Abstract
Maintenance of redox balance is essential for normal cellular functions. Any perturbation in this balance due to increased reactive oxygen species (ROS) leads to oxidative stress and may lead to cell dysfunction/damage/death. Mitochondria are responsible for the majority of cellular ROS production secondary to electron leakage as a consequence of respiration. Furthermore, electron leakage by the cytochrome P450 enzymes may render steroidogenic tissues acutely vulnerable to redox imbalance. The adrenal cortex, in particular, is well supplied with both enzymatic (glutathione peroxidases and peroxiredoxins) and non-enzymatic (vitamins A, C and E) antioxidants to cope with this increased production of ROS due to steroidogenesis. Nonetheless oxidative stress is implicated in several potentially lethal adrenal disorders including X-linked adrenoleukodystrophy, triple A syndrome and most recently familial glucocorticoid deficiency. The finding of mutations in antioxidant defence genes in the latter two conditions highlights how disturbances in redox homeostasis may have an effect on adrenal steroidogenesis.
Introduction
Reactive oxygen species (ROS) are derived from O2 and comprise molecules with varying oxidant properties. At low concentrations, ROS modulate many cellular processes through redox-dependent signalling, including proliferation, differentiation, apoptosis, immune regulation and cellular adaptation to stress (Ray et al. 2012, Sena & Chandel 2012). A critical balance in redox status needs to be maintained and this is achieved by numerous interacting antioxidant pathways. Oxidative stress occurs when this balance is disturbed. ROS can then have deleterious effects on proteins, lipids and nucleic acids, ultimately leading to cell damage and death. Oxidative stress is implicated in a plethora of conditions including neurodegenerative disorders, diabetes mellitus, cardiovascular disease and ageing. Antioxidant defence mechanisms are complex and can be specific to cell type and furthermore to sub-cellular compartment. In comparison to many other tissues, including those with high metabolic demand such as the liver and brain, the adrenal cortex has high levels of several antioxidants, both enzymatic and non-enzymatic. This investment is necessary given the high turnover of lipid within the mitochondria and ROS production during steroidogenesis. Disturbances in redox homeostasis within the adrenocortical environment may therefore have an effect on steroidogenesis, as evidenced by several disorders of adrenal insufficiency, including most recently familial glucocorticoid deficiency (FGD).
ROS generation in mitochondria
Mitochondria are responsible for the majority of cellular ROS production secondary to electron leakage as a consequence of respiration. During respiration, electrons are transferred across to molecular oxygen to generate water via the four complexes of the electron transport chain. The electron–proton gradient established during this process is used to generate energy in the form of ATP. As a result of electron leakage at complex I (NADH dehydrogenase) and complex III (cytochrome c reductase), a small percentage of the molecular oxygen is converted to superoxide anions (O2·−) (Fig. 1). These superoxide anions can be protonated to form strongly oxidant hydroxyl radicals (·OH) which can cause oxidative modification of proteins and membrane lipids. ROS can also modify key components of the electron transport chain thereby further exacerbating electron leakage and superoxide production. Dismutation, catalysed by the superoxide dismutases (SODs), reduces superoxide ions to hydrogen peroxide (H2O2). H2O2 can also contribute to oxidative stress by reacting with free metals to form OH. In addition, in comparison to O2·−, which tends to remain at the site of production, H2O2 readily traverses membranes into other subcellular compartments where it may affect signalling pathways.
Several compartment-specific antioxidant mechanisms are in place to target superoxide production. Cytoplasmic copper/zinc-dependent SOD1 (CuZnSOD), mutations of which are associated with the neurodegenerative disorder, amyotrophic lateral sclerosis, and mitochondrial matrix manganese-dependent SOD2 (MnSOD) catalyse the conversion of superoxide anions into H2O2 (Fig. 1). H2O2 has preferential reactivity towards (seleno) cysteine (Cys) residues in target proteins, and is detoxified by members of the glutathione peroxidase (GPX) and peroxiredoxin (PRDX) families, discussed later in this review. The relative contribution of each of these enzymes may be tissue- and compartment-specific and determined by the source of H2O2 and the expression levels of each individual enzyme.
In addition to electron leakage during respiration, other sources of superoxide production within the mitochondria include reactions catalysed by xanthine/xanthine oxidase, uncoupled nitric oxide synthases, NADPH-dependent oxidases (NOXs) and, most pertinent to the adrenal cortex, cytochrome P450 isoforms. The P450 enzymes are involved in the biosynthesis of cholesterol-derived steroidal compounds (Miller 2005). In steroidogenic tissues, the levels of expression of P450 enzymes are approximately ten times higher than those of the other electron transport chain proteins and electron leakage in the P450 system can also contribute to ROS production (Hanukoglu & Hanukoglu 1986, Hanukoglu 2006). P450 groups are represented by microsomal cytochrome P450s present in the endoplasmic reticulum, and mitochondrial cytochrome P450s present in the inner mitochondrial membrane. Type 1 P450 isoforms present in the mitochondria include P450scc (side-chain cleavage; CYP11A1), which catalyses the conversion of cholesterol to pregnenolone, and P450c11β (CYP11B1) responsible for the β-hydroxylation of 11-deoxycortisol to cortisol (Fig. 2). The reactions catalysed by these P450 enzymes require NADPH as a reducing agent, in addition to molecular oxygen. NADPH donates two electrons which are transferred to P450 enzymes via two electron transfer proteins, ferredoxin reductase (adrenodoxin reductase) and then ferredoxin (adrenodoxin) (Ziegler et al. 1999, Grinberg et al. 2000). Ferredoxin reductase is a flavin adenine dinucleotide, containing flavoenzyme and is able to accept both electrons from NADPH. These are then passed one at a time to ferredoxin and finally to the P450 enzymes for hydroxylation of substrates, the order of electron transfer is as follows (Hanukoglu 2006):
NADPH→ferrodoxin reductase→ferrodoxin→P450
In a tightly coupled system, all electrons from NADPH are used in substrate hydroxylation; however, electron transfer within the P450 system can be relatively ‘uncoupled’ or ‘leaky’, with the rate of electron leakage varying depending on P450 subtype (Hanukoglu 2006). Up to 40% of total electron flow in the P450c11β system, catalysing the final step in cortisol synthesis, is directed to ROS formation in comparison to 15% in the P450scc system (Rapoport et al. 1995). Thus steroidogenesis, particularly glucocorticoid production, contributes significantly to cellular ROS production (Fig. 2). Type 2 microsomal P450 isoforms, catalysing all the other steps in steroidogenesis, are present in the endoplasmic reticulum and are reliant on P450 oxidoreductase and NADPH for reduction (Miller 2005).
Adrenal cortex antioxidant defence mechanisms
The adrenal cortex is particularly equipped to handle the increased risk of oxidative stress. Several antioxidants, both enzymatic and non-enzymatic, are highly expressed in comparison to other tissues. Ascorbic acid (vitamin C), which recycles α-tocopherol (vitamin A) radicals, is present at the highest levels in the adrenal cortex (Hornig 1975), indeed endogenous ascorbic acid was first isolated from adrenal tissue (Svirbely & Szent-Gyorgyi 1932). Depletion of ascorbic acid secondary to vitamin A deficiency in rats leads to adrenocortical degeneration (Gruber et al. 1976). Other non-enzymatic antioxidants present at high levels within the adrenal cortex include vitamins A and E (Azhar et al. 1995).
