Differential ubiquitination as an effective strategy employed by Blood-Brain Barrier for prevention of bacterial transcytosis [article]

Smita Bhutda, Sourav Ghosh, Akash Raj Sinha, Shweta Santra, Aishwarya Hiray, Anirban Banerjee
2021 bioRxiv   pre-print
The protective mechanisms of blood-brain barrier (BBB) prohibiting entry of blood borne pathogens and toxins into the central nervous system (CNS) is critical for maintenance of homeostasis in the brain. These include various forms of intracellular defence mechanisms which are vital to block bacterial transcytosis, the major route of trafficking adopted by meningeal pathogens to transit into the CNS. However, mechanistic details of the defence mechanisms and their exploitation to prevent
more » ... al meningitis remain unexplored. In this study, we established that brain endothelium driven ubiquitination acts as a major intracellular defence mechanism for clearance of S. pneumoniae, a critical neurotropic pathogen, during its transit through BBB. Our findings suggest that brain endothelium employs differential ubiquitination with either K48 or K63-Ub chain topologies as an effective strategy to target SPN towards diverse killing pathways. While K63-Ub decoration triggers autophagic killing, K48-Ub directs pneumococcus exclusively to the proteasome machinery. Indeed, time lapse fluorescence imaging involving proteasomal marker LMP2 revealed that in BBB, majority of the ubiquitinated SPN were cleared by proteasome. Fittingly, pharmacological inhibition of proteasome and autophagy pathway not only led to exclusive accumulation of K48-Ub and K63-Ub marked SPN, respectively, but also triggered significant increment in intracellular SPN burden. Moreover, genetic impairment of formation of either K48 or K63-Ub chain topology demonstrated that though both chain types play important roles in disposal of intracellular SPN, K48-Ub chains and subsequent proteasomal degradation has more pronounced contribution towards ubiquitinated SPN killing in brain endothelium. Collectively, these observations for the first time illustrated a pivotal role of differential ubiquitination in orchestrating a symphony of intracellular defence mechanisms blocking pathogen trafficking into the brain which could be further exploited to prevent bacterial CNS infections.
doi:10.1101/2021.06.20.449199 fatcat:2x2rddux6vc7rpi36lk6vtqfzq