小鼠 Slc32a1 抗体 | 抗体综述基于正式出版物

这是一篇来自已证抗体库的有关小鼠 Slc32a1的综述，是根据76篇发表使用所有方法的文章归纳的。这综述旨在帮助来邦网的访客找到最适合Slc32a1 抗体。

Slc32a1 同义词: R75019; VGAT; Viaat

Synaptic Systems

小鼠单克隆（117G4） 131 011	免疫组化-自由浮动切片; African green monkey; 1:500 免疫组化-自由浮动切片; 人类; 1:500	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131011)被用于被用于免疫组化-自由浮动切片在African green monkey样本上浓度为1:500 和被用于免疫组化-自由浮动切片在人类样本上浓度为1:500. Sci Rep (2022) ncbi
豚鼠多克隆 131 004	免疫组化-自由浮动切片; African green monkey; 1:400; 图 7f	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131004)被用于被用于免疫组化-自由浮动切片在African green monkey样本上浓度为1:400 (图 7f). Front Neural Circuits (2021) ncbi
小鼠单克隆（117G4） 131 011C3	免疫组化-自由浮动切片; 小鼠; 图 8a	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131011C3)被用于被用于免疫组化-自由浮动切片在小鼠样本上 (图 8a). EMBO J (2022) ncbi
豚鼠多克隆 131 004	免疫细胞化学; 人类; 1:1000; 图 6b	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 004)被用于被用于免疫细胞化学在人类样本上浓度为1:1000 (图 6b). Int J Mol Sci (2021) ncbi
豚鼠多克隆 131 004	免疫组化-冰冻切片; 小鼠; 1:200; 图 4a	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 004)被用于被用于免疫组化-冰冻切片在小鼠样本上浓度为1:200 (图 4a). Sci Rep (2021) ncbi
豚鼠多克隆 131 004	免疫组化-石蜡切片; 小鼠; 1:200; 图 1a	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131004)被用于被用于免疫组化-石蜡切片在小鼠样本上浓度为1:200 (图 1a). elife (2021) ncbi
豚鼠多克隆 131 004	免疫组化; 小鼠; 图 4i	Synaptic Systems Slc32a1抗体（SySy, 131 004)被用于被用于免疫组化在小鼠样本上 (图 4i). Cell Rep (2021) ncbi
domestic rabbit 多克隆 131 003	免疫组化; 小鼠; 1:1000; 图 5f	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 003)被用于被用于免疫组化在小鼠样本上浓度为1:1000 (图 5f). Nat Commun (2021) ncbi
domestic rabbit 多克隆 131 003	免疫组化-冰冻切片; 小鼠; 1:1000; 图 s8a	Synaptic Systems Slc32a1抗体（Synaptic System, 131003)被用于被用于免疫组化-冰冻切片在小鼠样本上浓度为1:1000 (图 s8a). Nat Commun (2021) ncbi
豚鼠多克隆 131 004	免疫组化-冰冻切片; 小鼠; 1:500; 图 1f	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131004)被用于被用于免疫组化-冰冻切片在小鼠样本上浓度为1:500 (图 1f). Cell Rep (2021) ncbi
domestic rabbit 多克隆 131 003	免疫组化-冰冻切片; 小鼠; 1:500; 图 6a	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131003)被用于被用于免疫组化-冰冻切片在小鼠样本上浓度为1:500 (图 6a). J Neurophysiol (2021) ncbi
小鼠单克隆（117G4） 131 011	免疫组化; 小鼠; 1:300; 图 7a	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131011)被用于被用于免疫组化在小鼠样本上浓度为1:300 (图 7a). Acta Neuropathol Commun (2021) ncbi
domestic rabbit 多克隆 131 003	免疫组化; 小鼠; 1:200; 图 8a	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 003)被用于被用于免疫组化在小鼠样本上浓度为1:200 (图 8a). Neural Plast (2021) ncbi
豚鼠多克隆 131 004	免疫组化; 小鼠; 1:200; 图 1b	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131004)被用于被用于免疫组化在小鼠样本上浓度为1:200 (图 1b). elife (2020) ncbi
domestic rabbit 多克隆 131 103C3	免疫细胞化学; 大鼠; 图 1i	Synaptic Systems Slc32a1抗体（SySy, 131 103 C3)被用于被用于免疫细胞化学在大鼠样本上 (图 1i). Proc Natl Acad Sci U S A (2020) ncbi
小鼠单克隆（117G4） 131 011	免疫印迹; 大鼠; 图 5s1	Synaptic Systems Slc32a1抗体（synaptic systems, 131 011)被用于被用于免疫印迹在大鼠样本上 (图 5s1). elife (2020) ncbi
domestic rabbit 多克隆 131 003	免疫细胞化学; 小鼠; 图 2n	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131003)被用于被用于免疫细胞化学在小鼠样本上 (图 2n). Neuron (2021) ncbi
小鼠单克隆（117G4） 131 011	免疫组化; 小鼠; 1:500; 图 4c	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 011)被用于被用于免疫组化在小鼠样本上浓度为1:500 (图 4c). elife (2020) ncbi
豚鼠多克隆 131 004	免疫组化; 小鼠; 1:500; 图 6a	Synaptic Systems Slc32a1抗体（SYSY, 131004)被用于被用于免疫组化在小鼠样本上浓度为1:500 (图 6a). Nat Commun (2020) ncbi
