Literature DB >> 31177094

The kynurenine pathway is essential for rhodoquinone biosynthesis in Caenorhabditis elegans.

Paloma M Roberts Buceta1, Laura Romanelli-Cedrez2, Shannon J Babcock1, Helen Xun1, Miranda L VonPaige1, Thomas W Higley1, Tyler D Schlatter1, Dakota C Davis1, Julia A Drexelius1, John C Culver1, Inés Carrera2, Jennifer N Shepherd3, Gustavo Salinas4.   

Abstract

A key metabolic adaptation of some species that face hypoxia as part of their life cycle involves an alternative electron transport chain in which rhodoquinone (RQ) is required for fumarate reduction and ATP production. RQ biosynthesis in bacteria and protists requires ubiquinone (Q) as a precursor. In contrast, Q is not a precursor for RQ biosynthesis in animals such as parasitic helminths, and most details of this pathway have remained elusive. Here, we used Caenorhabditis elegans as a model animal to elucidate key steps in RQ biosynthesis. Using RNAi and a series of C. elegans mutants, we found that arylamine metabolites from the kynurenine pathway are essential precursors for RQ biosynthesis de novo Deletion of kynu-1, encoding a kynureninase that converts l-kynurenine (KYN) to anthranilic acid (AA) and 3-hydroxykynurenine (3HKYN) to 3-hydroxyanthranilic acid (3HAA), completely abolished RQ biosynthesis but did not affect Q levels. Deletion of kmo-1, which encodes a kynurenine 3-monooxygenase that converts KYN to 3HKYN, drastically reduced RQ but not Q levels. Knockdown of the Q biosynthetic genes coq-5 and coq-6 affected both Q and RQ levels, indicating that both biosynthetic pathways share common enzymes. Our study reveals that two pathways for RQ biosynthesis have independently evolved. Unlike in bacteria, where amination is the last step in RQ biosynthesis, in worms the pathway begins with the arylamine precursor AA or 3HAA. Because RQ is absent in mammalian hosts of helminths, inhibition of RQ biosynthesis may have potential utility for targeting parasitic infections that cause important neglected tropical diseases.
© 2019 Roberts Buceta et al.

Entities:  

Keywords:  Caenorhabditis elegans (C. elegans); anthranilic acid; biosynthesis; electron transport; facultative anaerobe; helminths; hypoxia; kynureninase (kynu-1); rhodoquinone; ubiquinone

Mesh:

Substances:

Year:  2019        PMID: 31177094      PMCID: PMC6635453          DOI: 10.1074/jbc.AC119.009475

Source DB:  PubMed          Journal:  J Biol Chem        ISSN: 0021-9258            Impact factor:   5.157


  31 in total

Review 1.  Biochemical and evolutionary aspects of anaerobically functioning mitochondria.

Authors:  Jaap J van Hellemond; Anita van der Klei; Susanne W H van Weelden; Aloysius G M Tielens
Journal:  Philos Trans R Soc Lond B Biol Sci       Date:  2003-01-29       Impact factor: 6.237

2.  Altered quinone biosynthesis in the long-lived clk-1 mutants of Caenorhabditis elegans.

Authors:  H Miyadera; H Amino; A Hiraishi; H Taka; K Murayama; H Miyoshi; K Sakamoto; N Ishii; S Hekimi; K Kita
Journal:  J Biol Chem       Date:  2001-01-17       Impact factor: 5.157

3.  Free-living nematodes Caenorhabditis elegans possess in their mitochondria an additional rhodoquinone, an essential component of the eukaryotic fumarate reductase system.

Authors:  S Takamiya; T Matsui; H Taka; K Murayama; M Matsuda; T Aoki
Journal:  Arch Biochem Biophys       Date:  1999-11-15       Impact factor: 4.013

4.  Loss of the putative RNA-directed RNA polymerase RRF-3 makes C. elegans hypersensitive to RNAi.

Authors:  Femke Simmer; Marcel Tijsterman; Susan Parrish; Sandhya P Koushika; Michael L Nonet; Andrew Fire; Julie Ahringer; Ronald H A Plasterk
Journal:  Curr Biol       Date:  2002-08-06       Impact factor: 10.834

Review 5.  Helminth infections: the great neglected tropical diseases.

