Your search keyword '"Olga N. Pakhomova"' showing total 7 results

1. Dose-dependent thresholds of 10-ns electric pulse induced plasma membrane disruption and cytotoxicity in multiple cell lines.

Author

Bennett L Ibey, Caleb C Roth, Andrei G Pakhomov, Joshua A Bernhard, Gerald J Wilmink, and Olga N Pakhomova

Subjects

Medicine, Science

Abstract

In this study, we determined the LD(50) (50% lethal dose) for cell death, and the ED(50) (50% of cell population staining positive) for propidium (Pr) iodide uptake, and phosphatidylserine (PS) externalization for several commonly studied cell lines (HeLa, Jurkat, U937, CHO-K1, and GH3) exposed to 10-ns electric pulses (EP). We found that the LD(50) varied substantially across the cell lines studied, increasing from 51 J/g for Jurkat to 1861 J/g for HeLa. PS externalized at doses equal or lower than that required for death in all cell lines ranging from 51 J/g in Jurkat, to 199 J/g in CHO-K1. Pr uptake occurred at doses lower than required for death in three of the cell lines: 656 J/g for CHO-K1, 634 J/g for HeLa, and 142 J/g for GH3. Both Jurkat and U937 had a LD(50) lower than the ED(50) for Pr uptake at 780 J/g and 1274 J/g, respectively. The mechanism responsible for these differences was explored by evaluating cell size, calcium concentration in the exposure medium, and effect of trypsin treatment prior to exposure. None of the studied parameters correlated with the observed results suggesting that cellular susceptibility to injury and death by 10-ns EP was largely determined by cell physiology. In contrast to previous studies, our findings suggest that permeabilization of internal membranes may not necessarily be responsible for cell death by 10-ns EP. Additionally, a mixture of Jurkat and HeLa cells was exposed to 10-ns EP at a dose of 280 J/g. Death was observed only in Jurkat cells suggesting that 10-ns EP may selectively kill cells within a heterogeneous tissue.

Published

2011

2. Nanosecond pulsed electric signals can affect electrostatic environment of proteins below the threshold of conformational effects: The case study of SOD1 with a molecular simulation study

Author

Micaela Liberti, Francesca Apollonio, Olga N. Pakhomova, Paolo Marracino, and Elena della Valle

Subjects

Protein Structure, Materials science, Protein Conformation, Science, Static Electricity, Molecular Dynamics Simulation, Dipole Moments, 01 natural sciences, Biochemistry, 03 medical and health sciences, Molecular dynamics, Protein structure, Superoxide Dismutase-1, Electromagnetism, Electricity, Electrostatics, Electric field, Catalytic Domain, 0103 physical sciences, Static electricity, Macromolecular Structure Analysis, Biochemical Simulations, Molecular Biology, 030304 developmental biology, 0303 health sciences, Multidisciplinary, 010304 chemical physics, Superoxide Dismutase, Physics, Water, Biology and Life Sciences, Proteins, Computational Biology, Nanosecond, Enzyme structure, Enzymes, Dipole, Dismutases, Electric Field, Chemical physics, Physical Sciences, Enzyme Structure, Enzymology, Medicine, Protein Multimerization, Research Article

Abstract

Electric fields can be a powerful tool to interact with enzymes or proteins, with an intriguing perspective to allow protein manipulation. Recently, researchers have focused the interest on intracellular enzyme modifications triggered by the application of nanosecond pulsed electric fields. These findings were also supported by theoretical predictions from molecular dynamics simulations focussing on significant variations in protein secondary structures. In this work, a theoretical study utilizing molecular dynamics simulations is proposed to explore effects of electric fields of high intensity and very short nanosecond duration applied to the superoxide dismutase (Cu/Zn-SOD or SOD-1), an important enzyme involved in the cellular antioxidant defence mechanism. The effects of 100-nanosecond pulsed electric fields, with intensities ranging from 108 to 7x108 V/m, on a single SOD1 enzyme are presented. We demonstrated that the lowest intensity of 108 V/m, although not inducing structural changes, can produce electrostatic modifications on the reaction centre of the enzyme, as apparent from the dipolar response and the electric field distribution of the protein active site. Electric pulses above 5x108 V/m produced a fast transition between the folded and a partially denatured state, as inferred by the secondary structures analysis. Finally, for the highest field intensity used (7x108 V/m), a not reversible transition toward an unfolded state was observed.