小鼠单克隆（117G4） 131 011	免疫组化-冰冻切片; 大鼠; 1:1000; 图 1f	Synaptic Systems Slc32a1抗体（Sysy, 131011)被用于被用于免疫组化-冰冻切片在大鼠样本上浓度为1:1000 (图 1f). Nat Commun (2020) ncbi
豚鼠多克隆 131 004	免疫组化-冰冻切片; 小鼠; 1:1000; 图 1b	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 004)被用于被用于免疫组化-冰冻切片在小鼠样本上浓度为1:1000 (图 1b). elife (2020) ncbi
鸡多克隆 131 006	免疫组化-冰冻切片; 小鼠; 1:1000; 图 1b	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 006)被用于被用于免疫组化-冰冻切片在小鼠样本上浓度为1:1000 (图 1b). elife (2020) ncbi
豚鼠多克隆 131 004	免疫组化; 大鼠; 1:500; 图 1e 免疫组化; 小鼠; 1:500; 图 5j	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 004)被用于被用于免疫组化在大鼠样本上浓度为1:500 (图 1e) 和被用于免疫组化在小鼠样本上浓度为1:500 (图 5j). Brain Struct Funct (2020) ncbi
domestic rabbit 多克隆 131 003	免疫组化; 大鼠; 1:500; 图 1e 免疫组化; 小鼠; 1:500; 图 5j	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 003)被用于被用于免疫组化在大鼠样本上浓度为1:500 (图 1e) 和被用于免疫组化在小鼠样本上浓度为1:500 (图 5j). Brain Struct Funct (2020) ncbi
豚鼠多克隆 131 004	免疫组化-冰冻切片; 小鼠; 1:1000; 图 4b	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131004)被用于被用于免疫组化-冰冻切片在小鼠样本上浓度为1:1000 (图 4b). Cell Rep (2020) ncbi
domestic rabbit 多克隆 131 002	免疫组化; 小鼠; 1:1000; 图 1c	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 002)被用于被用于免疫组化在小鼠样本上浓度为1:1000 (图 1c). J Comp Neurol (2019) ncbi
小鼠单克隆（117G4） 131 011	免疫组化-冰冻切片; 人类; 1:200; 图 7s1a 免疫细胞化学; 人类; 1:200; 图 5g 免疫印迹; 人类; 1:500; 图 5i	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 011)被用于被用于免疫组化-冰冻切片在人类样本上浓度为1:200 (图 7s1a), 被用于免疫细胞化学在人类样本上浓度为1:200 (图 5g) 和被用于免疫印迹在人类样本上浓度为1:500 (图 5i). elife (2019) ncbi
豚鼠多克隆 131 005	免疫组化-冰冻切片; 小鼠; 1:1000; 图 s1b	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131005)被用于被用于免疫组化-冰冻切片在小鼠样本上浓度为1:1000 (图 s1b). Science (2019) ncbi
domestic rabbit 多克隆 131 002	免疫细胞化学; 小鼠; 1:1000; 图 1a	Synaptic Systems Slc32a1抗体（Synaptic systems, 131002)被用于被用于免疫细胞化学在小鼠样本上浓度为1:1000 (图 1a). Science (2019) ncbi
domestic rabbit 多克隆 131 002	免疫细胞化学; 小鼠; 1:500; 图 3d	Synaptic Systems Slc32a1抗体（SYSY, 131002)被用于被用于免疫细胞化学在小鼠样本上浓度为1:500 (图 3d). Sci Adv (2019) ncbi
小鼠单克隆（117G4） 131 011	免疫组化-自由浮动切片; 小鼠; 1:500; 图 2a	Synaptic Systems Slc32a1抗体（SYSY, 131011)被用于被用于免疫组化-自由浮动切片在小鼠样本上浓度为1:500 (图 2a). J Comp Neurol (2019) ncbi
小鼠单克隆（117G4） 131 011	免疫组化; 小鼠; 1:200; 图 5c	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 011)被用于被用于免疫组化在小鼠样本上浓度为1:200 (图 5c). Neuron (2019) ncbi
domestic rabbit 多克隆 131 002	免疫细胞化学; 小鼠; 1:1500; 图 3a	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131002)被用于被用于免疫细胞化学在小鼠样本上浓度为1:1500 (图 3a). Front Cell Neurosci (2019) ncbi
豚鼠多克隆 131 004	免疫细胞化学; 小鼠; 1:1500; 图 3a	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131004)被用于被用于免疫细胞化学在小鼠样本上浓度为1:1500 (图 3a). Front Cell Neurosci (2019) ncbi
豚鼠多克隆 131 004	免疫组化-冰冻切片; 小鼠; 图 1c	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 004)被用于被用于免疫组化-冰冻切片在小鼠样本上 (图 1c). Science (2019) ncbi
小鼠单克隆（117G4） 131 011	免疫组化; 小鼠; 1:1000; 图 2i	Synaptic Systems Slc32a1抗体（SYSY, 131011)被用于被用于免疫组化在小鼠样本上浓度为1:1000 (图 2i). J Neurosci (2019) ncbi
domestic rabbit 多克隆 131 002	免疫组化-冰冻切片; 小鼠; 图 6h	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131002)被用于被用于免疫组化-冰冻切片在小鼠样本上 (图 6h). PLoS Biol (2019) ncbi