Authors:  Peter J Hotez; Paul J Brindley; Jeffrey M Bethony; Charles H King; Edward J Pearce; Julie Jacobson
Journal:  J Clin Invest       Date:  2008-04       Impact factor: 14.808

6.  Evidence that ubiquinone is a required intermediate for rhodoquinone biosynthesis in Rhodospirillum rubrum.

Authors:  Brian C Brajcich; Andrew L Iarocci; Lindsey A G Johnstone; Rory K Morgan; Zachary T Lonjers; Matthew J Hotchko; Jordan D Muhs; Amanda Kieffer; Bree J Reynolds; Sarah M Mandel; Beth N Marbois; Catherine F Clarke; Jennifer N Shepherd
Journal:  J Bacteriol       Date:  2009-11-20       Impact factor: 3.490

7.  Rhodoquinone reaction site of mitochondrial complex I, in parasitic helminth, Ascaris suum.

Authors:  Tetsuo Yamashita; Takara Ino; Hideto Miyoshi; Kimitoshi Sakamoto; Arihiro Osanai; Eiko Nakamaru-Ogiso; Kiyoshi Kita
Journal:  Biochim Biophys Acta       Date:  2004-02-15

8.  Change of subunit composition of mitochondrial complex II (succinate-ubiquinone reductase/quinol-fumarate reductase) in Ascaris suum during the migration in the experimental host.

Authors:  Fumiko Iwata; Noriko Shinjyo; Hisako Amino; Kimitoshi Sakamoto; M Khyrul Islam; Naotoshi Tsuji; Kiyoshi Kita
Journal:  Parasitol Int       Date:  2007-08-25       Impact factor: 2.230

9.  A dietary source of coenzyme Q is essential for growth of long-lived Caenorhabditis elegans clk-1 mutants.

Authors:  T Jonassen; P L Larsen; C F Clarke
Journal:  Proc Natl Acad Sci U S A       Date:  2001-01-02       Impact factor: 11.205

10.  Efficient gene transfer in C.elegans: extrachromosomal maintenance and integration of transforming sequences.

Authors:  C C Mello; J M Kramer; D Stinchcomb; V Ambros
Journal:  EMBO J       Date:  1991-12       Impact factor: 11.598
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1.  Differential regulation of degradation and immune pathways underlies adaptation of the ectosymbiotic nematode Laxus oneistus to oxic-anoxic interfaces.

Authors:  Lena König; Silvia Bulgheresi; Gabriela F Paredes; Tobias Viehboeck; Stephanie Markert; Michaela A Mausz; Yui Sato; Manuel Liebeke
Journal:  Sci Rep       Date:  2022-06-13       Impact factor: 4.996

2.  Rhodoquinone biosynthesis in C. elegans requires precursors generated by the kynurenine pathway.

Authors:  Samantha Del Borrello; Margot Lautens; Kathleen Dolan; June H Tan; Taylor Davie; Michael R Schertzberg; Mark A Spensley; Amy A Caudy; Andrew G Fraser
Journal:  Elife       Date:  2019-06-24       Impact factor: 8.140

3.  Identification of enzymes that have helminth-specific active sites and are required for Rhodoquinone-dependent metabolism as targets for new anthelmintics.

Authors:  Margot J Lautens; June H Tan; Xènia Serrat; Samantha Del Borrello; Michael R Schertzberg; Andrew G Fraser
Journal:  PLoS Negl Trop Dis       Date:  2021-11-29

4.  Identification and characterization of the kynurenine pathway in the pond snail Lymnaea stagnalis.

Authors:  Benatti Cristina; Rivi Veronica; Alboni Silvia; Grilli Andrea; Castellano Sara; Pani Luca; Brunello Nicoletta; Blom Johanna M C; Bicciato Silvio; Tascedda Fabio
Journal:  Sci Rep       Date:  2022-09-16       Impact factor: 4.996

5.  Alternative splicing of coq-2 controls the levels of rhodoquinone in animals.

Authors:  June H Tan; Margot Lautens; Laura Romanelli-Cedrez; Jianbin Wang; Michael R Schertzberg; Samantha R Reinl; Richard E Davis; Jennifer N Shepherd; Andrew G Fraser; Gustavo Salinas
Journal:  Elife       Date:  2020-08-03       Impact factor: 8.140

6.  Caenorhabditis elegans as a model for studies on quinolinic acid-induced NMDAR-dependent glutamatergic disorders.

Authors:  Tássia Limana da Silveira; Marina Lopes Machado; Fabiane Bicca Obetine Baptista; Débora Farina Gonçalves; Diane Duarte Hartmann; Larissa Marafiga Cordeiro; Aline Franzen da Silva; Cristiane Lenz Dalla Corte; Michael Aschner; Felix Alexandre Antunes Soares
Journal:  Brain Res Bull       Date:  2021-07-13       Impact factor: 3.715
  6 in total

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