コーパス検索結果 (1語後でソート)
通し番号をクリックするとPubMedの該当ページを表示します
1 issive temperature and a secretory defect at restrictive temperature.
2 romosomes when expressed individually at its restrictive temperature.
3 recruit the MCM complex to chromatin at the restrictive temperature.
4 aughter cells immediately after the shift to restrictive temperature.
5 promotes rapid degradation of Cdc45p at the restrictive temperature.
6 temperature and subsequently analyzed at the restrictive temperature.
7 d displays a pre-mRNA splicing defect at the restrictive temperature.
8 of genes are differentially expressed at the restrictive temperature.
9 enesis and over multiple generations, at the restrictive temperature.
10 l reduction in translation initiation at the restrictive temperature.
11 hydroxyurea or by the mutant arrests at the restrictive temperature.
12 ed mtDNA replication in the germarium at the restrictive temperature.
13 ants that are blocked in this process at the restrictive temperature.
14 tants rebud and reduplicate their DNA at the restrictive temperature.
15 r photosynthetic ability at the 35 degrees C restrictive temperature.
16 ts are specifically lost from the complex at restrictive temperature.
17 p is diffusely localized in the cytoplasm at restrictive temperature.
18 y1 allele replace those encoded by rsw1-1 at restrictive temperature.
19 following a shift from the permissive to the restrictive temperature.
20 n yeast TBP-associated factors (TAFs) at the restrictive temperature.
21 ain spindle integrity during anaphase at the restrictive temperature.
22 eins from the ER to the Golgi complex at the restrictive temperature.
23 bited in the srs2Delta sgs1-ts strain at the restrictive temperature.
24 on, is stabilized in the kar2 strains at the restrictive temperature.
25 TATA-less Pol II promoters is reduced at the restrictive temperature.
26 14(ts) cpt1 strains to grow at the sec14(ts) restrictive temperature.
27 a loss of growth polarity when incubated at restrictive temperature.
28 SA4 mRNAs that were newly synthesized at the restrictive temperature.
29 lation of HRP were markedly inhibited at the restrictive temperature.
30 ely 30% decrease in protein synthesis at the restrictive temperature.
31 and can complete the asexual growth cycle at restrictive temperature.
32 f invertase and the vacuolar protease CPY at restrictive temperature.
33 COP is degraded after cells are shifted to a restrictive temperature.
34 o permitted growth of plc1delta cells at the restrictive temperature.
35 MOB1 cause a late nuclear division arrest at restrictive temperature.
36 tely 50% in the CB286 ts mutant grown at the restrictive temperature.
37 ntromere chromatin structure is disrupted at restrictive temperature.
38 and SNAP-25, accumulates in comt mutants at restrictive temperature.
39 tly skipped by the splicing machinery at the restrictive temperature.
40 ion inhibits nuclear migration and growth at restrictive temperature.
41 produced after a shift of the mcb mutant to restrictive temperature.
42 ex (NPC) structure and nuclear import at the restrictive temperature.
43 gates, was not observed in ts85 cells at the restrictive temperature.
44 nt induction of a heat shock response at the restrictive temperature.
45 rsibly when vti1-1 cells were shifted to the restrictive temperature.
46 when mdm1 mutant cells are incubated at the restrictive temperature.
47 d receptors was mildly defective only at the restrictive temperature.
48 has no adverse effect on this process at the restrictive temperature.
49 yurea and display an S-phase arrest at their restrictive temperature.
50 lected by increased Poly(A)+ RNA export at a restrictive temperature.
51 verely inhibited in the pol3-3 mutant at the restrictive temperature.
52 nuclear export of Poly(A)+ RNA when grown at restrictive temperature.
53 retion phenotype when grown at the sec14(ts)-restrictive temperature.
54 oss of growth polarity when incubated at the restrictive temperature.
55 tion of noninfectious progeny virions at the restrictive temperature.
56 genesis following upshift from permissive to restrictive temperature.
57 the SPB decrease in the mutant cells at the restrictive temperature.
58 and arrest in G2 after being shifted to the restrictive temperature.
59 chronized pol30 cells through S phase at the restrictive temperature.
60 mutants prepared from cells incubated at the restrictive temperature.
61 imD arrest with aberrant mitotic spindles at restrictive temperature.
62 apable of rescuing sec7 mutant growth at the restrictive temperature.
63 tant accumulates unspliced precursors at the restrictive temperature.
