Mild traumatic brain injury/concussion (mTBI) accounts for 70–90% of all reported TBI cases and causes long-lasting neurological consequences in 10–40% of patients. Recent clinical studies revealed increased blood–brain barrier (BBB) permeability in mTBI patients, which correlated with secondary damage after mTBI. However, the cascade of cellular events initiated by exposure to blood-borne factors resulting in sustained damage is not fully understood. We previously reported that astrocytes respond atypically to mTBI, rapidly losing many proteins essential to their homeostatic function, while classic scar formation does not occur. Here, we tested the hypothesis that mTBI-induced BBB damage causes atypical astrocytes through exposure to blood-borne factors. Using an mTBI mouse model, two-photon imaging, an endothelial cell-specific genetic ablation approach, and serum-free primary astrocyte cultures, we demonstrated that areas with atypical astrocytes coincide with BBB damage and that exposure of astrocytes to plasma proteins is sufficient to initiate loss of astrocyte homeostatic proteins. Although mTBI resulted in frequent impairment of both physical and metabolic BBB properties and leakage of small-sized blood-borne factors, deposition of the coagulation factor fibrinogen or vessel rupture were rare. Surprisingly, even months after mTBI, BBB repair did not occur in areas with atypical astrocytes. Together, these findings implicate that even relatively small BBB disturbances are sustained long term, and render nearby astrocytes dysfunctional, likely at the cost of neuronal health and function.
Get full access to this article
View all access options for this article.
References
1.
CassidyJ.D., CarrollL.J., PelosoP.M., BorgJ., von HolstH., HolmL., KrausJ., and CoronadoV.G. (2004). Incidence, risk factors and prevention of mild traumatic brain injury: results of the WHO Collaborating Centre Task Force on Mild Traumatic Brain Injury. J. Rehabil. Med. 43, Suppl., 28–60.
2.
FehilyB., and FitzgeraldM. (2017). Repeated mild traumatic brain injury: potential mechanisms of damage. Cell Transplant. 26, 1131–1155.
3.
FehilyB., and FitzgeraldM. (2017). Repeated mild traumatic brain injury: potential mechanisms of damage. Cell Transplant. 26, 1131–1155.
4.
WillerB., and LeddyJ.J. (2006). Management of concussion and post-concussion syndrome. Curr. Treat. Options Neurol. 8, 415–426.
5.
Bolton-HallA.N., HubbardW.B., and SaatmanK.E. (2019). Experimental designs for repeated mild traumatic brain injury: challenges and considerations. J. Neurotrauma, 36, 1203–1221.
6.
EllisM.J., LeddyJ., CordingleyD., and WillerB. (2018). A physiological approach to assessment and rehabilitation of acute concussion in collegiate and professional athletes. Front. Neurol. 9, 1115–1115.
7.
KenzieE.S., ParksE.L., BiglerE.D., WrightD.W., LimM.M., ChesnuttJ.C., HawrylukG.W.J., GordonW., and WakelandW. (2018). The dynamics of concussion: mapping pathophysiology, persistence, and recovery with causal-loop diagramming. Front. Neurol. 9, 203–203.
8.
JohnsonV.E., StewartJ.E., BegbieF.D., TrojanowskiJ.Q., SmithD.H., and StewartW. (2013). Inflammation and white matter degeneration persist for years after a single traumatic brain injury. Brain, 136, 28–42.
9.
WangM.L., and LiW.B. (2016). Cognitive impairment after traumatic brain injury: The role of MRI and possible pathological basis. J. Neurol. Sci. 370, 244–250.
10.
SahyouniR., GutierrezP., GoldE., RobertsonR.T., and CummingsB.J. (2017). Effects of concussion on the blood–brain barrier in humans and rodents. J. Concussion [Epub ahead of print].
11.
IvensS., KauferD., FloresL.P., BechmannI., ZumstegD., TomkinsO., SeiffertE., HeinemannU., and FriedmanA. (2007). TGF-beta receptor-mediated albumin uptake into astrocytes is involved in neocortical epileptogenesis. Brain, 130, 535–547.
