Mild repetitive traumatic brain injury (rTBI) induces chronic behavioral and cognitive alterations and increases the risk for dementia. Currently, there are no therapeutic strategies to prevent or mitigate chronic deficits associated with rTBI. Previously we developed an animal model of rTBI that recapitulates the cognitive and behavioral deficits observed in humans. We now report that rTBI results in an increase in risk-taking behavior in male but not female mice. This behavioral phenotype is associated with chronic activation of the integrated stress response and cell-specific synaptic alterations in the type A subtype of layer V pyramidal neurons in the medial prefrontal cortex. Strikingly, by briefly treating animals weeks after injury with ISRIB, a selective inhibitor of the integrated stress response (ISR), we (1) relieve ISR activation, (2) reverse the increased risk-taking behavioral phenotype and maintain this reversal, and (3) restore cell-specific synaptic function in the affected mice. Our results indicate that targeting the ISR even at late time points after injury can permanently reverse behavioral changes. As such, pharmacological inhibition of the ISR emerges as a promising avenue to combat rTBI-induced behavioral dysfunction.
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References
1.
SmithD.H., JohnsonV.E., and StewartW. (2013). Chronic neuropathologies of single and repetitive TBI: substrates of dementia?. Nat. Rev. Neurol. 9, 211–221.
2.
DeKoskyS.T., IkonomovicM.D., and GandyS. (2010). Traumatic brain injury—football, warfare, and long-term effects. N. Engl. J. Med. 363, 1293–1296.
3.
EngbergA.W., and TeasdaleT.W. (2004). Psychosocial outcome following traumatic brain injury in adults: a long-term population-based follow-up. Brain Inj. 18, 533–545.
4.
SullivanP., PetittiD., and BarbacciaJ. (1987). Head trauma and age of onset of dementia of the Alzheimer type. JAMA, 257, 2289–2290.
5.
NelsonL.D., TemkinN.R., DikmenS., BarberJ., GiacinoJ.T., YuhE., LevinH.S., McCreaM.A., SteinM.B., MukherjeeP., OkonkwoD.O., Diaz-ArrastiaR., ManleyG.T., and theTR, ACK-TBIInvestigators, AdeoyeO., BadjatiaN., BoaseK., BodienY., BullockM.R., ChesnutR., CorriganJ.D., CrawfordK., MIS, DuhaimeA.C., EllenbogenR., FeeserV.R., FergusonA., ForemanB., GardnerR., GaudetteE., GonzalezL., GopinathS., GullapalliR., HemphillJ.C., HotzG., JainS., KorleyF., KramerJ., KreitzerN., LindsellC., MachamerJ., MaddenC., MartinA., McAllisterT., MerchantR., NoelF., PalaciosE., PerlD., PuccioA., RabinowitzM., RobertsonC.S., RosandJ., SanderA., SatrisG., SchnyerD., SeaburyS., ShererM., TaylorS., TogaA., ValadkaA., VassarM.J., VespaP., WangK., YueJ.K., and ZafonteR. (2019). Recovery after mild traumatic brain injury in patients presenting to US Level I trauma centers: a transforming research and clinical knowledge in traumatic brain injury (TRACK-TBI) study. JAMA Neurol. E-pub ahead of print.
6.
LasryO., LiuE.Y., PowellG.A., Ruel-LaliberteJ., MarcouxJ., and BuckeridgeD.L. (2017). Epidemiology of recurrent traumatic brain injury in the general population: a systematic review. Neurology, 89, 2198–2209.
7.
BelangerH.G., SpiegelE., and VanderploegR.D. (2010). Neuropsychological performance following a history of multiple self-reported concussions: a meta-analysis. J. Int. Neuropsychol. Soc. 16, 262–267.
8.
GeddesJ.F., VowlesG.H., NicollJ.A., and ReveszT. (1999). Neuronal cytoskeletal changes are an early consequence of repetitive head injury. Acta Neuropathol. 98, 171–178.
9.
ManleyG., GardnerA.J., SchneiderK.J., GuskiewiczK.M., BailesJ., CantuR.C., CastellaniR.J., TurnerM., JordanB.D., RandolphC., DvorakJ., HaydenK.A., TatorC.H., McCroryP., and IversonG.L. (2017). A systematic review of potential long-term effects of sport-related concussion. Br. J. Sports Med. 51, 969–977.
10.
McAllisterT., and McCreaM. (2017). Long-term cognitive and neuropsychiatric consequences of repetitive concussion and head-impact exposure. J. Athl. Train. 52, 309–317.