Published

2019

3. Two modes of cell death caused by exposure to nanosecond pulsed electric field

Author

Olga N. Pakhomova, Andrei G. Pakhomov, Betsy Gregory, and Iurii Semenov

Subjects

Sucrose, Necrosis, Medical Physics, Cell, Cell Pores, Cancer Treatment, lcsh:Medicine, Apoptosis, Electrical Discharges, Cell membrane, chemistry.chemical_compound, 0302 clinical medicine, Electricity, Molecular Cell Biology, lcsh:Science, Skin Tumors, Image Cytometry, Cellular Stress Responses, 0303 health sciences, Multidisciplinary, Cell Death, Malignant Melanoma, Physics, U937 Cells, Gene Therapy, Cellular Structures, Cell biology, medicine.anatomical_structure, Oncology, Electric Field, 030220 oncology & carcinogenesis, Medicine, medicine.symptom, Poly(ADP-ribose) Polymerases, Research Article, Programmed cell death, Cell Survival, Poly ADP ribose polymerase, Immunoblotting, Biology, Cell Growth, 03 medical and health sciences, Complementary and Alternative Medicine, medicine, Humans, Propidium iodide, Squamous Cell Carcinoma, Fragmentation (cell biology), 030304 developmental biology, Cell Membrane, lcsh:R, Cancers and Neoplasms, Electrochemical Techniques, Chemotherapy and Drug Treatment, chemistry, lcsh:Q, Cytometry

Abstract

High-amplitude electric pulses of nanosecond duration, also known as nanosecond pulsed electric field (nsPEF), are a novel modality with promising applications for cell stimulation and tissue ablation. However, key mechanisms responsible for the cytotoxicity of nsPEF have not been established. We show that the principal cause of cell death induced by 60- or 300-ns pulses in U937 cells is the loss of the plasma membrane integrity (“nanoelectroporation”), leading to water uptake, cell swelling, and eventual membrane rupture. Most of this early necrotic death occurs within 1–2 hr after nsPEF exposure. The uptake of water is driven by the presence of pore-impermeable solutes inside the cell, and can be counterbalanced by the presence of a pore-impermeable solute such as sucrose in the medium. Sucrose blocks swelling and prevents the early necrotic death; however the long-term cell survival (24 and 48 hr) does not significantly change. Cells protected with sucrose demonstrate higher incidence of the delayed death (6–24 hr post nsPEF). These cells are more often positive for the uptake of an early apoptotic marker dye YO-PRO-1 while remaining impermeable to propidium iodide. Instead of swelling, these cells often develop apoptotic fragmentation of the cytoplasm. Caspase 3/7 activity increases already in 1 hr after nsPEF and poly-ADP ribose polymerase (PARP) cleavage is detected in 2 hr. Staurosporin-treated positive control cells develop these apoptotic signs only in 3 and 4 hr, respectively. We conclude that nsPEF exposure triggers both necrotic and apoptotic pathways. The early necrotic death prevails under standard cell culture conditions, but cells rescued from the necrosis nonetheless die later on by apoptosis. The balance between the two modes of cell death can be controlled by enabling or blocking cell swelling.

Published

2013

4. Cell Electrosensitization Exists Only in Certain Electroporation Buffers

Author

Andrei G. Pakhomov, Janja Dermol, Olga N. Pakhomova, and Damijan Miklavčič

Subjects

0301 basic medicine, Sucrose, Electrochemotherapy, Fluorescence-lifetime imaging microscopy, Cell Membranes, Cell, lcsh:Medicine, Disaccharides, Mechanical Treatment of Specimens, 0302 clinical medicine, Electricity, lcsh:Science, Cell Disruption, Cytoskeleton, Internal Ribosome Entry Site, Sensitization, Multidisciplinary, Organic Compounds, Chemistry, Physics, Electroporation, Irreversible electroporation, medicine.anatomical_structure, Specimen Disruption, Electric Field, Delayed hypersensitivity, 030220 oncology & carcinogenesis, Physical Sciences, Cell disruption, Cellular Structures and Organelles, Algorithms, Research Article, Imaging Techniques, Carbohydrates, Buffers, Research and Analysis Methods, Microbiology, Models, Biological, Cell Line, 03 medical and health sciences, Virology, Fluorescence Imaging, medicine, Animals, Humans, lcsh:R, Organic Chemistry, Chemical Compounds, Biology and Life Sciences, Cell Biology, Viral Replication, Electrophysiological Phenomena, 030104 developmental biology, Specimen Preparation and Treatment, Biophysics, lcsh:Q