小鼠单克隆（117G4） 131 011	免疫组化-自由浮动切片; 小鼠; 1:100; 图 8d	Synaptic Systems Slc32a1抗体（SYSY, 131011)被用于被用于免疫组化-自由浮动切片在小鼠样本上浓度为1:100 (图 8d). Aging (Albany NY) (2019) ncbi
豚鼠多克隆 131 004	免疫细胞化学; 小鼠; 1:300; 图 3c	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131004)被用于被用于免疫细胞化学在小鼠样本上浓度为1:300 (图 3c). Front Mol Neurosci (2019) ncbi
小鼠单克隆（117G4） 131 011	免疫细胞化学; 小鼠; 图 s1h	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131011)被用于被用于免疫细胞化学在小鼠样本上 (图 s1h). Science (2019) ncbi
domestic rabbit 多克隆 131 003	免疫细胞化学; 豚鼠; 1:1000; 图 3b	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 003)被用于被用于免疫细胞化学在豚鼠样本上浓度为1:1000 (图 3b). J Neurosci (2019) ncbi
小鼠单克隆（117G4） 131 011	免疫印迹; 小鼠; 1:1250; 图 3g	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131011)被用于被用于免疫印迹在小鼠样本上浓度为1:1250 (图 3g). Mol Neurobiol (2019) ncbi
小鼠单克隆（117G4） 131 011	proximity ligation assay; 小鼠; 1:200; 图 s14e	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131011)被用于被用于proximity ligation assay在小鼠样本上浓度为1:200 (图 s14e). Mol Syst Biol (2018) ncbi
小鼠单克隆（117G4） 131 011	免疫组化-冰冻切片; 小鼠; 1:200; 图 2a	Synaptic Systems Slc32a1抗体（Synaptic systems, 131011)被用于被用于免疫组化-冰冻切片在小鼠样本上浓度为1:200 (图 2a). Exp Neurobiol (2018) ncbi
小鼠单克隆（117G4） 131 011	免疫组化; 小鼠; 1:1000; 图 4a 免疫组化-石蜡切片; 人类; 1:1000; 图 7g	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131-011)被用于被用于免疫组化在小鼠样本上浓度为1:1000 (图 4a) 和被用于免疫组化-石蜡切片在人类样本上浓度为1:1000 (图 7g). Brain Res (2019) ncbi
豚鼠多克隆 131 004	免疫组化; 小鼠; 1:500; 图 s2a	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131004)被用于被用于免疫组化在小鼠样本上浓度为1:500 (图 s2a). Nature (2017) ncbi
小鼠单克隆（117G4） 131 011	免疫组化; 大鼠; 1:200; 图 5f	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131011)被用于被用于免疫组化在大鼠样本上浓度为1:200 (图 5f). Hum Mol Genet (2017) ncbi
domestic rabbit 多克隆 131 003	免疫印迹; 小鼠; 1:10,000; 图 4c 免疫细胞化学; 人类; 1:1000; 图 1b	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 003)被用于被用于免疫印迹在小鼠样本上浓度为1:10,000 (图 4c) 和被用于免疫细胞化学在人类样本上浓度为1:1000 (图 1b). Nat Commun (2017) ncbi
豚鼠多克隆 131 004	免疫组化; 小鼠; 图 4b	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 004)被用于被用于免疫组化在小鼠样本上 (图 4b). elife (2017) ncbi
domestic rabbit 多克隆 131 003	免疫组化-冰冻切片; 小鼠; 1:300; 图 4b	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 003)被用于被用于免疫组化-冰冻切片在小鼠样本上浓度为1:300 (图 4b). J Neurosci (2017) ncbi
domestic rabbit 多克隆 131 003	免疫组化; 小鼠; 1:500; 图 1b	Synaptic Systems Slc32a1抗体（Synaptic systems, 131-003)被用于被用于免疫组化在小鼠样本上浓度为1:500 (图 1b). Front Neural Circuits (2017) ncbi
豚鼠多克隆 131 004	免疫组化-自由浮动切片; 小鼠; 1:500; 图 2a	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131004)被用于被用于免疫组化-自由浮动切片在小鼠样本上浓度为1:500 (图 2a). J Neurosci (2017) ncbi
domestic rabbit 多克隆 131 003	免疫细胞化学; 大鼠; 图 2b 免疫印迹; 大鼠; 图 1	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131,003)被用于被用于免疫细胞化学在大鼠样本上 (图 2b) 和被用于免疫印迹在大鼠样本上 (图 1). Front Cell Neurosci (2017) ncbi
小鼠单克隆（117G4） 131 011	免疫印迹; 小鼠; 图 6d	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131011)被用于被用于免疫印迹在小鼠样本上 (图 6d). Front Genet (2017) ncbi
domestic rabbit 多克隆 131 003	免疫组化; 小鼠; 1 ug/ml; 图 4c	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131003)被用于被用于免疫组化在小鼠样本上浓度为1 ug/ml (图 4c). Front Neuroanat (2016) ncbi
豚鼠多克隆 131 004	免疫组化; 小鼠; 1 ug/ml; 图 4c	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131004)被用于被用于免疫组化在小鼠样本上浓度为1 ug/ml (图 4c). Front Neuroanat (2016) ncbi
