Shari R. Atilano

Mitochondrial DNA Haplogroups Associated with Age-Related Macular Degeneration

PURPOSE To examine the mtDNA control regions in normal and age-related macular degeneration (AMD) retinas. To identify the mtDNA variations associated with AMD. METHODS Retinas from 10 normal and 11 AMD globes were isolated and analyzed for mtDNA rearrangements by long extension-polymerase chain reaction (LX-PCR) and for the nature and frequency of single-nucleotide polymorphisms (SNPs) in the mtDNA control region by direct sequencing. Blood DNA was extracted from 99 AMD and 92 age-matched control subjects. The sequence variations that define haplogroups H, I, J, K, T, V, X, and U were characterized by PCR, restriction enzyme digestion, and/or sequencing. RESULTS LX-PCR of retinal mtDNAs revealed high levels of rearrangements in the patients with AMD and the control subjects, consistent with the decline in mitochondrial function with age. However, the AMD retinas had higher oxidized DNA levels and a higher number of SNPs than controls (P = 0.02). The control region SNPs T16126C and A73G, commonly found in haplogroups J and T, were more frequent in the AMD retinas than in normal retinas. The associations between AMD and haplogroups J and T were confirmed and extended by analysis of blood DNA. SNPs at position a T16126C (J; odds ratio [OR] = 3.66), T16126C+G13368A (JT; OR = 10.27), A4917G+A73G (T4; OR = 5), and T3197C+A12308G (U5; OR = infinity), were all strongly associated with AMD. CONCLUSIONS AMD retinas exhibited increased mtDNA control region SNPs compared to normal retinas. This correlated with an increased frequency of mtDNA SNPs associated with haplogroups J, T and U in patients with AMD. These results implicate mitochondrial alterations in the etiology of AMD.

Molecular and bioenergetic differences between cells with African versus European inherited mitochondrial DNA haplogroups: Implications for population susceptibility to diseases

The geographic origins of populations can be identified by their maternally inherited mitochondrial DNA (mtDNA) haplogroups. This study compared human cybrids (cytoplasmic hybrids), which are cell lines with identical nuclei but mitochondria from different individuals with mtDNA from either the H haplogroup or L haplogroup backgrounds. The most common European haplogroup is H while individuals of maternal African origin are of the L haplogroup. Despite lower mtDNA copy numbers, L cybrids had higher expression levels for nine mtDNA-encoded respiratory complex genes, decreased ATP (adenosine triphosphate) turnover rates and lower levels of reactive oxygen species production, parameters which are consistent with more efficient oxidative phosphorylation. Surprisingly, GeneChip arrays showed that the L and H cybrids had major differences in expression of genes of the canonical complement system (5 genes), dermatan/chondroitin sulfate biosynthesis (5 genes) and CCR3 (chemokine, CC motif, receptor 3) signaling (9 genes). Quantitative nuclear gene expression studies confirmed that L cybrids had (a) lower expression levels of complement pathway and innate immunity genes and (b) increased levels of inflammation-related signaling genes, which are critical in human diseases. Our data support the hypothesis that mtDNA haplogroups representing populations from different geographic origins may play a role in differential susceptibilities to diseases.

Mitochondrial DNA Variants Mediate Energy Production and Expression Levels for CFH, C3 and EFEMP1 Genes: Implications for Age-Related Macular Degeneration

Background Mitochondrial dysfunction is associated with the development and progression of age-related macular degeneration (AMD). Recent studies using populations from the United States and Australia have demonstrated that AMD is associated with mitochondrial (mt) DNA haplogroups (as defined by combinations of mtDNA polymorphisms) that represent Northern European Caucasians. The aim of this study was to use the cytoplasmic hybrid (cybrid) model to investigate the molecular and biological functional consequences that occur when comparing the mtDNA H haplogroup (protective for AMD) versus J haplogroup (high risk for AMD). Methodology/Principal Findings Cybrids were created by introducing mitochondria from individuals with either H or J haplogroups into a human retinal epithelial cell line (ARPE-19) that was devoid of mitochondrial DNA (Rho0). In cybrid lines, all of the cells carry the same nuclear genes but vary in mtDNA content. The J cybrids had significantly lower levels of ATP and reactive oxygen/nitrogen species production, but increased lactate levels and rates of growth. Q-PCR analyses showed J cybrids had decreased expressions for CFH, C3, and EFEMP1 genes, high risk genes for AMD, and higher expression for MYO7A, a gene associated with retinal degeneration in Usher type IB syndrome. The H and J cybrids also have comparatively altered expression of nuclear genes involved in pathways for cell signaling, inflammation, and metabolism. Conclusion/Significance Our findings demonstrate that mtDNA haplogroup variants mediate not only energy production and cell growth, but also cell signaling for major molecular pathways. These data support the hypothesis that mtDNA variants play important roles in numerous cellular functions and disease processes, including AMD.

