Source: Okayama University (JAPAN), Public Relations and Information Strategy
For immediate release: 22 May 2017
Okayama University research: Antibodies prolong seizure latency in epileptic mice
(Okayama, 22 May) Researchers at Okayama University describe in Scientifc Reports the effect of a particular type of monoclonal antibody on epilepsy in mice. Findings include the prevention of disrupted brain–blood barrier function, the inhibition of inflammations, and prolonged epilepsy seizure latency.
Epilepsy is a category of neurological disorders characterized by recurrent seizures. The causes of epilepsy are largely unknown, but it has been established that high mobility group box 1 (HMBG1) protein expression may be linked to epilepsy-related inflammations. A team of researchers led by Masahiro Nishibori from Okayama University has now investigated the HMBG1–epilepsy connection in detail, and found that administering anti-HMBG1 monoclonal antibodies (mAb) prolongs the latency of epileptic seizures — an important finding in the on-going quest for understanding and curing epilepsy.
Since an increased production of HMBG1 has been observed earlier in human and rat epileptic brain, Nishibori and colleagues tested the hypothesis that HMBG1 plays a role in epileptogenesis and, specifically, in disruptions of the functioning of the blood–brain barrier. The latter is a semipermeable membrane in the brain separating blood from other, extracellular fluid.
The researchers did experiments with mice treated with pilocarpine, a model commonly used for the study of epilepsy. Pilocarpine is a molecule normally used as a medicine (for e.g. relaxing increased pressure in the eye), but when injected systematically with a high dose in mice, it could initiate seizure and then cause status epilepticus. Nishibori and colleagues confirmed this disruption: pilocarpine-injected mice undergo a translocation of HMGB1 from the cerebrum (the principal part of the brain located at the front of the skull) to the blood, affecting the permeability of blood-brain barrier. They also proved that administering of exogenous HMGB1 could exacerbate the blood-brain barrier disruption.
The scientists then looked at the effect of intravenously introducing anti-HMGB1 mAb to the pilocarpine mouse model. They found that such treatment leads to the inhibition of HMGB1 translocation and the protection of blood–brain barrier permeability. This in turn resulted in prolonged seizure latency. Nishibori and colleagues therefore conclude that “anti-HMGB1 therapy may provide a novel strategy for controlling the epileptogenesis”.
Background
Pilocarpine
Pilocarpine is an organic molecule often used as a medicine, e.g. for treating dry mouth (xerostomia) or decreased the pressure of the fluid in the eye (intraocular pressure). When injected in rodents, such as rats and mice, it could causes status epilepticus. Pilocarpine-injected mice are therefore good models for studying the physiology and treatment of epilepsy. Specifically, pilocarpine-induced epilepsy has been reported to be a very good model for human temporal lobe epilepsy, a form of epilepsy affecting at least 20% of patients suffering from recurrent seizures.
HMGB1 and antibodies
High mobility group box 1 (HMGB1), sometimes referred to as amphoterin, is a protein produced by almost all kinds of cells. Excessive release of HMGB1 is believed to be associated with brain injury and dysfunction. Masahiro Nishibori from Okayama University and colleagues investigated how exactly the protein is involved in the development of epileptogenesis — what role it plays in the disrupted functioning of the brain–blood barrier and the induction of inflammatory processes.
Realizing the importance of HMGB1 in the context of epilepsy, the researchers tried, with success, to inhibit its effects by intravenous HMGB1 antibodies. Antibodies, also known as immunoglobulins, are molecules that are able to identify and ‘capture’ molecules considered harmful (e.g.HMGB1 molecules).
Reference
Li Fu, Keyue Liu, Hidenori Wake, Kiyoshi Teshigawara, Tadashi Yoshino, Hideo Takahashi, Shuji Mori & Masahiro Nishibori. Therapeutic effects of anti-HMGB1 monoclonal antibody on pilocarpine-induced status epilepticus in mice. Scientific Reports, April 26, 2017.