As previously described, O2·− radicals are converted by SODs to H2O2. Mitochondrial H2O2 is further reduced by two major thiol antioxidant systems dependent on reduced glutathione (GSH) and the small protein thioredoxin 2 (TXN2), each system has several associated proteins (Fig. 1). Reduced GSH and components of the TXN2 system are seen in abundance in the adrenal cortex (Azhar et al. 1995, Watabe et al. 1999). Both TXN2 and GSH systems are dependent on the reducing power of NADPH. NADPH supply within the mitochondria is maintained by the proton pump nicotinamide nucleotide transhydrogenase (NNT). Mutations in NNT have recently been associated with FGD, discussed later in this review (Meimaridou et al. 2012). Mitochondrial NADPH stores can also be restored by mitochondrial dehydrogenases including malate dehydrogenase and isocitrate dehydrogenase.
GSH contributes significantly to maintenance of a reduced cellular environment. Under physiological conditions, a high reduced (GSH):oxidised glutathione (glutathione disulphide (GSSG)) ratio is maintained. GSH, synthesised in the cytosol, is transported into the mitochondria by dicarboxylate and 2-oxoglutarate carriers (Palmieri 1994). Within the mitochondria, GSH is regenerated from GSSG by the enzyme GSH reductase with NADPH as a cofactor. GSH acts as an electron donor for the GPXs, members of the selenoprotein family, which incorporate selenocysteine in their enzymatic catalytic site. These selenocysteine residues are highly redox-reactive and GPXs play an important role in the reduction of H2O2 to water. Selenium content of the adrenal is high and selenium is preferentially retained in this organ during selenium deficiency (Behne & Hofer-Bosse 1984). Indeed, selenium deficiency results in a significant depletion of GPX activity and a reduction in steroidogenesis in an adrenal cell line (Chanoine et al. 2001). Eight GPX isoforms have been identified in humans, GPX1 being the major isoform in most tissues, present primarily in the cytosol but also in small amounts in the mitochondria. Our unpublished data shows especially high expression in the adrenal cortex. In the testes and spermatozoa, the mitochondrial isoform of Gpx4 is the most prevalent form, with its depletion causing male infertility in mice (Imai et al. 2009).
Mammalian PRDXs also catalyse the reduction of H2O2 and lipid peroxides, albeit less efficiently than the GPXs. They comprise a family of six members, most of which (PRDX1–5) use TXN as an electron donor. PRDX3 and PRDX5 are present within the mitochondria; PRDX3 is mitochondria-specific and is seen in abundance particularly within the adrenal cortex, with a significant role in H2O2 detoxification within the mitochondrial matrix. It is estimated that PRDX3 is the catalyst for up to 90% of H2O2 generated within the matrix (Cox et al. 2010). During H2O2 elimination, two reduced PRDX3 subunits are converted to an oxidised disulphide-linked dimer that is reduced again by the mitochondrial TXN2 system (Zhang et al. 2007; Figs 1 and 3). TXN2 in turn is maintained in reduced form by the mitochondrial selenoprotein, thioredoxin reductase 2 (Fig. 1). In parallel, GSH can work together with glutaredoxin 2 in the mitochondria to also reduce PRDXs (Hanschmann et al. 2010) (Fig. 1).
The catalytic Cys in the mammalian 2-Cys PRDX enzymes (PRDX1–4) can undergo hyperoxidation to Cys sulfinic acid (Cys-SO2−), inactivating its peroxidase function (Woo et al. 2003). This inactive sulfinic form can be reduced back to the active form by sulfiredoxin, also seen most abundantly within the adrenal gland (Kil et al. 2012; Fig. 3). The only PRDX to be seen in sulfinic form within the adrenal cortex is PRDX3 and this inactivation of PRDX3 has recently been demonstrated to trigger a series of events within the adrenocortical environment (Kil et al. 2012). In both the murine and bovine models, adrenocorticotropic hormone (ACTH) stimulation increases inactivated sulfinic PRDX3, an effect that is prevented by treatment with metyrapone, a P450c11β (CYP11B1) inhibitor. This indicates that H2O2 produced in this final step of cortisol synthesis is mainly responsible for this hyperoxidation of PRDX3. Inactivation of PRDX3 results in accumulation of H2O2 which can diffuse into the cytosol, activating p38 MAPK signalling pathways with subsequent suppression of STAR protein synthesis and inhibition of steroidogenesis (Kil et al. 2012). It has been proposed that this mechanism of redox signalling exerts physiological control over steroidogenesis at the level of the adrenal gland, in addition to the well-characterised negative feedback exerted by cortisol on the hypothalamic–pituitary–adrenal (HPA) axis.
Oxidative stress and steroidogenesis
Steroidogenesis significantly contributes to mitochondrial ROS production (Fig. 2) and in turn oxidative stress can impede steroidogenesis. STAR protein is essential for the transport of cholesterol across the mitochondrial membrane and is the first and rate-limiting step of steroidogenesis (Fig. 2). STAR is synthesised as a 37 kDa protein which is cleaved to a 30 kDa form in the mitochondria. The precise mechanism of cholesterol transfer across the mitochondrial membrane remains unclear. STAR is proposed to act in conjunction with a multi-component complex on the outer mitochondrial membrane. This complex includes the translocator protein (TSPO), voltage-dependent anion channel 1, TSPO-associated protein 7 (PAP7, ABCD3) and protein kinase A regulatory subunit 1α (PKAR1A) (Papadopoulos & Miller 2012). STAR mutations in humans have a clear effect on steroidogenesis with a phenotype ranging from severe lipoid congenital adrenal hyperplasia (LCAH), involving both adrenal and gonadal dysfunction to milder atypical or non-classic forms of LCAH which can resemble FGD (Baker et al. 2006, Metherell et al. 2009, Miller 2011). Mutations in other members of this outer mitochondrial membrane complex have, as yet, not been associated with human disease.
There is evidence that STAR is sensitive to both physiological and pathophysiological levels of ROS. Studies in Leydig cells, using H2O2 and agents such as perfluorododecanoic acid, demonstrate a clear reduction in the protein expression of the intramitochondrial (30 kDa) form of STAR, in response to ROS (Diemer et al. 2003, Shi et al. 2010). There is no clear consensus as to whether ROS also have an effect at a transcriptional level as current data are inconsistent. Evidence of an effect on other key components of the steroidogenic pathway such as 3β-hydroxysteroid dehydrogenase and P450c11β are also documented (Zhao et al. 2012, Prasad et al. 2013). P450c11 activity in cultured bovine adrenal cells and foetal human adrenocortical cells decreases rapidly as a result of oxidative damage and this inactivation may confer protection given the propensity of the P450c11β system to produce superoxide anions (Hornsby 1980). Recently, an additional mechanism by which steroidogenesis may be compromised by oxidative stress has been proposed in the Leydig cell model. STAR-mediated trafficking of redox-active cholesterol hydroperoxides results in mitochondrial toxicity, rendering steroidogenic cells susceptible to further oxidative insult (Korytowski et al. 2013).