11.
CastileL., CollinsC.L., McIlvainN.M., and ComstockR.D. (2012). The epidemiology of new versus recurrent sports concussions among high school athletes, 2005-2010. Br. J. Sports Med. 46, 603–610.
12.
McKeeA.C., CantuR.C., NowinskiC.J., Hedley-WhyteE.T., GavettB.E., BudsonA.E., SantiniV.E., LeeH.S., KubilusC.A., and SternR.A. (2009). Chronic traumatic encephalopathy in athletes: progressive tauopathy after repetitive head injury. J. Neuropathol. Exp. Neurol. 68, 709–735.
MezJ., DaneshvarD.H., KiernanP.T., AbdolmohammadiB., AlvarezV.E., HuberB.R., AloscoM.L., SolomonT.M., NowinskiC.J., McHaleL., CormierK.A., KubilusC.A., MartinB.M., MurphyL., BaughC.M., MontenigroP.H., ChaissonC.E., TripodisY., KowallN.W., WeuveJ., McCleanM.D., CantuR.C., GoldsteinL.E., KatzD.I., SternR.A., SteinT.D., and McKeeA.C. (2017). Clinicopathological evaluation of chronic traumatic encephalopathy in players of American football. JAMA, 318, 360–370.
15.
JuengstS.B., KumarR.G., ArenthP.M., and WagnerA.K. (2014). Exploratory associations with tumor necrosis factor-alpha, disinhibition and suicidal endorsement after traumatic brain injury. Brain Behav. Immun. 41, 134–143.
16.
PolinderS., CnossenM.C., RealR.G.L., CovicA., GorbunovaA., VoormolenD.C., MasterC.L., HaagsmaJ.A., Diaz-ArrastiaR., and von SteinbuechelN. (2018). A multidimensional approach to post-concussion symptoms in mild traumatic brain injury. Front. Neurol. 9, 1113.
17.
TellierA., MarshallS.C., WilsonK.G., SmithA., PeruginiM., and StiellI.G. (2009). The heterogeneity of mild traumatic brain injury: Where do we stand?. Brain Inj. 23, 879–887.
18.
DonnellyN., GormanA.M., GuptaS., and SamaliA. (2013). The eIF2alpha kinases: their structures and functions. Cell Mol. Life Sci. 70, 3493–3511.
19.
ChouA., KrukowskiK., JopsonT., ZhuP.J., Costa-MattioliM., WalterP., and RosiS. (2017). Inhibition of the integrated stress response reverses cognitive deficits after traumatic brain injury. Proc. Natl. Acad. Sci. U. S. A. 114, E6420–E6426.
20.
DashP.K., HylinM.J., HoodK.N., OrsiS.A., ZhaoJ., RedellJ.B., TsvetkovA.S., and MooreA.N. (2015). Inhibition of eukaryotic initiation factor 2 alpha phosphatase reduces tissue damage and improves learning and memory after experimental traumatic brain injury. J. Neurotrauma, 32, 1608–1620.
21.
RubovitchV., BarakS., RachmanyL., GoldsteinR.B., ZilbersteinY., and PickC.G. (2015). The neuroprotective effect of salubrinal in a mouse model of traumatic brain injury. Neuromolecular Med. 17, 58–70.
22.
HinnebuschA.G., IvanovI.P., and SonenbergN. (2016). Translational control by 5'-untranslated regions of eukaryotic mRNAs. Science, 352, 1413–1416.
23.
SonenbergN., and HinnebuschA.G. (2009). Regulation of translation initiation in eukaryotes: mechanisms and biological targets. Cell, 136, 731–745.
24.
De Pietri TonelliD., MihailovichM., Di CesareA., CodazziF., GrohovazF., and ZacchettiD. (2004). Translational regulation of BACE-1 expression in neuronal and non-neuronal cells. Nucleic Acids Res. 32, 1808–1817.
25.
LammichS., SchobelS., ZimmerA.K., LichtenthalerS.F., and HaassC. (2004). Expression of the Alzheimer protease BACE1 is suppressed via its 5'-untranslated region. EMBO Rep. 5, 620–625.
26.
MihailovichM., ThermannR., GrohovazF., HentzeM.W., and ZacchettiD. (2007). Complex translational regulation of BACE1 involves upstream AUGs and stimulatory elements within the 5' untranslated region. Nucleic Acids Res. 35, 2975–2985.
27.
