Immunology in Hypertension, Preeclampsia, and Target-Organ Damage
2009; Lippincott Williams & Wilkins; Volume: 54; Issue: 3 Linguagem: Inglês
10.1161/hypertensionaha.108.120253
ISSN1524-4563
AutoresStefan Verlohren, Dominik N. Müller, Friedrich C. Luft, Ralf Dechend,
Tópico(s)Birth, Development, and Health
ResumoHomeHypertensionVol. 54, No. 3Immunology in Hypertension, Preeclampsia, and Target-Organ Damage Free AccessReview ArticlePDF/EPUBAboutView PDFView EPUBSections ToolsAdd to favoritesDownload citationsTrack citationsPermissions ShareShare onFacebookTwitterLinked InMendeleyReddit Jump toFree AccessReview ArticlePDF/EPUBImmunology in Hypertension, Preeclampsia, and Target-Organ Damage Stefan Verlohren, Dominik N. Muller, Friedrich C. Luft and Ralf Dechend Stefan VerlohrenStefan Verlohren From the Franz-Volhard Clinic, HELIOS Klinikum-Berlin Buch (R.D., F.C.L.); the Experimental and Clinical Research Center and Max-Delbrück Center for Molecular Medicine (D.N.M., F.C.L., R.D.), Berlin, Germany; and Department of Obstetrics (S.V.), Campus Virchow-Clinic, Charité University Medicine Berlin, Berlin, Germany. , Dominik N. MullerDominik N. Muller From the Franz-Volhard Clinic, HELIOS Klinikum-Berlin Buch (R.D., F.C.L.); the Experimental and Clinical Research Center and Max-Delbrück Center for Molecular Medicine (D.N.M., F.C.L., R.D.), Berlin, Germany; and Department of Obstetrics (S.V.), Campus Virchow-Clinic, Charité University Medicine Berlin, Berlin, Germany. , Friedrich C. LuftFriedrich C. Luft From the Franz-Volhard Clinic, HELIOS Klinikum-Berlin Buch (R.D., F.C.L.); the Experimental and Clinical Research Center and Max-Delbrück Center for Molecular Medicine (D.N.M., F.C.L., R.D.), Berlin, Germany; and Department of Obstetrics (S.V.), Campus Virchow-Clinic, Charité University Medicine Berlin, Berlin, Germany. and Ralf DechendRalf Dechend From the Franz-Volhard Clinic, HELIOS Klinikum-Berlin Buch (R.D., F.C.L.); the Experimental and Clinical Research Center and Max-Delbrück Center for Molecular Medicine (D.N.M., F.C.L., R.D.), Berlin, Germany; and Department of Obstetrics (S.V.), Campus Virchow-Clinic, Charité University Medicine Berlin, Berlin, Germany. Originally published13 Jul 2009https://doi.org/10.1161/HYPERTENSIONAHA.108.120253Hypertension. 2009;54:439–443Other version(s) of this articleYou are viewing the most recent version of this article. Previous versions: July 13, 2009: Previous Version 1 Hypertension generally brings to mind hemodynamic mechanisms, increased peripheral vascular resistance, the laws of Ohm or Hagen-Poisseule, and perhaps target-organ damage mediated through acceleration of atherosclerosis, vasculitis, or other concomitant processes. However, innate and acquired adaptive cellular or even antibody-mediated immunity plays an active role in the pathogenesis of hypertension (Figure 1). In primarily angiotensin (Ang) II-dependent animal models for end-organ damage, an intense inflammatory component, namely, inflammation, that was principally steered by the innate-immunity regulator nuclear factor κB (NF-κB) was observed. Immunosuppression with dexamethasone, the tumor necrosis factor (TNF)-α soluble receptor, etanercept, and mycophenolate decreased albuminuria, NF-κB activation, and infiltration of all of the immunocompetent cells in the animals but had little or no effect on blood pressure.1 Using mechanisms to block NF-κB either pharmacologically or subsequently locally in endothelial cells with Cre/lox transgenic mice harboring an endothelial cell-restricted NF-κB superrepressor Iκ-B-α-ΔN (Tie-1-ΔN mice), it became evident that innate immune mechanisms were certainly important in target-organ damage.2 Since then, numerous observations have been made regarding immune mechanisms that influence hypertension development and its resultant target-organ damage.3–6 These findings may offer important new insights into our understanding of mechanisms and could influence treatment. Download figureDownload PowerPointFigure 1. Immunity schematic: all of the various components can be activated by Ang II. Some components also influence the blood pressure-raising responses of Ang II.Immune Cells and Hypertension DevelopmentGuzik et al7 showed