ライフサイエンスコーパス: nondividing cell

1 irus - its ability to enter the nucleus of a nondividing cell.

2 d maintenance of phosphoinositide balance in nondividing cells.

3 eplicates only in terminally differentiated, nondividing cells.

4 ly been thought of as metabolically dormant, nondividing cells.

5 enes that effectively kill both dividing and nondividing cells.

6 required for maintaining a silenced state in nondividing cells.

7 egrating their viral DNA into the genomes of nondividing cells.

8 owed by rapid apoptosis in both dividing and nondividing cells.

9 l for virus replication in both dividing and nondividing cells.

10 ed gene delivery and long-term expression in nondividing cells.

11 st, adenoviruses (Ad) can efficiently infect nondividing cells.

12 is essential for the productive infection of nondividing cells.

13 a gene therapy vector to transfer genes into nondividing cells.

14 virus (SNV), which are capable of infecting nondividing cells.

15 transfer systems for delivery of genes into nondividing cells.

16 ites, which are highly toxic to dividing and nondividing cells.

17 -modified HIV-1 particles are able to infect nondividing cells.

18 t gene delivery to a variety of dividing and nondividing cells.

19 en pathway for generating mutant proteins in nondividing cells.

20 ead to viral- and lipid-free transfection of nondividing cells.

21 1-derived vectors is their ability to infect nondividing cells.

22 for MMR in helping create new phenotypes in nondividing cells.

23 essory gene expression in either dividing or nondividing cells.

24 entivirus vectors can transduce dividing and nondividing cells.

25 mited in certain cell types, particularly in nondividing cells.

26 ence of antigenic stimulation and persist as nondividing cells.

27 f high-level gene transfer and expression in nondividing cells.

28 port of the viral genome into the nucleus of nondividing cells.

29 ency virus type 1 (HIV-1) that can transduce nondividing cells.

30 at high titers and infect both dividing and nondividing cells.

31 gene transfer agents because they can infect nondividing cells.

32 type 1 (HIV-1) vectors to deliver genes into nondividing cells.

33 etrotransposons and retroviruses that infect nondividing cells.

34 nescence associated with the accumulation of nondividing cells.

35 e only types of mismatches that can arise in nondividing cells.

36 in cells undergoing DNA replication than in nondividing cells.

37 gesting that R2 is able to retrotranspose in nondividing cells.

38 s is limited by their inability to transduce nondividing cells.

39 play an important role in viral infection of nondividing cells.

40 resuscitate from starvation, leaving intact nondividing cells.

41 ds to HIV-1 CA, regulates HIV-1 infection of nondividing cells.

42 mage and genomic instability during aging in nondividing cells.

43 ) CA abrogate the ability of HIV-1 to infect nondividing cells.

44 ich binds to HIV-1 CA, on HIV-1 infection of nondividing cells.

45 es can enter the nuclei of both dividing and nondividing cells.

46 homologous recombination is not essential in nondividing cells.

47 mine effects of growth factor stimulation on nondividing cells.

48 Rad17, and Chk1 protein expression in these nondividing cells.

49 ficiency virus, by their inability to infect nondividing cells.

50 different half-lives in rapidly dividing or nondividing cells.

51 cript abundance limits retrotransposition in nondividing cells.

52 cells and their isolated lipids relative to nondividing cells.

53 TDP1), repairs single-stranded DNA breaks in nondividing cells.

54 yeast by measuring the long-term survival of nondividing cells.

55 n of these foci was seen most prominently in nondividing cells.

56 eine also inhibits efficient transduction of nondividing cells.

57 curing of [PSI+] cells in both dividing and nondividing cells.

58 NA-PKcs) that are expressed predominately in nondividing cells.

59 cells are more vulnerable to apoptosis than nondividing cells.

60 is defined as the age-dependent viability of nondividing cells.

61 on of human immunodeficiency virus type 1 in nondividing cells.

62 ween HIV and MLV in the ability to transduce nondividing cells.

63 uses is their ability to productively infect nondividing cells.

64 protein (CA) in the infectious phenotype in nondividing cells.

65 MLV) loses the ability to efficiently infect nondividing cells.

66 ility to stably integrate into the genome of nondividing cells.

67 stricted infection of this chimeric virus in nondividing cells.

68 rabidopsis culture cells than in stationary, nondividing cells.

69 ave the potential to change the phenotype of nondividing cells.

70 ion, thereby facilitating HIV replication in nondividing cells.

71 lls (HSCs) due to their ability to transduce nondividing cells.

72 d more sensitive to VEGF(121)/rGel than were nondividing cells.

73 sistence may be adequate for gene therapy of nondividing cells, a very high MOI or improvements in ba

74 phase) mutagenesis is a phenomenon by which nondividing cells acquire beneficial mutations as a resp

75 educed, they recovered to original levels in nondividing cells after drug treatment.

