Hydrocephalus is caused by an imbalance in cerebrospinal fluid (CSF) production and absorption, resulting in excess ventricular fluid accumulation and neurologic impairment. Current therapy for hydrocephalus involves surgical diversion of excess ventricular fluid. The water-transporting protein aquaporin-4 (AQP4) is expressed at the brain-CSF and blood-brain barriers. Here, we provide evidence for AQP4-facilitated CSF absorption in hydrocephalus by a transparenchymal pathway into the cerebral vasculature. A mouse model of obstructive hydrocephalus was created by injecting kaolin (2.5 mg/mouse) into the cisterna magna. Intracranial pressure (ICP) was ~5mm Hg and ventricular size < 0.3 mm3 in control mice. Lateral ventricle volume increased to 3.7 ± 0.5 and 5.1 ±0.5 mm3 in AQP4 null mice at 3 and 5 days after injection, respectively, significantly greater than 2.6 ± 0.3 and 3.5 ± 0.5 mm3 in wildtype mice (P < 0.005). The corresponding ICP was 22 ± 2 mm Hg at 3 days in AQP4 null mice, significantly greater than 14 ± 1 mm Hg in wildtype mice (P < 0.005). Brain parenchymal water content increased by 2% to 3% by 3 days, corresponding to ~50 μL of fluid, indicating backflow of CSF from the ventricle into the parenchymal extracellular space. A multi-compartment model of hydrocephalus based on experimental data from wildtype mice accurately reproduced the greater severity of hydrocephalus in AQP4 null mice, and predicted a much reduced severity if AQP4 expression/function were increased. Our results indicate a significant role for AQP4-mediated transparenchymal CSF absorption in hydrocephalus and provide a rational basis for evaluation of AQP4 induction as a nonsurgical therapy for hydrocephalus.
Amiry-MoghaddamMXueRHaugFMNeelyJDBhardwajAAgrePAdamsMEFroehnerSCMoriSOttersenOP (2004) Alpha-syntrophin deletion removes the perivascular but not endothelial pool of aquaporin-4 at the blood-brain barrier and delays the develop-ment of brain edema in an experimental model of acute hyponatremia. Faseb J18:542–4.
2.
ArimaHYamamotoNSobueKUmenishiFTadaTKatsuyaHAsaiK (2003) Hyperosmolar mannitol simulates expression of aquaporins 4 and 9 through a p38 mitogen-activated protein kinase-dependent path-way in rat astrocytes. J Biol Chem278:44525–34.
3.
AzziGMCanadyAIHamSMitchellJA (1999) Kaolin-induced hydrocephalus in the hamster: temporal sequence of changes in intracranial pressure, ventriculomegaly and whole-brain specific gravity. Acta Neuropathol (Berl)98:245–50.
4.
BadautJBrunetJFGrollimundLHamouMFMagistrettiPJVillemureJGRegliL (2003) Aquaporin 1 and aquaporin 4 expression in human brain after subarachnoid hemorrhage and in peritumoral tissue. Acta Neurochir Suppl86:495–8.
5.
BadautJLasbennesFMagistrettiPJRegliL (2002) Aquaporins in brain: distribution, physiology, and pathophysiology. J Cereb Blood Flow Metab22:367–78.
6.
BlochOPapadopoulosMCManleyGTVerkmanAS (2005) Aquaporin-4 gene deletion in mice increases focal brain edema associated with staphylococcal brain abscess. J Neurochem95:254–62.
7.
BraunKPDijkhuizenRMDe GraafRANicolayKVandertopWPGooskensRHTullekenKA (1997) Cerebral ischemia and white matter edema in experimental hydrocephalus: a combined in vivo MRI and MRS study. Brain Res757:295–8.
8.
CherianSWhitelawAThoresenMLoveS (2004) The pathogenesis of neonatal post-hemorrhagic hydrocephalus. Brain Pathol14:305–11.
9.
CollinsP (1979) Experimental obstructive hydrocephalus in the rat: a scanning electron microscopic study. Neuropathol Appl Neurobiol5:457–68.
10.
CrewsLWyss-CorayTMasliahE (2004) Insights into the pathogenesis of hydrocephalus from transgenic and experimental animal models. Brain Pathol14:312–6.
11.
CserrHF (1971) Physiology of the choroid plexus. Physiol Rev51:273–311.
12.
CurlFDPollayM (1968) Transport of water and electrolytes between brain and ventricular fluid in the rabbit. Exp Neurol20:558–74.
13.
DeFeoDRMyersPFoltzELEverettBRamshawB (1979) Histological examination of kaolin-induced hydrocephalus. Its implications in the therapy of animals with experimentally induced hydrocephalus. J Neurosurg50:70–4.
14.
FishmanRA (1992) Cerebrospinal Fluid in Diseases of the Nervous System. Philadelphia: W.B. Saunders.
HiratsukaHTabataHTsuruokaSAoyagiMOkadaKInabaY (1982) Evaluation of periventricular hypodensity in experimental hydrocephalus by metrizamide CT ventriculography. J Neurosurg56:235–10.
19.
HochwaldGMSaharASadikARRansohoffJ (1969) Cerebrospinal fluid production and histological observations in animals with experimental obstructive hydrocephalus. Exp Neurol25:190–9.
20.