64 ) Yersinia pseudotuberculosis strains at the restrictive temperature.
65 accumulate single-stranded DNA breaks at the restrictive temperature.
66 eration while also inducing paralysis at the restrictive temperature.
67 NA defects only when grown and maintained at restrictive temperature.
68 t1 cells show a pleiotropic phenotype at the restrictive temperature.
69 inability of myo2-E1 to form colonies at the restrictive temperature.
70 are symmetric and markedly diminished at the restrictive temperature.
71 APC) arrest at metaphase of meiosis I at the restrictive temperature.
72 strains and increases their survival at the restrictive temperature.
73 plasmid can also rescue sid2-250 at the low restrictive temperature.
74 s59-Asn98del) completely failed to rescue at restrictive temperature.
75 reflected by reduced viral replication at a restrictive temperature.
76 ng plasmid was then removed by growth at the restrictive temperature.
77 re sensitive mutant strain in RNase P at the restrictive temperature.
78 ype strain but not in a mutant strain at the restrictive temperature.
79 sed in the dU2AF50 mutant flies grown at the restrictive temperature.
80 display diminished levels of 60S subunits at restrictive temperature.
81 t in the Sec23p component of COPII) grown at restrictive temperature.
82 mbly-defective (fla) mutant fla11(ts) at the restrictive temperature.
83 rt all RNAs, including poly(A) mRNAs, at the restrictive temperature.
84 r a temperature shift from the permissive to restrictive temperature.
85 h other components of the Brm complex at the restrictive temperature.
86 -phase of the cell cycle when shifted to the restrictive temperature.
87 to complement the ftsQ1(Ts) mutation at the restrictive temperature.
88 ulated less efficiently after shifted to the restrictive temperature.
89 xhibit a block in ER-to-Golgi traffic at the restrictive temperature.
90 rental efficiency at both the permissive and restrictive temperatures.
91 henotype than did these cells cultured under restrictive temperatures.
92 ic ribosomal subunits at both permissive and restrictive temperatures.
93 fail to accumulate in a subset of nuclei at restrictive temperatures.
94 s) allele enter the cell cycle and arrest at restrictive temperatures.
95 t permissive temperature, were functional at restrictive temperatures.
96 d from cells cultured at both permissive and restrictive temperatures.
97 med, suppressing rad27 -induced lethality at restrictive temperatures.
98 thus synaptic transmission, at elevated, or restrictive temperatures.
99 the growth defect of the DerN321D mutant at restrictive temperatures.
100 ned operon allowed them to grow at otherwise restrictive temperatures.
101 ntion site in the mother cell after shift to restrictive temperatures.
102 mperatures below 20 degrees C, but at higher restrictive temperatures (26 to 29 degrees C) chromosoma
106 ermissive temperatures (23 degrees C) to the restrictive temperature (37 degrees C), but hydroxyurea-
107 tron microscopy, 30 min after a shift to the restrictive temperature (37 degrees C), reveals a striki
110 FT210 cells, which arrest at G2 phase at the restrictive temperature (39 degrees C), due to a mutatio
111 rmissive temperature (32.5 degrees C) to the restrictive temperature (39.5 degrees C), both small nuc
113 l genome and subsequently transferred to the restrictive temperature, a DNA-packaging defect was evid
114 lta, and simultaneously became denser at the restrictive temperature, a hallmark of secretion-defecti
116 ive growth and a G(2)/M cell cycle arrest at restrictive temperatures, a phenotype similar to that of
119 with conditionally defective tropomyosin to restrictive temperatures, actin cables disappear within
120 erestingly, hsk1(ts) mutants released to the restrictive temperature after early S-phase arrest in hy
121 rupts its acetyl-transferase activity at the restrictive temperature, alters the transcription of spe
122 impaired in rRNA synthesis upon shift to the restrictive temperature, although the mechanism of inhib
123 ceptors was defective at both permissive and restrictive temperatures, although transactivation by gl
124 ormally but cannot complete cell division at restrictive temperature and arrest with decreased CTD ph
125 ele inhibited cortical actin motility at the restrictive temperature and eventually disrupted actin p
126 pld1 strains are not viable at the sec14(ts) restrictive temperature and exhibit a pattern of inverta
127 nsitivity (ts) limits viral replication at a restrictive temperature and may be involved with viral a
128 an sgs1 temperature-sensitive allele at the restrictive temperature and Slx1 and Slx4 proteins are s
129 ivide for three cell cycles after a shift to restrictive temperature and then arrest as a mixture of
130 mpletion of anaphase when cells are grown at restrictive temperature and this has been shown to be du
131 orp2-2 fail to complete DNA replication at a restrictive temperature and undergo cell cycle arrest.
