Restricted accessResearch articleFirst published online 2018-07
Delayed Administration of BQ788,an ET B Antagonist,after Experimental Traumatic Brain Injury Promotes Recovery of Blood–Brain Barrier Function and a Reduction of Cerebral Edema in Mice
Traumatic brain injury (TBI) is induced by immediate physical disruption of brain tissue, and causes death and disability. Studies on experimental TBI animal models show that disruption of the blood–brain barrier (BBB) underlies brain edema and neuroinflammation during the delayed phase of TBI. In neurological disorders, endothelin-1 (ET-1) is involved in BBB dysfunction and brain edema. In this study, the effect of ET antagonists on BBB dysfunction and brain edema were examined in a mouse focal TBI model using lateral fluid percussion injury (FPI). ET-1 and ETB receptors were increased at 2–7 days after FPI, which was accompanied by extravasation of Evans blue (EB) and brain edema. Repeated intracerebroventricular administration of BQ788 (15 nmol/day), an ETB antagonist, from 2 days after FPI promoted recovery of EB extravasation and brain edema, while FR 139317, an ETA antagonist, had no effect. Delayed intravenous administration of BQ788 also promoted recovery from FPI-induced EB extravasation and brain edema. While FPI caused decreases in claudin-5, occludin, and zonula occludens-1 proteins, BQ788 reversed FPI-induced reductions of them. Immunohistochemical observation of the cerebrum after FPI showed that ETB receptors are predominantly expressed in glial fibrillary acidic protein (GFAP)-positive astrocytes. BQ788 reduced FPI-induced increases in GFAP-positive astrocytes. GFAP-positive astrocytes produced vascular endothelial growth factor-A (VEGF-A) and matrix metalloproteinase-9 (MMP9). FPI-induced increases in VEGF-A and MMP-9 production were reversed by BQ788. These results suggest that ETB receptor antagonism during the delayed phase of focal TBI promotes recovery of BBB function and reduction of brain edema.
Get full access to this article
View all access options for this article.
References
1.
LoaneD.J., StoicaB.A., and FadenA.I. (2015). Neuroprotection for traumatic brain injury. Handb. Clin. Neurol., 127, 343–366.
2.
O'ConnorW.T., SmythA., and GilchristM.D. (2011). Animal models of traumatic brain injury: a critical evaluation. Pharmacol. Ther., 130, 106–113.
3.
BaşkayaM.K., RaoA.M., DoğanA., DonaldsonD., and DempseyR.J. (1997). The biphasic opening of the blood-brain barrier in the cortex and hippocampus after traumatic brain injury in rats. Neurosci. Lett., 226, 33–36.
4.
ShapiraY., SettonD., ArtruA.A., and ShohamiE. (1993). Blood-brain barrier permeability, cerebral edema, and neurologic function after closed head injury in rats. Anesth. Analg., 77, 141–148.
5.
UnterbergA.W., StoverJ., KressB., and KieningK.L. (2004). Edema and brain trauma. Neuroscience, 129, 1021–1029.
6.
Faden.A.I., WuJ., StoicaB.A., and LoaneD.J. (2016). Progressive inflammation-mediated neurodegeneration after traumatic brain or spinal cord injury. Br. J. Pharmacol., 173, 681–691.
7.
LoaneD.J. and FadenA.I. (2010). Neuroprotection for traumatic brain injury: translational challenges and emerging therapeutic strategies. Trends Pharmacol. Sci., 31, 596–604.
8.
AlluriH., Wiggins-DohlvikK., DavisM.L., HuangJ.H., and TharakanB. (2015). Blood-brain barrier dysfunction following traumatic brain injury. Metab. Brain Dis., 30, 1093–1104.
9.
ThalS.C. and NeuhausW. (2014). The blood-brain barrier as a target in traumatic brain injury treatment. Arch. Med. Res., 45, 698–710.
10.
AlvarezJ.I., KatayamaT., and PratA. (2013). Glial influence on the blood brain barrier. Glia, 61, 1939–1958.
11.
ObermeierB., DanemanR., and RansohoffR.M. (2013). Development, maintenance and disruption of the blood-brain barrier. Nat. Med., 19, 1584–1596.
12.
BurdaJ.E., BernsteinA.M., and SofroniewM.V. (2016). Astrocyte roles in traumatic brain injury. Exp. Neurol., 275, 305–315.
13.
DingJ.Y., KreipkeC.W., SchaferP., SchaferS., SpeirsS.L., and RafolsJ.A. (2009). Synapse loss regulated by matrix metalloproteinases in traumatic brain injury is associated with hypoxia inducible factor-1alpha expression. Brain Res. 1268, 125–1234.
14.
