Effects of metformin and other biguanides on oxidative phosphorylation in mitochondria

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Abstract

The biguanide metformin is widely prescribed for Type II diabetes and has anti-neoplastic activity in laboratory models. Despite evidence that inhibition of mitochondrial respiratory complex I by metformin is the primary cause of its cell-lineage-specific actions and therapeutic effects, the molecular interaction(s) between metformin and complex I remain uncharacterized. In the present paper, we describe the effects of five pharmacologically relevant biguanides on oxidative phosphorylation in mammalian mitochondria. We report that biguanides inhibit complex I by inhibiting ubiquinone reduction (but not competitively) and, independently, stimulate reactive oxygen species production by the complex I flavin. Biguanides also inhibit mitochondrial ATP synthase, and two of them inhibit only ATP hydrolysis, not synthesis. Thus we identify biguanides as a new class of complex I and ATP synthase inhibitor. By comparing biguanide effects on isolated complex I and cultured cells, we distinguish three anti-diabetic and potentially anti-neoplastic biguanides (metformin, buformin and phenformin) from two anti-malarial biguanides (cycloguanil and proguanil): the former are accumulated into mammalian mitochondria and affect oxidative phosphorylation, whereas the latter are excluded so act only on the parasite. Our mechanistic and pharmacokinetic insights are relevant to understanding and developing the role of biguanides in new and existing therapeutic applications, including cancer, diabetes and malaria.

Abstract

Metformin is a widely prescribed anti-diabetic, but its mode of action is disputed. It has been proposed to inhibit respiratory complex I. We show how metformin and related compounds affect both complex I and ATP synthase in mammalian mitochondria.

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Most cited references 64

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Dimethylbiguanide inhibits cell respiration via an indirect effect targeted on the respiratory chain complex I.

Daniel V Nogueira, L. M. Mir, N Avéret … (2000)

We report here a new mitochondrial regulation occurring only in intact cells. We have investigated the effects of dimethylbiguanide on isolated rat hepatocytes, permeabilized hepatocytes, and isolated liver mitochondria. Addition of dimethylbiguanide decreased oxygen consumption and mitochondrial membrane potential only in intact cells but not in permeabilized hepatocytes or isolated mitochondria. Permeabilized hepatocytes after dimethylbiguanide exposure and mitochondria isolated from dimethylbiguanide pretreated livers or animals were characterized by a significant inhibition of oxygen consumption with complex I substrates (glutamate and malate) but not with complex II (succinate) or complex IV (N,N,N',N'-tetramethyl-1, 4-phenylenediamine dihydrochloride (TMPD)/ascorbate) substrates. Studies using functionally isolated complex I obtained from mitochondria isolated from dimethylbiguanide-pretreated livers or rats further confirmed that dimethylbiguanide action was located on the respiratory chain complex I. The dimethylbiguanide effect was temperature-dependent, oxygen consumption decreasing by 50, 20, and 0% at 37, 25, and 15 degrees C, respectively. This effect was not affected by insulin-signaling pathway inhibitors, nitric oxide precursor or inhibitors, oxygen radical scavengers, ceramide synthesis inhibitors, or chelation of intra- or extracellular Ca(2+). Because it is established that dimethylbiguanide is not metabolized, these results suggest the existence of a new cell-signaling pathway targeted to the respiratory chain complex I with a persistent effect after cessation of the signaling process.

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Crystal structure of the entire respiratory complex I

Rozbeh Baradaran, John Berrisford, Gurdeep Minhas … (2013)

Complex I is the first and largest enzyme of the respiratory chain, playing a central role in cellular energy production by coupling electron transfer between NADH and ubiquinone to proton translocation. It is implicated in many common human neurodegenerative diseases. Here we report the first crystal structure of the entire, intact complex I (from T. thermophilus) at 3.3 Å resolution. The structure of the 536 kDa complex comprises 16 different subunits with 64 transmembrane helices and 9 Fe-S clusters. The core fold of subunit Nqo8 (NuoH/ND1) is, unexpectedly, similar to a half-channel of the antiporter-like subunits. Small subunits nearby form a linked second half-channel, thus completing the fourth proton translocation pathway, in addition to the channels in three antiporter-like subunits. The quinone-binding site is unusually long, narrow and enclosed. The quinone headgroup binds at the deep end of this chamber, near cluster N2. Strikingly, the chamber is linked to the fourth channel by a “funnel” of charged residues. The link continues over the entire membrane domain as a remarkable flexible central axis of charged and polar residues. It likely plays a leading role in the propagation of conformational changes, aided by coupling elements. The structure suggests that a unique, out-of-the-membrane quinone reaction chamber allows the redox energy to drive concerted long-range conformational changes in the four antiporter-like domains, resulting in translocation of four protons per cycle.

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Mitochondrial complex I.

Judy Hirst (2013)

Complex I (NADH:ubiquinone oxidoreductase) is crucial for respiration in many aerobic organisms. In mitochondria, it oxidizes NADH from the tricarboxylic acid cycle and β-oxidation, reduces ubiquinone, and transports protons across the inner membrane, contributing to the proton-motive force. It is also a major contributor to cellular production of reactive oxygen species. The redox reaction of complex I is catalyzed in the hydrophilic domain; it comprises NADH oxidation by a flavin mononucleotide, intramolecular electron transfer along a chain of iron-sulfur clusters, and ubiquinone reduction. Redox-coupled proton translocation in the membrane domain requires long-range energy transfer through the protein complex, and the molecular mechanisms that couple the redox and proton-transfer half-reactions are currently unknown. This review evaluates extant data on the mechanisms of energy transduction and superoxide production by complex I, discusses contemporary mechanistic models, and explores how mechanistic studies may contribute to understanding the roles of complex I dysfunctions in human diseases.

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Author and article information

Journal

Journal ID (nlm-ta): Biochem J

Journal ID (iso-abbrev): Biochem. J

Journal ID (pmc): bic

Journal ID (publisher-id): BJ

Title: Biochemical Journal

Publisher: Portland Press Ltd.

ISSN (Print): 0264-6021

ISSN (Electronic): 1470-8728

Publication date (Electronic preprint): 14 July 2014

Publication date (Electronic): 22 August 2014

Publication date (Print): 15 September 2014

Volume: 462

Issue: Pt 3

Pages: 475-487

Affiliations

*Medical Research Council Mitochondrial Biology Unit, Wellcome Trust/MRC Building, Hills Road, Cambridge, CB2 0XY, U.K.

†Department of Oncology, McGill University and Lady Davis Research Institute of the Jewish General Hospital, Montreal, Quebec, Canada, H3T 1E2

Author notes

¹To whom correspondence should be addressed (email jh@ 123456mrc-mbu.cam.ac.uk ).

Article

Publisher ID: BJ20140620

DOI: 10.1042/BJ20140620

PMC ID: 4148174

PubMed ID: 25017630

SO-VID: f6882368-1cbf-415b-bc85-01743d5da6a1

Copyright © © 2014 This is an Open Access article distributed under the terms of the Creative Commons Attribution Licence (CC-BY)(http://creativecommons.org/licenses/by/3.0/) which permits unrestricted use, distribution and reproduction in any medium, provided the original work is properly cited.

License:

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution and reproduction in any medium, provided the original work is properly cited.

History

Date received : 16 May 2014

Date revision received : 3 July 2014

Date accepted : 14 July 2014

Page count

Figures: 6, References: 75, Pages: 13

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