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1 the second messengers in plant responses to hyperosmotic stress.
2 of SPAK to increase activity of NKCC1 during hyperosmotic stress.
3 g the response of mature collecting ducts to hyperosmotic stress.
4 the mechanism by which WNK1 is regulated by hyperosmotic stress.
5 he internal K+ concentration as a measure of hyperosmotic stress.
6 t are rapidly and transiently induced during hyperosmotic stress.
7 nifest by subsequent apoptosis, to sustained hyperosmotic stress.
8 on of ERK1/2 and p38MAPalpha/beta kinases by hyperosmotic stress.
9 ot prevent FAK phosphorylation stimulated by hyperosmotic stress.
10 volved in control of apoptosis during severe hyperosmotic stress.
11 le of RBOH-dependent ROS, specifically under hyperosmotic stress.
12 the response partially overlaps with that to hyperosmotic stress.
13 and tyrosine phosphorylation in response to hyperosmotic stress.
14 ng that Orb6p has a role in cell response to hyperosmotic stress.
15 uited to this PKN1-positive compartment upon hyperosmotic stress.
16 ally expressed in response to dehydration or hyperosmotic stress.
17 manner to a vesicular compartment following hyperosmotic stress.
18 nd, is required for short-term adaptation to hyperosmotic stress.
19 by hypoosmotic stress, but were unchanged by hyperosmotic stress.
20 pensatory genes in response to extracellular hyperosmotic stress.
21 th of proline-overaccumulating cells in mild hyperosmotic stress.
22 tivation mechanism fail to proliferate after hyperosmotic stress.
23 ine stresses, whereas levels increased after hyperosmotic stress.
24 cell growth and polarity under conditions of hyperosmotic stress.
25 nthesize phosphoinositides during periods of hyperosmotic stress.
26 pathway that may lead to plant adaptation to hyperosmotic stress.
27 mponent of the p38 MAPK-mediated response to hyperosmotic stress.
28 igated the role of p53 in mIMCD3 response to hyperosmotic stress.
29 ulons closely co-operate in the managment of hyperosmotic stress.
30 ctivated protein (MAP) kinase in response to hyperosmotic stress.
31 s environmental stress conditions, including hyperosmotic stress.
32 hanisms for regulation of gene expression by hyperosmotic stress.
33 ullary cells are uniquely exposed to extreme hyperosmotic stress.
34 ined when the HeLa cells are challenged with hyperosmotic stress.
35 ation of Xenopus p38 isoforms in response to hyperosmotic stress.
36 e rapid synthesis of glycerol in response to hyperosmotic stress.
37 d widespread transcriptional repression upon hyperosmotic stress.
38 om adaptation to inflammation in response to hyperosmotic stress.
39 at human cells survive gradual but not acute hyperosmotic stress.
40 -2 targets DNMBP to P-body condensates under hyperosmotic stress.
41 nitudes after preexposure to an intermediate hyperosmotic stress.
42 nd indirect targets of SchA post-exposure to hyperosmotic stress.
43 ptible to DNA (de)methylation in response to hyperosmotic stress.
44 1 (SOD1) and peroxiredoxin-4 (PRDX4) during hyperosmotic stress.
45 duced cytosolic Ca(2+) signal in response to hyperosmotic stress.
46 creased sensitivities to SDS, Congo red, and hyperosmotic stress.
47 ol accumulation, and enhanced survival under hyperosmotic stress.
48 lling, but does not affect MAPK responses to hyperosmotic stress.
49 serve interphase microtubules in response to hyperosmotic stress.
50 kinase II (CK2) in the cellular response to hyperosmotic stress.
51 ces a transcriptional program in response to hyperosmotic stress.
52 ich decrease under proline limitation and/or hyperosmotic stress.
53 d to maintain interphase microtubules during hyperosmotic stress.
54 its importance for the cellular response to hyperosmotic stress.
55 ch becomes negative as they recover from the hyperosmotic stress.
56 ive of the in vivo changes that occur during hyperosmotic stress.
57 onal up-regulation is necessary to cope with hyperosmotic stress.
58 l microtubules in plant cells that are under hyperosmotic stresses.
59 es plant response to abscisic acid (ABA) and hyperosmotic stresses.
