Your search keyword '"631/378/340"' showing total 2 results

1. Natural variants of human SARM1 cause both intrinsic and dominant loss-of-function influencing axon survival

Author

Mirlinda Ademi, Xiuna Yang, Michael P. Coleman, Jonathan Gilley, Coleman, Michael [0000-0002-9354-532X], and Apollo - University of Cambridge Repository

Subjects

631/378/340, Armadillo Domain Proteins, Neurons, Cytoskeletal Proteins, Multidisciplinary, 631/378/87, HEK293 Cells, 631/378/1934, article, Humans, NAD, Axons

Abstract

Funder: Pinsent Darwin Trust, Funder: Thompson Family Foundation Initiative, SARM1 is a central executioner of programmed axon death, and this role requires intrinsic NAD(P)ase or related enzyme activity. A complete absence of SARM1 robustly blocks axon degeneration in mice, but even a partial depletion confers meaningful protection. Since axon loss contributes substantially to the onset and progression of multiple neurodegenerative disorders, lower inherent SARM1 activity is expected to reduce disease susceptibility in some situations. We, therefore, investigated whether there are naturally occurring SARM1 alleles within the human population that encode SARM1 variants with loss-of-function. Out of the 18 natural SARM1 coding variants we selected as candidates, we found that 10 display loss-of-function in three complimentary assays: they fail to robustly deplete NAD in transfected HEK 293T cells; they lack constitutive and NMN-induced NADase activity; and they fail to promote axon degeneration in primary neuronal cultures. Two of these variants are also able to block axon degeneration in primary culture neurons in the presence of endogenous, wild-type SARM1, indicative of dominant loss-of-function. These results demonstrate that SARM1 loss-of-function variants occur naturally in the human population, and we propose that carriers of these alleles will have different degrees of reduced susceptibility to various neurological conditions.

Published

2022

2. Mechanisms of inhibition and activation of extrasynaptic ���� GABAA receptors

Author

Kasaragod, Vikram Babu, Mortensen, Martin, Hardwick, Steven, Wahid, Ayla, Dorovykh, Valentina, Chirgadze, Dima, Smart, Trevor G, and Miller, Paul

Subjects

631/378/340, 82/80, 13/1, 631/535/1258/1259, 9/74, 101/28, article, 631/378/2586, 13/106, 13/109, 82/83

Abstract

Type A GABA (��-aminobutyric acid) receptors represent a diverse population in the mammalian brain, forming pentamers from combinations of ��-, ��-, ��-, ��-, ��-, ��-, ��- and ��-subunits1. ����, ��4����, ��6���� and ��5���� receptors favour extrasynaptic localization, and mediate an essential persistent (tonic) inhibitory conductance in many regions of the mammalian brain1,2. Mutations of these receptors in humans are linked to epilepsy and insomnia3,4. Altered extrasynaptic receptor function is implicated in insomnia, stroke and Angelman and Fragile X syndromes1,5, and drugs targeting these receptors are used to treat postpartum depression6. Tonic GABAergic responses are moderated to avoid excessive suppression of neuronal communication, and can exhibit high sensitivity to Zn2+ blockade, in contrast to synapse-preferring ��1����, ��2���� and ��3���� receptor responses5,7-12. Here, to resolve these distinctive features, we determined structures of the predominantly extrasynaptic ���� GABAA receptor class. An inhibited state bound by both the lethal paralysing agent ��-cobratoxin13 and Zn2+ was used in comparisons with GABA-Zn2+ and GABA-bound structures. Zn2+ nullifies the GABA response by non-competitively plugging the extracellular end of the pore to block chloride conductance. In the absence of Zn2+, the GABA signalling response initially follows the canonical route until it reaches the pore. In contrast to synaptic GABAA receptors, expansion of the midway pore activation gate is limited and it remains closed, reflecting the intrinsic low efficacy that characterizes the extrasynaptic receptor. Overall, this study explains distinct traits adopted by ���� receptors that adapt them to a role in tonic signalling., This work was supported by a Department of Pharmacology new lab start-up fund, the University of Cambridge Isaac Newton & Wellcome Trust Institutional Strategic Support Fund, and Academy of Medical Sciences Springboard Award (SBF004\1074). Electrophysiology work in the laboratory of Professor Trevor Smart was funded by an MRC programme grant (MR/T002581/1) and Wellcome Trust Collaborative Award (217199/Z/19/Z). The cryo-EM facility receives funding from the Wellcome Trust (206171/Z/17/Z; 202905/Z/16/Z) and University of Cambridge.

Published

2022