GongD., ZhangS., LiuL., DongJ., GuoX., HaoM., TuY., DiaoY., and ZhangJ. (2011). Dynamic changes of vascular endothelial growth factor and angiopoietin-1 in association with circulating endothelial progenitor cells after severe traumatic brain injury. J. Trauma, 70, 1480–1484.
15.
SuehiroE., FujisawaH., AkimuraT., IshiharaH., KajiwaraK., KatoS., FujiiM., YamashitaS., MaekawaT., and SuzukiM. (2004). Increased matrix metalloproteinase-9 in blood in association with activation of interleukin-6 after traumatic brain injury: influence of hypothermic therapy. J. Neurotrauma, 21, 1706–1711.
16.
BlixtJ., SvenssonM., GunnarsonE., and WanecekM. (2015). Aquaporins and blood-brain barrier permeability in early edema development after traumatic brain injury. Brain Res. 1611, 18–28.
17.
GaoW., ZhaoZ., YuG., ZhouZ., ZhouY., HuT., JiangR., and ZhangJ. (2015). VEGI attenuates the inflammatory injury and disruption of blood-brain barrier partly by suppressing the TLR4/NF-κB signaling pathway in experimental traumatic brain injury. Brain Res. 1622, 230–239.
18.
ZhaoJ., PatiS., RedellJ.B., ZhangM., MooreA.N., and DashP.K. (2012). Caffeic Acid phenethyl ester protects blood-brain barrier integrity and reduces contusion volume in rodent models of traumatic brain injury. J. Neurotrauma, 29, 1209–1218.
19.
ArgawA.T., GurfeinB.T., ZhangY., ZameerA., and JohnGR. (2009). VEGF-mediated disruption of endothelial CLN-5 promotes blood-brain barrier breakdown. Proc. Natl. Acad. Sci. U. S. A., 106, 977–982.
20.
BoroujerdiA., Welser-AlvesJ.V., and MilnerR. (2015). Matrix metalloproteinase-9 mediates post-hypoxic vascular pruning of cerebral blood vessels by degrading laminin and claudin-5. Angiogenesis, 18, 255–264.
21.
KimJ.Y., KoA.R., HyunH.W., and KangT.C. (2015). ETB receptor-mediated MMP-9 activation induces vasogenic edema via ZO-1 protein degradation following status epilepticus. Neuroscience, 304, 355–367.
22.
YangY. and RosenbergG.A. (2011). MMP-mediated disruption of claudin-5 in the blood-brain barrier of rat brain after cerebral ischemia. Methods Mol. Biol., 762, 333–345.
23.
YangY., ThompsonJ.F., TaheriS., SalayandiaV.M., McAvoyT.A., HillJ.W., YangY., EstradaE.Y., and RosenbergG.A. (2013). Early inhibition of MMP activity in ischemic rat brain promotes expression of tight junction proteins and angiogenesis during recovery. J. Cereb. Blood Flow Metab., 33, 1104–1114.
24.
HostenbachS., D'haeseleerM., KooijmanR., and De KeyserJ. (2016). The pathophysiological role of astrocytic endothelin-1. Prog. Neurobiol., 144, 88–102.
25.
KoyamaY. and MichinagaS. (2012). Regulations of astrocytic functions by endothelins: roles in the pathophysiological responses of damaged brains. J. Pharmacol. Sci., 118, 401–407.
26.
ChatfieldD.A., BrahmbhattD.H., SharpT., PerkesI.E., OutrimJ.G., and MenonD.K. (2011). Juguloarterial endothelin-1 gradients after severe traumatic brain injury. Neurocrit. Care, 14, 55–60.
27.
MaierB., LehnertM., LaurerH.L., and MarziI. (2007). Biphasic elevation in cerebrospinal fluid and plasma concentrations of endothelin 1 after traumatic brain injury in human patients. Shock, 27, 610–614.
28.
SaloniaR., EmpeyP.E., PoloyacS.M., WisniewskiS.R., KlamerusM., OzawaH., WagnerA.K., RuppelR., BellM.J., FeldmanK., AdelsonP.D., ClarkR.S., and KochanekP.M. (2010). Endothelin-1 is increased in cerebrospinal fluid and associated with unfavorable outcomes in children after severe traumatic brain injury. J. Neurotrauma., 27, 1819–1825.
29.
PetrovT. (2009). Amelioration of hypoperfusion after traumatic brain injury by in vivo endothelin-1 knockout. Can. J. Physiol. Pharmacol., 87, 379–386.
30.
ReynoldsC.A., SchaferS., PiroozR., MarinicaA., ChbibA., BedfordC., FronczakM., RafolsJ.A., KuhnD., and KreipkeC.W. (2011). Differential effects of endothelin receptor A and B antagonism on behavioral outcome following traumatic brain injury. Neurol. Res., 33, 197–200.
31.