DOI:10.1038/s41598-017-01325-y
https://www.nature.com/articles/s41598-017-01325-y
Reference (Okayama University e-Bulletin & OU-MRU) : Professor Nishibori’s team
e-Bulletin Vol.2:The invention of an antibody drug for the treatment of brain infarction
OU-MRU Vol.27:Keeping cells in shape to fight sepsis
Correspondence to
Professor Masahiro Nishibori, M.D., Ph.D.
Department of Pharmacology, Graduate School of
Medicine, Dentistry and Pharmaceutical Sciences,
Okayama University, Shikata-cho 2-5-1,
Okayama city, Okayama 700-8558, Japan
E-mail: mbori(a)md.okayama-u.ac.jp
For inquiries, please contact us by replacing (a) with the @ mark.
//www.okayama-u.ac.jp/user/pharmaco/en/index.html
Further information
Okayama University
1-1-1 Tsushima-naka , Kita-ku , Okayama 700-8530, Japan
Public Relations and Information Strategy
E-mail: www-adm (a) adm.okayama-u.ac.jp
For inquiries, please contact us by replacing (a) with the @ mark.
Website: //www.okayama-u.ac.jp/index_e.html
Okayama Univ. e-Bulletin: //www.okayama-u.ac.jp/user/kouhou/ebulletin/
Okayama Univ. e-Bulletin (PDF Issues): //www.okayama-u.ac.jp/user/kouhou/ebulletin/
About Okayama University (You Tube): https://www.youtube.com/watch?v=iDL1coqPRYIOkayama University Image Movie (You Tube): https://www.youtube.com/watch?v=KU3hOIXS5kk
Okayama University Medical Research Updates (OU-MRU)
Vol.1:Innovative non-invasive ‘liquid biopsy’ method to capture circulating tumor cells from blood samples for genetic testingVol.2:Ensuring a cool recovery from cardiac arrestVol.3:Organ regeneration research leaps forwardVol.4:Cardiac mechanosensitive integratorVol.5:Cell injections get to the heart of congenital defectsVol.6:Fourth key molecule identified in bone developmentVol.7:Anticancer virus solution provides an alternative to surgeryVol.8:Light-responsive dye stimulates sight in genetically blind patientsVol.9:Diabetes drug helps towards immunity against cancerVol.10:Enzyme-inhibitors treat drug-resistant epilepsyVol.11:Compound-protein combination shows promise for arthritis treatmentVol.12:Molecular features of the circadian clock system in fruit fliesVol.13:Peptide directs artificial tissue growthVol.14:Simplified boron compound may treat brain tumoursVol.15:Metamaterial absorbers for infrared inspection technologiesVol.16:Epigenetics research traces how crickets restore lost limbsVol.17:Cell research shows pathway for suppressing hepatitis B virusVol.18:Therapeutic protein targets liver diseaseVol.19:Study links signalling protein to osteoarthritisVol.20:Lack of enzyme promotes fatty liver disease in thin patientsVol.21:Combined gene transduction and light therapy targets gastric cancerVol.22:Medical supportive device for hemodialysis catheter punctureVol.23:Development of low cost oral inactivated vaccines for dysenteryVol.24:Sticky molecules to tackle obesity and diabetesVol.25:Self-administered aroma foot massage may reduce symptoms of anxietyVol.26:Protein for preventing heart failureVol.27:Keeping cells in shape to fight sepsisVol.28:Viral-based therapy for bone cancerVol.29:Photoreactive compound allows protein synthesis control with lightVol.30:Cancer stem cells’ role in tumor growth revealedVol.31:Prevention of RNA virus replicationVol.32:Enzyme target for slowing bladder cancer invasionVol.33:Attacking tumors from the insideVol.34:Novel mouse model for studying pancreatic cancerVol.35:Potential cause of Lafora disease revealedVol.36:Overloading of protein localization triggers cellular defectsVol.37:Protein dosage compensation mechanism unravelledVol.38:Bioengineered tooth restoration in a large mammalVol.39:Successful test of retinal prosthesis implanted in rats