Impact of 4-hydroxy-2-nonenal in Arabidopsis mitochondria

Winger, Alison Marie

January 2007

[Truncated abstract] A range of biotic and abiotic stresses increase levels of reactive oxygen species (ROS) in plants due to perturbations of chloroplast and mitochondrial metabolism and the generation of ROS in defence responses. The polyunsaturated fatty acids of membrane lipids are susceptible to ROS induced peroxidation yielding various aldehydes, alkenals and hydroxyalkenals including the cytotoxic compound 4-hydroxy- 2-nonenal (HNE). HNE has the potential to cause substantial oxidative damage in cells via its reactivity with sulfhydryl groups of cysteine (Cys) and lipoic acid, the imidazole group of histidine (His) and the ?-amino group of lysine (Lys) protein residues. Analysis of the components of the plant respiratory electron transport chain to HNE revealed a particular susceptibility to inhibition of activity of the alternative oxidase (Aox). Incubation with HNE prevented dimerisation of Aox protein, suggesting that one site of modification was the conserved cysteine residue involved in dimerisation and activation of this enzyme (Cys1). However, a naturally occurring isoform of Aox lacking Cys1 and unable to dimerise, LeAox1b from tomato, was equally sensitive to HNE inhibition, showing that other amino acid residues in Aox also interact with HNE and are likely responsible for inactivation of the enzyme. ... The broader impact of HNE on the whole Arabidopsis mitochondrial proteome was examined by use of various 2-dimensional gel separation techniques coupled with use of HNE-adduct antibodies. 32 proteins involved in a number of mitochondrial functions were found to be susceptible to modification by HNE, including components of the electron transport chain, the TCA cycle, as well as proteins involved amino acid metabolism and stress-responses. Implications of modification of these proteins by HNE are discussed. As HNE is produced in vivo during oxidative stress, the profile of mitochondrial targets of HNE was examined from Arabidopsis cell cultures exposed to various oxidative stress inducers. Menadione and hydrogen peroxide induced oxidative stress throughout the cell, while antimycin A initiated a mitochondrial targeted stress. A differential profile of mitochondrial proteins was observed to be modified by HNE in the various treatments. These results also showed that induction of stress within a whole cell can impact lipid peroxidation within the mitochondria. Overall, this work showed the presence and production of HNE in plant cells, and that HNE, both exogenous and endogenous, has the ability to modify a specific subset of mitochondrial proteins. In several cases this HNE modification was shown to have functional or structural consequences.

Plant cellular control mechanisms

Plant defenses

Oxidation, Physiological

Arabidopsis -- Respiration

Plant mitochondria

Plants -- Respiration

Arabidopsis

Mitochondria

The alternative oxidase gene family in arabidopsis : insights from a transcriptomic study

Clifton, Rachel

January 2006

[Truncated abstract] Mitochondria play an essential role in diverse metabolic pathways in plants. Their primary roles are the oxidation of organic acids via the tricarboxylic acid cycle and the synthesis of ATP coupled to the transfer of electrons from reduced NAD+ to oxygen via the electron transport chain. Plant mitochondria also contain nonphosphorylating bypasses of the respiratory chain, catalysed by the alternative oxidase (AOX), type II NAD(P)H dehydrogenases (NDHs) and uncoupling proteins (UCPs). Each of these components bypasses energy conservation by either circumventing the formation or utilization of the electrochemical proton gradient, and each is encoded by a small gene family in Arabidopsis. It is proposed that the alterative pathways are likely to be involved in balancing cellular redox and energy status and in minimizing the production of ROS generated by over-reduction of basal respiratory chain components. Furthermore the alternative respiratory pathways are thought to play a role in plant responses to stress. In this study a transcriptomic approach was taken to investigate the role of the alternative respiratory pathways in Arabidopsis, with a focus on elucidating the role and regulation of the AOX gene family. Analysis of the expression of the five AOX genes in Arabidopsis over development and in a range of tissues revealed a unique spatiotemporal expression pattern for each gene. Expression profiling using quantitative RT-PCR, MPSS and microarrays detected an abundance of the AOX1a transcript throughout the plant and over development. The expression patterns of other AOX genes provide insight into their putative roles, AOX1b was expressed predominantly in the flower, AOX1d was particularly abundant in senescing leaves and AOX2 expression was only observed in the seed.

Plants -- Respiration

Plant mitochondria

Arabidopsis -- Respiration

Arabidopsis -- Genetics

Arabidopsis -- Effect of stress on

Gene expression

Alternative oxidase

Mitochondria

Alternative respiratory pathway