Dr. Myriam E. Rodriguez Profile

Dr. Myriam E. Rodriguez

at Case Western Reserve Univ

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Author

Publications (6)

SPIE Journal Paper | 1 September 2010 Open Access

Binding to and photo-oxidation of cardiolipin by the phthalocyanine photosensitizer Pc 4

Myriam Rodriguez, Junhwan Kim, Grace Delos Santos, Kashif Azizuddin, Jeffrey Berlin, Vernon Anderson, Malcolm Kenney, Nancy Oleinick

JBO, Vol. 15, Issue 05, 051604, (September 2010) https://doi.org/10.1117/12.10.1117/1.3484256

KEYWORDS: Luminescence, Control systems, Photodynamic therapy, Cell death, Cancer, Confocal microscopy, Calcium, Oxygen, Flow cytometry, Oxidation

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Proceedings Article | 3 March 2010 Paper

Molecular factors in cell (and tumor) response to photodynamic therapy: the role of Bid

Song-mao Chiu, Liang-yan Xue, Minh Lam, Myriam Rodriguez, Ping Zhang, Malcolm Kenney, Anna-Liisa Nieminen, Nancy Oleinick

Proceedings Volume 7551, 755103 (2010) https://doi.org/10.1117/12.842523

KEYWORDS: Cell death, Photodynamic therapy, Cancer, Tumors, Breast cancer, Confocal microscopy, Luminescence, Oxygen, Silicon, Oncology

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Proceedings Article | 1 July 2009 Paper

Identifying initial molecular targets of PDT: protein and lipid oxidation products

Nancy Oleinick, Junhwan Kim, Myriam Rodriguez, Liang-yan Xue, Malcolm Kenney, Vernon Anderson

Proceedings Volume 7380, 738008 (2009) https://doi.org/10.1117/12.827051

KEYWORDS: Proteins, Photodynamic therapy, Oxygen, Cancer, Cell death, Tissues, Ions, Photosensitizer targeting, Heart, Oxidation

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Photodynamic Therapy (PDT) generates singlet oxygen (¹O₂) which oxidizes biomolecules in the immediate vicinity of its formation. The phthalocyanine photosensitizer Pc 4 localizes to mitochondria and endoplasmic reticulum, and the primary targets of Pc 4-PDT are expected to be lipids and proteins of those membranes. The initial damage then causes apoptosis in cancer cells via the release of cytochrome c (Cyt-c) from mitochondria into the cytosol, followed by the activation of caspases. That damage also triggers the induction of autophagy, an attempt by the cells to eliminate damaged organelles, or when damage is too extensive, to promote cell death. Cyt-c is bound to the cytosolic side of the mitochondrial inner membrane through association with cardiolipin (CL), a phospholipid containing four unsaturated fatty acids and thus easily oxidized by ¹O₂ or by other oxidizing agents. Increasing evidence suggests that oxidation of CL loosens its association with Cyt-c, and that the peroxidase activity of Cyt-c can oxidize CL. In earlier studies of Cyt-c in homogeneous medium by MALDI-TOF-MS and LC-ESI-MS, we showed that ¹O₂ generated by Pc 4-PDT oxidized histidine, methionine, tryptophan, and unexpectedly phenylalanine but not tyrosine. Most of the oxidation products were known to be formed by other oxidizing agents, such as hydroxyl radical, superoxide radical anion, and peroxynitrite. However, two products of histidine were unique to ¹O₂ and may be useful for reporting the action of ¹O₂ in cells and tissues. These products, as well as CL oxidation products, have now been identified in liposomes and mitochondria after Pc 4-PDT. In mitochondria, the PDT dose-dependent oxidations can be related to specific changes in mitochondrial function, Bcl-2 photodamage, and Cyt-c release. Thus, the role of PDT-generated ¹O₂ in oxidizing Cyt-c and CL and the interplay between protein and lipid targets may be highly relevant to understanding one mechanism for cell killing by PDT.

Proceedings Article | 11 February 2008 Paper

Lysosome vs. mitochondrion as photosensitizer binding site: how does the tortoise overtake the hare?

Nancy Oleinick, Kashif Azizuddin, Song-mao Chiu, Sheeba Joseph, Myriam Rodriguez, Liang-yan Xue, Ping Zhang, Malcolm Kenney, Minh Lam, Anna-Liisa Nieminen

Proceedings Volume 6845, 684505 (2008) https://doi.org/10.1117/12.769226

KEYWORDS: Photodynamic therapy, Cell death, Luminescence, Silicon, Flow cytometry, Proteins, Cancer, Confocal microscopy, Clinical trials, Polymers

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Proceedings Article | 11 February 2008 Paper

Protein oxidation by the phthalocyanine photosensitizer Pc 4 and light: detection of a unique singlet oxygen-generated product in cytochrome c

Myriam Rodriguez, Junhwan Kim, Malcolm Kenney, Nancy Oleinick, Vernon Anderson

Proceedings Volume 6845, 684507 (2008) https://doi.org/10.1117/12.763779

KEYWORDS: Proteins, Oxygen, Photodynamic therapy, Ions, Bioalcohols, Silicon, Spectroscopy, Oncology, Cancer, Oxidation

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Proceedings Article | 27 February 2007 Paper

Initial targets and cellular responses to PDT

Myriam Rodriguez, Kashif Azizuddin, Song-mao Chiu, Grace Delos Santos, Sheeba Joseph, Liang-yan Xue, Nancy Oleinick

Proceedings Volume 6427, 642703 (2007) https://doi.org/10.1117/12.717011

KEYWORDS: Cell death, Photodynamic therapy, Luminescence, Proteins, Cancer, Oxygen, Fluorescence resonance energy transfer, Electron microscopy, Medical research, Photosensitizer targeting

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Pc 4, a photosensitizer first synthesized at Case Western Reserve University and now in clinical trial at University Hospitals of Cleveland, has been shown to bind preferentially and with high affinity to mitochondrial and endoplasmic reticulum membranes. Upon photoirradiation of Pc 4-loaded cells, membrane components are photodamaged. In most cancer cells, apoptosis is triggered by the initial photodamage; however, in cells deficient in one of the critical intermediates of apoptosis, this process does not occur, although the cells remain as sensitive to the lethal effects of Pc 4-PDT as the apoptosis-competent cells, when cell death is determined by colony formation. Here we report that an alternative death process, autophagy, is induced in all cells tested and becomes the dominant pathway for elimination of lethally damaged cells when apoptosis is compromised. The anti-apoptotic protein Bcl-2, when overexpressed, protects only apoptosis-competent cells against loss of clonogenicity, while the autophagy inhibitor 3-methyladenine provides a markedly greater protection to apoptosis-deficient cells. The results suggest that the primary determinant of cell death is not the final pathway for elimination of the cells but the initial photodamage to critical membrane targets. In attempts to identify those targets, we have studied the role of different membrane phospholipids in the localization of Pc 4. Cardiolipin (CL) is a phospholipid found exclusively in the mitochondrial inner membrane and at the contact sites between the inner and outer membranes. Previous fluorescence resonance energy transfer studies revealed colocalization of Pc 4 and CL, which points to CL as a possible binding site and target for Pc 4. Unilamellar liposomes with different lipid compositions were used as membrane models to test the affinity of Pc 4. As revealed by the binding constants, Pc 4 does not display preferential binding to CL in these systems. Moreover, binding affinities appear to be independent of lipid composition. Localization of Pc 4 in mitochondrial membranes is likely determined by proteins or other factors not replicated in the liposomes. Studies in cells with modified CL content could report modified binding affinities.

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