Oxidative stress and adrenal insufficiency in humans
Oxidative stress is implicated in several conditions characterised by primary adrenal failure including triple A syndrome, X-linked adrenoleukodystrophy (ALD) and most recently FGD. Despite ubiquitous expression of the proteins involved, in all three conditions defects in antioxidant defence specifically affect the adrenal. Mechanisms involving mitochondrial and peroxisomal dysfunction in addition to defective nucleocytoplasmic transport of DNA repair proteins and antioxidants demonstrate how disturbances in redox homeostasis in several subcellular compartments can have an effect on steroidogenesis.
FGD and NNT deficiency
FGD is characterised by ACTH resistance and glucocorticoid deficiency, which may prove fatal if appropriate treatment with corticosteroids is not instigated. The majority of cases are caused by defects in ACTH signalling within the adrenal, namely mutations in the ACTH receptor, melanocortin 2 receptor (MC2R), and its accessory protein MRAP (melanocortin receptor accessory protein) (Clark et al. 1993, Metherell et al. 2005, Meimaridou et al. 2013). Novel mechanisms have recently been described in FGD, involving replicative and oxidative stresses (Hughes et al. 2012, Meimaridou et al. 2012). These include mutations in minichromosome maintenance protein 4 (MCM4), a DNA replicase and NNT, encoding NNT, a proton pump located in the inner mitochondrial membrane (Hughes et al. 2012, Meimaridou et al. 2012). NNT uses energy from the mitochondrial proton gradient to regenerate NADPH from NADP+, using NADH produced in the tricarboxylic acid cycle. NNT couples the production of NADPH to the rate of mitochondrial metabolism and the production of ROS generated by the electron transport chain. High concentrations of NADPH are required by both the GSH and TXN systems for detoxification of mitochondrial ROS. NADPH is also utilised by the electron transfer proteins ferredoxin reductase and ferredoxin, critical for the reduction of the P450 enzymes in steroidogenesis (Hanukoglu 2006). Thus there are several mechanisms by which NNT deficiency may affect steroidogenesis. NNT is widely expressed with high levels apparent in the adrenal gland in both human and mouse tissues (Meimaridou et al. 2012).
A substrain of C57BL6/J mice carries a spontaneous Nnt mutation leading to a 5-exon deletion; partial-deletion of the first domain of NNT, which binds NADH, and four of the 14 transmembrane domains which comprise the proton channel (Toye et al. 2005). This substrain of C57BL6/J mice shows an increased sensitivity to O2·−/ H2O2, particularly in the absence of mitochondrial MnSOD (SOD2) and a deficiency in both antioxidants results in death within 1–2 days (Huang et al. 2006) due to dilated cardiomyopathy. Introduction of a normal copy of Nnt into the Sod2−/− mice with the C57BL6/J background confers improved cardiovascular function during foetal development (Kim et al. 2010). Adrenals from the Nnt-mutant substrain have been noted to have slightly disorganised zona fasciculata with higher levels of apoptosis than WTs (Meimaridou et al. 2012). No differences in P450scc (CYP11A1) and P450c11β (CYP11B1) distribution were seen between the two substrains; however, the mutant mice had lower basal and stimulated levels of corticosterone, though the deficiency was not as marked as that seen in the human disease (Meimaridou et al. 2012). Lentiviral short hairpin RNA (shRNA)-knockdown of NNT in the human adrenocortical H295R cell line leads to increased levels of mitochondrial ROS, a decrease in the GSH:GSSG ratio and increased apoptosis (Meimaridou et al. 2012).
Extra-adrenal features have also been demonstrated in this substrain of mice. Nnt-mutant mice have impaired glucose tolerance with loss of glucose-dependent insulin secretion and ATP production in isolated pancreatic islet cells, reminiscent of a type 2 diabetes mellitus model (Kulkarni et al. 2003, Toye et al. 2005). When fed on a high-fat diet, C57BL/6J mice develop obesity, hyperglycaemia and insulin resistance (Rossmeisl et al. 2003). Interestingly, it has been demonstrated that whilst this strain does have reduced insulin secretion and impaired glucose tolerance in comparison to other strains of mice with higher expression levels of NNT, the C57BL/6J mice expressing the truncated protein have similar insulin secretion and glucose tolerance to the C57BL/6N mice expressing the full-length WT protein, though at lower levels than other strains (Wong et al. 2010). This indicates that it is low levels of NNT rather than the protein truncation caused by the 5-exon deletion that has an effect. This also raises the possibility that another enzyme is able to functionally compensate for the loss of NNT in the C57BL/6J mouse, this could explain the relative preservation of steroidogenesis in this strain in comparison to the human phenotype. C57BL/6J mice have also been shown to have a higher sensitivity to neurotoxic agents (Hamre et al. 1999). There are currently no published reports of extra-adrenal clinical manifestations in patients with NNT mutations; however, careful clinical surveillance is required for these patients given the ubiquitous expression of NNT.
Triple A syndrome
Triple A syndrome (Allgrove syndrome) is a rare autosomal recessive disease characterised by the triad of alacrima, achalasia of the oesophageal cardia and primary adrenal failure (Allgrove et al. 1978). Alacrima is the earliest and most consistent sign with achalasia, occurring in about 75% of patients, the usual reason for referral. Adrenal insufficiency develops gradually over the first decade of life and may present later than the first two symptoms, but in some cases may be the presenting symptom leading to diagnosis of disease. This has led to the recommendation that in cases of the presence of alacrima and at least one more symptom of triple A syndrome, adrenal function testing and molecular analysis should be performed (Milenkovic et al. 2010). Glucocorticoid and adrenal androgen production are affected and a proportion of patients also go on to develop a mineralocorticoid deficiency. Neurodegenerative disease, features of which can include peripheral neuropathy, autonomic impairment, pyramidal and bulbar dysfunction, cerebellar and neuro-ophthalmological signs, occurs in ∼60% of patients (Houlden et al. 2002, Dixit et al. 2011, Vallet et al. 2012). In more than 90% of cases, the defect is due to mutations in the AAAS gene, with over 60 different mutations described in the literature. The phenotype is variable even within members of the same kindred and no genotype–phenotype correlation has been identified (Houlden et al. 2002, Huebner et al. 2002, Milenkovic et al. 2010).
The AAAS gene product is the 60 kDa nuclear pore complex (NPC) protein ALADIN (alacrima–achalasia–adrenal insufficiency neurologic disorder). AAAS mRNA and the ALADIN protein are ubiquitously expressed with predominance in the adrenal and CNS structures in the human and the rat (Handschug et al. 2001, Storr et al. 2005, Cho et al. 2009). ALADIN is the only nucleoporin to be associated with hereditary adrenal disease and the first to be associated with hereditary neurodegenerative disease. CNS disorders have since been described in two other nucleoporinopathies, resulting from mutations in Nup62 and RanBP2/Nup358, although the precise pathogenic mechanisms are unclear (Basel-Vanagaite et al. 2006, Neilson et al. 2009, Neilson 2010). ALADIN's role at the NPC is unknown. Most naturally occurring AAAS mutations result in mislocalisation of the abnormal ALADIN protein (mainly into the cytoplasm), implying that correct NPC targeting is vital for its function (Krumbholz et al. 2006).