recently that mice lacking T and B cells (RAG-1−/− mice) have blunted hypertension and do not develop target-organ damage after Ang II or desoxycorticosterone acetate-salt treatment. Adoptive transfer of T but not B cells restored these abnormalities. Adoptive transfer of T cells lacking the G protein-coupled receptor Ang II type 1 (AT1) blunted Ang II-dependent hypertension. Ang II increased T-cell markers of activation and tissue homing in wild-type mice but not in NADPH oxidase-deficient mice. Ang II markedly increased T cells in the perivascular adipose tissue (periadventitial fat) and in the adventitia. These cells expressed high levels of CC chemokine receptor 5 and were commonly double negative (CD3+CD4−CD8−). The infiltration was associated with an increase in intercellular adhesion molecule 1 and, regulated on activation, normal T expressed and secreted (RANTES) in the aorta. Hypertension also increased T-lymphocyte production of TNF-α. Etanercept prevented the hypertension and increase in vascular superoxide caused by Ang II. Guzik et al7 identified a previously undefined role for T cells in the genesis of hypertension. How could the presence or absence of a certain T-cell subset influence how Ang II signals and determine whether Ang II is capable of elevating blood pressure? The helix-loop-helix transcription factor, inhibitor of differentiation (Id2−/−), has been shown to play a role in the pathogenesis of Ang II-induced hypertension.8 Mice deficient for Id2 lack Langerhans and splenic CD8a+ dendritic cells, have reduced natural killer (NK) cells, and have altered CD8 T-cell memory. Infusing Ang II to these mice, they failed to develop hypertension or target-organ damage, whereas control mice did. Id2−/− mice responded normally to phenylephrine, and their blood vessels constricted in response to Ang II in vitro. Neither bone marrow nor kidney transplants restored blood pressure responses to Ang II in Id2−/− mice.T-Cell SwitchingShao et al9 investigated T-helper cell subsets. They used a continuous, Ang II infusion model in rats, harvested T cells from the spleen, and measured cytokine levels. Ang II-infused rats showed an increase in the Th (T-helper) 1 cytokine interferon-γ and a decrease in the Th2 cytokine interleukin (IL) 4. Shao et al9 then confirmed the same change in cytokine mRNA expression in the spleen and kidney. They found that Ang II increased the numbers of interferon-γ-secreting T cells. AT1 receptor blockade restored the Th subset imbalance, whereas lowering blood pressure with hydralazine did not. These results demonstrated a direct role for Ang II in the modification of Th balance. Since these studies, other T-helper cell subsets have been described. A third subset of IL-17-producing effector Th cells, called Th17 cells, has now been discovered and characterized. Th17 cells also secrete IL-21 to communicate with the cells of the immune system.The differentiation factors, transforming growth factor-β plus IL-6 or IL-21; the growth and stabilization factor (IL-23); and the transcription factors, signal transducers and activators of transcription (STAT3), the orphan nuclear receptor retinoic acid receptor-related orphan receptor (γ)t, and retinoic acid receptor-related orphan receptor-α are all involved in the development of Th17 cells. The participation of transforming growth factor-β in the differentiation of Th17 cells places the Th17 lineage in close relationship with CD4(+)CD25(+), forkhead box P3 (Foxp3) positive regulatory T cells (Tregs).10 Tregs are remarkable immunosuppressive cells that are selected in the thymus and move to the periphery. Furthermore, CD4 Th cells in the periphery can be induced to become regulatory T cells and, hence, are called induced or adaptive T-regulatory cells. Tregs can make IL-10 or transforming growth factor-β or both, by which they attain most of their immunosuppressive activity.Tregs have been implicated in cardiovascular diseases, including atherosclerosis and diabetes mellitus. A therapeutic potential for Tregs has been suggested in combating allograft rejection and autoimmune diseases. Our group tested the notion that Tregs would control inflammation in a mouse model involving chronic