76 77 impairs viral infectivity in dividing and nondividing cells, although the assembly of these Ser mu

77 vectors that express the transduced gene in nondividing cells and (b) increasing the frequency of st

78 a demonstrate essential roles for cohesin in nondividing cells and also introduce a powerful tool by

79 ty of adenoviruses to transduce dividing and nondividing cells and because of their high transduction

80 ribute to the formation of tumors arising in nondividing cells and could also contribute to mutagenes

81 in that is critical for HIV-1 replication in nondividing cells and induces cell cycle arrest and apop

82 eting of the viral preintegration complex in nondividing cells and induces G(2) cell cycle arrest in

83 aries among cell types (e.g. dividing versus nondividing cells and normal versus tumor cells).

84 herefore is linked to higher virus yields in nondividing cells and potentially higher virulence in ex

85 This increased the efficiency of infecting nondividing cells and was sufficient to endow the virus

86 Retroviruses in nondividing cells and yeast retrotransposons must transi

87 DNA, (iii) enabling analysis in individual, nondividing cells, and (iv) uncoupling other potential f

88 n E1A that preclude efficient replication in nondividing cells, and a deletion of the E3 genes which

89 The extrachromosomal circle is maintained in nondividing cells, and a gene located on such a circle c

90 cantly impaired (1,000-fold lower titers) in nondividing cells, and plaque-forming ability was severe

91 or that determines retrovirus infectivity in nondividing cells, and several mutations in HIV type 1 (

92 5-Aza-2'-deoxycytidine-treated and untreated nondividing cells, and their mRNA transcripts were down-

93 The nondividing cells are heterogeneous for naive versus mem

94 andomly into the genome of both dividing and nondividing cells as determined by fluorescence in situ

95 t reversibility is not a passive property of nondividing cells, because enforced cell cycle arrest fo

96 /1107) that prevent efficient replication in nondividing cells but allow replication in dividing canc

97 t is unclear how repeats are destabilized in nondividing cells, but it cannot involve DNA replication

98 sed lentiviral vectors efficiently transduce nondividing cells, but present complex safety concerns.

99 This modification facilitates infection of nondividing cells by allowing for the recruitment of the

100 Lentiviruses likely infect nondividing cells by commandeering host nuclear transpor

101 AMHD1), a dNTPase, prevents the infection of nondividing cells by retroviruses, including HIV, by dep

102 The efficiency of infection of nondividing cells by the three viruses correlates with t

103 ke the gammaretroviruses, are able to infect nondividing cells by transiting through nuclear pores to

104 s for efficient transduction of dividing and nondividing cells by vector particles based on FIV, a se

105 cells and during transcription initiation in nondividing cells can culminate in genome instability.

106 ncy virus (FIV) is a lentivirus that infects nondividing cells, causes progressive CD4(+) T-cell depl

107 se transcription complex into the nucleus of nondividing cells, cellular differentiation including ce

108 omal rearrangement frequency during aging of nondividing cells compared with that generated during th

109 The capacity of mutant virions to transduce nondividing cells could help to elucidate incompletely u

110 viral vectors to deliver genes in vivo into nondividing cells could increase the applicability of re

111 rocessing and protein synthesis so that even nondividing cells die of protein starvation.

112 as human immunodeficiency virus, that infect nondividing cells generate integration precursors that m

113 ause they achieve efficient integration into nondividing cell genomes and successful long-term expres

114 mine whether DNA nanoparticles can transfect nondividing cells, growth-arrested neuroblastoma and hep

115 Compared with proliferating hRPE cells, the nondividing cells had lower intracellular GSH, GSSG, and

116 r mitotic spindles along the tubule, whereas nondividing cells improperly position their centrosomes.

117 re reduced in their capacity to replicate in nondividing cells in culture and in vivo.

118 Lat1 is also a limiting longevity factor in nondividing cells in that overexpressing Lat1 extends ce

119 ng epithelial cells but not in the nuclei of nondividing cells in the lens fiber compartment.

120 induced by oxidative metabolism, which kills nondividing cells in the nervous system.

121 of 10(9) IU/ml and can efficiently transduce nondividing cells in vitro and in vivo.

122 ts demonstrate the efficient transduction of nondividing cells in vitro by a multiply attenuated FIV

123 that exhibit profound replication defects in nondividing cells in vitro.

124 ectors have recently been shown to transduce nondividing cells in vivo as well as in vitro.

125 to efficiently convert to a circular form in nondividing cells in vivo using transgenic mice.

126 but was independent of MinC and continued in nondividing cells in which FtsZ function was inhibited.

127 replicated equivalently to the wild type in nondividing cells, including macrophages.

128 ed transgene integration in several types of nondividing cells, including neurons.

129 have evolved a number of mechanisms to drive nondividing cells into S phase.