All the clinical features are progressive, suggesting a degenerative process. Patient adrenal histology reveals atrophy of the zona fasciculata and reticularis (Allgrove et al. 1978). Oxidative stress may play a role in the pathogenesis of this complex disease. Dermal fibroblasts of triple A patients have higher basal intracellular ROS and are more sensitive to oxidative stress than WT fibroblasts (Hirano et al. 2006, Kiriyama et al. 2008, Kind et al. 2010). Additionally in the dermal fibroblast model, failure of nuclear import of DNA repair proteins, aprataxin and DNA ligase I, and the antioxidant ferritin heavy-chain protein (FTH1) has been described (Hirano et al. 2006, Storr et al. 2009). How these nuclear import defects lead to an increase in intracellular ROS remains unclear. Increased chromosomal fragility has also been reported (Reshmi-Skarja et al. 2003), a finding that has also recently been described in cases of FGD within the Irish traveller community, caused by mutations in the DNA replicase MCM4 (Hughes et al. 2012). Lentiviral-shRNA knockdown of AAAS in H295R human adrenocortical cells and SH-SY5Y human neuroblastoma cells renders them hypersensitive to oxidative stress, with a decrease in the GSH/GSSG ratio (Prasad et al. 2013). Furthermore, AAAS knockdown in H295R cells affects the key components of the steroidogenic pathway, STAR and P450c11β expression, with an effect on cortisol production, an effect that is partially reversed with antioxidant N-acetylcysteine treatment (Prasad et al. 2013).
Aaas−/− mice fail to show a similar phenotype to triple A syndrome patients and are largely indistinguishable from WT mice (Huebner et al. 2006). No significant difference in baseline ACTH and corticosterone measurements was observed. Histology revealed no gross abnormality of the organs and the adrenals, ovary, testes, oesophagus, pituitary and peripheral nerves had features similar to those of the WT. Infertility seen in the female Aaas−/− mice was postulated to be related to problems with the maturation of oocytes. Ultrastructurally, there were no observable differences in the NPC (using kidney and liver tissue; Huebner et al. 2006). Additionally, no NPC structural differences were detected by immunocytochemistry of embryonic dermal fibroblasts. These findings indicate the functional redundancy of ALADIN, at least in mice. ALADIN's function at the NPC may therefore be species-specific, certainly species-specific function of nucleoporins has been demonstrated with other Nups (Gigliotti et al. 1998, Grimaldi et al. 2007).
X-linked ALD
X-linked ALD is an inherited neurometabolic disorder, incorporating progressive demyelination in the CNS, axonopathy in the spinal cord and adrenal insufficiency (Kemp et al. 2012). The disease is caused by mutations in the ABCD1 gene on Xq28, encoding the ALD protein (ALDP), a member of the peroxisomal ATP-binding cassette (ABC) transporters. The disease is clinically heterogeneous and the clinical phenotype can be variable even within families. The three most common phenotypes reported are isolated adrenal insufficiency; a late onset slowly progressive disease adrenomyeloneuropathy in which two-thirds of patients also have adrenal insufficiency; and a cerebral inflammatory demyelinating form which can be fatal in early childhood (Kemp et al. 2012). Adrenocortical insufficiency can be the presenting symptom of adrenomyeloneuropathy years or even decades before the onset of neurological symptoms (Wichers-Rothers et al. 2005).
ALDP imports VLCFA-CoA esters into the peroxisome for degradation by β-oxidation (van Roermund et al. 2008). Peroxisomes play an important role in lipid metabolism and are in close communication with mitochondria. Human ABCD1 expression is abundant in the adrenal gland, testis, liver, kidney, lung, placenta and intestine and this is mirrored in mouse expression profiles (Troffer-Charlier et al. 1998, Hoftberger et al. 2007). ALDP protein expression is particularly high in cells characterised by steroid hormone production (the adrenal gland and testis; Hoftberger et al. 2007). Within the adrenal gland, the highest expression is seen in the zona fasciculata and zona reticularis, reflective of the areas affected by the disease. Mutations in ABCD1 result in abnormal accumulation of VLCFAs in plasma and various tissues, predominantly in myelin sheath, adrenal cortex and testis (Forss-Petter et al. 1997). Histology from both the mouse model and human specimens indicates the involvement of oxidative stress in the pathogenesis of the disease, with the evidence of increased MnSOD and lipid peroxidation (Powers et al. 2005). Increased ROS production, depletion of GSH and decreased mitochondrial membrane potential in patient dermal fibroblasts have been described (Fourcade et al. 2008). The precise mechanism whereby the accumulation of VLFCAs leads to the generation of free radicals is unclear and several effects have been proposed (Galea et al. 2012). VLCFAs are substrates of β-oxidation within the peroxisomes, a process that aids acyl-CoA availability and subsequent synthesis of plasmalogens, phospholipids with reported antioxidant properties (Hayashi & Oohashi 1995, Khan et al. 2008, Brites et al. 2009). Dysfunction within peroxisomes can have effects on mitochondria, as both organelles are in communication and generation of ROS within peroxisomes can disturb the mitochondrial redox balance (Ivashchenko et al. 2011). VLCFAs may also have direct effects on mitochondrial function, and structural abnormalities including lipid accumulation are seen within the mitochondria in Abcd1−/− mice (Forss-Petter et al. 1997). Diminished levels of NADH and ATP are seen within the spinal cord of Abcd1−/− mice, indicating defects in energy biosynthesis (Galino et al. 2011). Incorporation of VLFCAs into plasma membranes may also have deleterious effects affecting membrane properties and stability. In addition to effects on redox balance within peroxisomes and mitochondria, it has been proposed that VLCFAs may be involved in signalling within the immune system exacerbating inflammation, which in turn can have further effects on ROS and reactive nitrogen species (RNS) generation (Galea et al. 2012).
Mouse models for X-linked ALD have been established, involving knockout of the ABCD1 gene. Elevated levels of VLCFAs are seen from 6 months of age in the nervous system and adrenal gland; however, there is no overt phenotype until 16 and 20 months of age, when locomotor alterations are evident (Forss-Petter et al. 1997, Pujol et al. 2002, 2004). The model is thus able to recapitulate some of the neurodegenerative aspects of the human disease. With regards to adrenal function, similar to the triple A syndrome mouse model, no effect is seen on corticosterone production at either baseline or upon stress, although histological changes including VLFCA accumulation and increased MnSOD expression are seen in the adrenal cortex (Forss-Petter et al. 1997, Lu et al. 2007).
Models of disease
In all three adrenal insufficiency conditions discussed, mouse models of the disease do not faithfully recapitulate the human phenotype. It is possible that additional mechanisms of antioxidant defence exist within the adrenocortical environment of the mouse, conferring relative protection. Given the potential limitations of mouse models for studies of the adrenal aspects of these diseases, consideration should be given to other available in vivo models for further investigation of precise pathogenic mechanisms.
