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Dive into the research topics where Mariola Kulawiec is active.

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Featured researches published by Mariola Kulawiec.


Current Molecular Medicine | 2007

Mitochondria and Human Cancer

Josephine S. Modica-Napolitano; Mariola Kulawiec; Keshav K. Singh

The better part of a century has passed since Otto Warburg first hypothesized that unique phenotypic characteristics of tumor cells might be associated with an impairment in the respiratory capacity of these cells. Since then a number of distinct differences between the mitochondria of normal cells and cancer cells have been observed at the genetic, molecular, and biochemical levels. This article begins with a general overview of mitochondrial structure and function, and then outlines more specifically the metabolic and molecular alterations in mitochondria associated with human cancer and their clinical implications. Special emphasis is placed on mtDNA mutations and their potential role in carcinogenesis. The potential use of mitochondria as biomarkers for early detection of cancer, or as unique cellular targets for novel and selective anti-cancer agents is also discussed.


Cancer Biology & Therapy | 2005

Cross talk between mitochondria and superoxide generating NADPH oxidase in breast and ovarian tumors.

Mohamed Mokhtar Desouki; Mariola Kulawiec; Sanjay Bansal; Gokul Das; Keshav K. Singh

Reactive oxygen species (ROS) signal cascades involved in cell growth, cell death, mitogenesis, angiogenesis and carcinogenesis. ROS are produced as a byproduct of oxidative phosphorylation (OXPHOS) in the mitochondria. It is estimated that 2–4% of the oxygen consumed during OXPHOS is converted to ROS. Besides mitochondria, NADPH-oxidase 1 (Nox1) also generates a significant amount of ROS in the cell. In this paper, we tested the hypothesis that mitochondria control Nox 1 redox signaling and the loss of control of this signaling contributes to tumorigenesis. We analyzed Nox1 expression in a mitochondrial gene knockout (?0) cell line and in the isogenic cybrid cell line in which mitochondrial genes were restored by transfer of wild type mitochondria into ?0 cells. Our study revealed, for the first time, that the inactivation of mitochondrial genes leads to down-regulation of Nox1 and that the transfer of wild type mitochondrial genes restores the Nox1 expression to a level comparable to that in the parental cell line. Consistent with Nox1 down-regulation, we found that ?0 cells contained low levels of superoxide anion and that superoxide levels reversed to parental levels in cybrid cells when Nox1 expression was restored by transfer of wild type mitochondria. Increasing mitochondrial superoxide levels also increased the expression of Nox1 in parental cells. Confocal microscopy studies revealed that Nox1 localizes in the mitochondria. Nox1 was highly expressed in breast (86%) and ovarian (71%) tumors and that its expression positively correlated with expression of cytochrome C oxidase encoded by mtDNA. Our study, described in this paper demonstrates the existence of cross talk between the mitochondria and NADPH oxidase. Furthermore, our studies suggest that mitochondria control Nox1 redox signaling and the loss of control of this signaling contributes to breast and ovarian tumorigenesis.


Cancer Biology & Therapy | 2008

A novel role for mitochondria in regulating epigenetic modification in the nucleus.

Dominic J. Smiraglia; Mariola Kulawiec; Gaia Bistulfi; Sampa Ghoshal; Keshav K. Singh

Epigenetic modification in the nuclear genome plays a key role in human tumorigenesis. In this paper, we investigated whether changes in the mtDNA copy number frequently reported to vary in a number of human tumors induce methylation changes in the nucleus. We utilized the Restriction Landmark Genomic Scanning (RLGS) to identify genes that undergo changes in their methylation status in response to the depletion and repletion of mtDNA. Our study demonstrates that depletion of mtDNA results in significant changes in methylation pattern of a number of genes. Furthermore, our study suggests that methylation changes are reversed by the restoration of mtDNA in cells otherwise lacking the entire mitochondrial genome. These studies provide the first direct evidence that mitochondria regulate epigenetic modification in the nucleus that may contribute to tumorigenesis.


Journal of Carcinogenesis | 2009

p53 regulates mtDNA copy number and mitocheckpoint pathway.