132 feration of RPMI 8226 and HS Sultan cells at restrictive temperatures and growth arrest and increased
133 rstabilized in cdc34-3 and cdc4-3 mutants at restrictive temperatures and when S/T-P phosphorylation
134 tes first that the MSC is established at the restrictive temperature, and that melanoblasts die or lo
135 irst synchronized in M phase, shifted to the restrictive temperature, and then released from the bloc
136 not in the wild type after the shift to the restrictive temperature; and 3) the overexpression of Co
137 utation leads to delayed nuclear division at restrictive temperatures, apparently as a result of an i
139 mitotic mutants, dim1-35 cells incubated at restrictive temperature arrest with low histone H1 kinas
140 splayed these phenotypes when shifted to the restrictive temperature at the appropriate developmental
141 n wild-type and tsaca2 cells, shifted to the restrictive temperature at various stages of development
142 ndergo cell cycle arrest when shifted to the restrictive temperature, becoming highly elongated.
143 ly in the second cycle after transfer to the restrictive temperature, blocking as large-budded cells
147 lements a conditional mutant of Cdc12 at the restrictive temperature, but arrests cells at the permis
148 t the mutation is due to loss of function at restrictive temperature, but molecular disruption of the
149 , many SIN mutants can be rescued at the low restrictive temperature by the osmotic stabilizer sorbit
150 chromosomal decatenase topoisomerase IV) at restrictive temperatures by high-copy suppressors is str
152 in a temperature-sensitive sec6 mutant at a restrictive temperature can be separated into at least t
153 coli, this ring assembly is impaired at the restrictive temperature causing lethal cell filamentatio
154 e-sensitive mcs6 allele was incubated at the restrictive temperature, Cdc2 was not activated and the
157 ive mtg3 mutants grown at the permissive and restrictive temperatures, combined with immunobloting wi
158 ic stability upon serial passage in vitro at restrictive temperatures compared to that of the parent
159 posure to UV radiation, cdc44 mutants at the restrictive temperature contain higher levels of single-
160 with anti-COPI antibodies, ldlF cells at the restrictive temperature could not be infected by vesicul
162 tains stable haploidy at both permissive and restrictive temperature, diploidizes at permissive tempe
164 ve temperature, yet acts as a null allele at restrictive temperature due to loss of sir3-8 protein.
166 also blocked in the cell cycle such that at restrictive temperatures, esa1 mutants succeed in replic
167 ust growth trajectory after release from the restrictive temperature, eventually growing into fertile
168 t permissive temperature and then shifted to restrictive temperature exhibit severe reductions in fec
169 erience a delay in traversing S phase at the restrictive temperature following alpha factor arrest; a
170 tracts prepared after culturing cells at the restrictive temperature for 1 h indicates that the K151L
172 , TOP1 was not modified in ts85 cells at the restrictive temperature for its thermolabile ubiquitin-a
173 expressing the ts v-abl PTK and grown at the restrictive temperature for PTK activity the cells were
176 similar mitotic defects when released to the restrictive temperature from an early S-phase block.
