Afshan N. Malik

Is mitochondrial DNA content a potential biomarker of mitochondrial dysfunction

Mitochondrial dysfunction is central to numerous diseases of oxidative stress. Changes in mitochondrial DNA (MtDNA) content, often measured as mitochondrial genome to nuclear genome ratio (Mt/N) using real time quantitative PCR, have been reported in a broad range of human diseases, such as diabetes and its complications, obesity, cancer, HIV complications, and ageing. We propose the hypothesis that MtDNA content in body fluids and tissues could be a biomarker of mitochondrial dysfunction and review the evidence supporting this theory. Increased reactive oxygen species resulting from an external trigger such as hyperglycaemia or increased fat in conditions of oxidative stress could lead to enhanced mitochondrial biogenesis, and increased Mt/N. Altered MtDNA levels may contribute to enhanced oxidative stress and inflammation and could play a pathogenic role in mitochondrial dysfunction and disease. Changes in Mt/N are detectable in circulating cells such as peripheral blood mononuclear cells and these could be used as surrogate to predict global changes in tissues and organs. We review a large number of studies reporting changes in MtDNA levels in body fluids such as circulating blood cells, cell free serum, saliva, sperm, and cerebrospinal fluid as well as in tumour and normal tissue samples. However, the data are often conflicting as the current methodology used to measure Mt/N can give false results because of one or more of the following reasons (1) use of mitochondrial primers which co-amplify nuclear pseudogenes (2) use of nuclear genes which are variable and/or duplicated in numerous locations (3) a dilution bias caused by the differing genome sizes of the mitochondrial and nuclear genome and (4) template preparation protocols which affect the yields of nuclear and mitochondrial genomes. Development of robust and reproducible methodology is needed to test the hypothesis that MtDNA content in body fluids is biomarker of mitochondrial dysfunction.

Altered Mitochondrial Function, Mitochondrial DNA and Reduced Metabolic Flexibility in Patients With Diabetic Nephropathy

The purpose of this study was to determine if mitochondrial dysfunction plays a role in diabetic nephropathy (DN), a kidney disease which affects > 100 million people worldwide and is a leading cause of renal failure despite therapy. A cross-sectional study comparing DN with diabetes patients without kidney disease (DC) and healthy controls (HCs); and renal mesangial cells (HMCs) grown in normal and high glucose, was carried out. Patients with diabetes (DC) had increased circulating mitochondrial DNA (MtDNA), and HMCs increased their MtDNA within 24 h of hyperglycaemia. The increased MtDNA content in DCs and HMCs was not functional as transcription was unaltered/down-regulated, and MtDNA damage was present. MtDNA was increased in DC compared to HC, conversely, patients with DN had lower MtDNA than DC. Hyperglycaemic HMCs had fragmented mitochondria and TLR9 pathway activation, and in diabetic patients, mitophagy was reduced. Despite MtDNA content and integrity changing within 4 days, hyperglycaemic HMCs had a normal bio-energetic profile until 8 days, after which mitochondrial metabolism was progressively impaired. Peripheral blood mononuclear cells (PBMCs) from DN patients had reduced reserve capacity and maximal respiration, loss of metabolic flexibility and reduced Bioenergetic Health Index (BHI) compared to DC. Our data show that MtDNA changes precede bioenergetic dysfunction and that patients with DN have impaired mitochondrial metabolism compared to DC, leading us to propose that systemic mitochondrial dysfunction initiated by glucose induced MtDNA damage may be involved in the development of DN. Longitudinal studies are needed to define a potential cause–effect relationship between changes in MtDNA and bioenergetics in DN.

Increased peripheral blood mitochondrial DNA in type 2 diabetic patients with nephropathy

We report that mitochondrial DNA (MtDNA) copy numbers are increased in peripheral blood of patients with diabetic nephropathy (DN). Using qPCR for quantitation, we found a 2-4-fold significant increase (p<0.05) in the mean MtDNA values in DN patients vs. healthy controls and diabetics without nephropathy. Increased MtDNA in DN could contribute to increased oxidative stress.

Isolation and Partial Characterization of Three Classes of Mutant in Pseudomonas syringae Pathovar pisi with Altered Behaviour towards Their Host, Pisum sativum

SUMMARY: Mating with Escherichia coli strain SM10 carrying the Tn5 vector pSUP2011 was used to mutagenize Pseudomonas syringae pv. pisi strain 299A. The resulting transconjugants were each tested by stem-inoculation into several pea (Pisum sativum) cultivars. Three classes of mutant, which probably resulted from insertion of part or all of RP4-2-Tc:: Mu into the genome of strain 299A, showed reduced virulence towards one or more pea cultivars. The single class I mutant was avirulent on all pea cultivars tested and had lost the ability to induce a hypersensitive response in tobacco (Nicotiana tabacum) cv. White Burley; the single class II mutant induced a hypersensitive response on all pea cultivars and tobacco; class III mutants showed reduced virulence towards pea cv. Early Onward, while remaining fully virulent towards other normally susceptible pea cultivars, and inducing a hypersensitive response in tobacco.