Mariola Kulawiec; Vanniarajan Ayyasamy; Keshav K. Singh

Background: We previously hypothesized a role for mitochondria damage checkpoint (mito-checkpoint) in maintaining the mitochondrial integrity of cells. Consistent with this hypothesis, defects in mitochondria have been demonstrated to cause genetic and epigenetic changes in the nuclear DNA, resistance to cell-death and tumorigenesis. In this paper, we describe that defects in mitochondria arising from the inhibition of mitochondrial oxidative phosphorylation (mtOXPHOS) induce cell cycle arrest, a response similar to the DNA damage checkpoint response. Materials and Methods: Primary mouse embryonic fibroblasts obtained from p53 wild-type and p53-deficient mouse embryos (p53 -/-) were treated with inhibitors of electron transport chain and cell cycle analysis, ROS production, mitochondrial content analysis and immunoblotting was performed. The expression of p53R2 was also measured by real time quantitative PCR. Results: We determined that, while p53 +/+ cells arrest in the cell cycle, p53 -/- cells continued to divide after exposure to mitochondrial inhibitors, showing that p53 plays an important role in the S-phase delay in the cell cycle. p53 is translocated to mitochondria after mtOXPHOS inhibition. Our study also revealed that p53-dependent induction of reactive oxygen species acts as a major signal triggering a mito-checkpoint response. Furthermore our study revealed that loss of p53 results in down regulation of p53R2 that contributes to depletion of mtDNA in primary MEF cells. Conclusions: Our study suggests that p53 1) functions as mito-checkpoint protein and 2) regulates mtDNA copy number and mitochondrial biogenesis. We describe a conceptual organization of the mito-checkpoint pathway in which identified roles of p53 in mitochondria are incorporated.


Cancer Biology & Therapy | 2008

Tumorigenic transformation of human breast epithelial cells induced by mitochondrial DNA depletion

Mariola Kulawiec; Mohamed M. Desouki; Ivan H. Still; Sei-ichi Matsui; Andrei V. Bakin; Keshav K. Singh

Human mitochondrial DNA (mtDNA) encodes 13 proteins involved in oxidative phosphorylation (OXPHOS). In order to investigate the role of mitochondrial OXPHOS genes in breast tumorigenesis, we have developed a breast epithelial cell line devoid of mtDNA (ρ0 cells). Our analysis revealed that depletion of mtDNA in breast epithelial cells results in in vitro tumorigenic phenotype as well as breast tumorigenesis in a xenograft model. We identified two major gene networks which were differentially regulated between parental and ρ0 epithelial cells. The focal proteins in these networks include i) FN1 (fibronectin) and ii) p53. Bioinformatic analyses of FN1 network identified laminin, integrin and 5 of 6 members of peroxiredoxin whose expression were altered in ρ0 epithelial cells. In the p53 network, we identified SMC4 and WRN whose changes in expression suggest that this network may affect the chromosomal stability. Consistent with above finding our study revealed an increase DNA double strand breaks, and unique chromosomal rearrangements in ρ0 breast epithelial cells. Additionally, we identified tight junction proteins claudin-1 and claudin-7 in p53 network. To determine the functional relevance of altered gene expression, we focused on detailed analyses of claudin-1 and -7 proteins in breast tumorigenesis. Our study determined that i) claudin-1 and 7 were indeed down regulated in ρ0 breast epithelial cells, ii) down regulation of claudin-1 or -7 led to neoplastic transformation of breast epithelial cells, and iii) claudin-1 and -7 were also down regulated in primary breast tumors. Together, our study suggest that mtDNA encoded OXPHOS genes play a key role in transformation of breast epithelial cells and that multiple pathway involved in mitochondria-to-nucleus retrograde regulation contribute to transformation of breast epithelial cells


Cancer Biology & Therapy | 2009

Cancer cell mitochondria confer apoptosis resistance and promote metastasis.

