ライフサイエンスコーパス: ER export

1 thus PLD is temporally regulated to support ER export.

2 vation is required to support COPII-mediated ER export.

3 13/31 COPII complexes to ER export sites and ER export.

4 FA) to cause Golgi collapse and H89 to block ER export.

5 the recruitment of COPII to the membranes or ER export.

6 Lst1p, suggesting a unique role for Lst1p in ER export.

7 was sufficient for COPII binding but not for ER export.

8 at is responsible for cargo selection during ER export.

9 ces in the N terminus supply information for ER export.

10 ze the possible role of kinase regulation in ER export.

11 n analyzed their role in cargo selection and ER export.

12 t-negative mutant of Sar1 (Sar1pdn) blocking ER export.

13 important regulator of COPII-mediated EphA2 ER export.

14 dispersion of Sec16A from ERES and impaired ER export.

15 asmic reticulum (ER) that disassociates post ER export.

16 aling that dimerization was not required for ER export.

17 n controls membrane constriction to regulate ER export.

18 uired in a number of instances for efficient ER export.

19 at AMPARs sample the gating cascade prior to ER export.

20 ks ERES membranes to regulate COPII-mediated ER export.

21 phosphatidylinositols (PtdIns) in regulating ER export.

22 Ins4P) is required to promote COPII-mediated ER export.

23 iculation of the Golgi complex and arrest of ER export.

24 bligatory role for the beta2 AChR subunit in ER export.

25 structural determinants of alpha4beta2 AChR ER export.

26 y unappreciated role for Nm23H2 in mammalian ER export.

27 s -4 and -1) that was required for efficient ER export.

28 mbly at steady state and reduced kinetics of ER export.

29 component SEC24C for endoplasmic reticulum (ER) export.

30 ocal zones of ER complexity compartmentalize ER export and correspond to sites of new dendritic branc

31 The combined effects of reduced ER export and endocytosis significantly deplete Pmel17 w

32 n ERAD-independent role for facilitating the ER export and endosome- and Golgi-associated degradation

33 Both ER export and ER Golgi intermediate compartment (ERGIC)-

34 both proteins are required in HeLa cells for ER export and for normal tER organization.

35 tinual fatty acid synthesis was required for ER export and for normal tER site structure, whereas inh

36 ive protein kinase A inhibitor, blocked both ER export and hypo-osmotic-, brefeldin A-, or nocodazole

37 s as a molecular chaperone, increasing gH/gL ER export and incorporation into virions.

38 d-type proinsulin improves, accelerating its ER export and increasing wild-type insulin production.

39 These results demonstrate that ER export and initiation of COPII vesicle formation in m

40 A C-terminal valine residue functioned in ER export and interacted with coat complex (COP)II, whil

41 We demonstrate that US11 itself undergoes ER export and proteasomal degradation and utilize this s

42 es the exit signal, and thereby prevents the ER export and surface expression of the channel.

43 Association with hERG 1a facilitated 1b ER export and surface expression.

44 st that TR gO acts as a chaperone to promote ER export and the incorporation of gH/gL complexes into

45 hat Arabidopsis p24 proteins are involved in ER export and transport to the plasma membrane of GPI-an

46 aperones released the CNX-bound receptors to ER export and, furthermore, were able to rescue the Cys(

47 anisms underlying the endoplasmic reticulum (ER) export and cell surface transport of nascent G prote

48 viously suggested to play important roles in ER-export and subunit co-assembly respectively in this f

49 between cell volume, endoplasmic reticulum (ER) export, and stimulated Golgi-to-ER transport.

50 exit-site (ERES) assembly and COPII-mediated ER export are currently unknown.

51 f ERGIC and Golgi proteins into the ER after ER export arrest.

52 Q-SNAREs into COPII vesicles, implying their ER export as a preassembled complex.

53 ther with the sensitivity of BFA remnants to ER export blockade, suggests that presence of matrix pro

54 ze large COPII-coated endoplasmic reticulum (ER) export carriers.

55 activity and Cdc14 nuclear release for Chs2 ER export, cells ensure that septum formation is conting

56 plasmic reticulum (ER) membranes and becomes ER export competent only upon coexpression with Gn.

57 the connecting [C]-peptide) is folded in the ER, exported, converted to human insulin, and secreted.

