Cells adapted to high NaCl have many DNA breaks and impaired DNA repair both in cell culture and
            <i>in vivo</i>

Dmitrieva, Natalia I.; Cai, Qing-Qing; Burg, Maurice B.

doi:10.1073/pnas.0308463100

Cited by 109 publications

(144 citation statements)

References 35 publications

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“…40 Telomerase may therefore play a role in the repair of doublestrand breaks, which have been detected almost exclusively in renal papilla. 37 This nonhomologous end-joining repair pathway involves the DNA repair heterodimer Ku86/Ku70 in IMCD cells, 41 and in other systems Ku70 directly associates with telomerase providing a biochemical link between telomerase and IMCD cell DNA repair. 33,42 Further support for this hypothesis is the observation that the deacetylase Sirt1 is selectively expressed in the inner medulla and papilla, and it also is a positive regulator of telomere length, like telomerase.…”

Section: Basic Research Wwwjasnorgmentioning

confidence: 99%

“…36 IMCD cells expressed high levels of mTert mRNA at baseline, compared with renal cortex and papilla ( Figure 7A). Using a hypotonic shock DNA damage model, 37 we subjected IMCD cells that were acclimated to culture in media at 520 mOsm to media at 320 mOsm. This rapidly activated the DNA damage pathway, as indicated by phosphorylation of ATM kinase ( Figure 7B).…”

Section: Mtert Is Induced By Osmotic Shockmentioning

confidence: 99%

“…Some cells were adapted to high osmolarity medium using NaCl in stepwise fashion, exactly as described. 37 Osmotic shock was accomplished using pre-equilabrated medium. The cells were used within the first three passages.…”

Section: Cell Culturementioning

confidence: 99%

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Characterization and Fate of Telomerase-expressing Epithelia during Kidney Repair

Song

Czerniak

Wang

et al. 2011

Journal of the American Society of Nephrology

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After acute kidney injury, mice with short telomeres develop increased damage with reduced proliferative capacity, which suggests an important role for telomere length in kidney repair. The enzyme telomerase reverse transcriptase (mTert) regulates telomere length; embryonic stem cells and certain adult stem cells express mTert, but whether cells in the adult kidney express mTert and whether these cells play a role in renal repair are unknown. Here, we found that telomerase protein and mRNA were highly enriched in renal papilla, a proposed niche of kidney stem cells. Using mTert-GFP reporter mice, we detected mTert in a subset of papillary epithelial cells comprising the collecting duct predominantly but also the loop of Henle. Approximately 5% of mTert-GFP ϩ cells were label retaining, a characteristic of stem cells. mTert mRNA levels increased in renal papilla after ischemia-reperfusion injury, but genetically labeled mTert-expressing papillary cells neither divided nor migrated out of the renal papilla during kidney repair. In summary, these data suggest that cells expressing telomerase reverse transcriptase are not a progenitor-cell population, and they do not play a direct role in kidney repair.

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Section: Basic Research Wwwjasnorgmentioning

confidence: 99%

Section: Mtert Is Induced By Osmotic Shockmentioning

confidence: 99%

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Characterization and Fate of Telomerase-expressing Epithelia during Kidney Repair

Song

Czerniak

Wang

et al. 2011

Journal of the American Society of Nephrology

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“…This hyperosmotic cell cycle delay is likely a consequence of activation of DNA damage checkpoints because hyperosmolality causes multiple forms of DNA damage (13,15,17). However, whether any of the three Gadd45 isoforms plays a role in mediating hyperosmotic G 2 /M arrest remains unclear.…”

mentioning

confidence: 99%

“…Potential Gadd45 functions during environmental stress include promotion of cell cycle arrest, apoptosis, chromatin remodeling, and DNA repair (10). All of these cell functions are altered during hyperosmolality (1,(11)(12)(13)(14)(15). To assess the mechanistic relevance of hyperosmotic Gadd45 induction, it is necessary to determine which of these cell functions are altered as a result of increased levels of each of the three mammalian Gadd45 isoforms.…”

mentioning

confidence: 99%

Gadd45 Proteins Induce G2/M Arrest and Modulate Apoptosis in Kidney Cells Exposed to Hyperosmotic Stress