Mitochondrial genes are altered in blood early in Alzheimer's disease

Although mitochondrial dysfunction is a consistent feature of Alzheimers disease in the brain and blood, the molecular mechanisms behind these phenomena are unknown. Here we have replicated our previous findings demonstrating reduced expression of nuclear-encoded oxidative phosphorylation (OXPHOS) subunits and subunits required for the translation of mitochondrial-encoded OXPHOS genes in blood from people with Alzheimers disease and mild cognitive impairment. Interestingly this was accompanied by increased expression of some mitochondrial-encoded OXPHOS genes, namely those residing closest to the transcription start site of the polycistronic heavy chain mitochondrial transcript (MT-ND1, MT-ND2, MT-ATP6, MT-CO1, MT-CO2, MT-C03) and MT-ND6 transcribed from the light chain. Further we show that mitochondrial DNA copy number was unchanged suggesting no change in steady-state numbers of mitochondria. We suggest that an imbalance in nuclear and mitochondrial genome-encoded OXPHOS transcripts may drive a negative feedback loop reducing mitochondrial translation and compromising OXPHOS efficiency, which is likely to generate damaging reactive oxygen species.

A simple high yield method for the preparation of lambda gt10 DNA suitable for subcloning, amplification and direct sequencing

This paper describes a simple method for the preparation of high quality XgtlO DNA utilising double nuclease digestion and PEG precipitation. The use of XgtlO as a cDNA cloning vector (Huynh et al., 1984) is often limited by difficulties in the preparation of insert DNA once clones of interest have been purified. Most previously described methods give low yields or involve time consuming CsCl step gradients and precipitation by ultracentrifugation (Sambrook et al., 1989). Unlike other liquid lysate methods (Grosberger, 1987), this method is reliable for a wide range of insert sizes, applicable to large numbers of clones, and routinely yields at least 2 mg of high purity DNA per 100 ml cultures. 2 ml plate lysate (of 3 ml taken from 9 cm plates) is added to 100 ml of exponentially growing culture of E. coli C600hfl~, and grown with shaking until lysis (37°C, 2 3 h). The bacterial cells are removed by centrifugation. DNasel (100 /d, 10 mg/ml) and RNaseA (100 jtl, 10 mg/ml) are added to the supernatant and incubated (37°C, 1 h). Following addition of PEG (10 g) and NaCl (4 g), phage is precipitated (1 h, ice/water) and pelletted (1500 g, 10 min). The pellet is resuspended in 5 ml SM buffer and a second DNasel (50 /d, 10 mg/ml) and RNaseA (50 fi\, 10 mg/ml) incubation is carried out (37°C, 30 min). The phage is lysed by incubation with SDS (0.2%) and proteinase K (50 til, 10 mg/ml, 37°C, 1 h). After phenol/chloroform extraction, the phage DNA is precipitated using 3M sodium acetate pH 5.4 (0.1 volume) and cold ethanol (2.5 volume), centrifuged (1500 g, 10 min), and washed in 70% ethanol.

Altered circulating mitochondrial DNA and increased inflammation in patients with diabetic retinopathy

AIMS We previously showed that circulating mitochondrial DNA (MtDNA) levels are altered in diabetic nephropathy. The aim of the current study was to determine if circulating MtDNA levels are altered in patients with diabetic retinopathy. METHODS Patients with diabetes (n=220) were studied in a clinical setting using a cross-sectional study design as the following groups: DR-0 (no retinopathy, n=53), DR-m (mild non-proliferative diabetic retinopathy NPDR, n=98) and DR-s (severe proliferative diabetic retinopathy, n=69). MtDNA content in peripheral blood DNA was measured as the mitochondrial to nuclear genome ratio using real time qPCR. Circulating cytokines were measured using the luminex assay and MtDNA damage was assessed using PCR. Differences were considered significant at P<0.05. RESULTS Circulating MtDNA values were higher in DR-m compared to DR-0 (P=0.02) and decreased in DR-s compared to DR-m (P=0.001). These changes remained significant after adjusting for associated parameters. In parallel there were increased levels of circulating cytokines IL-4 (P=0.005) and TNF-α (P=0.02) in the DR-s group and increased MtDNA damage in DR-m patients compared to DR-0 (P=0.03). CONCLUSIONS Our data show that circulating MtDNA levels are independently associated with diabetic retinopathy, showing an increase in DR-m and decrease in DR-s with a parallel increase in MtDNA damage and inflammation. Hyperglycemia-induced changes in MtDNA in early diabetes may contribute to inflammation and progression of diabetic retinopathy. Longitudinal studies should be carried out to determine a potential causality of MtDNA in diabetic retinopathy.