Abstract

Electroporation-induced cell sensitization was described as the occurrence of a delayed hypersensitivity to electric pulses caused by pretreating cells with electric pulses. It was achieved by increasing the duration of the electroporation treatment at the same cumulative energy input. It could be exploited in electroporation-based treatments such as electrochemotherapy and tissue ablation with irreversible electroporation. The mechanisms responsible for cell sensitization, however, have not yet been identified. We investigated cell sensitization dynamics in five different electroporation buffers. We split a pulse train into two trains varying the delay between them and measured the propidium uptake by fluorescence microscopy. By fitting the first-order model to the experimental results, we determined the uptake due to each train (i.e. the first and the second) and the corresponding resealing constant. Cell sensitization was observed in the growth medium but not in other tested buffers. The effect of pulse repetition frequency, cell size change, cytoskeleton disruption and calcium influx do not adequately explain cell sensitization. Based on our results, we can conclude that cell sensitization is a sum of several processes and is buffer dependent. Further research is needed to determine its generality and to identify underlying mechanisms.

Published

2016

5. Dose-dependent thresholds of 10-ns electric pulse induced plasma membrane disruption and cytotoxicity in multiple cell lines

Author

Caleb C. Roth, Andrei G. Pakhomov, Olga N. Pakhomova, Joshua A. Bernhard, Bennett L. Ibey, and Gerald J. Wilmink

Subjects

Time Factors, Light, Radio Waves, lcsh:Medicine, Jurkat cells, Cell membrane, HeLa, Jurkat Cells, 0302 clinical medicine, Engineering, Electricity, Cricetinae, Scattering, Radiation, Trypsin, Annexin A5, lcsh:Science, 0303 health sciences, education.field_of_study, Multidisciplinary, Microscopy, Confocal, biology, Cell Death, Physics, Electromagnetic Radiation, Radiation Exposure, Flow Cytometry, Phospholipid translocation, Cell biology, medicine.anatomical_structure, 030220 oncology & carcinogenesis, Fluorescein-5-isothiocyanate, Research Article, Cell Survival, Radiation Biophysics, Population, Biophysics, Biomedical Engineering, Bioengineering, CHO Cells, Phosphatidylserines, 03 medical and health sciences, Cricetulus, medicine, Animals, Humans, Microwave Radiation, education, Biology, 030304 developmental biology, Cell Size, Lethal dose, Cell Membrane, lcsh:R, biology.organism_classification, Molecular biology, Electric Stimulation, Rats, Radiation Effects, Microscopy, Fluorescence, Apoptosis, Cell culture, Calcium, lcsh:Q, Extracellular Space, HeLa Cells

Abstract

In this study, we determined the LD(50) (50% lethal dose) for cell death, and the ED(50) (50% of cell population staining positive) for propidium (Pr) iodide uptake, and phosphatidylserine (PS) externalization for several commonly studied cell lines (HeLa, Jurkat, U937, CHO-K1, and GH3) exposed to 10-ns electric pulses (EP). We found that the LD(50) varied substantially across the cell lines studied, increasing from 51 J/g for Jurkat to 1861 J/g for HeLa. PS externalized at doses equal or lower than that required for death in all cell lines ranging from 51 J/g in Jurkat, to 199 J/g in CHO-K1. Pr uptake occurred at doses lower than required for death in three of the cell lines: 656 J/g for CHO-K1, 634 J/g for HeLa, and 142 J/g for GH3. Both Jurkat and U937 had a LD(50) lower than the ED(50) for Pr uptake at 780 J/g and 1274 J/g, respectively. The mechanism responsible for these differences was explored by evaluating cell size, calcium concentration in the exposure medium, and effect of trypsin treatment prior to exposure. None of the studied parameters correlated with the observed results suggesting that cellular susceptibility to injury and death by 10-ns EP was largely determined by cell physiology. In contrast to previous studies, our findings suggest that permeabilization of internal membranes may not necessarily be responsible for cell death by 10-ns EP. Additionally, a mixture of Jurkat and HeLa cells was exposed to 10-ns EP at a dose of 280 J/g. Death was observed only in Jurkat cells suggesting that 10-ns EP may selectively kill cells within a heterogeneous tissue.