60 m murine renal IM cells responds to moderate hyperosmotic stress (540 mosmol/kg) by activation of G(2
63 Our results for the first time reveal that hyperosmotic stress-activated Plk3 elicited gammaH2AX.
65 eased dissolved solute in their environment (hyperosmotic stress), all eukaryotic cells respond by ra
68 ts were unable to accumulate ABA following a hyperosmotic stress, although their basal ABA level was
69 inase Pho85/CDK5 provides protection against hyperosmotic stress and acts before long-term adaptation
70 preferentially to OSTF1 target genes during hyperosmotic stress and compensate for reduced rates of
71 lock allows anticipation and preparation for hyperosmotic stress and desiccation that begin at sunris
72 s) phase-separates in mammalian cells during hyperosmotic stress and dissolves upon isosmotic rescue
73 maintaining bacterial cell viability during hyperosmotic stress and functions by co-transporting bet
74 ranscriptional response when fluctuations of hyperosmotic stress and glucose deprivation occurred in
75 ocation, Hrp1p redistribution is specific to hyperosmotic stress and is only reversed after stress re
76 growth (FG) pathways are activated following hyperosmotic stress and nutrient deprivation, respective
77 o rapamycin, high concentrations of calcium, hyperosmotic stress and SchA was involved in iron metabo
78 udy budding yeast in dynamic environments of hyperosmotic stress and show how the corresponding signa
79 ated tiRNAs and cell survival in response to hyperosmotic stress and suggest a novel cellular complex
80 AMPK in H-2Kb cells is also activated by hyperosmotic stress and the mitochondrial uncoupling age
81 otect cells from excessive Na(+) loading and hyperosmotic stress and to protect the animal from hyper
82 ular crowding, we reduced the cell volume by hyperosmotic stress and used an IDP as a crowding sensor
83 lpha3 positively mediates plant responses to hyperosmotic stresses and that increased PLDalpha3 expre
84 efect in fibroblasts, less responsiveness to hyperosmotic stress, and reduced persistence in tissues
85 a fundamental role in protecting cells from hyperosmotic stress, and that the pathway(s) that mediat
86 T cells under oxidative stress but not under hyperosmotic stress, and they were high and unchanging i
87 une cell function and cellular adaptation to hyperosmotic stress, as a possible cause of this syndrom
88 tion of 40-kD protein kinase is specific for hyperosmotic stress, as hypotonic stress does not activa
91 ction of promoter-proximal termination under hyperosmotic stress, but paused transcripts from TATA bo
92 bcellular compartments that protects against hyperosmotic stress by generating osmolytes and metaboli
93 rst time that human ALDH7A1 protects against hyperosmotic stress by generating osmolytes and metaboli
94 ned the hypothesis that IVD cells respond to hyperosmotic stress by increasing the concentration of i
96 Our results for the first time reveal that hyperosmotic stress can activate the Plk3 signaling path
97 ion difference of the samples in response to hyperosmotic stress can potentially provide us with a un
99 ogic implication of osmotic imbalance (i.e., hyperosmotic stress caused by intracellular over-accumul
104 y and pulsed field gel electrophoresis, that hyperosmotic stress causes DNA damage in the form of dou
107 liquid-liquid phase separation (LLPS) under hyperosmotic stress conditions allows cells to react to
108 snrk2.1/2/3/4/5/6/7/8/9/10 grew poorly under hyperosmotic stress conditions but was similar to the wi
109 udomonas aeruginosa grown under steady-state hyperosmotic stress conditions showed an up-regulation o
110 ect to partial repression by succinate under hyperosmotic stress conditions, in contrast to strong re
119 The results presented here demonstrate that hyperosmotic stress elicited increases in ATF-2 phosphor
121 ediated targeting of DNMBP to P-bodies under hyperosmotic stress facilitates the activation of Cdc42
122 ivating a complex array of signaling events, hyperosmotic stress fails to up-regulate PtdIns 3,5-P(2)
123 is required for optimal invasive growth and hyperosmotic stress (high-osmolarity glycerol [HOG]) sig
124 plete loss in NKCC activation in response to hyperosmotic stress, immunoprecipitation of NKCC reveale
125 rked PtdIns 3,5-P(2) increase in response to hyperosmotic stress in differentiated 3T3-L1 adipocytes.
126 , we show that ROS production in response to hyperosmotic stress in embryonic cells of the alga Fucus
127 Skb1 homolog, Skb1Hs, is also stimulated by hyperosmotic stress in fission yeast, providing evidence
128 the present study, we highlight the role of hyperosmotic stress in inducing human alpha-syn to aggre
129 )-2Cl(-) cotransporter (NKCC) by insulin and hyperosmotic stress in L6 rat skeletal muscle cells.
