Keiko Morotomi-Yano

Functional significance of the interaction with Ku in DNA double-strand break recognition of XLF.

XLF physically interacts with XRCC4 and Ku by anti tag coimmunoprecipitation (View interaction).

Nanosecond pulsed electric fields activate MAPK pathways in human cells

Application of nanosecond pulsed electric fields (nsPEFs) has attracted attention as a unique tool in life sciences, especially for cancer therapy, but the molecular mechanism of its action on living organisms is yet to be fully elucidated. Here, we report a transient activation of signaling pathways involving mitogen-activated protein kinases (MAPKs) by nsPEFs. Application of nsPEFs to HeLa S3 cells induced phosphorylation of MAPKs, including p38, JNK and ERK, and their upstream kinases. The application of nsPEFs also elicited elevated phosphorylation of downstream factors including MSK1, Hsp27, ATF2, p90RSK, and c-Jun. In addition, the application of nsPEFs led to the transcriptional activation of immediate early genes in the MAPK pathways. Treatment with inhibitors of the MAPK pathways suppressed nsPEF-induced protein phosphorylation and gene expression downstream of MAPKs, confirming the functional connection between the nsPEF-activated MAPKs and the observed induction of the downstream events. Taken together, these results provide important clues to the action of nsPEFs on human cells and demonstrate a new possibility for the utilization of nsPEFs in the control of various biological phenomena involving activation of the MAPK pathways.

Different involvement of extracellular calcium in two modes of cell death induced by nanosecond pulsed electric fields.

Exposure of cultured cells to nanosecond pulsed electric fields (nsPEFs) induces various cellular responses, including the influx of extracellular Ca2+ and cell death. Recently, nsPEFs have been regarded as a novel means of cancer therapy, but their molecular mechanism of action remains to be fully elucidated. Here, we demonstrate the involvement of extracellular Ca2+ in nsPEF-induced cell death. Extracellular Ca2+ was essential for necrosis and consequent poly(ADP-ribose) (PAR) formation in HeLa S3 cells. Treatment with a Ca2+ ionophore enhanced necrosis as well as PAR formation in nsPEF-exposed HeLa S3 cells. In the absence of extracellular Ca2+, HeLa S3 cells were less susceptible to nsPEFs and exhibited apoptotic proteolysis of caspase 3 and PARP-1. HeLa S3 cells retained the ability to undergo apoptosis even after nsPEF exposure but instead underwent necrosis, suggesting that necrosis is the preferential mode of cell death. In K562 and HEK293 cells, exposure to nsPEFs resulted in the formation of necrosis-associated PAR, whereas Jurkat cells exclusively underwent apoptosis independently of extracellular Ca2+. These observations demonstrate that the mode of cell death induced by nsPEFs is cell-type dependent and that extracellular Ca2+ is a critical factor for nsPEF-induced necrosis.

Nanosecond pulsed electric fields induce poly(ADP-ribose) formation and non-apoptotic cell death in HeLa S3 cells.

Nanosecond pulsed electric fields (nsPEFs) have recently gained attention as effective cancer therapy owing to their potency for cell death induction. Previous studies have shown that apoptosis is a predominant mode of nsPEF-induced cell death in several cell lines, such as Jurkat cells. In this study, we analyzed molecular mechanisms for cell death induced by nsPEFs. When nsPEFs were applied to Jurkat cells, apoptosis was readily induced. Next, we used HeLa S3 cells and analyzed apoptotic events. Contrary to our expectation, nsPEF-exposed HeLa S3 cells exhibited no molecular signs of apoptosis execution. Instead, nsPEFs induced the formation of poly(ADP-ribose) (PAR), a hallmark of necrosis. PAR formation occurred concurrently with a decrease in cell viability, supporting implications of nsPEF-induced PAR formation for cell death. Necrotic PAR formation is known to be catalyzed by poly(ADP-ribose) polymerase-1 (PARP-1), and PARP-1 in apoptotic cells is inactivated by caspase-mediated proteolysis. Consistently, we observed intact and cleaved forms of PARP-1 in nsPEF-exposed and UV-irradiated cells, respectively. Taken together, nsPEFs induce two distinct modes of cell death in a cell type-specific manner, and HeLa S3 cells show PAR-associated non-apoptotic cell death in response to nsPEFs.

Activation of the JNK pathway by nanosecond pulsed electric fields

Nanosecond pulsed electric fields (nsPEFs) are increasingly recognized as a novel and unique tool in various life science fields, including electroporation and cancer therapy, although their mode of action in cells remains largely unclear. Here, we show that nsPEFs induce strong and transient activation of a signaling pathway involving c-Jun N-terminal kinase (JNK). Application of nsPEFs to HeLa S3 cells rapidly induced phosphorylation of JNK1 and MKK4, which is located immediately upstream of JNK in this signaling pathway. nsPEF application also elicited increased phosphorylation of c-Jun protein and dramatically elevated c-jun and c-fos mRNA levels. nsPEF-inducible events downstream of JNK were markedly suppressed by the JNK inhibitor SP600125, which confirmed JNK-dependency of these events in this pathway. Our results provide novel mechanistic insights into the mode of nsPEF action in human cells.

Nanosecond pulsed electric fields act as a novel cellular stress that induces translational suppression accompanied by eIF2α phosphorylation and 4E-BP1 dephosphorylation.