小鼠单克隆（117G4） 131 011 131 011C2	免疫细胞化学; 小鼠; 图 3b	Synaptic Systems Slc32a1抗体（Synaptic Systems, 117G4)被用于被用于免疫细胞化学在小鼠样本上 (图 3b). Proc Natl Acad Sci U S A (2016) ncbi
domestic rabbit 多克隆 131 003	免疫组化; 非洲爪蛙; 1:400; 图 4d	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 003)被用于被用于免疫组化在非洲爪蛙样本上浓度为1:400 (图 4d). J Neurophysiol (2016) ncbi
domestic rabbit 多克隆 131 013	免疫细胞化学; 大鼠; 图 6a	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 013)被用于被用于免疫细胞化学在大鼠样本上 (图 6a). Cell (2016) ncbi
豚鼠多克隆 131 004	免疫细胞化学; 小鼠; 1:500; 图 s5a	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 004)被用于被用于免疫细胞化学在小鼠样本上浓度为1:500 (图 s5a). Neuron (2016) ncbi
小鼠单克隆（117G4） 131 011	免疫组化; 小鼠; 1:5000; 图 5b	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131011)被用于被用于免疫组化在小鼠样本上浓度为1:5000 (图 5b). J Comp Neurol (2017) ncbi
domestic rabbit 多克隆 131 003	免疫细胞化学; 大鼠; 图 6a	Synaptic Systems Slc32a1抗体（Synaptic System, 131003)被用于被用于免疫细胞化学在大鼠样本上 (图 6a). ACS Nano (2016) ncbi
domestic rabbit 多克隆 131 013	免疫细胞化学; 人类; 1:500; 图 3	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131013)被用于被用于免疫细胞化学在人类样本上浓度为1:500 (图 3). J Biol Chem (2016) ncbi
domestic rabbit 多克隆 131 002	免疫细胞化学; 大鼠; 1:400; 表 3	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 002)被用于被用于免疫细胞化学在大鼠样本上浓度为1:400 (表 3). Cell Mol Life Sci (2016) ncbi
豚鼠多克隆 131 004	免疫组化-冰冻切片; 小鼠; 1:250; 图 4	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 004)被用于被用于免疫组化-冰冻切片在小鼠样本上浓度为1:250 (图 4). Nat Neurosci (2016) ncbi
domestic rabbit 多克隆 131 002	免疫印迹; 小鼠; 图 2	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131002)被用于被用于免疫印迹在小鼠样本上 (图 2). Sci Rep (2016) ncbi
豚鼠多克隆 131 004	免疫组化-冰冻切片; 小鼠; 1:500; 图 6	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 004)被用于被用于免疫组化-冰冻切片在小鼠样本上浓度为1:500 (图 6). Front Cell Neurosci (2016) ncbi
domestic rabbit 多克隆 131 003	免疫印迹; 小鼠; 图 1	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131003)被用于被用于免疫印迹在小鼠样本上 (图 1). Stem Cell Reports (2016) ncbi
豚鼠多克隆 131 004	免疫细胞化学; 小鼠; 1:700; 表 1	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131004)被用于被用于免疫细胞化学在小鼠样本上浓度为1:700 (表 1). J Neurosci Res (2016) ncbi
小鼠单克隆（117G4） 131 011	免疫印迹; 大鼠; 1:500	Synaptic Systems Slc32a1抗体（Synaptic System, 131011)被用于被用于免疫印迹在大鼠样本上浓度为1:500. Front Cell Neurosci (2015) ncbi
小鼠单克隆（117G4） 131 011	免疫细胞化学; 小鼠; 1:500; 图 6	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 011)被用于被用于免疫细胞化学在小鼠样本上浓度为1:500 (图 6). Nat Neurosci (2015) ncbi
豚鼠多克隆 131 004		Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 004)被用于. elife (2015) ncbi
小鼠单克隆（117G4） 131 011	免疫组化; 小鼠; 图 4	Synaptic Systems Slc32a1抗体（SynapticSystems, 131 011)被用于被用于免疫组化在小鼠样本上 (图 4). Front Neuroanat (2015) ncbi
小鼠单克隆（117G4） 131 011	免疫组化-自由浮动切片; 小鼠; 1:100; 图 s8	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 011)被用于被用于免疫组化-自由浮动切片在小鼠样本上浓度为1:100 (图 s8). Nature (2015) ncbi
小鼠单克隆（117G4） 131 011	免疫组化; 小鼠; 1:1000; 图 8E	Synaptic Systems Slc32a1抗体（Synaptic Systems, 131 011)被用于被用于免疫组化在小鼠样本上浓度为1:1000 (图 8E). J Comp Neurol (2015) ncbi
小鼠单克隆（117G4） 131 011	免疫组化-冰冻切片; 大鼠	Synaptic Systems Slc32a1抗体（sysy, 131011)被用于被用于免疫组化-冰冻切片在大鼠样本上. Brain Res (2015) ncbi
小鼠单克隆（117G4） 131 011	免疫细胞化学; 小鼠; 1:100; 图 s4	Synaptic Systems Slc32a1抗体（SYSY, 131011)被用于被用于免疫细胞化学在小鼠样本上浓度为1:100 (图 s4). Nat Neurosci (2014) ncbi