Mariola Kulawiec; Kjerstin M. Owens; Keshav K. Singh

Mutations in mtDNA are found in most cancers. In this study, we studied the role of cancer cell mutant mtDNA in tumorigenesis. We sequenced the entire mitochondrial genome of three different breast cancer cell lines and found that all three, MCF7, MDA- MB-231 and MDA-MB-435, contained mutations in mtDNA. MDA-MB-435 cells contained mutation in tRNA Leu (CUN) gene known to be involved in pathogenesis of mitochondrial diseases. We generated a mutant cybrid (cytoplasmic hybrid) by repopulating the recipient ρ0 (completely devoid of mtDNA) cells with donor mtDNA derived from an enucleated MDA-MB-435 breast cancer cell line. An isogenic wild-type cybrid was produced by transfer of normal mtDNA from a healthy donor. When compared to the wild type, we found that mutant mtDNA increases mitochondrial membrane potential. However, increase in mitochondrial membrane potential was not associated with increase in reactive oxygen species (ROS) production. MtDNA mutations conferred resistance to apoptosis triggered by etoposide. Our study also revealed that mutations in mtDNA increase metastatic potential. Using a tail-vein model of metastatis in a mouse model, we show that the mutant cybrid metastatizes to the lungs and forms macrometastic foci. Additionally we found that mutations in mtDNA constitutively activate the PI3/Akt pathway that contributes to increased metastatis. Together our study demonstrates that mutant mtDNA promotes apoptotic resistance and metastasis in a mouse model.


Methods of Molecular Biology | 2009

Mitochondrial DNA Polymorphism and Risk of Cancer

Keshav K. Singh; Mariola Kulawiec

ATP (energy production) production is not the only function of the mitochondria. Mitochondria perform multiple cellular functions. Among others, these functions include control of cell death, growth, development, integration of signals from mitochondria to nucleus and nucleus to mitochondria, and various metabolic pathways. Although defects in mitochondrial function are most commonly associated with bioenergetic deficiencies, our studies demonstrate that mitochondrial defects lead to genome instability in the nuclear DNA, resistance to apoptosis and induction of NADPH oxidase, a designated producer of reactive oxygen species. These transformations in cellular phenotype are known contributors to the development of tumors in humans. Consistent with the role of mitochondria in carcinogenesis, studies in the past few years have described an increased risk of cancers associated with specific mitochondrial DNA (mtDNA) polymorphism among various different haplogroups in human population. However, molecular mechanisms underlying increased risk of cancer due to specific mtDNA polymorphisms is currently lacking. It is likely that mtDNA polymorphisms in mitochondrial genes involved in electron transport chain and oxidative phosphorylation result in increased oxidative stress and hypermutagenesis of mitochondrial as well as nuclear DNA. We suggest that in studies relating to cancer epidemiology, the significance of a particular mtDNA polymorphism(s) should be analyzed together with other polymorphisms in mtDNA and in nuclear DNA.


Journal of Human Genetics | 2009

mtDNA G10398A variant in African-American women with breast cancer provides resistance to apoptosis and promotes metastasis in mice

Mariola Kulawiec; Kjerstin M. Owens; Keshav K. Singh

We investigated the effect of the mitochondrial DNA (mtDNA) polymorphism G10398A found in African-American women with aggressive breast cancer on apoptosis and tumorigenesis. We generated human cytoplasmic hybrid (cybrid) by repopulation of recipient ρ0 cells (devoid of mtDNA) with donor mtDNA derived from patients with breast cancer harboring the G10398A polymorphism. We investigated a number of functional phenotypes of the G10398A cybrid. The G10398A cybrid showed a slower proliferation rate and progression through the cell cycle, as well as increased complex I activity, increased levels of reactive oxygen species and depolarized mitochondria. The G10398A cybrid also showed resistance to apoptosis triggered by etoposide. Resistance to apoptosis was mediated by Akt activation. In addition, our studies showed that the G10398A cybrid cells form an increased number of anchorage-independent colonies in vitro and metastases in mice. Together our studies suggest that the G10398A variant confers resistance to apoptosis and promotes metastasis.