Non-human primate models such as Papio hamadryas (baboons) and Macaca mulatta (rhesus monkeys) have been used to study age-related changes in endocrine function (Goncharova & Lapin 2004). These have an advantage over rodents in that they produce DHEA/DHEAS, with a steroidogenic profile therefore more reflective of that in man. Similar to man, DHEA/DHEAS production decreases significantly whilst glucocorticoid production varies little with age (Ferrari et al. 2001, Goncharova & Lapin 2004). However, older monkeys exhibit reduced HPA axis sensitivity to glucocorticoid regulation, with a delay in normalisation of the axis after stimulation. This indicates impairment of negative feedback mechanisms, a phenomenon also observed in man. These non-human primate models have been used to study the effect of corticosteroids on antioxidant defence, in the context of ageing (Goncharova et al. 2008a,b, 2013). Circadian rhythmicity of SOD in erythrocytes correlates well with the characterised rhythmicity of DHEAS and cortisol (Goncharova et al. 2008b). Additionally, a similar age-related flattening of these SOD circadian rhythms has been observed, indicating a possible regulatory effect of corticosteroids on antioxidant defence. Age-related changes in stress responsiveness of SOD (increasing with age) and GSH reductase (decreasing with age) have also been described in non-human primate models (Goncharova et al. 2008a). This in turn can lead to peroxide oxidation of lipids, haemolysis of erythrocytes and a diminished reliability of oxygen transport. These studies indicate that corticosteroids themselves play a role in regulating the activity of antioxidants such as SOD and GSH reductase within erythrocytes.
Conclusion
ROS play an important physiological role in steroidogenesis; however, in excess they can have deleterious effects on adrenal function. Steroidogenesis itself increases the generation of ROS, rendering the adrenal gland susceptible to oxidative damage. Inherited defects in the components of several different subcellular compartments have been described in association with increased susceptibility to oxidative stress and adrenal insufficiency. The use and further development of techniques pertaining to the detection of ROS in a site-specific manner will provide further information on the specific cellular targets involved. Further functional interrogation together with careful phenotyping of the respective patient cohorts will allow better understanding of the role of these proteins in human biology. Given the ubiquitous expression of the causative genes identified so far, this knowledge could be invaluable in directing patient surveillance and could also potentially provide targets for therapeutic intervention. Antioxidant defence within the adrenal certainly warrants further investigation and other components within this pathway may prove to be causative in the aetiology of as yet unaccounted for cases of primary adrenal insufficiency.
Declaration of interest
The authors declare that there is no conflict of interest that could be perceived as prejudicing the impartiality of the review.
Funding
This work has been supported by the Wellcome Trust (Clinical Research Training Fellowship grant number WT095984AIA to R P) and the Medical Research Council UK (project grant number MR/K020455/1 to L A M).
References
Allgrove J, Clayden GS, Grant DB & Macaulay JC 1978 Familial glucocorticoid deficiency with achalasia of the cardia and deficient tear production. Lancet 1 1284–1286. (doi:10.1016/S0140-6736(78)91268-0)
Azhar S, Cao L & Reaven E 1995 Alteration of the adrenal antioxidant defense system during aging in rats. Journal of Clinical Investigation 96 1414–1424. (doi:10.1172/JCI118177)
Baker BY, Lin L, Kim CJ, Raza J, Smith CP, Miller WL & Achermann JC 2006 Nonclassic congenital lipoid adrenal hyperplasia: a new disorder of the steroidogenic acute regulatory protein with very late presentation and normal male genitalia. Journal of Clinical Endocrinology and Metabolism 91 4781–4785. (doi:10.1210/jc.2006-1565)
Basel-Vanagaite L, Muncher L, Straussberg R, Pasmanik-Chor M, Yahav M, Rainshtein L, Walsh CA, Magal N, Taub E & Drasinover V et al. 2006 Mutated nup62 causes autosomal recessive infantile bilateral striatal necrosis. Annals of Neurology 60 214–222. (doi:10.1002/ana.20902)
Behne D & Hofer-Bosse T 1984 Effects of a low selenium status on the distribution and retention of selenium in the rat. Journal of Nutrition 114 1289–1296.
Brites P, Mooyer PA, El Mrabet L, Waterham HR & Wanders RJ 2009 Plasmalogens participate in very-long-chain fatty acid-induced pathology. Brain 132 482–492. (doi:10.1093/brain/awn295)
Chanoine JP, Compagnone NA, Wong AC & Mellon SH 2001 Modulation of steroidogenesis by selenium in a novel adrenal cell line developed using targeted tumorigenesis. BioFactors 14 229–238. (doi:10.1002/biof.5520140129)
Cho AR, Yang KJ, Bae Y, Bahk YY, Kim E, Lee H, Kim JK, Park W, Rhim H & Choi SY et al. 2009 Tissue-specific expression and subcellular localization of ALADIN, the absence of which causes human triple A syndrome. Experimental & Molecular Medicine 41 381–386. (doi:10.3858/emm.2009.41.6.043)
Clark AJ, McLoughlin L & Grossman A 1993 Familial glucocorticoid deficiency associated with point mutation in the adrenocorticotropin receptor. Lancet 341 461–462. (doi:10.1016/0140-6736(93)90208-X)
Cox AG, Winterbourn CC & Hampton MB 2010 Mitochondrial peroxiredoxin involvement in antioxidant defence and redox signalling. Biochemical Journal 425 313–325. (doi:10.1042/BJ20091541)
Diemer T, Allen JA, Hales KH & Hales DB 2003 Reactive oxygen disrupts mitochondria in MA-10 tumor Leydig cells and inhibits steroidogenic acute regulatory (StAR) protein and steroidogenesis. Endocrinology 144 2882–2891. (doi:10.1210/en.2002-0090)