Recent advances in electrical engineering enable the generation of ultrashort electric fields, namely nanosecond pulsed electric fields (nsPEFs). Contrary to conventional electric fields used for DNA electroporation, nsPEFs can directly reach intracellular components without membrane destruction. Although nsPEFs are now recognized as a unique tool in life sciences, the molecular mechanism of nsPEF action remains largely unclear. Here, we present evidence that nsPEFs act as a novel cellular stress. Exposure of HeLa S3 cells to nsPEFs quickly induced phosphorylation of eIF2α, activation of its upstream stress-responsive kinases, PERK and GCN2, and translational suppression. Experiments using PERK- and GCN2-knockout cells demonstrated dual contribution of PERK and GCN2 to nsPEF-induced eIF2α phosphorylation. Moreover, nsPEF exposure yielded the elevated GADD34 expression, which is known to downregulate the phosphorylated eIF2α. In addition, nsPEF exposure caused a rapid decrease in 4E-BP1 phosphorylation irrespective of the PERK/GCN2 status, suggesting participation of both eIF2α and 4E-BP1 in nsPEF-induced translational suppression. RT-PCR analysis of stress-inducible genes demonstrated that cellular responses to nsPEFs are distinct from those induced by previously known forms of cellular stress. These results provide new mechanistic insights into nsPEF action and implicate the therapeutic potential of nsPEFs for stress response-associated diseases.

Nanosecond pulsed electric fields activate AMP-activated protein kinase: Implications for calcium-mediated activation of cellular signaling

Nanosecond pulsed electric fields (nsPEFs) are increasingly being recognized as a potential tool for use in the life sciences. Exposure of human cells to nsPEFs elicits the formation of small membrane pores, intracellular Ca(2+) mobilization, signaling pathway activation, and apoptosis. Here we report the activation of AMP-activated protein kinase (AMPK) by nsPEFs. AMPK activation is generally achieved by the phosphorylation of AMPK in response to changes in cellular energy status and is mediated by two protein kinases, LKB1 and CaMKK. Exposure to nsPEFs rapidly induced phosphorylation of AMPK and its downstream target ACC in both LKB1-proficient and LKB1-deficient cells. In LKB1-deficient cells, AMPK activation by nsPEFs was mediated by CaMKK and required extracellular Ca(2+), which suggested the occurrence of Ca(2+) mobilization and its participation in AMPK activation by nsPEFs. Our results provide experimental evidence for a direct link between activated cellular signaling and Ca(2+) mobilization in nsPEF-exposed cells.

Cernunnos/XLF: A new player in DNA double-strand break repair

Non-homologous end-joining (NHEJ) is the predominant repair pathway for DNA double-strand breaks (DSBs) in vertebrates and also plays a crucial role in V(D)J recombination of immunoglobulin genes. Cernunnos/XLF is a newly identified core factor for NHEJ, and its defect causes a genetic disease characterized by neural disorders, immunodeficiency and increased radiosensitivity. Cernunnos/XLF has at least two distinct functions in NHEJ. Cernunnos/XLF interacts with and stimulates the XRCC4/DNA ligase IV complex, which acts at the final ligation step in NHEJ. In living cells, Cernunnos/XLF quickly responds to DSB induction and accumulates at damaged sites in a Ku-dependent but XRCC4-independent manner. These observations indicate that Cernunnos/XLF plays a unique role in bridging damage sensing and DSB rejoining steps of NHEJ. Recent crystallographic analyses of the homodimeric Cernunnos/XLF protein provide structural insights into the Cernunnos/XLF functions. These studies offer important clues toward understanding the molecular mechanism for NHEJ-defective diseases.

Nuclear extrusion precedes discharge of genomic DNA fibers during tunicamycin-induced neutrophil extracellular trap-osis (NETosis)-like cell death in cultured human leukemia cells.

We previously reported that the nucleoside antibiotic tunicamycin (TN), a protein glycosylation inhibitor triggering unfolded protein response (UPR), induced neutrophil extracellular trap‐osis (NETosis)‐like cellular suicide and, thus, discharged genomic DNA fibers to extracellular spaces in a range of human myeloid cell lines under serum‐free conditions. In this study, we further evaluated the effect of TN on human promyelocytic leukemia HL‐60 cells using time‐lapse microscopy. Our assay revealed a previously unappreciated early event induced by TN‐exposure, in which, at 30–60 min after TN addition, the cells extruded their nuclei into the extracellular space, followed by discharge of DNA fibers to form NET‐like structures. Intriguingly, neither nuclear extrusion nor DNA discharge was observed when cells were exposed to inducers of UPR, such as brefeldin A, thapsigargin, or dithiothreitol. Our findings revealed novel nuclear dynamics during TN‐induced NETosis‐like cellular suicide in HL‐60 cells and suggested that the toxicological effect of TN on nuclear extrusion and DNA discharge was not a simple UPR.

Dynamic behavior of DNA topoisomerase IIβ in response to DNA double-strand breaks

DNA topoisomerase II (Topo II) is crucial for resolving topological problems of DNA and plays important roles in various cellular processes, such as replication, transcription, and chromosome segregation. Although DNA topology problems may also occur during DNA repair, the possible involvement of Topo II in this process remains to be fully investigated. Here, we show the dynamic behavior of human Topo IIβ in response to DNA double-strand breaks (DSBs), which is the most harmful form of DNA damage. Live cell imaging coupled with site-directed DSB induction by laser microirradiation demonstrated rapid recruitment of EGFP-tagged Topo IIβ to the DSB site. Detergent extraction followed by immunofluorescence showed the tight association of endogenous Topo IIβ with DSB sites. Photobleaching analysis revealed that Topo IIβ is highly mobile in the nucleus. The Topo II catalytic inhibitors ICRF-187 and ICRF-193 reduced the Topo IIβ mobility and thereby prevented Topo IIβ recruitment to DSBs. Furthermore, Topo IIβ knockout cells exhibited increased sensitivity to bleomycin and decreased DSB repair mediated by homologous recombination (HR), implicating the role of Topo IIβ in HR-mediated DSB repair. Taken together, these results highlight a novel aspect of Topo IIβ functions in the cellular response to DSBs.