Cancer Biology & Therapy | 2006

Proteomic analysis of proteins involved in mitochondria-to-nucleus retrograde response in human cancer cells

Mariola Kulawiec; Hilal Arnouk; Mohamed M. Desouki; Latif Kazim; Ivan H. Still; Keshav K. Singh

All tumors examined to date contain mutations in mitochondrial DNA (mtDNA). In addition, depletion of mtDNA is reported in a variety of tumors. Mitochondrial dysfunction resulting from changes in mtDNA invokes mitochondria-to-nucleus retrograde response in human cells. To identify proteins involved in retrograde response and their potential role in tumorigenesis, we carried out a comparative proteomic analysis using a cell line in which the mitochondrial genome was completely depleted (?0 cells lacking all mtDNA-encoded protein subunits), a cybrid cell line in which mtDNA was restored, and the parental cell line. Our comparative proteomic approach revealed marked changes in the cellular proteome and led us to identify quantitative changes in expression of several proteins. We found that subunits of complex I and complex III, molecular chaperones, and a protein involved in cell cycle control were down-regulated and Inosine 5’-monophosphate dehydrogenase type 2 (IMPDH2) involved in nucleotides biosynthesis was up-regulated in ?0 cells. Our findings demonstrate that the expression of proteins is restored to wild type level by transfer of wild type mitochondria to ?0 cells, suggesting that these proteins play key roles in retrograde response. To determine a potential role for identified retrograde responsive proteins in tumorigenesis, we analyzed the expression of UQCRC1 gene (encoding ubiquinol cytochrome-c reductase core protein I) in breast and ovarian tumors. We found that 1) UQCRC1 was highly expressed in breast (74%) and ovarian tumors (34%) and 2) the expression positively correlated with cytochrome c-oxidase (COXII) encoded by mtDNA. Our study opens an avenue for identification of retrograde proteins as potential tumor suppressors or oncogenes involved in carcinogenesis.


Journal of Cellular Biochemistry | 2010

Cellular Stress Induced by Resazurin Leads to Autophagy and Cell Death Via Production of Reactive Oxygen Species and Mitochondrial Impairment

Bjarte Skoe Erikstein; Hanne R. Hagland; Julie Nikolaisen; Mariola Kulawiec; Keshav K. Singh; Bjørn Tore Gjertsen; Karl Johan Tronstad

Mitochondrial bioenergetics and reactive oxygen species (ROS) often play important roles in cellular stress mechanisms. In this study we investigated how these factors are involved in the stress response triggered by resazurin (Alamar Blue) in cultured cancer cells. Resazurin is a redox reactive compound widely used as reporter agent in assays of cell biology (e.g. cell viability and metabolic activity) due to its colorimetric and fluorimetric properties. In order to investigate resazurin‐induced stress mechanisms we employed cells affording different metabolic and regulatory phenotypes. In HL‐60 and Jurkat leukemia cells resazurin caused mitochondrial disintegration, respiratory dysfunction, reduced proliferation, and cell death. These effects were preceded by a burst of ROS, especially in HL‐60 cells which were also more sensitive and contained autophagic vesicles. Studies in Rho0 cells (devoid of mitochondrial DNA) indicated that the stress response does not depend on the rates of mitochondrial respiration. The anti‐proliferative effect of resazurin was confirmed in native acute myelogenous leukemia (AML) blasts. In conclusion, the data suggest that resazurin triggers cellular ROS production and thereby initiates a stress response leading to mitochondrial dysfunction, reduced proliferation, autophagy, and cell degradation. The ability of cells to tolerate this type of stress may be important in toxicity and chemoresistance. J. Cell. Biochem. 111: 574–584, 2010.

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Keshav K. Singh

University of Alabama at Birmingham

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Ivan H. Still

Roswell Park Cancer Institute

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Mohamed Mokhtar Desouki

Medical University of South Carolina

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Kjerstin M. Owens

Roswell Park Cancer Institute

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Sei-ichi Matsui

Roswell Park Cancer Institute

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Gaia Bistulfi

Roswell Park Cancer Institute

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Sampa Ghoshal

Roswell Park Cancer Institute

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Vanniarajan Ayyasamy

Roswell Park Cancer Institute

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Brian Bigger

University of Manchester

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