58 Alternatively, disruption of procollagen I ER export could activate the unfolded protein response (

59 The ER export delay and cell surface retention are also obse

60 er with the previously identified N-terminal ER export diacidic motif, account for the differential l

61 localize adjacent to endoplasmic reticulum (ER) export domains, and resident Golgi transmembrane pro

62 Star acts as an endoplasmic reticulum (ER) export factor for all three.

63 ished as either competent or incompetent for ER export has not been elucidated.

64 rons to examine the role of SEC24C-dependent ER export in axonal targeting of SERT.

65 These data suggest that hERG undergoes ER export in COPII vesicles and endosomal recycling prio

66 We have characterized the organization of ER export in the malaria parasite, Plasmodium falciparum

67 ing cargo export in live cells, we show that ER export in vivo is also characterized by the formation

68 Blocking ER export in vivo stabilized the interaction between Vma

69 ER export is accelerated by the alternatively spliced C2

70 This ER export is blocked by brefeldin A and wortmannin but i

71 ents show that the site of the new Golgi and ER export is determined by the location of the new basal

72 These results indicate that efficient ER export is not sufficient to enable normal cell-surfac

73 broblasts, consistent with the proposal that ER export is the rate-limiting step for procollagen secr

74 inhibited without disrupting COPII-dependent ER export machinery (by brefeldin A treatment or express

75 d oxidative folding exceeded the capacity of ER export machinery.

76 e residue at position +2 downstream from the ER export motif ((607)RI(608) in SERT).

77 enesis identified an acidic-residue putative ER export motif responsible for the I-II loop-mediated i

78 Loss of an ER export motif upon cleavage of GIRK2 abolishes surface

79 We also verified that the presence of two ER export motifs (in concatemers of SERT and GABA transp

80 interaction through mutation of the putative ER export motifs of Sed5p and the cargo-binding A-site o

81 eir cytoplasmic tails, which themselves lack ER export motifs.

82 these nAChRs include endoplasmic reticulum (ER) export motifs but not ER retention motifs.

83 Consistent with a function for Nm23H2 in ER export, Nm23H2 localized to a reticular network that

84 We investigated where endoplasmic reticulum (ER) export occurs in dendrites using an in vitro permeab

85 We conclude that, when nicotine accelerates ER export of alpha4beta2 nAChRs, this suppresses ER stre

86 ER export of BiP occurs via COPII-dependent transport to

87 ionally, these states can adjust the rate of ER export of COPII-sorted cargos up or down by ~50%.

88 The effect of these three mutations on ER export of DAT was demonstrated in porcine aortic endo

89 nt of protein folding and leads to efficient ER export of even misfolded species.

90 BiP, therefore, prevents the ER export of folded but alpha(1)-unassembled beta subuni

91 the F(X)(6)LL motif plays a general role in ER export of G protein-coupled receptors (GPCRs).

92 that CLN6 deficiency results in inefficient ER export of lysosomal enzymes and diminished levels of

93 Thus, ER export of membrane proteins is not necessarily limite

94 p26Delta cells revealed a role for Svp26p in ER export of only a subset of type II membrane proteins.

95 This prevents premature ER export of partially folded receptors.

96 fibroblasts of this individual revealed that ER export of procollagen was inefficient and that ER tub

97 The C-terminal domain facilitates ER export of proSP-B.

98 endoplasmic reticulum (ER) quality control, ER export of secretory cargo, and programmed cell death.

99 Furthermore, ER export of the complexes is dependent of the interacti

100 , impaired (pre)proinsulin oxidation affects ER export of the mutant as well as that of coexpressed w

101 We show that efficient ER export of the p24 family of proteins is a major drive

102 n the C terminus were also found to regulate ER export of the receptors.

103 t transmembrane domain are essential for the ER export of the transporter.

104 component SEC24D, which is important in the ER export of wild type DAT, also blocked the rescue effe

105 In the absence of Pma1-D378N, ER export of wild-type Pma1 is not affected by eps1 dele

106 negative effect on cell growth by preventing ER export of wild-type Pma1.

107 aggregated Akita proinsulin helps to restore ER export of WT proinsulin, which can promote WT insulin

108 s critical for proper endoplasmic reticulum (ER) export of Cx36.

109 that acts to promote endoplasmic reticulum (ER) export of gH/gL and that gO is not stably incorporat

110 and ARF1 regulate the endoplasmic reticulum (ER) export of proteins in COPII and COPI vesicles, respe

111 tion or chemical inhibitor, BRD4780, blocked ER-export of misfolded GPI-APs.