O'ConnorT., SadleirK.R., MausE., VelliquetteR.A., ZhaoJ., ColeS.L., EimerW.A., HittB., BembinsterL.A., LammichS., LichtenthalerS.F., HebertS.S., De StrooperB., HaassC., BennettD.A., and VassarR. (2008). Phosphorylation of the translation initiation factor eIF2alpha increases BACE1 levels and promotes amyloidogenesis. Neuron, 60, 988–1009.
28.
ChenA., MuzzioI.A., MalleretG., BartschD., VerbitskyM., PavlidisP., YonanA.L., VronskayaS., GrodyM.B., CepedaI., GilliamT.C., and KandelE.R. (2003). Inducible enhancement of memory storage and synaptic plasticity in transgenic mice expressing an inhibitor of ATF4 (CREB-2) and C/EBP proteins. Neuron, 39, 655–669.
29.
PasiniS., CoronaC., LiuJ., GreeneL.A., and ShelanskiM.L. (2015). Specific downregulation of hippocampal ATF4 reveals a necessary role in synaptic plasticity and memory. Cell Rep. 11, 183–191.
30.
Costa-MattioliM., GobertD., SternE., GamacheK., ColinaR., CuelloC., SossinW., KaufmanR., PelletierJ., RosenblumK., KrnjevicK., LacailleJ.C., NaderK., and SonenbergN. (2007). eIF2alpha phosphorylation bidirectionally regulates the switch from short- to long-term synaptic plasticity and memory. Cell, 129, 195–206.
31.
BatistaG., JohnsonJ.L., DominguezE., Costa-MattioliM., and PenaJ.L. (2016). Translational control of auditory imprinting and structural plasticity by eIF2alpha. Elife. 5.
32.
JiangZ., BelforteJ.E., LuY., YabeY., PickelJ., SmithC.B., JeH.S., LuB., and NakazawaK. (2010). eIF2alpha Phosphorylation-dependent translation in CA1 pyramidal cells impairs hippocampal memory consolidation without affecting general translation. J. Neurosci. 30, 2582–2594.
SidrauskiC., McGeachyA.M., IngoliaN.T., and WalterP. (2015). The small molecule ISRIB reverses the effects of eIF2alpha phosphorylation on translation and stress granule assembly. Elife. 4.
35.
SidrauskiC., TsaiJ.C., KampmannM., HearnB.R., VedanthamP., JaishankarP., SokabeM., MendezA.S., NewtonB.W., TangE.L., VerschuerenE., JohnsonJ.R., KroganN.J., FraserC.S., WeissmanJ.S., RensloA.R., and WalterP. (2015). Pharmacological dimerization and activation of the exchange factor eIF2B antagonizes the integrated stress response. Elife, 4, e07314.
36.
NolanA., HennessyE., KrukowskiK., GuglielmettiC., ChaumeilM.M., SohalV.S,. and RosiS. (2018). Repeated mild head injury leads to wide-ranging deficits in higher-order cognitive functions associated with the prefrontal cortex. J. Neurotrauma, 35, 2425–2434.
37.
KrukowskiK., ChouA., FengX., TiretB., PaladiniM.S., RiparipL.K., ChaumeilM.M., LemereC., and RosiS. (2018). Traumatic brain injury in aged mice induces chronic microglia activation, synapse loss, and complement-dependent memory deficits. Int. J. Mol. Sci. 19.
38.
NamjoshiD.R., ChengW.H., McInnesK.A., MartensK.M., CarrM., WilkinsonA., FanJ., RobertJ., HayatA., CriptonP.A., and WellingtonC.L. (2014). Merging pathology with biomechanics using CHIMERA (Closed-Head Impact Model of Engineered Rotational Acceleration): a novel, surgery-free model of traumatic brain injury. Mol. Neurodegener. 9, 55.
39.
NamjoshiD.R., ChengW.H., BashirA., WilkinsonA., StukasS., MartensK.M., WhyteT., AbebeZ.A., McInnesK.A., CriptonP.A., and WellingtonC.L. (2017). Defining the biomechanical and biological threshold of murine mild traumatic brain injury using CHIMERA (Closed Head Impact Model of Engineered Rotational Acceleration). Exp. Neurol. 292, 80–91.
40.
ChouA., KrukowskiK., MorgantiJ.M., RiparipL.K., and RosiS. (2018). Persistent infiltration and impaired response of peripherally-derived monocytes after traumatic brain injury in the aged brain. Int. J. Mol. Sci. 19.
41.
