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Bacterially produced metabolites protect C. elegans neurons from degeneration

Author

Listed:
  • Arles Urrutia
  • Víctor A García-Angulo
  • Andrés Fuentes
  • Mauricio Caneo
  • Marcela Legüe
  • Sebastián Urquiza
  • Scarlett E Delgado
  • Juan Ugalde
  • Paula Burdisso
  • Andrea Calixto

Abstract

Caenorhabditis elegans and its cognate bacterial diet comprise a reliable, widespread model to study diet and microbiota effects on host physiology. Nonetheless, how diet influences the rate at which neurons die remains largely unknown. A number of models have been used in C. elegans as surrogates for neurodegeneration. One of these is a C. elegans strain expressing a neurotoxic allele of the mechanosensory abnormality protein 4 (MEC-4d) degenerin/epithelial Na+ (DEG/ENaC) channel, which causes the progressive degeneration of the touch receptor neurons (TRNs). Using this model, our study evaluated the effect of various dietary bacteria on neurodegeneration dynamics. Although degeneration of TRNs was steady and completed at adulthood in the strain routinely used for C. elegans maintenance (Escherichia coli OP50), it was significantly reduced in environmental and other laboratory bacterial strains. Strikingly, neuroprotection reached more than 40% in the E. coli HT115 strain. HT115 protection was long lasting well into old age of animals and was not restricted to the TRNs. Small amounts of HT115 on OP50 bacteria as well as UV-killed HT115 were still sufficient to produce neuroprotection. Early growth of worms in HT115 protected neurons from degeneration during later growth in OP50. HT115 diet promoted the nuclear translocation of DAF-16 (ortholog of the FOXO family of transcription factors), a phenomenon previously reported to underlie neuroprotection caused by down-regulation of the insulin receptor in this system. Moreover, a daf-16 loss-of-function mutation abolishes HT115-driven neuroprotection. Comparative genomics, transcriptomics, and metabolomics approaches pinpointed the neurotransmitter γ-aminobutyric acid (GABA) and lactate as metabolites differentially produced between E. coli HT115 and OP50. HT115 mutant lacking glutamate decarboxylase enzyme genes (gad), which catalyze the conversion of GABA from glutamate, lost the ability to produce GABA and also to stop neurodegeneration. Moreover, in situ GABA supplementation or heterologous expression of glutamate decarboxylase in E. coli OP50 conferred neuroprotective activity to this strain. Specific C. elegans GABA transporters and receptors were required for full HT115-mediated neuroprotection. Additionally, lactate supplementation also increased anterior ventral microtubule (AVM) neuron survival in OP50. Together, these results demonstrate that bacterially produced GABA and other metabolites exert an effect of neuroprotection in the host, highlighting the role of neuroactive compounds of the diet in nervous system homeostasis.How can diet influence neurodegeneration? This study shows that injured neurons in the nematode Caenorhabditis elegans are protected by a supply of the neurotransmitter GABA from their dietary bacteria.

Suggested Citation

  • Arles Urrutia & Víctor A García-Angulo & Andrés Fuentes & Mauricio Caneo & Marcela Legüe & Sebastián Urquiza & Scarlett E Delgado & Juan Ugalde & Paula Burdisso & Andrea Calixto, 2020. "Bacterially produced metabolites protect C. elegans neurons from degeneration," PLOS Biology, Public Library of Science, vol. 18(3), pages 1-31, March.
    • Handle: RePEc:plo:pbio00:3000638
    DOI: 10.1371/journal.pbio.3000638
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    as
    1. Cynthia J. Kenyon, 2010. "The genetics of ageing," Nature, Nature, vol. 464(7288), pages 504-512, March.
    2. Lynne Turnbull & Masanori Toyofuku & Amelia L. Hynen & Masaharu Kurosawa & Gabriella Pessi & Nicola K. Petty & Sarah R. Osvath & Gerardo Cárcamo-Oyarce & Erin S. Gloag & Raz Shimoni & Ulrich Omasits &, 2016. "Explosive cell lysis as a mechanism for the biogenesis of bacterial membrane vesicles and biofilms," Nature Communications, Nature, vol. 7(1), pages 1-13, September.
    3. Masanori Toyofuku & Gerardo Cárcamo-Oyarce & Tatsuya Yamamoto & Fabian Eisenstein & Chien-Chi Hsiao & Masaharu Kurosawa & Karl Gademann & Martin Pilhofer & Nobuhiko Nomura & Leo Eberl, 2017. "Prophage-triggered membrane vesicle formation through peptidoglycan damage in Bacillus subtilis," Nature Communications, Nature, vol. 8(1), pages 1-10, December.
    4. Kenya Honda & Dan R. Littman, 2016. "The microbiota in adaptive immune homeostasis and disease," Nature, Nature, vol. 535(7610), pages 75-84, July.
    5. Andrew G. Fraser & Ravi S. Kamath & Peder Zipperlen & Maruxa Martinez-Campos & Marc Sohrmann & Julie Ahringer, 2000. "Functional genomic analysis of C. elegans chromosome I by systematic RNA interference," Nature, Nature, vol. 408(6810), pages 325-330, November.
    6. Popi Syntichaki & Keli Xu & Monica Driscoll & Nektarios Tavernarakis, 2002. "Specific aspartyl and calpain proteases are required for neurodegeneration in C. elegans," Nature, Nature, vol. 419(6910), pages 939-944, October.
    7. Ravi S. Kamath & Andrew G. Fraser & Yan Dong & Gino Poulin & Richard Durbin & Monica Gotta & Alexander Kanapin & Nathalie Le Bot & Sergio Moreno & Marc Sohrmann & David P. Welchman & Peder Zipperlen &, 2003. "Systematic functional analysis of the Caenorhabditis elegans genome using RNAi," Nature, Nature, vol. 421(6920), pages 231-237, January.
    Full references (including those not matched with items on IDEAS)

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