Dixit A, Chow G & Sarkar A 2011 Neurologic presentation of triple A syndrome. Pediatric Neurology 45 347–349. (doi:10.1016/j.pediatrneurol.2011.07.003)
Ferrari E, Cravello L, Muzzoni B, Casarotti D, Paltro M, Solerte SB, Fioravanti M, Cuzzoni G, Pontiggia B & Magri F 2001 Age-related changes of the hypothalamic–pituitary–adrenal axis: pathophysiological correlates. European Journal of Endocrinology 144 319–329. (doi:10.1530/eje.0.1440319)
Forss-Petter S, Werner H, Berger J, Lassmann H, Molzer B, Schwab MH, Bernheimer H, Zimmermann F & Nave KA 1997 Targeted inactivation of the X-linked adrenoleukodystrophy gene in mice. Journal of Neuroscience Research 50 829–843. (doi:10.1002/(SICI)1097-4547(19971201)50:5%3C;829::AID-JNR19%3E;3.0.CO;2-W)
Fourcade S, Lopez-Erauskin J, Galino J, Duval C, Naudi A, Jove M, Kemp S, Villarroya F, Ferrer I & Pamplona R et al. 2008 Early oxidative damage underlying neurodegeneration in X-adrenoleukodystrophy. Human Molecular Genetics 17 1762–1773. (doi:10.1093/hmg/ddn085)
Galea E, Launay N, Portero-Otin M, Ruiz M, Pamplona R, Aubourg P, Ferrer I & Pujol A 2012 Oxidative stress underlying axonal degeneration in adrenoleukodystrophy: a paradigm for multifactorial neurodegenerative diseases? Biochimica et Biophysica Acta 1822 1475–1488. (doi:10.1016/j.bbadis.2012.02.005)
Galino J, Ruiz M, Fourcade S, Schluter A, Lopez-Erauskin J, Guilera C, Jove M, Naudi A, Garcia-Arumi E & Andreu AL et al. 2011 Oxidative damage compromises energy metabolism in the axonal degeneration mouse model of X-adrenoleukodystrophy. Antioxidants and Redox Signaling 15 2095–2107. (doi:10.1089/ars.2010.3877)
Gigliotti S, Callaini G, Andone S, Riparbelli MG, Pernas-Alonso R, Hoffmann G, Graziani F & Malva C 1998 Nup154, a new Drosophila gene essential for male and female gametogenesis is related to the Nup155 vertebrate nucleoporin gene. Journal of Cell Biology 142 1195–1207. (doi:10.1083/jcb.142.5.1195)
Goncharova ND & Lapin BA 2004 Age-related endocrine dysfunction in nonhuman primates. Annals of the New York Academy of Sciences 1019 321–325. (doi:10.1196/annals.1297.054)
Goncharova ND, Marenin VY & Bogatyrenko TN 2008a Stress, aging and reliability of antioxidant enzyme defense. Current Aging Science 1 22–29. (doi:10.2174/1874609810801010022)
Goncharova ND, Shmaliy AV, Marenin VY, Smelkova SA & Lapin BA 2008b Circadian and age-related changes in stress responsiveness of the adrenal cortex and erythrocyte antioxidant enzymes in female rhesus monkeys. Journal of Medical Primatology 37 229–238. (doi:10.1111/j.1600-0684.2007.00278.x)
Goncharova ND, Marenin VY & Vengerin AA 2013 Age-related changes in the reliability of antioxidant enzyme defense in monkeys with different types of adaptive behavior. Current Aging Science 6 163–169. (doi:10.2174/18746098112059990004)
Grimaldi MR, Cozzolino L, Malva C, Graziani F & Gigliotti S 2007 nup154 genetically interacts with cup and plays a cell-type-specific function during Drosophila melanogaster egg-chamber development. Genetics 175 1751–1759. (doi:10.1534/genetics.106.062844)
Grinberg AV, Hannemann F, Schiffler B, Muller J, Heinemann U & Bernhardt R 2000 Adrenodoxin: structure, stability, and electron transfer properties. Proteins 40 590–612. (doi:10.1002/1097-0134(20000901)40:4%3C;590::AID-PROT50%3E;3.0.CO;2-P)
Gruber KA, O'Brien LV & Gerstner R 1976 Vitamin A: not required for adrenal steroidogenesis in rats. Science 191 472–475. (doi:10.1126/science.1246630)
Hamre K, Tharp R, Poon K, Xiong X & Smeyne RJ 1999 Differential strain susceptibility following 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP) administration acts in an autosomal dominant fashion: quantitative analysis in seven strains of Mus musculus. Brain Research 828 91–103. (doi:10.1016/S0006-8993(99)01273-1)
Handschug K, Sperling S, Yoon SJ, Hennig S, Clark AJ & Huebner A 2001 Triple A syndrome is caused by mutations in AAAS, a new WD-repeat protein gene. Human Molecular Genetics 10 283–290. (doi:10.1093/hmg/10.3.283)
Hanschmann EM, Lonn ME, Schutte LD, Funke M, Godoy JR, Eitner S, Hudemann C & Lillig CH 2010 Both thioredoxin 2 and glutaredoxin 2 contribute to the reduction of the mitochondrial 2-Cys peroxiredoxin Prx3. Journal of Biological Chemistry 285 40699–40705. (doi:10.1074/jbc.M110.185827)
Hanukoglu I 2006 Antioxidant protective mechanisms against reactive oxygen species (ROS) generated by mitochondrial P450 systems in steroidogenic cells. Drug Metabolism Reviews 38 171–196. (doi:10.1080/03602530600570040)
Hanukoglu I & Hanukoglu Z 1986 Stoichiometry of mitochondrial cytochromes P-450, adrenodoxin and adrenodoxin reductase in adrenal cortex and corpus luteum. Implications for membrane organization and gene regulation. European Journal of Biochemistry 157 27–31. (doi:10.1111/j.1432-1033.1986.tb09633.x)
Hayashi H & Oohashi M 1995 Incorporation of acetyl-CoA generated from peroxisomal β-oxidation into ethanolamine plasmalogen of rat liver. Biochimica et Biophysica Acta 1254 319–325. (doi:10.1016/0005-2760(94)00194-4)
Hirano M, Furiya Y, Asai H, Yasui A & Ueno S 2006 ALADINI482S causes selective failure of nuclear protein import and hypersensitivity to oxidative stress in triple A syndrome. PNAS 103 2298–2303. (doi:10.1073/pnas.0505598103)
Hoftberger R, Kunze M, Weinhofer I, Aboul-Enein F, Voigtlander T, Oezen I, Amann G, Bernheimer H, Budka H & Berger J 2007 Distribution and cellular localization of adrenoleukodystrophy protein in human tissues: implications for X-linked adrenoleukodystrophy. Neurobiology of Disease 28 165–174. (doi:10.1016/j.nbd.2007.07.007)
Hornig D 1975 Distribution of ascorbic acid, metabolites and analogues in man and animals. Annals of the New York Academy of Sciences 258 103–118. (doi:10.1111/j.1749-6632.1975.tb29271.x)
Hornsby PJ 1980 Regulation of cytochrome P-450-supported 11β-hydroxylation of deoxycortisol by steroids, oxygen, and antioxidants in adrenocortical cell cultures. Journal of Biological Chemistry 255 4020–4027.