圣克鲁斯生物技术

小鼠单克隆（F-2）

sc-393373

免疫印迹; 人类; 1 ug/ml; 图 1

圣克鲁斯生物技术 Slc32a1抗体（Santa Cruz, sc-393373)被用于被用于免疫印迹在人类样本上浓度为1 ug/ml (图 1). Nat Commun (2015) ncbi

赛默飞世尔

小鼠单克隆（CL2793）

MA5-24643

免疫组化-冰冻切片; 小鼠; 1:200; 图 3s2a

赛默飞世尔 Slc32a1抗体（分子探针, MA5-24643)被用于被用于免疫组化-冰冻切片在小鼠样本上浓度为1:200 (图 3s2a). elife (2018) ncbi

西格玛奥德里奇

domestic rabbit 多克隆

V5764

免疫细胞化学; 小鼠; 1:100; 图 2d

西格玛奥德里奇 Slc32a1抗体（Sigma-Aldrich, V5764)被用于被用于免疫细胞化学在小鼠样本上浓度为1:100 (图 2d). Histochem Cell Biol (2016) ncbi

文章列表

Chou S, Ranganath T, Fish K, Lewis D, Sweet R. Cell type specific cannabinoid CB1 receptor distribution across the human and non-human primate cortex. Sci Rep. 2022;12:9605 pubmed 出版商
Tsolias A, Medalla M. Muscarinic Acetylcholine Receptor Localization on Distinct Excitatory and Inhibitory Neurons Within the ACC and LPFC of the Rhesus Monkey. Front Neural Circuits. 2021;15:795325 pubmed 出版商
Reifschneider A, Robinson S, van Lengerich B, Gnörich J, Logan T, Heindl S, et al. Loss of TREM2 rescues hyperactivation of microglia, but not lysosomal deficits and neurotoxicity in models of progranulin deficiency. EMBO J. 2022;41:e109108 pubmed 出版商
Tate K, Kirk B, Tseng A, Ulffers A, LITWA K. Effects of the Selective Serotonin Reuptake Inhibitor Fluoxetine on Developing Neural Circuits in a Model of the Human Fetal Cortex. Int J Mol Sci. 2021;22: pubmed 出版商
Komorowska Müller J, Ravichandran K, Zimmer A, Schürmann B. Cannabinoid receptor 2 deletion influences social memory and synaptic architecture in the hippocampus. Sci Rep. 2021;11:16828 pubmed 出版商
Guo C, Rudolph S, Neuwirth M, Regehr W. Purkinje cell outputs selectively inhibit a subset of unipolar brush cells in the input layer of the cerebellar cortex. elife. 2021;10: pubmed 出版商
Kohnke S, Buller S, Nuzzaci D, Ridley K, Lam B, Pivonkova H, et al. Nutritional regulation of oligodendrocyte differentiation regulates perineuronal net remodeling in the median eminence. Cell Rep. 2021;36:109362 pubmed 出版商
Tamada K, Fukumoto K, Toya T, Nakai N, Awasthi J, Tanaka S, et al. Genetic dissection identifies Necdin as a driver gene in a mouse model of paternal 15q duplications. Nat Commun. 2021;12:4056 pubmed 出版商
Amegandjin C, Choudhury M, Jadhav V, Carriço J, Quintal A, Berryer M, et al. Sensitive period for rescuing parvalbumin interneurons connectivity and social behavior deficits caused by TSC1 loss. Nat Commun. 2021;12:3653 pubmed 出版商
Magno L, Asgarian Z, Pendolino V, Velona T, Mackintosh A, Lee F, et al. Transient developmental imbalance of cortical interneuron subtypes presages long-term changes in behavior. Cell Rep. 2021;35:109249 pubmed 出版商
Jami S, Cameron S, Wong J, Daly E, McAllister A, Gray J. Increased excitation-inhibition balance and loss of GABAergic synapses in the serine racemase knockout model of NMDA receptor hypofunction. J Neurophysiol. 2021;126:11-27 pubmed 出版商
Frew J, Nygaard H. Neuropathological and behavioral characterization of aged Grn R493X progranulin-deficient frontotemporal dementia knockin mice. Acta Neuropathol Commun. 2021;9:57 pubmed 出版商
Zhang L, Wu C, Martel D, West M, Sutton M, Shore S. Noise Exposure Alters Glutamatergic and GABAergic Synaptic Connectivity in the Hippocampus and Its Relevance to Tinnitus. Neural Plast. 2021;2021:8833087 pubmed 出版商
Turecek J, Regehr W. Cerebellar and vestibular nuclear synapses in the inferior olive have distinct release kinetics and neurotransmitters. elife. 2020;9: pubmed 出版商
Cho I, Panzera L, Chin M, Alpizar S, Olveda G, Hill R, et al. The potassium channel subunit Kvβ1 serves as a major control point for synaptic facilitation. Proc Natl Acad Sci U S A. 2020;117:29937-29947 pubmed 出版商
Kreutzberger A, Kiessling V, Doyle C, Schenk N, Upchurch C, Elmer Dixon M, et al. Distinct insulin granule subpopulations implicated in the secretory pathology of diabetes types 1 and 2. elife. 2020;9: pubmed 出版商