Accurate quantification of mouse mitochondrial DNA without co-amplification of nuclear mitochondrial insertion sequences

BACKGROUND Mitochondria contain an extra-nuclear genome in the form of mitochondrial DNA (MtDNA), damage to which can lead to inflammation and bioenergetic deficit. Changes in MtDNA levels are increasingly used as a biomarker of mitochondrial dysfunction. We previously reported that in humans, fragments in the nuclear genome known as nuclear mitochondrial insertion sequences (NumtS) affect accurate quantification of MtDNA. In the current paper our aim was to determine whether mouse NumtS affect the quantification of MtDNA and to establish a method designed to avoid this. METHODS The existence of NumtS in the mouse genome was confirmed using blast N, unique MtDNA regions were identified using FASTA, and MtDNA primers which do not co-amplify NumtS were designed and tested. MtDNA copy numbers were determined in a range of mouse tissues as the ratio of the mitochondrial and nuclear genome using real time qPCR and absolute quantification. RESULTS Approximately 95% of mouse MtDNA was duplicated in the nuclear genome as NumtS which were located in 15 out of 21 chromosomes. A unique region was identified and primers flanking this region were used. MtDNA levels differed significantly in mouse tissues being the highest in the heart, with levels in descending order (highest to lowest) in kidney, liver, blood, brain, islets and lung. CONCLUSION The presence of NumtS in the nuclear genome of mouse could lead to erroneous data when studying MtDNA content or mutation. The unique primers described here will allow accurate quantification of MtDNA content in mouse models without co-amplification of NumtS.

Molecular genetics of Pseudomonas syringae pathovar pisi : plasmid involvement in cultivar-specific incompatibility

A mutant (PF24) of the race 1 strain, 299A, of Pseudomonas syringae pv. pisi has been characterized in terms of its interactions with pea (Pisum sativum) cultivars. The mutant showed a changed reaction (avirulence to virulence) with a group of pea cultivars, including cvs. Belinda and Puget, previously thought to contain resistance genes R1 and R3. Avirulence towards cv. Puget was restored by transfer of any one of five cosmid clones from a race 3 (strain 870A) gene library to a rifampicin-resistant derivative of PF24. These observations were in agreement with a revised race-specific resistance genotype for Belinda and similar cultivars comprising a single resistance gene, R3. An incompatible interaction was observed between strain PF24 and cvs. Vinco (postulated to harbour race-specific resistance genes R1, R2, R3 and R5) and Hursts Greenshaft (R4 and possibly R1), indicating that the mutant retains at least one avirulence gene (A1 or A1 and A4). Mutant PF24 showed loss of a cryptic plasmid (pAV212) compared with its progenitor, strain 299A. A subclone (pAV233) of one of the race 3 restoration clones showed strong hybridization with similar-sized digestion fragments in race 3 plasmid DNA, confirming the A3 gene to be plasmid-borne. Strong cross-hybridization was also observed with a single 3.27 kb EcoRI fragment of plasmid DNA present in strain 299A but absent from strain PF24. This is consistent with the corresponding A3 determinant being located on pAV212 in the race 1 strain 299A. The novel avirulence gene corresponding to A3 in strain 870A is provisionally designated avrPpi3.(ABSTRACT TRUNCATED AT 250 WORDS)

Hyperglycemia induced damage to mitochondrial respiration in renal mesangial and tubular cells: Implications for diabetic nephropathy

Damage to renal tubular and mesangial cells is central to the development of diabetic nephropathy (DN), a complication of diabetes which can lead to renal failure. Mitochondria are the site of cellular respiration and produce energy in the form of ATP via oxidative phosphorylation, and mitochondrial dysfunction has been implicated in DN. Since the kidney is an organ with high bioenergetic needs, we postulated that hyperglycemia causes damage to renal mitochondria resulting in bioenergetic deficit. The bioenergetic profiles and the effect of hyperglycemia on cellular respiration of human primary mesangial (HMCs) and proximal tubular cells (HK-2) were compared in normoglycemic and hyperglycemic conditions using the seahorse bio-analyzer. In normoglycemia, HK-2 had significantly lower basal, ATP-linked and maximal respiration rates, and lower reserve capacity compared to HMCs. Hyperglycemia caused a down-regulation of all respiratory parameters within 4 days in HK-2 but not in HMCs. After 8 days of hyperglycemia, down-regulation of respiratory parameters persisted in tubular cells with compensatory up-regulated glycolysis. HMCs had reduced maximal respiration and reserve capacity at 8 days, and by 12 days had compromised mitochondrial respiration despite which they did not enhance glycolysis. These data suggest that diabetes is likely to lead to a cellular deficit in ATP production in both cell types, although with different sensitivities, and this mechanism could significantly contribute to the cellular damage seen in the diabetic kidney. Prevention of diabetes induced damage to renal mitochondrial respiration may be a novel therapeutic approach for the prevention/treatment of DN.