Ang II infusion.11 Control mice developed hypertension and cardiac hypertrophy and easily evoked ventricular arrhythmias after catheter stimulation. The hearts exhibited immune cell infiltration, TNF-α expression, and fibrosis. Tregs obtained from spleens and lymph nodes of donor mice were infused into mice that then received Ang II. Telemetric blood pressure measurements were the same. However, Treg-treated mice developed less cardiac hypertrophy, less TNF-α expression, less immune cell infiltration, and resisted stimulated arrhythmia. We found that Ang II did not directly influence Tregs. However, Treg treatment maintained other T-cell populations closer to the proportion observed in control mice compared with mice given Ang II but no Tregs. The importance of these findings is mechanistic. They underscore earlier observations concerning T lymphocytes, other immune cells, and their regulators in blood pressure responses and target-organ damage after Ang II. They suggest additional avenues of research regarding Ang II-related target-organ damage and immunity.Mold et al12 showed recently that the human fetal immune system takes advantage of Tregs to maintain "tolerogenicity." They found that substantial numbers of maternal cells cross the placenta to reside in fetal lymph nodes, inducing the development of CD4+CD25highFoxP3-positive Tregs. These Tregs then suppress fetal antimaternal immunity and persist at least until early adulthood. The findings of Mold et al12 reveal a form of antigen-specific tolerance in humans, induced in utero and probably active in regulating immune responses after birth. Conceivably, disturbances of these relationships could result in difficulties between mother and child during pregnancy. Indeed, the most severe, life-threatening form of hypertension and target-organ damage is preeclampsia. The soluble fms-like tyrosine kinase receptor (sFlt1) and soluble endoglin 1 have been strongly implicated in the pathogenesis of preeclampsia, as reviewed elsewhere.13 The immune system plays a pivotal role in preeclampsia, and other mechanisms that either contribute or interplay also require consideration.General Immunologic Aspects of PreeclampsiaThe initiating event in the etiology of preeclampsia is the mal-implantation of the placenta. Placental development is a complex interplay of paternal antigens and the maternal immune system. The interaction of decidual leukocytes and invasive cytotrophoblasts is essential for the normal development of the placenta. In normal placental development, an immunologic tolerance toward paternal antigens is observed. The cause of this immunologic tolerance is unclear, although, as Mold et al12 suggest, Tregs may be important. The placenta exhibits a unique human leucocyte antigen (HLA) type and specific inflammatory cells, the "large granular lymphocytes," are found. Trophoblasts do not express classic major histocompatibility complex class I, human leukocyte antigens HLA-A and HLA-B, or major histocompatibility complex class II molecules, whereas 3 nonclassical HLA class I molecules, HLA-G, HLA-E, and HLA-C, are expressed.14 There is an abundance of uterine NK in the decidua. These cells express a variety of receptors (CD94/NKG2, KIR, and ILT), which are known to recognize HLA class I molecules expressed by the trophoblast.15The interaction between leukocytes and trophoblasts is defective in preeclampsia.16 Decidual lymphocytes and peripheral blood mononuclear cells from patients with preeclampsia synthesize high levels of Th1 cytokines, eg, IL-1, IL-2, and interferon-γ. However, the secretion of the Th2 cytokines IL-10 and IL-5 is decreased. The circulating levels of TNF-α and IL-6, which are already more elevated in healthy pregnant women compared with nonpregnant women, are further raised in patients with preeclampsia.17 Furthermore, the expression of IL-8 and intercellular adhesion molecule 1 (ICAM 1) in vascular smooth muscle cells of resistance vessels in women with preeclampsia is increased, indicating inflammation possibly caused by neutrophil infiltration.18 Secretion of interferon-γ by mouse uterine NK cells positively regulates decidual vascular lumen size, and a ligand expression pattern