Kuijpers M, Kochlamazashvili G, Stumpf A, Puchkov D, Swaminathan A, Lucht M, et al. Neuronal Autophagy Regulates Presynaptic Neurotransmission by Controlling the Axonal Endoplasmic Reticulum. Neuron. 2021;109:299-313.e9 pubmed 出版商
Granger A, Wang W, Robertson K, El Rifai M, Zanello A, Bistrong K, et al. Cortical ChAT+ neurons co-transmit acetylcholine and GABA in a target- and brain-region-specific manner. elife. 2020;9: pubmed 出版商
Wu Z, Parry M, Hou X, Liu M, Wang H, Cain R, et al. Gene therapy conversion of striatal astrocytes into GABAergic neurons in mouse models of Huntington's disease. Nat Commun. 2020;11:1105 pubmed 出版商
Lorenzo L, Godin A, Ferrini F, Bachand K, Plasencia Fernandez I, Labrecque S, et al. Enhancing neuronal chloride extrusion rescues α2/α3 GABAA-mediated analgesia in neuropathic pain. Nat Commun. 2020;11:869 pubmed 出版商
Pelkey K, Calvigioni D, Fang C, Vargish G, Ekins T, Auville K, et al. Paradoxical network excitation by glutamate release from VGluT3+ GABAergic interneurons. elife. 2020;9: pubmed 出版商
Katona L, Hartwich K, Tomioka R, Somogyi J, Roberts J, Wagner K, et al. Synaptic organisation and behaviour-dependent activity of mGluR8a-innervated GABAergic trilaminar cells projecting from the hippocampus to the subiculum. Brain Struct Funct. 2020;225:705-734 pubmed 出版商
Burrus C, McKinstry S, Kim N, Ozlu M, Santoki A, Fang F, et al. Striatal Projection Neurons Require Huntingtin for Synaptic Connectivity and Survival. Cell Rep. 2020;30:642-657.e6 pubmed 出版商
Carceller H, Guirado R, Nacher J. Dark exposure affects plasticity-related molecules and interneurons throughout the visual system during adulthood. J Comp Neurol. 2019;: pubmed 出版商
Ghatak S, Dolatabadi N, Trudler D, Zhang X, Wu Y, Mohata M, et al. Mechanisms of hyperexcitability in Alzheimer's disease hiPSC-derived neurons and cerebral organoids vs isogenic controls. elife. 2019;8: pubmed 出版商
Otsu Y, Darcq E, Pietrajtis K, Matyas F, Schwartz E, Bessaih T, et al. Control of aversion by glycine-gated GluN1/GluN3A NMDA receptors in the adult medial habenula. Science. 2019;366:250-254 pubmed 出版商
Han W, Li J, Pelkey K, Pandey S, Chen X, Wang Y, et al. Shisa7 is a GABAA receptor auxiliary subunit controlling benzodiazepine actions. Science. 2019;366:246-250 pubmed 出版商
Guo H, Li Y, Shen L, Wang T, Jia X, Liu L, et al. Disruptive variants of CSDE1 associate with autism and interfere with neuronal development and synaptic transmission. Sci Adv. 2019;5:eaax2166 pubmed 出版商
Collins L, Brunjes P. The mouse olfactory peduncle 4: Development of synapses, perineuronal nets, and capillaries. J Comp Neurol. 2019;: pubmed 出版商
Pan H, Fatima M, Li A, Lee H, Cai W, Horwitz L, et al. Identification of a Spinal Circuit for Mechanical and Persistent Spontaneous Itch. Neuron. 2019;103:1135-1149.e6 pubmed 出版商
Duan J, Pandey S, Li T, Castellano D, Gu X, Li J, et al. Genetic Deletion of GABAA Receptors Reveals Distinct Requirements of Neurotransmitter Receptors for GABAergic and Glutamatergic Synapse Development. Front Cell Neurosci. 2019;13:217 pubmed 出版商
Szonyi A, Sos K, Nyilas R, Schlingloff D, Domonkos A, Takács V, et al. Brainstem nucleus incertus controls contextual memory formation. Science. 2019;364: pubmed 出版商
Popova D, Desai N, Blendy J, Pang Z. Synaptic regulation by OPRM1 variants in reward neurocircuitry. J Neurosci. 2019;: pubmed 出版商
Rojek K, Krzemien J, Dolezyczek H, Boguszewski P, Kaczmarek L, Konopka W, et al. Amot and Yap1 regulate neuronal dendritic tree complexity and locomotor coordination in mice. PLoS Biol. 2019;17:e3000253 pubmed 出版商
Duan W, Guo M, Yi L, Zhang J, Bi Y, Liu Y, et al. Deletion of Tbk1 disrupts autophagy and reproduces behavioral and locomotor symptoms of FTD-ALS in mice. Aging (Albany NY). 2019;11:2457-2476 pubmed 出版商
Upadhyay A, Hosseinibarkooie S, Schneider S, Kaczmarek A, Torres Benito L, Mendoza Ferreira N, et al. Neurocalcin Delta Knockout Impairs Adult Neurogenesis Whereas Half Reduction Is Not Pathological. Front Mol Neurosci. 2019;12:19 pubmed 出版商