Published

2011

6. Electroporation-Induced Electrosensitization

Author

Olga N. Pakhomova, Betsy W. Gregory, Vera A. Khorokhorina, Angela M. Bowman, Shu Xiao, and Andrei G. Pakhomov

Subjects

Anatomy and Physiology, Time Factors, lcsh:Medicine, Biochemistry, Cytopathology, 0302 clinical medicine, Electricity, Molecular Cell Biology, Pathology, lcsh:Science, 0303 health sciences, Membrane permeabilization, Multidisciplinary, Cell Death, Physics, Electroporation, 3. Good health, Electrophysiology, 030220 oncology & carcinogenesis, Electrode, Cytochemistry, Medicine, Optoelectronics, Membranes and Sorting, Research Article, Biotechnology, Propidium, Cell Physiology, Materials science, Cell Survival, Biophysics, Cell Line, 03 medical and health sciences, Diagnostic Medicine, Humans, Biology, Cell survival, 030304 developmental biology, business.industry, Extramural, Cell Membrane, lcsh:R, Dye exclusion, Biological Transport, Molecular biology, Anatomical Pathology, lcsh:Q, business, Membrane Characteristics, Membrane Composition

Abstract

Background Electroporation is a method of disrupting the integrity of cell membrane by electric pulses (EPs). Electrical modeling is widely employed to explain and study electroporation, but even most advanced models show limited predictive power. No studies have accounted for the biological consequences of electroporation as a factor that alters the cell's susceptibility to forthcoming EPs. Methodology/Principal Findings We focused first on the role of EP rate for membrane permeabilization and lethal effects in mammalian cells. The rate was varied from 0.001 to 2,000 Hz while keeping other parameters constant (2 to 3,750 pulses of 60-ns to 9-µs duration, 1.8 to 13.3 kV/cm). The efficiency of all EP treatments was minimal at high rates and started to increase gradually when the rate decreased below a certain value. Although this value ranged widely (0.1–500 Hz), it always corresponded to the overall treatment duration near 10 s. We further found that longer exposures were more efficient irrespective of the EP rate, and that splitting a high-rate EP train in two fractions with 1–5 min delay enhanced the effects severalfold. Conclusions/Significance For varied experimental conditions, EPs triggered a delayed and gradual sensitization to EPs. When a portion of a multi-pulse exposure was delivered to already sensitized cells, the overall effect markedly increased. Because of the sensitization, the lethality in EP-treated cells could be increased from 0 to 90% simply by increasing the exposure duration, or the exposure dose could be reduced twofold without reducing the effect. Many applications of electroporation can benefit from accounting for sensitization, by organizing the exposure either to maximize sensitization (e.g., for sterilization) or, for other applications, to completely or partially avoid it. In particular, harmful side effects of electroporation-based therapies (electrochemotherapy, gene therapies, tumor ablation) include convulsions, pain, heart fibrillation, and thermal damage. Sensitization can potentially be employed to reduce these side effects while preserving or increasing therapeutic efficiency.

Published

2011

7. Cell Electrosensitization Exists Only in Certain Electroporation Buffers.

Author

Janja Dermol, Olga N Pakhomova, Andrei G Pakhomov, and Damijan Miklavčič

Subjects

Medicine, Science

Abstract

Electroporation-induced cell sensitization was described as the occurrence of a delayed hypersensitivity to electric pulses caused by pretreating cells with electric pulses. It was achieved by increasing the duration of the electroporation treatment at the same cumulative energy input. It could be exploited in electroporation-based treatments such as electrochemotherapy and tissue ablation with irreversible electroporation. The mechanisms responsible for cell sensitization, however, have not yet been identified. We investigated cell sensitization dynamics in five different electroporation buffers. We split a pulse train into two trains varying the delay between them and measured the propidium uptake by fluorescence microscopy. By fitting the first-order model to the experimental results, we determined the uptake due to each train (i.e. the first and the second) and the corresponding resealing constant. Cell sensitization was observed in the growth medium but not in other tested buffers. The effect of pulse repetition frequency, cell size change, cytoskeleton disruption and calcium influx do not adequately explain cell sensitization. Based on our results, we can conclude that cell sensitization is a sum of several processes and is buffer dependent. Further research is needed to determine its generality and to identify underlying mechanisms.

Published

2016