Mak

Kültz

2004

Journal of Biological Chemistry

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Gadd45 proteins are induced by hyperosmolality in renal inner medullary (IM) cells, but their role for cell adaptation to osmotic stress is not known. We show that a cell line derived from murine renal IM cells responds to moderate hyperosmotic stress (540 mosmol/kg) by activation of G 2 /M arrest without significant apoptosis. If the severity of hyperosmotic stress exceeds the tolerance limit of this cell line (620 mosmol/kg) apoptosis is strongly induced. Using transient overexpression of ectopic Gadd45 proteins and simultaneous analysis of transfected versus non-transfected cells by laser-scanning cytometry, we were able to measure the effects of Gadd45 super-induction during hyperosmolality on G 2 /M arrest and apoptosis. Our results demonstrate that induction of all three Gadd45 isoforms inhibits mitosis and promotes G 2 /M arrest during moderate hyperosmotic stress but not in isosmotic controls. Furthermore, all three Gadd45 proteins are also involved in control of apoptosis during severe hyperosmotic stress. Under these conditions Gadd45␥ induction strongly potentiates apoptosis. In contrast, Gadd45␣/␤ induction transiently increases caspase 3/7 and annexin V binding before 12 h but inhibits later stages of apoptosis during severe hyperosmolality. These results show that Gadd45 isoforms function in common but also in distinct pathways during hyperosmolality and that their increased abundance contributes to the low mitotic index and protection of genomic integrity in cells of the mammalian renal inner medulla.Cells of the mammalian renal inner medulla (IM) 1 are characterized by a stress-tolerant phenotype that enables them to resist extremes in multiple environmental variables, including osmolality. We have shown that these cells induce all three Gadd45 isoforms during hyperosmotic stress via posttranscriptional mechanisms (1, 2). Gadd45␣ was initially discovered based on its induction in hamster cells exposed to ionizing radiation stress (3). Gadd45␤ was cloned a few years later and initially described as myeloid differentiation immediate early gene MyD118 (4). More recently, GADD45␥ was described under different names, including GADD45␥ (5, 6), GRP17 (7), CR6 (8), and OIG37 (9).Despite their hyperosmotic induction, functional consequences of Gadd45 up-regulation in cells exposed to osmotic stress are unknown. Potential Gadd45 functions during environmental stress include promotion of cell cycle arrest, apoptosis, chromatin remodeling, and DNA repair (10). All of these cell functions are altered during hyperosmolality (1,(11)(12)(13)(14)(15). To assess the mechanistic relevance of hyperosmotic Gadd45 induction, it is necessary to determine which of these cell functions are altered as a result of increased levels of each of the three mammalian Gadd45 isoforms. The present study addresses the question of how super-induction of Gadd45␣, Gadd45␤, and Gadd45␥ during hyperosmotic stress affects cell proliferation and apoptosis.Renal IM cells exposed to hyperosmolality undergo growth arrest in G 2 phase of the ...

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Intracellular water homeostasis and the mammalian cellular osmotic stress response

2005

Journal Cellular Physiology

113

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The cellular response to osmotic stress ensures that the concentration of water inside the cell is maintained within a range that is compatible with biologic function. Single cell organisms are particularly dependent on mechanisms that permit adaptation to osmotic stress because each individual cell is directly exposed to the external environment. Mammals, however, limit osmotic stress by establishing an internal aqueous environment in which intravascular water and electrolytes are subject to sensitive and dynamic, organism-based homeostatic regulation. Recent studies of NFAT5/TonEBP, an essential mammalian osmoregulatory transcription factor, demonstrate the unexpected yet critical significance of cell-based osmotic regulation in vivo. These results highlight the fundamental importance of maintaining intracellular water homeostasis in the face of varying cellular metabolic activity and distinct tissue microenvironments.

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Cells adapted to high NaCl have many DNA breaks and impaired DNA repair both in cell culture and in vivo

Cited by 109 publications

References 35 publications

Characterization and Fate of Telomerase-expressing Epithelia during Kidney Repair

Characterization and Fate of Telomerase-expressing Epithelia during Kidney Repair

Gadd45 Proteins Induce G2/M Arrest and Modulate Apoptosis in Kidney Cells Exposed to Hyperosmotic Stress

Intracellular water homeostasis and the mammalian cellular osmotic stress response

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