on fetal trophoblasts favoring stimulation of inhibitory receptors on decidual NK cells is unexpectedly associated with increased risk for preeclampsia. These cells may be critically involved in placental development, because they possibly possess the unique ability to regulate crucial developmental processes, including trophoblast invasion and vascular growth.19AutoantibodiesAT1 autoantibodies (AT1-AAs) have been prominent in preeclampsia research for more than a decade. This situation again draws attention to the immunologic mechanisms possibly being a connecting link in the pathogenesis of preeclampsia. Our group first observed that AT1-AAs bind to a 7-amino acid sequence present on the second extracellular loop of the AT1 receptor. Other investigators pursuing the same hypothesis have since expanded on these findings.20 The presence of this peptide epitope, AFHYESQ, in a cardiomyocyte contraction assay blocked antibody-induced stimulation of cardiomyocyte contraction. AT1-AAs have been shown to be involved in a host of pathogenetic effects in preeclampsia. AT1-AA-mediated activation of AT1 receptors on human trophoblast cells results in increased production of reduced NADPH oxidase, tissue factor, and plasminogen activator inhibitor 1.AT1-AAs can be detected before 20 weeks of gestation in women with impaired uterine perfusion. However, the association with pathological uterine flow seems to be irrespective of the later onset of preeclampsia. The predictive value of the AT1-AA is better in late-onset rather than early onset preeclampsia. Furthermore, the AAs are not specific for preeclampsia, because it has been shown that they are involved in renal transplant allograft rejection.21In artificial animal models of preeclampsia, AAs are present, as in the transgenic and reduced uterine perfusion pressure model, as well as in low-dose TNF-α infused rats.22,23 AT1 receptor activation by Ang II is a potent stimulus for endothelin production, and endothelin-A receptor activation plays a major role in mediating chronic Ang II-induced hypertension in rats. AT1 receptor antagonism in the reduced uterine perfusion pressure model significantly reduced endothelin concentration of cells exposed to sera from pregnant rats with chronic reductions in uterine perfusion.Accumulating evidence suggests a pivotal role for a disturbed angiogenic balance in the pathophysiology of preeclampsia, a decrease of the proangiogenic vascular endothelial growth factor and placental growth factor, and an increase of the antiangiogenic sFlt and soluble endoglin 1.13 In the clinical setting, these factors, and especially changes in their levels in the course of pregnancy, can be used to identify patients who are at risk for developing preeclampsia, because they predict the later onset of the disease weeks in advance. However, alterations in sFlt1 and/or soluble endoglin levels are also found in other pregnancy complications, eg, intrauterine growth restriction.AT1-AAs and Angiogenic Factors: Cause and Effect?What is the possible connection between AT1-AAs and the angiogenic factors? In a newsworthy article by Zhou et al,24 a connecting link seems to have been found. The authors found that Ang II stimulates sFlt-1 production by human trophoblast cells, placental villous explants, and pregnant mice. These findings suggest that Ang II regulates sFlt-1 synthesis and secretion by trophoblast cells of the placenta during pregnancy. However, in preeclampsia, Ang II levels are not elevated as compared with noncomplicated pregnancies. The AT1-AAs are possible candidates for a stimulus of enhanced synthesis and secretion of sFlt-1 associated with preeclampsia. In a subsequent publication using the adoptive transfer method in pregnant mice, the group was able to prove this hypothesis.25 Hallmarks of the disease, eg, hypertension, proteinuria, glomerular endotheliosis, placental abnormalities, intrauterine growth restriction, and elevated sFlt-1 levels, were found in pregnant mice after injection with either total IgG or affinity-purified AT1-AAs from women with preeclampsia. Coinjection with losartan or by an antibody neutralizing 7-amino acid epitope peptide prevented the onset of theses