthase (eNOS) were unchanged, but levels of several contractile proteins (SM-myosin, h-caldesmon, and calponin) were selectively reduced in mesenteric arteries from sg/sg mice.

These initial findings regarding vascular function in the staggerer mouse raise many questions. First, mechanisms that regulate myogenic tone, flow-mediated and endothelium-dependent relaxation, and receptor-mediated vasoconstriction are divergent. Hence, deficiency in which potential target genes for ROR could account for this spectrum of vascular changes? For example, NO produced by eNOS is a major mediator of endothelium-dependent relaxation in many studies in blood vessels from both experimental animals and humans.⁶ The finding that relaxation of the mesenteric artery in response to acetylcholine was impaired in sg/sg mice raised the possibility that eNOS signaling is altered. However, eNOS protein levels were similar in control and sg/sg mice suggesting that differences in levels of expression of eNOS cannot account for this impairment. In addition, the finding that relaxation of this artery to nitroprusside was also impaired suggests that function of soluble guanylate cyclase and/or cGMP-dependent protein kinase I (the major signaling pathway for NO in vascular muscle)⁷ may be abnormal. Conversely, vasorelaxation in response to isoproterenol, which was also impaired in small arteries from sg/sg mice, is likely mediated by cAMP and involves activation of potassium channels and calcium sparks in vascular muscle.⁸

Second, almost all the vascular changes in sg/sg mice were observed in the mesenteric artery raising the question of how representative is the mesenteric artery of blood vessels in general. A reasonable possibility is that the role of ROR varies in large conduit vessels compared with smaller arteries and microvessels. Although ROR deficiency did not alter function of aorta, ROR can affect vascular biology in large vessels because atherosclerosis in aorta is much greater in sg/sg mice fed a high-fat diet.⁴ It is noteworthy that, by far, most studies of vascular function in genetically altered mice are performed using aorta.⁶ If Besnard et al⁵ had studied only that blood vessel, they would have obtained an essentially negative study in relation to altered vascular phenotypes in sg/sg mice.

Third, previous work with vascular cells in culture and studies of atherosclerosis suggest that ROR may be an important antiinflammatory molecule in blood vessels. In addition to contributing to the overall atherosclerotic process, inflammation and inflammatory stimuli are known to alter vascular function. Other antiinflammatory molecules including interleukin-10 and PPAR⁹ have protective effects on vascular function.^10–12 Interestingly, a target gene for ROR may be PPAR,¹³ another member of the nuclear receptor superfamily. Does ROR have similar protective effects on vascular function during inflammation? There are many pathophysiological conditions in which components of the inflammatory response are expressed within the vessel wall. In addition to atherosclerosis, these conditions include sepsis (endotoxin shock), diabetes, ischemia with reperfusion, subarachnoid hemorrhage, Alzheimer’s disease, and aging. Thus, the role of ROR on vascular function may be potentially very broad.

Finally, it may be useful to consider what approaches, in addition to the use of sg/sg and ROR-deficient mice, might be used to better define the role of ROR in vascular biology. In addition to studies of vascular cells in culture (which have already been initiated),^2,3 other methods have potential. An adenovirus encoding ROR has been made² and might be used to overexpress locally the transcription factor in intact blood vessels. A variation of this approach might be to create a viral vector that expresses a dominant-negative form of ROR. Similarly, it may be possible to make transgenic mice that overexpress wild type or a mutant form of ROR. Because of the importance of ROR in embryonic development,¹ it might be necessary to limit the temporal or spatial expression of ROR within the vessel wall.

Footnotes

The opinions expressed in this editorial are not necessarily those of the editors or of the American Heart Association.

References

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2. Delerive P, Monte D, Dubois G, Trottein F, Fruchart-Najib J, Mariani J, Fruchart J-C, Staels B. The orphan nuclear receptor ROR is a negative regulator of the inflammatory response. EMBO Rep. 2001; 2: 42–48.[CrossRef][Medline] [Order article via Infotrieve]

3. Besnard S, Heymes C, Merval R, Rodriguez M, Galizzi J-P, Bontin JA, Mariani J, Tedgui A. Expression and regulation of nuclear receptor ROR in human vascular cells. FEBS Lett. 2002; 511: 36–40.[CrossRef][Medline] [Order article via Infotrieve]

4. Mamontova A, Seguret-Mace S, Esposito B, Chaniale C, Bouly M, Delhaye-Bouchaud N, Luc G, Staels B, Duverger N, Mariani J, Tedgui A. Severe atherosclerosis and hypoalphalipoproteinemia in the staggerer mouse, a mutant of the nuclear receptor ROR. Circulation. 1998; 98: 2738–2743.[Abstract/Free Full Text]

5. Besnard S, Bakouche J, Lemaigre-Dubreuil Y, Mariani J, Tedgui A, Henrion D. Smooth muscle dysfunction in resistance arteries of the staggerer mouse, a mutant of the nuclear receptor ROR. Circ Res. 2002; 90: 820–825.[Abstract/Free Full Text]

6. Faraci FM, Sigmund CD. Vascular biology in genetically altered mice: smaller vessels, bigger insight. Circ Res. 1999; 85: 1214–1225.[Free Full Text]

7. Pfeifer A, Klatt P, Massberg S, Ny L, Sausbier M, Hirneib C, Wang G-X, Korth M, Aszodi A, Andersson K-E, Krombach F, Mayerhofer A, Ruth P, Fassler R, Hofmann F. Defective smooth muscle regulation in cGMP kinase I-deficient mice. EMBO J. 1998; 17: 3045–3051.[CrossRef][Medline] [Order article via Infotrieve]

8. Porter VA, Bonev AD, Knot HJ, Heppner TJ, Stevenson AS, Kleppisch T, Lederer WJ, Nelson MT. Frequency modulation of Ca²⁺ sparks is involved in regulation of arterial diameter by cyclic nucleotides. Am J Physiol. 1998; 274: C1346–C1355.[Medline] [Order article via Infotrieve]

9. Tedgui A, Mallat Z. Anti-inflammatory mechanisms in the vascular wall. Circ Res. 2001; 88: 877–887.[Abstract/Free Full Text]

10. Gunnett CA, Heistad DD, Berg DJ, Faraci FM. Interleukin-10 deficiency increases superoxide and endothelial dysfunction during inflammation. Am J Physiol. 2000; 279: H1555–H1562.

11. Gunnett CA, Heistad DD, Faraci FM. Interleukin-10 protects endothelium-dependent relaxation during diabetes: role of superoxide. Diabetes. In press.

12. Didion SP, Ryan MJ, Faraci FM, Sigmund CD. Activation of PPAR reduces blood pressure and improves vascular function in hypertensive transgenic mice. FASEB J. Abstract. In press.

13. Sundvold H, Lien S. Identification of a novel peroxisome proliferator-activated receptor (PPAR) promoter in man and transactivation by the nuclear receptor ROR. Biochem Biophys Res Commun. 2001; 287: 383–390.[CrossRef][Medline] [Order article via Infotrieve]

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