ReynoldsC.A., KallakuriS., BagchiM., SchaferS., KreipkeC.W., and RafolsJ.A. (2011). Endothelin receptor A antagonism reduces the extent of diffuse axonal injury in a rodent model of traumatic brain injury. Neurol Res. 33, 192–196.
32.
DidierN., RomeroI.A., CréminonC., WijkhuisenA., GrassiJ., and MabondzoA. (2003). Secretion of interleukin-1beta by astrocytes mediates endothelin-1 and tumour necrosis factor-alpha effects on human brain microvascular endothelial cell permeability. J. Neurochem., 86, 246–254.
33.
KoyamaY. and TanakaK. (2010). Intracerebroventricular administration of an endothelin ETB-receptor agonist increases expression of matrix metalloproteinase-2 and −9 in rat brain. J. Pharmacol. Sci, 114, 433–443.
34.
KoyamaY., MaebaraY., HayashiM., NagaeR., TokuyamaS., and MichinagaS. (2012). Endothelins reciprocally regulate VEGF-A and angiopoietin-1 production in cultured rat astrocytes: implications on astrocytic proliferation. Glia, 60, 1954–1963.
35.
KoyamaY., KotaniM., SawamuraT., KuribayashiM., KonishiR., and MichinagaS. (2013). Different actions of endothelin-1 on chemokine production in rat cultured astrocytes: reduction of CX3CL1/fractalkine and an increase in CCL2/MCP-1 and CXCL1/CINC-1. J. Neuroinflammation, 10, 51.
36.
MorgaE., FaberC., and HeuschlingP. (2000). Stimulation of endothelin B receptor modulates the inflammatory activation of rat astrocytes. J. Neurochem., 74, 603–612.
37.
BaroneF.C., OhlsteinE.H., HunterA.J., CampbellC.A., HadinghamS.H., ParsonsA.A., YangY., and ShohamiE. (2000). Selective antagonism of endothelin-A-receptors improves outcome in both head trauma and focal stroke in rat. J. Cardiovasc. Pharmacol., 36(5 Suppl 1), S357–S361.
38.
MatsuoY., MiharaSI., NinomiyaM., and FujimotoM. (2001). Protective effect of endothelin type A receptor antagonist on brain edema and injury after transient middle cerebral artery occlusion in rats. Stroke, 32, 2143–2148.
39.
MoldesO., SobrinoT., BlancoM., AgullaJ., BarralD., Ramos-CabrerP., and CastilloJ. (2012). Neuroprotection afforded by antagonists of endothelin-1 receptors in experimental stroke. Neuropharmacology, 63, 279–285.
40.
KimJ.E., RyuH.J., and KangT.C. (2013). Status epilepticus induces vasogenic edema via tumor necrosis factor-α/endothelin-1-mediated two different pathways. PLoS One, 8, e74458.
41.
MichinagaS., NagaseM., MatsuyamaE., YamanakaD., SenoN., FukaM., YamamotoY., and KoyamaY. (2014). Amelioration of cold injury-induced cortical brain edema formation by selective endothelin ETB receptor antagonists in mice. PLoS ONE, 9, e102009.
42.
MichinagaS., SenoN., FukaM., YamamotoY., MinamiS., KimuraA., HatanakaS., NagaseM., MatsuyamaE., YamanakaD., and KoyamaY. (2015). Improvement of cold injury-induced mouse brain edema by endothelin ETB antagonists is accompanied by decreases in matrixmetalloproteinase 9 and vascular endothelial growth factor-A. Eur. J. Neurosci., 42, 2356–2370.
KoyamasY. (2013) Endothelin systems in the brain: involvement in pathophysiological responses of damaged nerve tissues. Biomol. Concepts, 4, 335–347.
45.
ZuccarelloM., BoccalettiR., RomanoA., and RapoportR.M. (1998) Endothelin B receptor antagonists attenuate subarachnoid hemorrhage-induced cerebral vasospasm. Stroke. 29, 1924–1929.
46.
LabanK.G., VergouwenM.D., DijkhuizenR.M., SenaE.S., MacleodM.R., RinkelG.J., and van der WorpH.B. (2015) Effect of endothelin receptor antagonists on clinically relevant outcomes after experimental subarachnoid hemorrhage: a systematic review and meta-analysis. J. Cereb. Blood Flow Metab., 35, 1085–1089.
47.
PalmerJ. and LoveS. (2011) Endothelin receptor antagonists: potential in Alzheimer's disease. Pharmacol. Res., 63, 525–531.
48.
RannoE., D'AntoniS., SpatuzzaM., BerrettaA., LaureantiF., BonaccorsoC.M., PellitteriR., LongoneP., SpalloniA., IyerA.M., AronicaE., and CataniaM.V. (2014) Endothelin-1 is over-expressed in amyotrophic lateral sclerosis and induces motor neuron cell death. Neurobiol. Dis., 65, 160–171.
