ABCC7 p.Thr339Cys
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PMID: 18056267
[PubMed]
Beck EJ et al: "Conformational changes in a pore-lining helix coupled to cystic fibrosis transmembrane conductance regulator channel gating."
No.
Sentence
Comment
100
The oocytes 750 500 250 0 µS 180012006000 s IBMX MTSEA Cd 2+ DTT 200 100 0 µS 180012006000 s IBMX DTT Cd 2+ MTSEA A B C -100 -80 -60 -40 -20 0 20 40 % Change in conductance Y325C A326C L327C I328C K329C G330C I331C I332C L333C R334C K335C I336C F337C T338C T339C I340C S341C F342C WT I344C V345C R347C M348C A349C V350C T351C Q353C * * * * * Cd 2+ 1mM MTSEA 1mM D FIGURE 1.
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ABCC7 p.Thr339Cys 18056267:100:267
status: NEW
PMID: 19754156
[PubMed]
Alexander C et al: "Cystic fibrosis transmembrane conductance regulator: using differential reactivity toward channel-permeant and channel-impermeant thiol-reactive probes to test a molecular model for the pore."
No.
Sentence
Comment
52
We proposed that these spontaneous changes, that are not seen in either wt or Cys-less CFTR, reflect the coordination of trace Table 1: Percent Change in Oocyte Conductance in the Presence of Compounda MTSETþ MTSES- [Ag(CN)2]- [Au(CN)2]- G330C O O O O I331C -51.6 ( 6.3 -28.9 ( 2.1 -63.1 ( 8.8 O I332C O O O O L333C -58.5 ( 4.8 -47.5 ( 7.6 -83.1 ( 2.2 O R334C þ76.9 ( 11.3 -84.4 ( 1.5 -67.4 ( 7.4 -41.4 ( 3.1 K335C þ10.7 ( 2.4 -37.3 ( 1.5 -29.1 ( 6.4 -54.6 ( 4.7 I336C -54.4 ( 7.9 -75.0 ( 0.6 -81.2 ( 10.5 O F337C O O -89.6 ( 1.9 -90.1 ( 1.3 T338C -37.1 ( 3.3 -85.4 ( 2.5 -75.0 ( 5.2 -88.3 ( 1.6 T339C O O -24.5 ( 7.2 O I340C O O -93.8 ( 1.0 O S341C O O -49.3 ( 4.8 O F342C O O -84.7 ( 1.8 O C343 O O O O I344C O O -66.9 ( 9.3 -77.9 ( 2.1 V345C O O -49.1 ( 9.3 O L346C O O O O R347C O O O O M348C O O -47.9 ( 8.8 -50.1 ( 3.3 A349C O O -19.0 ( 2.0 O V350C O O O O T351C O O O O R352C O O -77.5 ( 1.3 O Q353C O O -72.6 ( 4.5 -76.7 ( 2.8 a Values are means ( SE of three or more oocytes.
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ABCC7 p.Thr339Cys 19754156:52:611
status: NEW
PMID: 9729613
[PubMed]
Linsdell P et al: "Non-pore lining amino acid side chains influence anion selectivity of the human CFTR Cl- channel expressed in mammalian cell lines."
No.
Sentence
Comment
238
Both T339A (McDonough et al. 1994) and T339C (Cheung & Akabas, 1996) mutant channels can be expressed in Xenopus oocytes following injection of in vitro transcribed cRNA.
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ABCC7 p.Thr339Cys 9729613:238:39
status: NEW
No.
Sentence
Comment
248
However, because the mutations T338C and T339C did not react with MTS reagents, the side PKA phosphorylation but did not substitute for ATP in opening phosphorylated CFTR Cl0 channels.chains of these residues do not interact with permeating ions (31, 77).
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ABCC7 p.Thr339Cys 9922375:248:41
status: NEW
PMID: 22014307
[PubMed]
Liu X et al: "Cystic fibrosis transmembrane conductance regulator: temperature-dependent cysteine reactivity suggests different stable conformers of the conduction pathway."
No.
Sentence
Comment
131
The values at 37 °C (gray bars) from T339C to V345C reflect small changes in conductance in response to the temperature pulse, rather than reactivity toward MTSES- .
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ABCC7 p.Thr339Cys 22014307:131:42
status: NEW
PMID: 8744306
[PubMed]
Cheung M et al: "Identification of cystic fibrosis transmembrane conductance regulator channel-lining residues in and flanking the M6 membrane-spanning segment."
No.
Sentence
Comment
86
The peak current at -100 mV was -7117 ± 511 nA for the wild type, and ranged from -1709 ± 124 nA for the R347C mutant to -7709 + 700 nA for the T339C mutant (Fig. 2 A).
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ABCC7 p.Thr339Cys 8744306:86:154
status: NEW91 Effects of MTS reagents on wild-type cysteines RESULTS in CFTR To identify the residues in and flanking the M6 membrane-spanning segment that are on the water-exposed surface of As reported previously (Akabas et al., 1994b), extracellular applications of the MTS reagents to Xenopus oocytes ex- L2j K329C L. _J *G330C 1331C 1332C L333C R334C K335C 1336C F337C T338C T339C 1340C S341C T342C C343,WT 1344C V345C L346C R347C M348C A349C V350C T351C R352C Q353C 0 2000 4000 6000 8000 0 25 50 PEAK CURRENTS (nA) TIME TO REACH PLATEAU (min) FIGURE 2 Peak CFTR-induced currents and time to reach the plateau current after stimulation with cAMP-activating reagents for 24 cysteine-substitution mutants and wild-type CFTR.
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ABCC7 p.Thr339Cys 8744306:91:366
status: NEW85 The peak current at -100 mV was -7117 &#b1; 511 nA for the wild type, and ranged from -1709 &#b1; 124 nA for the R347C mutant to -7709 + 700 nA for the T339C mutant (Fig. 2 A).
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ABCC7 p.Thr339Cys 8744306:85:152
status: NEW90 Effects of MTS reagents on wild-type cysteines RESULTS in CFTR To identify the residues in and flanking the M6 membrane-spanning segment that are on the water-exposed surface of As reported previously (Akabas et al., 1994b), extracellular applications of the MTS reagents to Xenopus oocytes ex- L2j K329C L. _J *G330C 1331C 1332C L333C R334C K335C 1336C F337C T338C T339C 1340C S341C T342C C343,WT 1344C V345C L346C R347C M348C A349C V350C T351C R352C Q353C 0 2000 4000 6000 8000 0 25 50 PEAK CURRENTS (nA) TIME TO REACH PLATEAU (min) FIGURE 2 Peak CFTR-induced currents and time to reach the plateau current after stimulation with cAMP-activating reagents for 24 cysteine-substitution mutants and wild-type CFTR.
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ABCC7 p.Thr339Cys 8744306:90:366
status: NEW