JohnstonITeoC (2000) Disorders of CSF hydrodynamics. Childs Nerv Syst16:776–99.
21.
LiV (2001) Methods and complications in surgical cerebrospinal fluid shunting. Neurosurg Clin N Am12:685–93vii.
22.
MaTYangBGillespieACarlsonEJEpsteinCJVerkmanAS (1997) Generation and phenotype of a transgenic knockout mouse lacking the mercurial-insensitive water channel aquaporin-4. J Clin Invest100:957–62.
23.
ManleyGTBinderDKPapadopoulosMCVerkmanAS (2004) New insights into water transport and edema in the central nervous system from phenotype analysis of aquaporin-4 null mice. Neuroscience129: 983–91.
24.
ManleyGTFujimuraMMaTNoshitaNFilizFBollenAWChanPVerkmanAS (2000) Aquaporin-4 deletion in mice reduces brain edema after acute water intoxication and ischemic stroke. Nat Med6:159–63.
25.
MarlinAEWaldAHochwaldGMMalhanC (1978) Kaolin-induced hydrocephalus impairs CSF secretion by the choroid plexus. Neurology28:945–9.
26.
MarmarouAHochwaldGNakamuraTTanakaKWeaverJDunbarJ (1994) Brain edema resolution by CSF pathways and brain vasculature in cats. Am J Physiol267:H514–520.
27.
MarmarouAPollWShulmanKBhagavanH (1978) A simple gravimetric technique for measurement of cerebral edema. J Neurosurg49:530–7.
28.
MatkowskyjKAMarreroJACarrollREDanilkovichAVGreenRMBenyaRV (1999) Azoxymethane-induced fulminant hepatic failure in C57BL/6J mice: characterization of a new animal model. Am J Physiol277:G455–462.
29.
MilhoratTHHammockMKFenstermacherJDLevinVA (1971) Cerebrospinal fluid production by the choroid plexus and brain. Science173:330–2.
30.
NakagawaYCervos-NavarroJArtigasJ (1984) A possible paracellular route for the resolution of hydrocephalic edema. Acta Neuropathol (Berl)64:122–8.
31.
NakagawaYCervos-NavarroJArtigasJ (1985) Tracer study on a paracellular route in experimental hydrocephalus. Acta Neuropathol (Berl)65:247–54.
32.
NakamuraSHochwaldGM (1983) Spinal fluid formation and glucose influx in normal and experimental hydrocephalic rats. Exp Neurol82:108–17.
33.
NelsonSRMantzMLMaxwellJA (1971) Use of specific gravity in the measurement of cerebral edema. J Appl Physiol30:268–71.
34.
NielsenSNagelhusEAAmiry-MoghaddamMBourqueCAgrePOttersenOP (1997) Specialized membrane domains for water transport in glial cells: high-resolution immunogold cytochemistry of aquaporin-4 in rat brain. J Neurosci17:171–80.
35.
OshioKWatanabeHSongYVerkmanASManleyGT (2005) Reduced cerebrospinal fluid production and intracranial pressure in mice lacking choroid plexus water channel Aquaporin-1. Faseb J19:76–8.
36.
PapadopoulosMCManleyGTKrishnaSVerkmanAS (2004) Aquaporin-4 facilitates reabsorption of 1537 excess fluid in vasogenic brain edema. Faseb J18: 1291–3.
37.
PapadopoulosMCVerkmanAS (2005) Aquaporin-4 gene disruption in mice reduces brain swelling and mortality in pneumococcal meningitis. J Biol Chem280: 13906–12.
38.
ReulenHJTsuyumuMTackAFenskeARPrioleauGR (1978) Clearance of edema fluid into cerebrospinal fluid. A mechanism for resolution of vasogenic brain edema. J Neurosurg48:754–64.
39.
SaadounSPapadopoulosMCDaviesDCKrishnaSBellBA (2002) Aquaporin-4 expression is increased in oedematous human brain tumours. J Neurol Neurosurg Psychiatry72:262–5.
40.
SaadounSPapadopoulosMCKrishnaS (2003) Water transport becomes uncoupled from K+ siphoning in brain contusion, bacterial meningitis, and brain tumours: immunohistochemical case review. J Clin Pathol56:972–5.
41.
SaharAHochwaldGMRansohoffJ (1969) Alternate pathway for cerebrospinal fluid absorption in animals with experimental obstructive hydrocephalus. Exp Neurol25:200–6.
42.
UlugAMTruongTNFilippiCGChunTLeeJKYangCSouweidaneMMZimmermanRD (2003) Diffusion imaging in obstructive hydrocephalus. AJNR Am J Neuroradiol24:1171–6.
43.
VizueteMLVeneroJLVargasCIlundainAAEchevarriaMMachadoACanoJ (1999) Differential upregulation of aquaporin-4 mRNA expression in reactive astrocytes after brain injury: potential role in brain edema. Neurobiol Dis6:245–58.
44.
WrbaENehringVBaethmannAReulenHJUhlE (1998) Resolution of experimental vasogenic brain edema at different intracranial pressures. Acta Neurochir Suppl71:313–5.
45.
YoshiokaHInagawaTTokudaYInokuchiF (2000) Chronic hydrocephalus in elderly patients following subarachnoid hemorrhage. Surg Neurol53:119–24; discussion 124–115.