Alu DNA polymorphism in ACE gene is protective for age-related macular degeneration.

Age-related macular degeneration (AMD) is the leading cause of blindness in the elderly. We report an association between an Alu polymorphism in the angiotensin-converting enzyme (ACE) gene with the dry/atrophic form of AMD. Using the polymerase chain reaction (PCR) on genomic DNA isolated from patients with AMD (n=173), and an age-matched control population (n=189), we amplified a region polymorphic for an Alu element insertion in the ACE gene. The Alu(+/+) genotype occurred 4.5 times more frequently in the control population than the dry/atrophic AMD patient population, (p=0.004). The predominance of the Alu(+/+) genotype within the unaffected control group represents a protective insertion with respect to the human ocular disease, dry/atrophic AMD. This is the first demonstration of an Alu element insertion exerting protective effects against a known human disease.

Characterization of Retinal and Blood Mitochondrial DNA from Age-Related Macular Degeneration Patients

PURPOSE To determine mitochondrial (mt)DNA variants in AMD and age-matched normal retinas. METHODS Total DNA was isolated from retinas (AMD, n = 13; age-matched normal, n = 13), choroid (AMD, n = 3), and blood (AMD, n = 138; normal, n = 133). Long-extension-polymerase chain reaction amplified the full-length ( approximately 16.2 kb) mtDNA genome. Retinal mtDNA was sequenced for nucleotide variants and length heteroplasmy. Pyrosequencing was performed on heteroplasmic mtDNA. PCR amplification and enzyme digestions were used to analyze for nucleotide changes. RESULTS Retinal mtDNA had a greater number of rearrangements and deletions than did blood mtDNA in normal samples (9.3 +/- 1.78 vs. 3 +/- 1.18, P = 0.019), and AMD samples (14.33 +/- 1.96 vs. 5.2 +/- 0.80, P = 0.0031. Five (55%) of 9 AMD patients had unreported SNPs, and 2 (16.6%) of 12 of the normal group did. The mtDNA coding region had 20 SNPs that produced amino acid changes. The noncoding MT-Dloop region had nucleotide heteroplasmy and length heteroplasmy. There were more SNPs per person in the AMD population than in the older (P = 0.003) and younger (P = 0.05) normal subjects. The C12557T (T-I) in the MT-ND5 gene was present in two AMD subjects (2/138) but was absent in the normal (0/133). Common mutations for Lebers hereditary optic neuropathy (LHON: G11778A; T14484C; and G3460A) were not present in AMD samples. CONCLUSIONS AMD subjects have high levels of large mtDNA deletions/rearrangements in the retinas, unreported and amino acid-changing SNPs in the coding genome, and a greater number of SNPs per person in the noncoding MT-Dloop region. These mtDNA variants could diminish energy production efficiency, alter the mtDNA copy numbers and/or impact transcription in AMD retinas.

Mitochondrial DNA haplogroups confer differences in risk for age-related macular degeneration: a case control study

BackgroundAge-related macular degeneration (AMD) is the leading cause of vision loss in elderly, Caucasian populations. There is strong evidence that mitochondrial dysfunction and oxidative stress play a role in the cell death found in AMD retinas. The purpose of this study was to examine the association of the Caucasian mitochondrial JTU haplogroup cluster with AMD. We also assessed for gender bias and additive risk with known high risk nuclear gene SNPs, ARMS2/LOC387715 (G > T; Ala69Ser, rs10490924) and CFH (T > C; Try402His, rs1061170).MethodsTotal DNA was isolated from 162 AMD subjects and 164 age-matched control subjects located in Los Angeles, California, USA. Polymerase chain reaction (PCR) and restriction enzyme digestion were used to identify the J, U, T, and H mitochondrial haplogroups and the ARMS2-rs10490924 and CFH-rs1061170 SNPs. PCR amplified products were sequenced to verify the nucleotide substitutions for the haplogroups and ARMS2 gene.ResultsThe JTU haplogroup cluster occurred in 34% (55/162) of AMD subjects versus 15% (24/164) of normal (OR = 2.99; p = 0.0001). This association was slightly greater in males (OR = 3.98, p = 0.005) than the female population (OR = 3.02, p = 0.001). Assuming a dominant effect, the risk alleles for the ARMS2 (rs10490924; p = 0.00001) and CFH (rs1061170; p = 0.027) SNPs were significantly associated with total AMD populations. We found there was no additive risk for the ARMS2 (rs10490924) or CFH (rs1061170) SNPs on the JTU haplogroup background.ConclusionsThere is a strong association of the JTU haplogroup cluster with AMD. In our Southern California population, the ARMS2 (rs10490924) and CFH (rs1061170) genes were significantly but independently associated with AMD. SNPs defining the JTU mitochondrial haplogroup cluster may change the retinal bioenergetics and play a significant role in the pathogenesis of AMD.