130 rus type 1 (HIV-1) infection of dividing and nondividing cells involves regulatory interactions with

131 human immunodeficiency virus (HIV) to infect nondividing cells is a fundamental property by which HIV

132 act nuclear envelope and productively infect nondividing cells is a salient feature of human immunode

133 Lipofection of nondividing cells is inefficient because much of the tra

134 Poor nuclear entry, especially into nondividing cells, is a limiting factor in nonviral gene

135 raries via iterative retroviral infection of nondividing cells led to the identification of a novel v

136 re efficient than MLV vectors at transducing nondividing cell lines as well as human CD34(+) cells an

137 egrate into the host genome and to transduce nondividing cells makes them attractive as vehicles for

138 curs on a largely unmethylated genome and in nondividing cells, making it a highly informative model

139 -long terminal repeat circle accumulation in nondividing cell nuclei was also equivalent to that of L

140 ion of mutant cDNA localized to dividing and nondividing cell nuclei.

141 rt models in which UV-induced mutagenesis in nondividing cells occurs during the Pol zeta-dependent f

142 al origin revealed that only differentiated, nondividing cells of the epidermis expressed interferon-

143 Of all mutations originating de novo in nondividing cells, only those in the transcribed (noncod

144 itially reported to function specifically in nondividing cells, other recently identified sequences a

145 vulnerable to h-IAPP-induced apoptosis than nondividing cells (P < 0.05).

146 ses of sensitivity to DNA-damaging agents in nondividing cell populations, such as cochlear hair and

147 rigin of double nonsilent CpG transitions in nondividing cells predicts a significant excess of the h

148 nodeficiency virus type 1 (HIV-1) can infect nondividing cells productively because the nuclear impor

149 HIV-1 is able to infect nondividing cells productively in part because the poste

150 In the remaining nondividing cells, progressive accumulation of a senesce

151 ize that inhibition of retrotransposition in nondividing cells protects somatic tissues from accumula

152 splice variants are expressed highly only in nondividing cells, quiescent cells would be afforded a m

153 feration could reduce the number of residual nondividing cells remaining after imatinib treatment.

154 n a replication strand-independent manner in nondividing cells, resulting in either fully wild-type o

155 ucleoprotein complex facilitate infection of nondividing cells such as macrophages and quiescent T ly

156 virus type 1 (HIV-1) is capable of infecting nondividing cells such as macrophages because the viral

157 gammaretroviruses by their ability to infect nondividing cells such as macrophages, an important vira

158 critical for efficient virus replication in nondividing cells such as macrophages.

159 ce potent and long-lasting HIV inhibition in nondividing cells such as macrophages.

160 lity to efficiently infect both dividing and nondividing cells, such as activated T cells and macroph

161 mutations of vpr are unable to replicate in nondividing cells, such as macaque monocyte-derived macr

162 unodeficiency virus type 1 is able to infect nondividing cells, such as macrophages, and the viral Vp

163 sting that this agent should not be toxic to nondividing cells, such as neurons.

164 ormation, especially during the infection of nondividing cells, suggesting that the function of small

165 iral capsids restrict HIV-1 more potently in nondividing cells than in dividing cells, thus rendering

166 nsgene, we demonstrate that differentiating, nondividing cells that express MEK1 stimulate adjacent t

167 -specific restriction of HIV-1 CA mutants in nondividing cells that is dependent on CypA-CA interacti

168 could deliver the active cellular kinase to nondividing cells that normally do not express it.

169 g mitosis, similar to retroviruses infecting nondividing cells, the cDNA produced must be translocate

170 of these vectors to infect both dividing and nondividing cells, their use as a therapeutic tool for t

171 Because lentiviruses are able to infect nondividing cells, these viruses might be utilized in ge

172 against viral capsids and the resistance of nondividing cells to retrovirus infection.

173 nal plasma samples, infectivity in initially nondividing cells was also significantly enhanced.

174 sification was unclear and nuclear import in nondividing cells was not addressed.

175 diated nuclear translocation of MoMLV DNA in nondividing cells was not sufficient for stable transduc

176 mammalian cell types, including primary and nondividing cells, we are developing lentiviral short ha

177 y of HIV-based vectors to deliver genes into nondividing cells, we have generated replication-defecti

178 s persistence in myofibers and perhaps other nondividing cells whereby cells that survive infection c

179 lation of superoxide-dependent DNA damage in nondividing cells, which induces error-prone DNA repair

180 replicated productively in both dividing and nondividing cells, while viruses with a mutation at IN-V

181 ith the cell cycle, typically resulting in a nondividing cell with a unique differentiated morphology

182 ating vector in directing gene expression in nondividing cells, with the proper choice of an internal

183 re it can identify rAAV integration sites in nondividing cells without cell manipulations.

184 gest that the foamy virus genome persists in nondividing cells without integrating.