Author(s): Tetsumori Yamashima, Arumugam Mathivanan, Maryia Y. Dazortsava, Shota Sakai, Shota Kurimoto, Hong Zhu, Nozomi Funaki, Hanbai Liang, Françoise Hullin-Matsuda, Toshihide Kobayashi, Hiroyasu Akatsu, Hitoshi Takahashi and Yoshio Minabe
For the past decade evidence has gathered for the implication of lysosomes in the development of programmed cell death. Recent data advocate for dual roles of heat-shock protein 70.1 (Hsp70.1) not only as a molecular chaperone for damaged/aged proteins but also as a guardian of lysosomal integrity. Hsp70.1-mediated lysosomal stabilization is tightly regulated, but its disorder under extreme conditions results in lysosomal rupture to cause cell death. Comparing with the pathological hallmark ‘granulo-vacuolar degenerations’ in Alzheimer’s disease, the postischemic monkey neurons were carefully observed with microscope. Intriguingly, we found very similar change, and identified it as ‘lysosomal vesiculosis’ by electron microscopy. However, the exact molecular and structural impacts of the Hsp70.1 disorder upon the lysosomal membrane are hardly elucidated in the human brain because of the practical and ethical problems. Accordingly, using the monkey brain tissues after in-vivo and in-vitro oxidative stresses, we studied molecular modifications of Hsp70.1 and its counterpart bis(monoacylglycero) phosphate (BMP), because these molecules are closely related to the lysosomal membrane stability by regulating acid sphingomyelinase. It still remains unelucidated whether ischemia/reperfusion can alter composition or amount of BMP in the brain. Regardless of the brain regions studied, the normal monkey brain tissues showed calpain-mediated cleavage of Hsp70.1 after in-vitro oxidative stress. In the CA1 after in-vivo ischemia/reperfusion, we first found that docosahexaenoic and oleic acids in BMP showed a significant decrease on days 1 and 3, compared to non-ischemic controls. Since Hsp70.1- BMP binding is indispensable for activating acid sphingomyelinase and producing ceramide to stabilize lysosomal membrane, dysfunction of Hsp70.1 and BMP presumably causes storage of sphingomyelin and deficiency of ceramide at the lysosomal membrane, leading to its destabilization in the postischemic CA1 neurons. These data, combined together, suggest that lysosomal destabilization induced by calpain-mediated cleavage of carbonylated Hsp70.1 and the concomitant BMP breakdown causes ‘lysosomal vesiculosis’.