Houlden H, Smith S, De Carvalho M, Blake J, Mathias C, Wood NW & Reilly MM 2002 Clinical and genetic characterization of families with triple A (Allgrove) syndrome. Brain 125 2681–2690. (doi:10.1093/brain/awf270)
Huang TT, Naeemuddin M, Elchuri S, Yamaguchi M, Kozy HM, Carlson EJ & Epstein CJ 2006 Genetic modifiers of the phenotype of mice deficient in mitochondrial superoxide dismutase. Human Molecular Genetics 15 1187–1194. (doi:10.1093/hmg/ddl034)
Huebner A, Kaindl AM, Braun R & Handschug K 2002 New insights into the molecular basis of the triple A syndrome. Endocrine Research 28 733–739. (doi:10.1081/ERC-120016998)
Huebner A, Mann P, Rohde E, Kaindl AM, Witt M, Verkade P, Jakubiczka S, Menschikowski M, Stoltenburg-Didinger G & Koehler K 2006 Mice lacking the nuclear pore complex protein ALADIN show female infertility but fail to develop a phenotype resembling human triple A syndrome. Molecular and Cellular Biology 26 1879–1887. (doi:10.1128/MCB.26.5.1879-1887.2006)
Hughes CR, Guasti L, Meimaridou E, Chuang CH, Schimenti JC, King PJ, Costigan C, Clark AJ & Metherell LA 2012 MCM4 mutation causes adrenal failure, short stature, and natural killer cell deficiency in humans. Journal of Clinical Investigation 122 814–820. (doi:10.1172/JCI60224)
Imai H, Hakkaku N, Iwamoto R, Suzuki J, Suzuki T, Tajima Y, Konishi K, Minami S, Ichinose S & Ishizaka K et al. 2009 Depletion of selenoprotein GPx4 in spermatocytes causes male infertility in mice. Journal of Biological Chemistry 284 32522–32532. (doi:10.1074/jbc.M109.016139)
Ivashchenko O, Van Veldhoven PP, Brees C, Ho YS, Terlecky SR & Fransen M 2011 Intraperoxisomal redox balance in mammalian cells: oxidative stress and interorganellar cross-talk. Molecular Biology of the Cell 22 1440–1451. (doi:10.1091/mbc.E10-11-0919)
Kemp S, Berger J & Aubourg P 2012 X-linked adrenoleukodystrophy: clinical, metabolic, genetic and pathophysiological aspects. Biochimica et Biophysica Acta 1822 1465–1474. (doi:10.1016/j.bbadis.2012.03.012)
Khan M, Singh J & Singh I 2008 Plasmalogen deficiency in cerebral adrenoleukodystrophy and its modulation by lovastatin. Journal of Neurochemistry 106 1766–1779. (doi:10.1111/j.1471-4159.2008.05513.x)
Kil IS, Lee SK, Ryu KW, Woo HA, Hu MC, Bae SH & Rhee SG 2012 Feedback control of adrenal steroidogenesis via H2O2-dependent, reversible inactivation of peroxiredoxin III in mitochondria. Molecular Cell 46 584–594. (doi:10.1016/j.molcel.2012.05.030)
Kim A, Chen CH, Ursell P & Huang TT 2010 Genetic modifier of mitochondrial superoxide dismutase-deficient mice delays heart failure and prolongs survival. Mammalian Genome 21 534–542. (doi:10.1007/s00335-010-9299-x)
Kind B, Koehler K, Krumbholz M, Landgraf D & Huebner A 2010 Intracellular ROS level is increased in fibroblasts of triple A syndrome patients. Journal of Molecular Medicine 88 1233–1242. (doi:10.1007/s00109-010-0661-y)
Kiriyama T, Hirano M, Asai H, Ikeda M, Furiya Y & Ueno S 2008 Restoration of nuclear-import failure caused by triple A syndrome and oxidative stress. Biochemical and Biophysical Research Communications 374 631–634. (doi:10.1016/j.bbrc.2008.07.088)
Korytowski W, Pilat A, Schmitt JC & Girotti AW 2013 Deleterious cholesterol hydroperoxide trafficking in steroidogenic acute regulatory (StAR) protein-expressing MA-10 Leydig cells: implications for oxidative stress-impaired steroidogenesis. Journal of Biological Chemistry 288 11509–11519. (doi:10.1074/jbc.M113.452151)
Krumbholz M, Koehler K & Huebner A 2006 Cellular localization of 17 natural mutant variants of ALADIN protein in triple A syndrome – shedding light on an unexpected splice mutation. Biochemistry and Cell Biology 84 243–249. (doi:10.1139/o05-198)
Kulkarni RN, Almind K, Goren HJ, Winnay JN, Ueki K, Okada T & Kahn CR 2003 Impact of genetic background on development of hyperinsulinemia and diabetes in insulin receptor/insulin receptor substrate-1 double heterozygous mice. Diabetes 52 1528–1534. (doi:10.2337/diabetes.52.6.1528)
Lu JF, Barron-Casella E, Deering R, Heinzer AK, Moser AB, deMesy Bentley KL, Wand GS, C McGuinness M, Pei Z & Watkins PA et al. 2007 The role of peroxisomal ABC transporters in the mouse adrenal gland: the loss of Abcd2 (ALDR), not Abcd1 (ALD), causes oxidative damage. Laboratory Investigation 87 261–272. (doi:10.1038/labinvest.3700512)
Meimaridou E, Kowalczyk J, Guasti L, Hughes CR, Wagner F, Frommolt P, Nurnberg P, Mann NP, Banerjee R & Saka HN et al. 2012 Mutations in NNT encoding nicotinamide nucleotide transhydrogenase cause familial glucocorticoid deficiency. Nature Genetics 44 740–742. (doi:10.1038/ng.2299)
Meimaridou E, Hughes CR, Kowalczyk J, Chan LF, Clark AJ & Metherell LA 2013 ACTH resistance: genes and mechanisms. Endocrine Development 24 57–66. (doi:10.1159/000342504)
Metherell LA, Chapple JP, Cooray S, David A, Becker C, Ruschendorf F, Naville D, Begeot M, Khoo B & Nurnberg P et al. 2005 Mutations in MRAP, encoding a new interacting partner of the ACTH receptor, cause familial glucocorticoid deficiency type 2. Nature Genetics 37 166–170. (doi:10.1038/ng1501)
Metherell LA, Naville D, Halaby G, Begeot M, Huebner A, Nurnberg G, Nurnberg P, Green J, Tomlinson JW & Krone NP et al. 2009 Nonclassic lipoid congenital adrenal hyperplasia masquerading as familial glucocorticoid deficiency. Journal of Clinical Endocrinology and Metabolism 94 3865–3871. (doi:10.1210/jc.2009-0467)
Milenkovic T, Zdravkovic D, Savic N, Todorovic S, Mitrovic K, Koehler K & Huebner A 2010 Triple A syndrome: 32 years experience of a single centre (1977–2008). European Journal of Pediatrics 169 1323–1328. (doi:10.1007/s00431-010-1222-7)
Miller WL 2005 Minireview: Regulation of steroidogenesis by electron transfer. Endocrinology 146 2544–2550. (doi:10.1210/en.2005-0096)
Miller WL 2011 Role of mitochondria in steroidogenesis. Endocrine Development 20 1–19. (doi:10.1016/j.beem.2012.05.002)
Neilson DE 2010 The interplay of infection and genetics in acute necrotizing encephalopathy. Current Opinion in Pediatrics 22 751–757. (doi:10.1097/MOP.0b013e3283402bfe)