symptoms. Others have not found this cause-and-effect relationship of AT1-AAs and sFlt-1. For instance, Stepan et al26 found that most of the preeclamptic patients were characterized by high sFlt-1 levels and in the presence of AT1-AAs. However, discordance between AT1-AAs and sFlt-1 was observed in a population of patients characterized by reduced uterine perfusion and no other pregnancy complications. In these cases, AT1-AAs were frequently present, whereas sFlt-1 was not necessarily elevated.In other animal models for preeclampsia, the situation of the angiogenic factors is not that clear. In the reduced uterine perfusion pressure model, a significant upregulation of sFlt-1 in the symptomatic group as compared with the sham-operated controls is seen.27 However, in the transgenic rat model of preeclampsia, sFlt-1 and vascular endothelial growth factor levels are not elevated in the symptomatic group as compared with the controls.28 Oxidative stress, also critically involved in the pathogenesis of preeclampsia and possibly provoked by AT1-AAs, has been shown recently to be a possible therapeutic target. Using a mouse model of preeclampsia (BPH/5), Hoffmann et al29 tested the hypothesis that an early increase in placental oxidative stress, before the onset of maternal symptoms, plays a central role in placental dysfunction and maternal disease and that antioxidant treatment would interrupt the disease process. They demonstrated a marked increase in reactive oxygen species levels in the placenta at midgestation attributable to a decrease in the activity and levels of cytoplasmic superoxide dismutase. Scavenging of reactive oxygen species with Tempol was effective in ameliorating the onset of fetoplacental abnormalities and maternal symptoms.Hypertension-Associated AAs and Other G Protein-Coupled ReceptorsOur group first showed that patients with essential hypertension could harbor AAs directed at the α1-adrenergic receptor. The antibodies seemed to have an agonistic action, reminiscent of thyrotropin-receptor antibodies in Graves' disease. We now showed that α1-adrenergic receptors are present in nearly half of our primary hypertensive cohort.30 This cohort consists of patients with documented hypertension that require ≥3 drug classes for control. In a proof-of-concept study, we showed that immunoadsorption lowers blood pressure in these hypertensive patients. Antibodies against the same epitope were generated and purified in rabbits. The α1-adrenergic receptor and the antibodies from the immunized rabbits induced a similar signal transduction cascade in vascular cells, inducing Ca2+ and extracellular signal-regulated kinase 1/2 phosphorylation. Concomitantly, Kem et al31 described an autoimmune hypertensive syndrome in a patient with well-controlled hypertension and atrial tachyarrhythmias and a restrictive cardiomyopathy. The authors detected AAs against β-adrenergic and M2 muscarinic receptors. Treatment with a specific receptor blocker improved cardiac function.PerspectivesImmunity, innate, adaptive, cellular, and antibody mediated, is integrally connected to not only target-organ damage but also to blood pressure levels. Much is unknown and poorly understood; however, investigators engaged in this field are upbeat and optimistic. We may not know precisely how this complex disease spectrum works, however, we now have available numerous basic and clinical tools with which to attack this problem. Download figureDownload PowerPointFigure 2. Schematic of regulatory T cells (Treg; A) and T cells (B) along with their characteristics, functions, and role in the development of hypertension.Download figureDownload PowerPointFigure 3. Immunologic, genetic, and environmental factors are involved in placental dysfunction, leading to the production and secretion of soluble factors, leading to hypertension, proteinuria, and target-organ damage.Sources of FundingThe Deutsche Forschungsgemeinschaft supports D.N.M., R.D., and F.C.L. with individual grants in aid. The Helmholtz Gemeinschaft supports all of the authors.DisclosuresNone.FootnotesCorrespondence to Ralf Dechend, HELIOS Cinic, Franz-Volhard Clinic, Experimental and Clinical Research Center, Wiltbergstrasse 50, 13125 Berlin, Germany. E-mail [email protected] References 1 Muller DN, Shagdarsuren E, Park JK, Dechend R, Mervaala E, Hampich F, Fiebeler A, Ju X, Finckenberg P, Theuer J, Viedt C, Kreuzer J, Heidecke H, Haller H, Zenke M, Luft FC. Immunosuppressive treatment protects against angiotensin II-induced renal damage. Am J Pathol. 