Insulin-like growth factor-I (IGF-I) and transforming growth factor-β (TGF-β) modulate tenascin-C and fibrillin-1 in bullous keratopathy stromal cells in vitro

Abstract Purpose. Pseudophakic bullous keratopathy (PBK) is a major indication for corneal transplantation. Previous studies showed that PBK corneas had increased levels of insulin-like growth factor-I (IGF-I), bone morphogenetic protein-4 (BMP-4), transforming growth factor-β (TGF-β), interleukin-1α (IL-1α) and IL-8. The PBK corneas also had accumulations of tenascin-C (TN-C), fibrillin-1 (Fib-1), matrix metalloproteinase-2 (MMP-2), inflammatory cells but not myofibroblasts. Our goal is to determine if the growth factors/cytokines that are elevated in PBK corneas alter the expression of extracellular matrix (ECM) and/or degradative enzymes in vitro. Methods. Stromal cell cultures from normal and PBK human corneas were established and treated for 6 days with IGF-I, BMP-4, IL-1α, IL-8 or TGF-β1/β2. Immunostaining, Western blot and dot blot analyses for TN-C, Fib-1, α-smooth muscle actin (α-SMA, a marker for myofibroblasts) or tissue inhibitor of metalloproteinase-1 (TIMP-1) were performed. RNAs were collected and analyzed with Northern blots for TN-C, Fib-1 and β2-microglobulin. Culture media were analyzed using gelatin zymography with or without ethylenediaminetetraacetic acid (EDTA). Some samples were activated with p-aminophenylmercuric acetate (APMA) and reduction/alkylation, and the degradative activities were measured by the MMP-gelatinase activity assay kit. Results. The IGF-I and TGF-β1/TGF-β2 increased (a) TN-C protein deposition, and (b) Fib-1 protein and RNA levels, but (c) had no significant affect on TIMP-1, matrix metalloproteinase-2 (MMP-2) or gelatinase activities. TGF-β1/TGF-β2 induced α-SMA protein (myofibroblasts) while IGF-I did not. BMP-4, IL-1α and IL-8 had little affect on the cells. Conclusions. Based upon our data, the fibrotic markers, TN-C and Fib-1, found in PBK corneas may be accounted for by IGF-I and TGF-β. These growth factors promote fibrosis and ECM deposition without promoting proteolysis. While the other growth factors/cytokines are elevated in PBK corneas, their role(s) in PBK pathogenesis are not clear. In addition, exogenous IGF-I most closely elicited a response that was most similar to the characteristics of the PBK/ABK corneas, i.e. accumulation of TN-C and Fib-1 proteins in the absence of myofibroblasts.

Increased retinal mtDNA damage in the CFH variant associated with age-related macular degeneration

Age-related macular degeneration (AMD) is a major cause of blindness among the elderly in the developed world. Genetic analysis of AMD has identified 34 high-risk loci associated with AMD. The genes at these high risk loci belong to diverse biological pathways, suggesting different mechanisms leading to AMD pathogenesis. Thus, therapies targeting a single pathway for all AMD patients will likely not be universally effective. Recent evidence suggests defects in mitochondria (mt) of the retinal pigment epithelium (RPE) may constitute a key pathogenic event in some AMD patients. The purpose of this study is to determine if individuals with a specific genetic background have a greater propensity for mtDNA damage. We used human eyebank tissues from 76 donors with AMD and 42 age-matched controls to determine the extent of mtDNA damage in the RPE that was harvested from the macula using a long extension polymerase chain reaction assay. Genotype analyses were performed for ten common AMD-associated nuclear risk alleles (ARMS2, TNFRSF10A, CFH, C2, C3, APOE, CETP, LIPC, VEGF and COL10A1) and mtDNA haplogroups. Sufficient samples were available for genotype association with mtDNA damage for TNFRSF10A, CFH, CETP, VEGFA, and COL10A1. Our results show that AMD donors carrying the high risk allele for CFH (C) had significantly more mtDNA damage compared with donors having the wild-type genetic profile. The data from an additional 39 donors (12 controls and 27 AMD) genotyped for CFH alleles further supported these findings. Taken together, these studies provide the rationale for a more personalized approach for treating AMD by uncovering a significant correlation between the CFH high risk allele and accelerated mtDNA damage. Patients harboring this genetic risk factor may benefit from therapies that stabilize and protect the mt in the RPE.