49.
BuffoA., RolandoC., and CerutiS. (2010). Astrocytes in the damaged brain: molecular and cellular insights into their reactive response and healing potential. Biochem. Pharmacol., 79, 77–89.
50.
KoyamaY., TakemuraM., FujikiK., IshikawaN., ShigenagaY., and BabaA. (1999). BQ788, an endothelin ETB receptor antagonist, attenuates stab wound injury-induced reactive astrocytes in rat brain. Glia, 26, 268–271.
51.
ArgawA.T., AspL., ZhangJ., NavrazhinaK., PhamT., MarianiJ.N., MahaseS., DuttaD.J., SetoJ., KramerE.G., FerraraN., SofroniewM.V., and JohnG.R. (2012). Astrocyte-derived VEGF-A drives blood-brain barrier disruption in CNS inflammatory disease. J. Clin. Invest., 122, 2454–2468.
52.
ReinholdA.K. and RittnerH.L. (2017). Barrier function in the peripheral and central nervous system-a review. Pflügers Arch. 469, 123–134.
53.
MinH., HongJ., ChoI.H., JangY.H., LeeH., KimD., YuS.W., LeeS., and LeeS.J. (2015). TLR2-induced astrocyte MMP9 activation compromises the blood brain barrier and exacerbates intracerebral hemorrhage in animal models. Mol. Brain, 8, 23.
54.
SköldM.K., von GerttenC., Sandberg-NordqvistA.C., MathiesenT., and HolminS. (2005). VEGF and VEGF receptor expression after experimental brain contusion in rat. J. Neurotrauma, 22, 353–367.
55.
KoyamaY., NagaeR., TokuyamaS., and TanakaK. (2011). I.c.v administration of an endothelin ETB receptor agonist stimulates vascular endothelial growth factor-A production and activates vascular endothelial growth factor receptors in rat brain. Neuroscience, 192, 689–698.
56.
AslS.Z., KhaksariM., KhachkiA.S., ShahrokhiN., and NourizadeS. (2013). Contribution of estrogen receptors alpha and beta in the brain response to traumatic brain injury. J. Neurosurg., 119, 353–361.
57.
PascualJ.L., MurcyM.A., LiS., GongW., EisenstadtR., KumasakaK., SimsC., SmithDH., BrowneK., AllenS., and BarenJ. (2013). Neuroprotective effects of progesterone in traumatic brain injury: blunted in vivo neutrophil activation at the blood-brain barrier. Am. J. Surg., 206, 840–845.
58.
BessonV.C., ChenX.R., PlotkineM., and Marchand-VerrecchiaC. (2005). Fenofibrate, a peroxisome proliferator-activated receptor alpha agonist, exerts neuroprotective effects in traumatic brain injury. Neurosci. Lett., 388, 7–12.
59.
ThalS.C., HeinemannM., LuhC., PieterD., WernerC., and EngelhardK. (2011). Pioglitazone reduces secondary brain damage after experimental brain trauma by PPAR-γ-independent mechanisms. J. Neurotrauma, 28, 983–993.
60.
KimblerD.E., ShieldsJ., YanasakN., VenderJ.R., and DhandapaniK.M. (2012). Activation of P2X7 promotes cerebral edema and neurological injury after traumatic brain injury in mice. PLoS One, 7, e41229.
61.
TehranianR., Andell-JonssonS., BeniS.M., YatsivI., ShohamiE., BartfaiT., LundkvistJ., and IverfeldtK. (2002) Improved recovery and delayed cytokine induction after closed head injury in mice with central overexpression of the secreted isoform of the interleukin-1 receptor antagonist. J. Neurotrauma, 19, 939–951.
62.
ClausenF., HånellA., IsraelssonC., HedinJ., EbendalT., MirA.K., GramH., and MarklundN. (2011) Neutralization of interleukin-1β reduces cerebral edema and tissue loss and improves late cognitive outcome following traumatic brain injury in mice. Eur. J. Neurosci., 34, 110–123.
63.
TraboldR., ErösC., ZweckbergerK., ReltonJ., BeckH., NussbergerJ., Müller-EsterlW., BaderM., WhalleyE., and PlesnilaN. (2010) The role of bradykinin B1 and B2 receptors for secondary brain damage after traumatic brain injury in mice. J. Cereb. Blood Flow Metab., 30, 130–139.
64.
Albert-WeissenbergerC., StetterC., MeuthS.G., GöbelK, BaderM., Sirén, and A.L., KleinschnitzC. (2012) Blocking of bradykinin receptor B1 protects from focal closed head injury in mice by reducing axonal damage and astroglia activation. J. Cereb. Blood Flow Metab., 32, 1747–1756.
Supplementary Material
Please find the following supplemental material available below.
For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.
For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.