LeeA.T., GeeS.M., VogtD., PatelT., RubensteinJ.L., and SohalV.S. (2014). Pyramidal neurons in prefrontal cortex receive subtype-specific forms of excitation and inhibition. Neuron, 81, 61–68.
42.
ListerR.G. (1987). The use of a plus-maze to measure anxiety in the mouse. Psychopharmacology (Berl) 92, 180–185.
43.
BoggT., FukunagaR., FinnP.R., and BrownJ.W. (2012). Cognitive control links alcohol use, trait disinhibition, and reduced cognitive capacity: evidence for medial prefrontal cortex dysregulation during reward-seeking behavior. Drug Alcohol Depend. 122, 112–118.
44.
CassidyJ.D., CarrollL.J., PelosoP.M., BorgJ., von HolstH., HolmL., KrausJ., CoronadoV.G., and InjuryW.H.O. Collaborating Centre Task Force on Mild Traumatic BrainInjury. (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. Suppl, 43, 28–60.
45.
BinderL.M., RohlingM.L., and LarrabeeG.J. (1997). A review of mild head trauma. Part I: meta-analytic review of neuropsychological studies. J. Clin. Exp. Neuropsychol. 19, 421–431.
46.
WillerB., and LeddyJ.J. (2006). Management of concussion and post-concussion syndrome. Curr. Treat. Options Neurol. 8, 415–426.
47.
MittenbergW., CanyockE.M., ConditD., and PattonC. (2001). Treatment of post-concussion syndrome following mild head injury. J. Clin. Exp. Neuropsychol. 23, 829–836.
48.
FaulM., and CoronadoV. (2015). Epidemiology of traumatic brain injury. Handb. Clin. Neurol. 127, 3–13.
49.
CoronadoV.G., McGuireL.C., SarmientoK., BellJ., LionbargerM.R., JonesC.D., GellerA.I., KhouryN., and XuL. (2012). Trends in traumatic brain injury in the U.S. and the public health response: 1995-2009. J. Safety Res. 43, 299–307.
50.
CovassinT., MoranR., and ElbinR.J. (2016). Sex differences in reported concussion injury rates and time loss from participation: an update of the National Collegiate Athletic Association Injury Surveillance Program from 2004-2005 Through 2008-2009. J. Athl. Train. 51, 189–194.
51.
SpaniC.B., BraunD.J., and Van EldikL.J. (2018). Sex-related responses after traumatic brain injury: considerations for preclinical modeling. Front. Neuroendocrinol. 50, 52–66.
52.
YamakawaG.R., LengkeekC., SalbergS., SpanswickS.C,. and MychasiukR. (2017). Behavioral and pathophysiological outcomes associated with caffeine consumption and repetitive mild traumatic brain injury (RmTBI) in adolescent rats. PLoS One, 12, e0187218.
53.
WrightD.K., O'BrienT.J., ShultzS.R., and MychasiukR. (2017). Sex matters: repetitive mild traumatic brain injury in adolescent rats. Ann. Clin. Transl. Neurol. 4, 640–654.
54.
MouzonB.C., BachmeierC., FerroA., OjoJ.O., CrynenG., AckerC.M., DaviesP., MullanM., StewartW., and CrawfordF. (2014). Chronic neuropathological and neurobehavioral changes in a repetitive mild traumatic brain injury model. Ann. Neurol. 75, 241–254.
55.
PetragliaA.L., PlogB.A., DayawansaS., ChenM., DashnawM.L., CzernieckaK., WalkerC.T., ViteriseT., HyrienO., IliffJ.J., DeaneR., NedergaardM., and HuangJ.H. (2014). The spectrum of neurobehavioral sequelae after repetitive mild traumatic brain injury: a novel mouse model of chronic traumatic encephalopathy. J. Neurotrauma, 31, 1211–1224.
56.
KondoA., ShahpasandK., MannixR., QiuJ., MoncasterJ., ChenC.H., YaoY., LinY.M., DriverJ.A., SunY., WeiS., LuoM.L., AlbayramO., HuangP., RotenbergA., RyoA., GoldsteinL.E., Pascual-LeoneA., McKeeA.C., MeehanW., ZhouX.Z., and LuK.P. (2015). Antibody against early driver of neurodegeneration cis P-tau blocks brain injury and tauopathy. Nature, 523, 431–436.
57.
MouzonB.C., BachmeierC., OjoJ.O., AckerC.M., FergusonS., ParisD., Ait-GhezalaG., CrynenG., DaviesP., MullanM., StewartW., and CrawfordF. (2017). Lifelong behavioral and neuropathological consequences of repetitive mild traumatic brain injury. Ann. Clin. Transl. Neurol. 5, 64–80.