Human Retinal Transmitochondrial Cybrids with J or H mtDNA Haplogroups Respond Differently to Ultraviolet Radiation: Implications for Retinal Diseases

Background It has been recognized that cells do not respond equally to ultraviolet (UV) radiation but it is not clear whether this is due to genetic, biochemical or structural differences of the cells. We have a novel cybrid (cytoplasmic hybrids) model that allows us to analyze the contribution of mitochondrial DNA (mtDNA) to cellular response after exposure to sub-lethal dose of UV. mtDNA can be classified into haplogroups as defined by accumulations of specific single nucleotide polymorphisms (SNPs). Recent studies have shown that J haplogroup is high risk for age-related macular degeneration while the H haplogroup is protective. This study investigates gene expression responses in J cybrids versus H cybrids after exposure to sub-lethal doses of UV-radiation. Methodology/Principal Findings Cybrids were created by fusing platelets isolated from subjects with either H (n = 3) or J (n = 3) haplogroups with mitochondria-free (Rho0) ARPE-19 cells. The H and J cybrids were cultured for 24 hours, treated with 10 mJ of UV-radiation and cultured for an additional 120 hours. Untreated and treated cybrids were analyzed for growth rates and gene expression profiles. The UV-treated and untreated J cybrids had higher growth rates compared to H cybrids. Before treatment, J cybrids showed lower expression levels for CFH, CD55, IL-33, TGF-A, EFEMP-1, RARA, BCL2L13 and BBC3. At 120 hours after UV-treatment, the J cybrids had decreased CFH, RARA and BBC3 levels but increased CD55, IL-33 and EFEMP-1 compared to UV-treated H cybrids. Conclusion/Significance In cells with identical nuclei, the cellular response to sub-lethal UV-radiation is mediated in part by the mtDNA haplogroup. This supports the hypothesis that differences in growth rates and expression levels of complement, inflammation and apoptosis genes may result from population-specific, hereditary SNP variations in mtDNA. Therefore, when analyzing UV-induced damage in tissues, the mtDNA haplogroup background may be important to consider.

Role of STING complex in differential retrograde signaling in cybrids with K versus H haplogroup mtDNA

Mitochondrial (mt) DNA haplogroups, defined by specific single nucleotide polymorphism (SNPs) patterns, represent populations of diverse geographic origins and may play a role in disparate disease susceptibilities found in different ethnic/racial populations. The most common European haplogroup is H, while the K haplogroup is highly associated with Ashkenazi Jewish populations. Studies using transmitochondrial cybrids (cell lines with identical nuclei but mitochondria from either H or K haplogroup subjects) demonstrated significant molecular and biological differences but mechanisms for these disparities are unclear. In this study, we hypothesized that there is differential retrograde signaling occurring between the Stimulator of Interferon Genes (STING) pathway and H versus K mtDNA haplogroups. Results showed that K cybrids exhibit increased levels of cytoplasmic mtDNA fragments. After STING Knock-Down, H cybrids had lower expression levels for EGFR, BRCA1, DNMT3A, DNMT3B, HDAC1, and IFNα genes, but upregulated DNMT3A compared to control H cybrids. The STING-KD K cybrids showed downregulation of EGFR, DNMT3A, HDAC1, HCAD9, CFH, and CHI, along with upregulation of DNMT1 and IL-6 compared to control K cybrids. Since all cybrids have identical nuclei, the STING DNA sensor system interacts differently with K haplogroup mtDNA compared to H mtDNA for genes related to cancer (EGFR, BRCA1), methylation (DNMT1, DNMT3A, DNMT3B), acetylation (HDAC1, HDCA9), complement (CFH, CHI) and inflammation (IFNα, IL-6). In summary, in non-pathologic conditions, (a) STING is an important retrograde signaling mechanism(s) and (b) cybrids possessing Ashkenazi Jewish mtDNA (K haplogroup) interact with the STING complex differently compared to H cybrids which affects various disease-related pathways.