178 ve FliP protein continued to function at the restrictive temperature if incorporated at the permissiv
179 ate with Cdc28 when cells are blocked at the restrictive temperature in a cdc34 mutant, a point in th
181 e kinesin KHP1(FLA10), a protein inactive at restrictive temperature in fla10, a temperature-dependen
182 tant plasma membrane ATPase defective at the restrictive temperature in stability at the cell surface
189 occurred normally at both the permissive and restrictive temperatures in these mutants, the results s
190 iator cease transcription of all mRNA at the restrictive temperature, in a manner virtually indisting
191 unoblotting experiments indicate that at the restrictive temperature, inactivation of TAF25p function
192 of these MM cells under permissive, but not restrictive, temperatures increased the expression of p5
193 mutant still formed septa when grown at the restrictive temperature, indicating that polarized depos
194 and snR13T both increase in abundance at the restrictive temperature, indicating that Sen1p stabilize
195 ults in only partial rescue of growth at the restrictive temperature, indicating that splicing functi
196 ich leads to synthesis of increased dsRNA at restrictive temperature, induced apoptosis at restrictiv
197 Loss of separase function in rsw4 at the restrictive temperature is indicated by the widespread f
198 le of rescuing ts-38 (but not ts-114) at the restrictive temperature; it was demonstrated that homoge
202 of synchronized material revealed that at a restrictive temperature mipAD159 does not inhibit mitoti
203 le to that of a fimH insertion mutant at the restrictive temperature, mouse peritoneal macrophages we
208 cannot inhibit cellular protein synthesis at restrictive temperature no longer blocks Mnk1 binding to
209 tationary phase to exponential growth at the restrictive temperature of 30 degrees C and that this is
214 sensitive mRNA poly(A) polymerase grown at a restrictive temperature of 37 degrees C also contained a
215 eased from the blockade and incubated at the restrictive temperature of 37 degrees C, 95% of the cell
219 s behavior below 15 degrees C-just above the restrictive temperature of mammalian fast axonal transpo
220 econd site mutations capable of reducing the restrictive temperature of the fission yeast mutant cdc2
222 d, pre4-2 and ump1-2 strains fail to grow at restrictive temperatures on nonfermentable carbon source
223 of a temperature-sensitive ACA mutant at the restrictive temperature prevented c-di-GMP-induced cAMP
226 of PtdIns(4)P observed in stt4(ts) cells at restrictive temperature result in a dramatic change in v
227 ts undergo chromosome mis-segregation at the restrictive temperature, resulting in a dramatic decreas
230 ensitive allele gpa-16(it143), which, at the restrictive temperature, results in spindle orientation
231 In vivo observations of chromosomes at a restrictive temperature revealed that mipAD159 caused a
233 r morphology in a trf4 (ts) trf5 mutant at a restrictive temperature reveals the presence of many cel
235 oping topless embryos between permissive and restrictive temperatures show that apical fates (cotyled
236 Plants containing this allele grown at the restrictive temperature showed weak radial swelling, wer
237 jections after exposure to pheromone; at the restrictive temperature, small budded cells accumulate.
238 elease experiments with cdc2.33 cells at the restrictive temperature, SPBs remained single, whereas i
240 re-sensitive alleles of SUG1 and SUG2 to the restrictive temperature strongly inhibited the expressio
241 be retained in hh(ts2) mutants raised at the restrictive temperature, suggesting it is not establishe
243 nsitive nudG mutation grew no more slowly at restrictive temperature than a strain with only the CDHC
245 ects in mitotic and cell cycle regulation at restrictive temperatures that are apparently independent
251 eases in sec14(ts) cki1 cells shifted to the restrictive temperature, the INO1 gene (encoding inosito
252 ts also accumulate unspliced pre-mRNA at the restrictive temperature, the mitotic arrest does not app
257 hich neuroglian protein is mislocated at the restrictive temperature to an intracellular location in
258 we find that septin mutants incubated at the restrictive temperature trigger a Swe1-dependent mitotic
261 2 export was blocked in a gle1 mutant at the restrictive temperature, we propose a model wherein Gfd1
262 ing and septum in the sid2-250 mutant at low restrictive temperatures, we show that the lysis phenoty
263 nts were characterized in detail, and at the restrictive temperature were found to have an arrest phe
265 eraction with the tsNIa-N393D protein at the restrictive temperature were recovered by a two-hybrid s
268 that prevent ER/Golgi transport in vitro at restrictive temperatures were used to selectively inacti
269 ons, as well as oncogene inactivation at the restrictive temperature when desired for functional stud
270 cold-sensitive mutant, Era(Cs) (E200K), at a restrictive temperature when expressed in a multicopy pl
271 he growth defects of some SIN mutants at low restrictive temperatures, where the SIN single mutants l
272 erature sensitive cesA1-1 allele (rsw1) at a restrictive temperature whereas mutations to A at these
273 mosomal copy of ctf13-30 fail to grow at the restrictive temperature, whereas a haploid strain carryi
274 oth nuclear division and polarity defects at restrictive temperature, which could be complemented by
275 a pronounced defect in rRNA biosynthesis at restrictive temperatures, while tRNA transcription and p
276 e cak1 mutant strains, which arrested at the restrictive temperature with nonuniform budding morpholo
277 We identified three short-sleep lines at the restrictive temperature with shared expression in the mu
278 leles of mps1 prevent SPB duplication at the restrictive temperature without affecting premeiotic DNA
279 t-off of protein synthesis upon shift to the restrictive temperature, without wholesale reduction in