58.
MollayevaT., El-Khechen-RichandiG., and ColantonioA. (2018). Sex & gender considerations in concussion research. Concussion 3,CNC51.
59.
CovassinT., SchatzP., and SwanikC.B. (2007). Sex differences in neuropsychological function and post-concussion symptoms of concussed collegiate athletes. Neurosurgery, 61, 345–350.
60.
HatskevichC.W., ItkisM.L., and MaloletnevV.I. (1992). Off-line methods for detection and correction of EEG artefacts of various origin. Int. J. Psychophysiol. 12, 179–185.
61.
NiemeierJ.P., MarwitzJ.H., LesherK., WalkerW.C., and BushnikT. (2007). Gender differences in executive functions following traumatic brain injury. Neuropsychol. Rehabil. 17, 293–313.
62.
CacceseJ.B., BuckleyT.A., TierneyR.T., ArbogastK.B., RoseW.C., GluttingJ.J., and KaminskiT.W. (2018). Head and neck size and neck strength predict linear and rotational acceleration during purposeful soccer heading. Sports Biomech. 17, 462–476.
63.
RuigrokA.N., Salimi-KhorshidiG., LaiM.C., Baron-CohenS., LombardoM.V., TaitR.J., and SucklingJ. (2014). A meta-analysis of sex differences in human brain structure. Neurosci. Biobehav. Rev. 39, 34–50.
64.
KimY., YangG.R., PradhanK., VenkatarajuK.U., BotaM., Garcia Del MolinoL.C., FitzgeraldG., RamK., HeM., LevineJ.M., MitraP., HuangZ.J., WangX.J., and OstenP. (2017). Brain-wide maps reveal stereotyped cell-type-based cortical architecture and subcortical sexual dimorphism. Cell, 171, 456–469.e422.
65.
RonD., and HardingH.P. (2012). Protein-folding homeostasis in the endoplasmic reticulum and nutritional regulation. Cold Spring Harb. Perspect. Biol. 4.
66.
TsaiJ.C., Miller-VedamL.E., AnandA.A., JaishankarP., NguyenH.C., RensloA.R., FrostA., and WalterP. (2018). Structure of the nucleotide exchange factor eIF2B reveals mechanism of memory-enhancing molecule. Science. 359.
67.
ZyryanovaA.F., WeisF., FailleA., AlardA.A., Crespillo-CasadoA., SekineY., HardingH.P., AllenF., PartsL., FromontC., FischerP.M., WarrenA.J., and RonD. (2018). Binding of ISRIB reveals a regulatory site in the nucleotide exchange factor eIF2B. Science, 359, 1533–1536.
68.
St OngeJ.R., and FlorescoS.B. (2010). Prefrontal cortical contribution to risk-based decision making. Cereb. Cortex, 20, 1816–1828.
69.
RigaD., MatosM.R., GlasA., SmitA.B., SpijkerS., and Van den OeverM.C. (2014). Optogenetic dissection of medial prefrontal cortex circuitry. Front. Syst .Neurosci. 8, 230.
70.
SmithC.J., XiongG., ElkindJ.A., PutnamB., and CohenA.S. (2015). Brain injury impairs working memory and prefrontal circuit function. Front. Neurol. 6, 240.
71.
BrumbackA.C., EllwoodI.T., KjaerbyC., IafratiJ., RobinsonS., LeeA.T., PatelT., NagarajS., DavatolhaghF., and SohalV.S. (2018). Identifying specific prefrontal neurons that contribute to autism-associated abnormalities in physiology and social behavior. Mol. Psychiatry, 23, 2078–2089.
72.
Di PriscoG.V., HuangW., BuffingtonS.A., HsuC.C., BonnenP.E., PlaczekA.N., SidrauskiC., KrnjevicK., KaufmanR.J., WalterP. ,and Costa-MattioliM. (2014). Translational control of mGluR-dependent long-term depression and object-place learning by eIF2alpha. Nat. Neurosci. 17, 1073–1082.
73.
PlaczekA.N., PriscoG.V., KhatiwadaS., SgrittaM., HuangW., KrnjevicK., KaufmanR.J., DaniJ.A., WalterP., and Costa-MattioliM. (2016). eIF2alpha-mediated translational control regulates the persistence of cocaine-induced LTP in midbrain dopamine neurons. Elife. 5.
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