135 in NMuMg mammary epithelial cells exposed to hyperosmotic stress induced by the organic osmolyte sorb
138 Our study results here demonstrate that hyperosmotic stress induced H2AX phosphorylation (gammaH
139 the authors explore the mechanism involving hyperosmotic stress-induced activation of c-Jun/AP-1 thr
142 lternative signaling mechanism that involves hyperosmotic stress-induced activation of the Plk3 pathw
143 ylation of c-Jun by Plk3 was responsible for hyperosmotic stress-induced apoptosis, which was indepen
149 , a transcription factor reported to mediate hyperosmotic stress-induced cytoprotection in renal medu
150 tridium difficile toxin B potently inhibited hyperosmotic stress-induced FAK tyrosine phosphorylation
153 he contribution of ArPIKfyve-PIKfyve for the hyperosmotic stress-induced rise in PtdIns 3,5-P(2).
154 of Ssh1p as two early successive events in a hyperosmotic stress-induced signaling cascade in plants.
162 l cell line, we originally demonstrated that hyperosmotic stress induces transcription of the aldose
164 tein kinase Hog1 is activated in response to hyperosmotic stress, inducing the production and retenti
167 phorylation switch is involved in perceiving hyperosmotic stress, initiating and amplifying osmotic s
170 cts and show that as a cell is compressed by hyperosmotic stress it becomes progressively more rigid.
171 increasing levels of cytoplasmic K(+) during hyperosmotic stress latter via its C-terminal domain and
173 neous exposure of L6 myotubes to insulin and hyperosmotic stress led to an additive increase in NKCC-
177 rophosphates also responded within 30 min of hyperosmotic stress: levels of bisdiphosphoinositol tetr
178 C1 and functional activation of NKCC1 during hyperosmotic stress, measured as bumetanide-sensitive ba
179 ression of N17 Rac only slightly altered the hyperosmotic stress-mediated localization of phosphoryla
180 Overexpression of N17 RhoA did not reduce hyperosmotic stress-mediated localization of phosphoryla
181 such as protein misfolding and aggregation, hyperosmotic stress, membrane fracturing, and changes in
183 binding partners in human skin wounds, where hyperosmotic stress occurs as a consequence of excessive
187 Identification of [PP]2-InsP4 as a sensor of hyperosmotic stress opens up a new area of research for
188 rast, caffeine had no effects on melphalan-, hyperosmotic stress-, or IL-1beta-induced activation of
189 ally sumoylated proteins during heat stress, hyperosmotic stress, oxidative stress, nitrogen starvati
190 d to improve bacterial growth recovery under hyperosmotic stress, partly through stabilization of the
191 Elevated extracellular solute concentration (hyperosmotic stress) perturbs cell function and stimulat
195 nuous 6-base pair substitutions identified a hyperosmotic stress-regulated element that is GC-rich an
196 fied four major DNA-protein complexes in the hyperosmotic stress-regulated element that, by competiti
199 work reveals a novel CK2 function during the hyperosmotic stress response that promotes cell-to-cell
200 le for Skb1-related proteins as mediators of hyperosmotic stress response, as well as mechanisms invo
204 lar turgor-sensing mechanisms might regulate hyperosmotic stress responses both in yeast and plants.
205 mbers, and the function of PLD activation in hyperosmotic stress responses has remained elusive.
208 own of storage oil and are more resistant to hyperosmotic stress, salt stress, oxidative stress, free
209 i2hai1hai2 quadruple mutant displays reduced hyperosmotic stress sensitivity and partially constituti
213 We show that proline can protect cells from hyperosmotic stress similar to the osmoprotection in pla
215 ression of the N17 mutant of Cdc42 disrupted hyperosmotic stress-stimulated FAK Tyr-397 localization
216 the p38 MAPK signaling pathway mediates the hyperosmotic stress stimulation of sgk gene expression.
217 Cdc42 inhibits both processes in response to hyperosmotic stress, suggesting that Cdc42 has a role in
223 physiological changes resulting from imposed hyperosmotic stress, thereby offering a clear visualizat
224 Organisms, almost universally, adapt to hyperosmotic stress through increased accumulation of or
227 These effects correlate with the ability of hyperosmotic stress to interfere with protein traffickin
231 s activated through hormonal stimulation and hyperosmotic stress via a protein kinase C (PKC) delta-m
234 ts interactome and substrates in cells under hyperosmotic stress, we performed a BioID screen using m
235 [PP](2)-InsP(4) levels normally seen during hyperosmotic stress were attenuated by 2-(2-chloro-4-iod
237 function of the inflammasome as a sensor of hyperosmotic stress, which is crucial for the induction
238 el role of c-Rel in the adaptive response to hyperosmotic stress, which is inhibited via a PACT/PKR-d