Neilson DE, Adams MD, Orr CM, Schelling DK, Eiben RM, Kerr DS, Anderson J, Bassuk AG, Bye AM & Childs AM et al. 2009 Infection-triggered familial or recurrent cases of acute necrotizing encephalopathy caused by mutations in a component of the nuclear pore, RANBP2. American Journal of Human Genetics 84 44–51. (doi:10.1016/j.ajhg.2008.12.009)
Palmieri F 1994 Mitochondrial carrier proteins. FEBS Letters 346 48–54. (doi:10.1016/0014-5793(94)00329-7)
Papadopoulos V & Miller WL 2012 Role of mitochondria in steroidogenesis. Best Practice & Research. Clinical Endocrinology & Metabolism 26 771–790. (doi:10.1016/j.beem.2012.05.002)
Powers JM, Pei Z, Heinzer AK, Deering R, Moser AB, Moser HW, Watkins PA & Smith KD 2005 Adreno-leukodystrophy: oxidative stress of mice and men. Journal of Neuropathology and Experimental Neurology 64 1067–1079. (doi:10.1097/01.jnen.0000190064.28559.a4)
Prasad R, Metherell LA, Clark AJ & Storr HL 2013 Deficiency of ALADIN impairs redox homeostasis in human adrenal cells and inhibits steroidogenesis. Endocrinology 154 3209–3218. (doi:10.1210/en.2013-1241)
Pujol A, Hindelang C, Callizot N, Bartsch U, Schachner M & Mandel JL 2002 Late onset neurological phenotype of the X-ALD gene inactivation in mice: a mouse model for adrenomyeloneuropathy. Human Molecular Genetics 11 499–505. (doi:10.1093/hmg/11.5.499)
Pujol A, Ferrer I, Camps C, Metzger E, Hindelang C, Callizot N, Ruiz M, Pampols T, Giros M & Mandel JL 2004 Functional overlap between ABCD1 (ALD) and ABCD2 (ALDR) transporters: a therapeutic target for X-adrenoleukodystrophy. Human Molecular Genetics 13 2997–3006. (doi:10.1093/hmg/ddh323)
Rapoport R, Sklan D & Hanukoglu I 1995 Electron leakage from the adrenal cortex mitochondrial P450scc and P450c11 systems: NADPH and steroid dependence. Archives of Biochemistry and Biophysics 317 412–416. (doi:10.1006/abbi.1995.1182)
Ray PD, Huang BW & Tsuji Y 2012 Reactive oxygen species (ROS) homeostasis and redox regulation in cellular signaling. Cellular Signalling 24 981–990. (doi:10.1016/j.cellsig.2012.01.008)
Reshmi-Skarja S, Huebner A, Handschug K, Finegold DN, Clark AJ & Gollin SM 2003 Chromosomal fragility in patients with triple A syndrome. American Journal of Medical Genetics. Part A 117A 30–36. (doi:10.1002/ajmg.a.10846)
van Roermund CW, Visser WF, Ijlst L, van Cruchten A, Boek M, Kulik W, Waterham HR & Wanders RJ 2008 The human peroxisomal ABC half transporter ALDP functions as a homodimer and accepts acyl-CoA esters. FASEB Journal 22 4201–4208. (doi:10.1096/fj.08-110866)
Rossmeisl M, Rim JS, Koza RA & Kozak LP 2003 Variation in type 2 diabetes – related traits in mouse strains susceptible to diet-induced obesity. Diabetes 52 1958–1966. (doi:10.2337/diabetes.52.8.1958)
Sena LA & Chandel NS 2012 Physiological roles of mitochondrial reactive oxygen species. Molecular Cell 48 158–167. (doi:10.1016/j.molcel.2012.09.025)
Shi Z, Feng Y, Wang J, Zhang H, Ding L & Dai J 2010 Perfluorododecanoic acid-induced steroidogenic inhibition is associated with steroidogenic acute regulatory protein and reactive oxygen species in cAMP-stimulated Leydig cells. Toxicological Sciences 114 285–294. (doi:10.1093/toxsci/kfq014)
Storr HL, Clark AJ, Priestley JV & Michael GJ 2005 Identification of the sites of expression of triple A syndrome mRNA in the rat using in situ hybridisation. Neuroscience 131 113–123. (doi:10.1016/j.neuroscience.2004.10.029)
Storr HL, Kind B, Parfitt DA, Chapple JP, Lorenz M, Koehler K, Huebner A & Clark AJ 2009 Deficiency of ferritin heavy-chain nuclear import in triple a syndrome implies nuclear oxidative damage as the primary disease mechanism. Molecular Endocrinology 23 2086–2094. (doi:10.1210/me.2009-0056)
Svirbely JL & Szent-Gyorgyi A 1932 The chemical nature of vitamin C. Biochemical Journal 26 865–870.
Toye AA, Lippiat JD, Proks P, Shimomura K, Bentley L, Hugill A, Mijat V, Goldsworthy M, Moir L & Haynes A et al. 2005 A genetic and physiological study of impaired glucose homeostasis control in C57BL/6J mice. Diabetologia 48 675–686. (doi:10.1007/s00125-005-1680-z)
Troffer-Charlier N, Doerflinger N, Metzger E, Fouquet F, Mandel JL & Aubourg P 1998 Mirror expression of adrenoleukodystrophy and adrenoleukodystrophy related genes in mouse tissues and human cell lines. European Journal of Cell Biology 75 254–264. (doi:10.1016/S0171-9335(98)80121-0)
Vallet AE, Verschueren A, Petiot P, Vandenberghe N, Nicolino M, Roman S, Pouget J & Vial C 2012 Neurological features in adult triple-A (Allgrove) syndrome. Journal of Neurology 259 39–46. (doi:10.1007/s00415-011-6115-9)
Watabe S, Makino Y, Ogawa K, Hiroi T, Yamamoto Y & Takahashi SY 1999 Mitochondrial thioredoxin reductase in bovine adrenal cortex its purification, properties, nucleotide/amino acid sequences, and identification of selenocysteine. European Journal of Biochemistry 264 74–84. (doi:10.1046/j.1432-1327.1999.00578.x)
Wichers-Rother M, Grigull A, Sokolowski P, Stoffel-Wagner B & Kohler W 2005 Adrenal steroids in adrenomyeloneuropathy. Dehydroepiandrosterone sulfate, androstenedione and 17α-hydroxyprogesterone. Journal of Neurology 252 1525–1529. (doi:10.1007/s00415-005-0908-7)
Wong N, Blair AR, Morahan G & Andrikopoulos S 2010 The deletion variant of nicotinamide nucleotide transhydrogenase (Nnt) does not affect insulin secretion or glucose tolerance. Endocrinology 151 96–102. (doi:10.1210/en.2009-0887)
Woo HA, Chae HZ, Hwang SC, Yang KS, Kang SW, Kim K & Rhee SG 2003 Reversing the inactivation of peroxiredoxins caused by cysteine sulfinic acid formation. Science 300 653–656. (doi:10.1126/science.1080273)
Zhang H, Go YM & Jones DP 2007 Mitochondrial thioredoxin-2/peroxiredoxin-3 system functions in parallel with mitochondrial GSH system in protection against oxidative stress. Archives of Biochemistry and Biophysics 465 119–126. (doi:10.1016/j.abb.2007.05.001)
Zhao Y, Ao H, Chen L, Sottas CM, Ge RS, Li L & Zhang Y 2012 Mono-(2-ethylhexyl) phthalate affects the steroidogenesis in rat Leydig cells through provoking ROS perturbation. Toxicology In Vitro 26 950–955. (doi:10.1016/j.tiv.2012.04.003)
Ziegler GA, Vonrhein C, Hanukoglu I & Schulz GE 1999 The structure of adrenodoxin reductase of mitochondrial P450 systems: electron transfer for steroid biosynthesis. Journal of Molecular Biology 289 981–990. (doi:10.1006/jmbi.1999.2807)