Awasthi A, Ramachandran B, Ahmed S, Benito E, Shinoda Y, Nitzan N, et al. Synaptotagmin-3 drives AMPA receptor endocytosis, depression of synapse strength, and forgetting. Science. 2019;363: pubmed 出版商
Olthof B, Gartside S, Rees A. Puncta of Neuronal Nitric Oxide Synthase (nNOS) Mediate NMDA Receptor Signaling in the Auditory Midbrain. J Neurosci. 2019;39:876-887 pubmed 出版商
Kaczmarek Hájek K, Zhang J, Kopp R, Grosche A, Rissiek B, Saul A, et al. Re-evaluation of neuronal P2X7 expression using novel mouse models and a P2X7-specific nanobody. elife. 2018;7: pubmed 出版商
Chmielewska J, Kuzniewska B, Milek J, Urbanska K, Dziembowska M. Neuroligin 1, 2, and 3 Regulation at the Synapse: FMRP-Dependent Translation and Activity-Induced Proteolytic Cleavage. Mol Neurobiol. 2019;56:2741-2759 pubmed 出版商
Trepte P, Kruse S, Kostova S, Hoffmann S, Buntru A, Tempelmeier A, et al. LuTHy: a double-readout bioluminescence-based two-hybrid technology for quantitative mapping of protein-protein interactions in mammalian cells. Mol Syst Biol. 2018;14:e8071 pubmed 出版商
Nam M, Han K, Lee J, Bae J, An H, Park S, et al. Expression of µ-Opioid Receptor in CA1 Hippocampal Astrocytes. Exp Neurobiol. 2018;27:120-128 pubmed 出版商
Dunn A, Hoffman C, Stout K, Ozawa M, Dhamsania R, Miller G. Immunochemical analysis of the expression of SV2C in mouse, macaque and human brain. Brain Res. 2019;1702:85-95 pubmed 出版商
Turecek J, Jackman S, Regehr W. Synaptotagmin 7 confers frequency invariance onto specialized depressing synapses. Nature. 2017;551:503-506 pubmed 出版商
Farhan S, Nixon K, Everest M, Edwards T, Long S, Segal D, et al. Identification of a novel synaptic protein, TMTC3, involved in periventricular nodular heterotopia with intellectual disability and epilepsy. Hum Mol Genet. 2017;26:4278-4289 pubmed 出版商
Tanabe Y, Naito Y, Vasuta C, Lee A, Soumounou Y, Linhoff M, et al. IgSF21 promotes differentiation of inhibitory synapses via binding to neurexin2?. Nat Commun. 2017;8:408 pubmed 出版商
Martenson J, Yamasaki T, Chaudhury N, Albrecht D, Tomita S. Assembly rules for GABAA receptor complexes in the brain. elife. 2017;6: pubmed 出版商
Schaefer N, Berger A, van Brederode J, Zheng F, Zhang Y, Leacock S, et al. Disruption of a Structurally Important Extracellular Element in the Glycine Receptor Leads to Decreased Synaptic Integration and Signaling Resulting in Severe Startle Disease. J Neurosci. 2017;37:7948-7961 pubmed 出版商
Zhang X, Sullivan C, Kratz M, Kasten M, Maness P, Manis P. NCAM Regulates Inhibition and Excitability in Layer 2/3 Pyramidal Cells of Anterior Cingulate Cortex. Front Neural Circuits. 2017;11:19 pubmed 出版商
Bouhours B, Gjoni E, Kochubey O, Schneggenburger R. Synaptotagmin2 (Syt2) Drives Fast Release Redundantly with Syt1 at the Output Synapses of Parvalbumin-Expressing Inhibitory Neurons. J Neurosci. 2017;37:4604-4617 pubmed 出版商
Latina V, Caioli S, Zona C, Ciotti M, Amadoro G, Calissano P. Impaired NGF/TrkA Signaling Causes Early AD-Linked Presynaptic Dysfunction in Cholinergic Primary Neurons. Front Cell Neurosci. 2017;11:68 pubmed 出版商
Larimore J, Zlatic S, Arnold M, Singleton K, Cross R, Rudolph H, et al. Dysbindin Deficiency Modifies the Expression of GABA Neuron and Ion Permeation Transcripts in the Developing Hippocampus. Front Genet. 2017;8:28 pubmed 出版商
Sohn J, Okamoto S, Kataoka N, Kaneko T, Nakamura K, Hioki H. Differential Inputs to the Perisomatic and Distal-Dendritic Compartments of VIP-Positive Neurons in Layer 2/3 of the Mouse Barrel Cortex. Front Neuroanat. 2016;10:124 pubmed 出版商
Egashira Y, Takase M, Watanabe S, Ishida J, Fukamizu A, Kaneko R, et al. Unique pH dynamics in GABAergic synaptic vesicles illuminates the mechanism and kinetics of GABA loading. Proc Natl Acad Sci U S A. 2016;113:10702-7 pubmed 出版商
Gambrill A, Faulkner R, Cline H. Experience-dependent plasticity of excitatory and inhibitory intertectal inputs in Xenopus tadpoles. J Neurophysiol. 2016;116:2281-2297 pubmed 出版商