12.
CacheauxL.P., IvensS., DavidY., LakhterA.J., Bar-KleinG., ShapiraM., HeinemannU., FriedmanA., and KauferD. (2009). Transcriptome profiling reveals TGF-beta signaling involvement in epileptogenesis. J. Neurosci. 29, 8927–8935.
13.
HooperC., Pinteaux-JonesF., FryV.A., SevastouI.G., BakerD., HealesS.J., and PocockJ.M. (2009). Differential effects of albumin on microglia and macrophages; implications for neurodegeneration following blood–brain barrier damage. J. Neurochem. 109, 694–705.
14.
LinC.C., LeeI.T., WuW.B., LiuC.J., HsiehH.L., HsiaoL.D., YangC.C., and YangC.M. (2013). Thrombin mediates migration of rat brain astrocytes via PLC, Ca2+, CaMKII, PKCα, and AP-1-dependent matrix metalloproteinase-9 expression. Mol. Neurobiol. 48, 616–630.
15.
MhatreM., NguyenA., KashaniS., PhamT., AdesinaA., and GrammasP. (2004). Thrombin, a mediator of neurotoxicity and memory impairment. Neurobiol. Aging, 25, 783–793.
16.
SchachtrupC., RyuJ.K., HelmrickM.J., VagenaE., GalanakisD.K., DegenJ.L., MargolisR.U., and AkassoglouK. (2010). Fibrinogen triggers astrocyte scar formation by promoting the availability of active TGF-beta after vascular damage. J. Neurosci. 30, 5843–5854.
SofroniewM.V. (2009). Molecular dissection of reactive astrogliosis and glial scar formation. Trends Neurosci. 32, 638–647.
19.
ShandraO., WinemillerA.R., HeithoffB.P., Munoz-BallesterC., GeorgeK.K., BenkoM.J., ZuidhoekI.A., BesserM.N., CurleyD.E., EdwardsG.F., 3rdMey, A., HarringtonA.N., KitchenJ.P., and RobelS. (2019). Repetitive diffuse mild traumatic brain injury causes an atypical astrocyte response and spontaneous recurrent seizures. J. Neurosci. 39, 1944–1963.
20.
ShandraO., and RobelS. (2019). Imaging and manipulating astrocyte function in vivo in the context of CNS injury. Methods Mol. Biol. 1938, 233–246.
21.
HoltL.M., and OlsenM.L. (2016). Novel applications of magnetic cell sorting to analyze cell-type specific gene and protein expression in the central nervous system. PLoS One, 11, e0150290.
22.
HeithoffB.P., GeorgeK.K., PharesA.N., ZuidhoekI.A., Munoz-BallesterC.. and RobelS. (2021). Astrocytes are necessary for blood–brain barrier maintenance in the adult mouse brain. Glia, 69, 436–472.
23.
PardridgeW.M., BoadoR.J., and FarrellC.R. (1990). Brain-type glucose transporter (GLUT-1) is selectively localized to the blood–brain barrier. Studies with quantitative western blotting and in situ hybridization. J. Biol. Chem. 265, 18, 035–18,040.
24.
IvanovaA., SignoreM., CaroN., GreeneN.D., CoppA.J., and Martinez-BarberaJ.P. (2005). In vivo genetic ablation by Cre-mediated expression of diphtheria toxin fragment A. Genesis, 43, 129–135.
25.
HoltL.M., HernandezR.D., PachecoN.L., Torres CejaB., HossainM., and OlsenM.L. (2019). Astrocyte morphogenesis is dependent on BDNF signaling via astrocytic TrkB.T1. Elife, 8, e44667.
26.
BushT.G., PuvanachandraN., HornerC.H., PolitoA., OstenfeldT., SvendsenC.N., MuckeL., JohnsonM.H., and SofroniewM.V. (1999). Leukocyte infiltration, neuronal degeneration, and neurite outgrowth after ablation of scar-forming, reactive astrocytes in adult transgenic mice. Neuron, 23, 297–308.
27.