2002; 161: 1679–1693.CrossrefMedlineGoogle Scholar2 Henke N, Schmidt-Ullrich R, Dechend R, Park JK, Qadri F, Wellner M, Obst M, Gross V, Dietz R, Luft FC, Scheidereit C, Muller DN. Vascular endothelial cell-specific NF-kappaB suppression attenuates hypertension-induced renal damage. Circ Res. 2007; 101: 268–276.LinkGoogle Scholar3 Bondeva T, Roger T, Wolf G. Differential regulation of Toll-like receptor 4 gene expression in renal cells by angiotensin II: dependency on AP1 and PU1 transcriptional sites. Am J Nephrol. 2007; 27: 308–314.CrossrefMedlineGoogle Scholar4 Shagdarsuren E, Wellner M, Braesen JH, Park JK, Fiebeler A, Henke N, Dechend R, Gratze P, Luft FC, Muller DN. Complement activation in angiotensin II-induced organ damage. Circ Res. 2005; 97: 716–724.LinkGoogle Scholar5 Diep QN, El Mabrouk M, Cohn JS, Endemann D, Amiri F, Virdis A, Neves MF, Schiffrin EL. Structure, endothelial function, cell growth, and inflammation in blood vessels of angiotensin II-infused rats: role of peroxisome proliferator-activated receptor-gamma. Circulation. 2002; 105: 2296–2302.LinkGoogle Scholar6 Harrison DG, Guzik TJ, Goronzy J, Weyand C. Is hypertension an immunologic disease? Curr Cardiol Rep. 2008; 10: 464–469.CrossrefMedlineGoogle Scholar7 Guzik TJ, Hoch NE, Brown KA, McCann LA, Rahman A, Dikalov S, Goronzy J, Weyand C, Harrison DG. Role of the T cell in the genesis of angiotensin II induced hypertension and vascular dysfunction. J Exp Med. 2007; 204: 2449–2460.CrossrefMedlineGoogle Scholar8 Gratze P, Dechend R, Stocker C, Park JK, Feldt S, Shagdarsuren E, Wellner M, Gueler F, Rong S, Gross V, Obst M, Plehm R, Alenina N, Zenclussen A, Titze J, Small K, Yokota Y, Zenke M, Luft FC, Muller DN. Novel role for inhibitor of differentiation 2 in the genesis of angiotensin II-induced hypertension. Circulation. 2008; 117: 2645–2656.LinkGoogle Scholar9 Shao J, Nangaku M, Miyata T, Inagi R, Yamada K, Kurokawa K, Fujita T. Imbalance of T-cell subsets in angiotensin II-infused hypertensive rats with kidney injury. Hypertension. 2003; 42: 31–38.LinkGoogle Scholar10 Korn T, Bettelli E, Oukka M, Kuchroo VK. IL-17 and Th17 cells. Annu Rev Immunol. 2009; 27: 485–517.CrossrefMedlineGoogle Scholar11 Kvakan H KM, Quadri F, Park J-K, Fischer R, Schwarz I, Rahn H-P, Plehm R, Elitok S, Gratze P, Dechend R, Luft FC, Muller DN. Regulatory T cells ameliorate angiotensin II-induced cardiac damage. Circulation. 2009; 119: 2904–2912.LinkGoogle Scholar12 Mold JE, Michaelsson J, Burt TD, Muench MO, Beckerman KP, Busch MP, Lee TH, Nixon DF, McCune JM. Maternal alloantigens promote the development of tolerogenic fetal regulatory T cells in utero. Science. 2008; 322: 1562–1565.CrossrefMedlineGoogle Scholar13 Maynard S, Epstein FH, Karumanchi SA. Preeclampsia and angiogenic imbalance. Annu Rev Med. 2008; 59: 61–78.CrossrefMedlineGoogle Scholar14 Norwitz ER, Schust DJ, Fisher SJ. Implantation and the survival of early pregnancy. N Engl J Med. 2001; 345: 1400–1408.CrossrefMedlineGoogle Scholar15 King A, Hiby SE, Gardner L, Joseph S, Bowen JM, Verma S, Burrows TD, Loke YW. Recognition of trophoblast HLA class I molecules by decidual NK cell receptors-a review. Placenta. 2000; 21 (suppl A): S81–S85.CrossrefMedlineGoogle Scholar16 Redman CW, Sargent IL. Latest advances in understanding preeclampsia. Science. 2005; 308: 1592–1594.CrossrefMedlineGoogle Scholar17 Conrad KP, Miles TM, Benyo DF. Circulating levels of immunoreactive cytokines in women with preeclampsia. Am J Reprod Immunol. 1998; 40: 102–111.CrossrefMedlineGoogle Scholar18 Leik CE, Walsh SW. Neutrophils infiltrate resistance-sized vessels of subcutaneous fat in women with preeclampsia. Hypertension. 