112 n contrast, TMED9-inhibition did not prevent ER-export of wild-type GPI-APs, indicating a specific ro

113 thesized proteins and directs them either to ER export or ER-associated degradation (ERAD).

114 motifs important for endoplasmic reticulum (ER) export or endocytotic trafficking.

115 o the cell periphery via the classical Golgi/ER export pathway.

116 misfolded GPI-APs traffic to the Golgi by an ER-export pathway called Rapid ER stress-induced Export

117 protein is sufficient to confer an enhanced ER export rate.

118 whether IP3Rs and penta-EF proteins regulate ER export rates at steady state.

119 signaling involving IP3 receptors modulates ER export rates through activation of the penta-EF Hand

120 s due to cycling via the ER and preferential ER export rather than their stable assembly in a matrix

121 s and therefore does not appear to act as an ER export receptor.

122 e; SVP26, encoding an endoplasmic reticulum (ER) export receptor for ALP; and AP-3 subunit genes.

123 ns between PCSK9, its endoplasmic reticulum (ER) export receptor SURF4, and SEC24A that mediate secre

124 this stress-induced pathway by depleting the ER-export receptors leads to aggregation of the ER-retai

125 We show here that Chs2 ER export requires the direct reversal of the inhibitory

126 e TGN because of the combined presence of an ER export signal and a TGN retention motif.

127 the first motif as a functional diacidic DxE ER export signal, because substituting Asp-211 and Glu-2

128 of the ER indicate that in the absence of an ER export signal, molecules are inefficiently captured i

129 leave the ER owing to a defective autonomous ER export signal.

130 l GPI-APs and provides a protein-independent ER export signal.

131 suggests that the NPF motif is the dominant ER export signal.

132 nnels or a G protein-coupled receptor, these ER export signals increased the number of functional pro

133 We further show that ER export signals of Cab45 and NUCB1 bind co-translation

134 Kir3.2 and Kir3.4, but not Kir3.1, contain ER export signals that are important for plasma membrane

135 Here, we describe two ER export signals that profoundly altered the steady-sta

136 about the identity of endoplasmic reticulum (ER) export signals and how they are used to regulate the

137 olgi is not the exclusive product of the new ER export site.

138 Duplication of the endoplasmic reticulum (ER) export site follows exactly the same time course.

139 place ERAS at the periphery of COPII-labeled ER export sites (ERES).

140 Here, we show that these areas correspond to ER export sites (ERESs), distinct ER domains where glyco

141 of Sec23/24 and Sec13/31 COPII complexes to ER export sites and ER export.

142 We show that ER export sites are assembled regularly throughout the e

143 eatment led to a rapid loss of Sec13-labeled ER export sites but betaCOP localization to the Golgi wa

144 terize the three-dimensional organization of ER export sites in vivo and in vitro.

145 l protein kinase, in recruitment of COPII to ER export sites, as well as in stimulated but not consti

146 d occupy the space between cis cisternae and ER export sites, whereas the COPIb vesicles bud exclusiv

147 rough the generation of transitional tubular ER export sites.

148 ntly inhibited binding of exogenous Sec13 to ER export sites.

149 e distribution of this critical component at ER export sites.

150 f the NMDA receptor subunit NR1 to remodeled ER export sites.

151 s us to specifically control the assembly of ER export sites.

152 In mitosis, when ER export stops, Golgi proteins redistributed into the E

153 segregated from other cargo proteins during ER export, suggesting that ER membranes produce more tha

154 of biosynthetic cargo to prevent or enhance ER export suggests that interactions of cargo with the C

155 that ERD2 Golgi-retention, rather than fast ER export supports its function.

156 The mechanism for triggering Chs2 ER export thus far is unknown.

157 capture, or may be specifically employed in ER export to control deployment of nascent proteins.

158 l into COPII-enriched ER exit sites prior to ER export via a process that requires Sar1-GTPase.

159 i complex after mitosis failed to occur when ER export was blocked.

160 An in vitro assay for ER export was used to demonstrate preferential packaging

161 bilizing agonist ATP causes ALG-2 to depress ER export, while in neuroendocrine PC12 cells, Ca(2+) mo

162 ed LRP6 molecules undergo palmitoylation and ER export, while unsuccessfully folded proteins are, wit