SimpkinsA.N., DiasC., LeighR. and National Institutes of Health Natural History of StrokeInvestigators (2016). Identification of reversible disruption of the human blood–brain barrier following acute ischemia. Stroke, 47, 2405–2408.
28.
HendrickxA., and BossuytX. (2001). Quantification of the leukocyte common antigen (CD45) in mature B-cell malignancies. Cytometry, 46, 336–339.
29.
FrikJ., Merl-PhamJ., PlesnilaN., MattuginiN., KjellJ., KraskaJ., GómezR.M., HauckS.M., SirkoS., and GötzM. (2018). Cross-talk between monocyte invasion and astrocyte proliferation regulates scarring in brain injury. EMBO Rep. [Epub ahead of print].
NicoB., TammaR., AnneseT., MangieriD., De LucaA., CorsiP., BenagianoV., LongoV., CrivellatoE., SalmaggiA., and RibattiD. (2010). Glial dystrophin-associated proteins, laminin and agrin, are downregulated in the brain of mdx mouse. Lab. Invest. 90, 1645–1660.
32.
BraggA.D., Amiry-MoghaddamM., OttersenO.P., AdamsM.E., and FroehnerS.C. (2006). Assembly of a perivascular astrocyte protein scaffold at the mammalian blood–brain barrier is dependent on alpha-syntrophin. Glia, 53, 879–890.
33.
HoddevikE.H., RaoS.B., ZahlS., BoldtH.B., OttersenO.P., and Amiry-MoghaddamM. (2020). Organisation of extracellular matrix proteins laminin and agrin in pericapillary basal laminae in mouse brain. Brain Struct. Funct. 225, 805–816.
34.
VillapolS., ByrnesK.R., and SymesA.J. (2014). Temporal dynamics of cerebral blood flow, cortical damage, apoptosis, astrocyte-vasculature interaction and astrogliosis in the pericontusional region after traumatic brain injury. Front. Neurol. 5, 82.
35.
AllahyariR.V., ClarkK.L., ShepardK.A., and GarciaA.D.R. (2019). Sonic hedgehog signaling is negatively regulated in reactive astrocytes after forebrain stab injury. Sci. Rep. 9, 565.
36.
AlvarezJ.I., Dodelet-DevillersA., KebirH., IferganI., FabreP.J., TerouzS., SabbaghM., WosikK., BourbonnièreL., BernardM., van HorssenJ., de VriesH.E., CharronF., and PratA. (2011). The Hedgehog pathway promotes blood–brain barrier integrity and CNS immune quiescence. Science, 334, 1727–1731.
37.
XingG., ZhaoT., ZhangX., LiH., LiX., CuiP., LiM., LiD., ZhangN., and JiangW. (2020). Astrocytic sonic hedgehog alleviates intracerebral hemorrhagic brain injury via modulation of blood–brain barrier integrity. Front. Cell Neurosci. 14, 575690.
38.
SamuelsJ.M., MooreE.E., SillimanC.C., BanerjeeA., CohenM.J., GhasabyanA., ChandlerJ., ColemanJ.R., and SauaiaA. (2019). Severe traumatic brain injury is associated with a unique coagulopathy phenotype. J. Trauma Acute Care Surg. 86, 686–693.
HuovinenA., MarinkovicI., IsokuorttiH., KorvenojaA., MäkiK., NyboT., RajR., and MelkasS. (2021). Traumatic microbleeds in mild traumatic brain injury are not associated with delayed return to work or persisting post-concussion symptoms. J. Neurotrauma, 38, 2400–2406.
41.
TothL., CziglerA., HorvathP., KornyeiB., SzarkaN., SchwarczA., UngvariZ., BukiA., and TothP. (2021). Traumatic brain injury-induced cerebral microbleeds in the elderly. GeroScience, 43, 125–136.
42.
ChenL., WangJ., YouQ., HeS., MengQ., GaoJ., WuX., ShenY., SunY., WuX., and XuQ. (2018). Activating AMPK to restore tight junction assembly in intestinal epithelium and to attenuate experimental colitis by metformin. Front. Pharmacol. 9, 761.
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.