2004; 44: 72–77.LinkGoogle Scholar19 Hanna J, Goldman-Wohl D, Hamani Y, Avraham I, Greenfield C, Natanson-Yaron S, Prus D, Cohen-Daniel L, Arnon TI, Manaster I, Gazit R, Yutkin V, Benharroch D, Porgador A, Keshet E, Yagel S, Mandelboim O. Decidual NK cells regulate key developmental processes at the human fetal-maternal interface. Nat Med. 2006; 12: 1065–1074.CrossrefMedlineGoogle Scholar20 Thway TM, Shlykov SG, Day MC, Sanborn BM, Gilstrap LC III, Xia Y, Kellems RE. Antibodies from preeclamptic patients stimulate increased intracellular Ca2+ mobilization through angiotensin receptor activation. Circulation. 2004; 110: 1612–1619.LinkGoogle Scholar21 Dragun D, Muller DN, Brasen JH, Fritsche L, Nieminen-Kelha M, Dechend R, Kintscher U, Rudolph B, Hoebeke J, Eckert D, Mazak I, Plehm R, Schonemann C, Unger T, Budde K, Neumayer HH, Luft FC, Wallukat G. Angiotensin II type 1-receptor activating antibodies in renal-allograft rejection. N Engl J Med. 2005; 352: 558–569.CrossrefMedlineGoogle Scholar22 Dechend R, Gratze P, Wallukat G, Shagdarsuren E, Plehm R, Brasen JH, Fiebeler A, Schneider W, Caluwaerts S, Vercruysse L, Pijnenborg R, Luft FC, Muller DN. Agonistic autoantibodies to the AT1 receptor in a transgenic rat model of preeclampsia. Hypertension. 2005; 45: 742–746.LinkGoogle Scholar23 Lamarca B, Wallukat G, Llinas M, Herse F, Dechend R, Granger JP. Autoantibodies to the angiotensin type I receptor in response to placental ischemia and tumor necrosis factor-α in pregnant rats. Hypertension. 2008; 52: 1168–1172.LinkGoogle Scholar24 Zhou CC, Ahmad S, Mi T, Abbasi S, Xia L, Day MC, Ramin SM, Ahmed A, Kellems RE, Xia Y. Autoantibody from women with preeclampsia induces soluble Fms-like tyrosine kinase-1 production via angiotensin type 1 receptor and calcineurin/nuclear factor of activated T-cells signaling. Hypertension. 2008; 51: 1010–1019.LinkGoogle Scholar25 Zhou CC, Zhang Y, Irani RA, Zhang H, Mi T, Popek EJ, Hicks MJ, Ramin SM, Kellems RE, Xia Y. Angiotensin receptor agonistic autoantibodies induce pre-eclampsia in pregnant mice. Nat Med. 2008; 14: 855–862.CrossrefMedlineGoogle Scholar26 Stepan H, Faber R, Wessel N, Wallukat G, Schultheiss HP, Walther T. Relation between circulating angiotensin II type 1 receptor agonistic autoantibodies and soluble fms-like tyrosine kinase 1 in the pathogenesis of preeclampsia. J Clin Endocrinol Metab. 2006; 91: 2424–2427.CrossrefMedlineGoogle Scholar27 Gilbert JS, Babcock SA, Granger JP. Hypertension produced by reduced uterine perfusion in pregnant rats is associated with increased soluble fms-like tyrosine kinase-1 expression. Hypertension. 2007; 50: 1142–1147.LinkGoogle Scholar28 Verlohren S, Niehoff M, Hering L, Geusens N, Herse F, Tintu AN, Plagemann A, LeNoble F, Pijnenborg R, Muller DN, Luft FC, Dudenhausen JW, Gollasch M, Dechend R. Uterine vascular function in a transgenic preeclampsia rat model. Hypertension. 2008; 51: 547–553.LinkGoogle Scholar29 Hoffmann DS, Weydert CJ, Lazartigues E, Kutschke WJ, Kienzle MF, Leach JE, Sharma JA, Sharma RV, Davisson RL. Chronic tempol prevents hypertension, proteinuria, and poor feto-placental outcomes in BPH/5 mouse model of preeclampsia. Hypertension. 2008; 51: 1058–1065.LinkGoogle Scholar30 Wenzel K, Haase H, Wallukat G, Derer W, Bartel S, Homuth V, Herse F, Hubner N, Schulz H, Janczikowski M, Lindschau C, Schroeder C, Verlohren S, Morano I, Muller DN, Luft FC, Dietz R, Dechend R, Karczewski P. Potential relevance of alpha(1)-adrenergic receptor autoantibodies in refractory hypertension. PLoS ONE. 2008; 3: e3742.CrossrefMedlineGoogle Scholar31 Kem DC, Yu X, Patterson E, Huang S, Stavrakis S, Szabo B, Olansky L, McCauley J, Cunningham MW. Autoimmune hypertensive syndrome. Hypertension. 2007; 50: 829–834.LinkGoogle Scholar Previous Back to top Next FiguresReferencesRelatedDetailsCited By Das U (2021) Molecular biochemical aspects of salt (sodium chloride) in inflammation and immune response with reference to hypertension and type 2 diabetes mellitus, Lipids in Health and Disease, 10.1186/s12944-021-01507-8, 20:1, Online publication date: 1-Dec-2021. Panova I, Kudryashova A, Panashchatenko A, Rokotyanskaya E, Malyshkina A, Parejshvili V and Harlamova N Character of β-lymphocytes differentiation in women with hypertensive disorders during pregnancy, Russian Clinical Laboratory Diagnostics, 10.51620/0869-2084-2021-66-8-489-495, 66:8, (489-495) Czop
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