Loh K, Stawski P, Draycott A, Udeshi N, Lehrman E, Wilton D, et al. Proteomic Analysis of Unbounded Cellular Compartments: Synaptic Clefts. Cell. 2016;166:1295-1307.e21 pubmed 出版商
Redmond S, Mei F, Eshed Eisenbach Y, Osso L, Leshkowitz D, Shen Y, et al. Somatodendritic Expression of JAM2 Inhibits Oligodendrocyte Myelination. Neuron. 2016;91:824-836 pubmed 出版商
Hamamoto M, Kiyokage E, Sohn J, Hioki H, Harada T, Toida K. Structural basis for cholinergic regulation of neural circuits in the mouse olfactory bulb. J Comp Neurol. 2017;525:574-591 pubmed 出版商
Bramini M, Sacchetti S, Armirotti A, Rocchi A, Vazquez E, León Castellanos V, et al. Graphene Oxide Nanosheets Disrupt Lipid Composition, Ca(2+) Homeostasis, and Synaptic Transmission in Primary Cortical Neurons. ACS Nano. 2016;10:7154-71 pubmed 出版商
Brown L, Nicholson M, Arama J, Mercer A, Thomson A, Jovanovic J. ?-Aminobutyric Acid Type A (GABAA) Receptor Subunits Play a Direct Structural Role in Synaptic Contact Formation via Their N-terminal Extracellular Domains. J Biol Chem. 2016;291:13926-42 pubmed 出版商
Bartelt Kirbach B, Moron M, Glomb M, Beck C, Weller M, Golenhofen N. HspB5/?B-crystallin increases dendritic complexity and protects the dendritic arbor during heat shock in cultured rat hippocampal neurons. Cell Mol Life Sci. 2016;73:3761-75 pubmed 出版商
Rossi M, Li H, Lu D, Kim I, Bartholomew R, Gaidis E, et al. A GABAergic nigrotectal pathway for coordination of drinking behavior. Nat Neurosci. 2016;19:742-748 pubmed 出版商
Hayashi Y, Nishimune H, Hozumi K, Saga Y, Harada A, Yuzaki M, et al. A novel non-canonical Notch signaling regulates expression of synaptic vesicle proteins in excitatory neurons. Sci Rep. 2016;6:23969 pubmed 出版商
Gao Y, Heldt S. Enrichment of GABAA Receptor Î±-Subunits on the Axonal Initial Segment Shows Regional Differences. Front Cell Neurosci. 2016;10:39 pubmed 出版商
Uda Y, Xu S, Matsumura T, Takei Y. P2Y4 Nucleotide Receptor in Neuronal Precursors Induces Glutamatergic Subtype Markers in Their Descendant Neurons. Stem Cell Reports. 2016;6:474-482 pubmed 出版商
Schwale C, Schumacher S, Bruehl C, Titz S, Schlicksupp A, Kokocinska M, et al. KCC2 knockdown impairs glycinergic synapse maturation in cultured spinal cord neurons. Histochem Cell Biol. 2016;145:637-46 pubmed 出版商
Leshchyns ka I, Liew H, Shepherd C, Halliday G, Stevens C, Ke Y, et al. AÎ²-dependent reduction of NCAM2-mediated synaptic adhesion contributes to synapse loss in Alzheimer's disease. Nat Commun. 2015;6:8836 pubmed 出版商
Hirata H, Umemori J, Yoshioka H, Koide T, Watanabe K, Shimoda Y. Cell adhesion molecule contactin-associated protein 3 is expressed in the mouse basal ganglia during early postnatal stages. J Neurosci Res. 2016;94:74-89 pubmed 出版商
Bragina L, Bonifacino T, Bassi S, Milanese M, Bonanno G, Conti F. Differential expression of metabotropic glutamate and GABA receptors at neocortical glutamatergic and GABAergic axon terminals. Front Cell Neurosci. 2015;9:345 pubmed 出版商
Aoto J, FÃ¶ldy C, Ilcus S, Tabuchi K, SÃ¼dhof T. Distinct circuit-dependent functions of presynaptic neurexin-3 at GABAergic and glutamatergic synapses. Nat Neurosci. 2015;18:997-1007 pubmed 出版商
Orduz D, Maldonado P, Balia M, VÃ©lez Fort M, de Sars V, Yanagawa Y, et al. Interneurons and oligodendrocyte progenitors form a structured synaptic network in the developing neocortex. elife. 2015;4: pubmed 出版商
Blanqué A, Repetto D, Rohlmann A, Brockhaus J, Duning K, PavenstÃ¤dt H, et al. Deletion of KIBRA, protein expressed in kidney and brain, increases filopodial-like long dendritic spines in neocortical and hippocampal neurons in vivo and in vitro. Front Neuroanat. 2015;9:13 pubmed 出版商
Saunders A, Oldenburg I, Berezovskii V, Johnson C, Kingery N, Elliott H, et al. A direct GABAergic output from the basal ganglia to frontal cortex. Nature. 2015;521:85-9 pubmed 出版商
PÃ©rez de Sevilla MÃ¼ller L, Sargoy A, FernÃ¡ndez SÃ¡nchez L, Rodriguez A, Liu J, Cuenca N, et al. Expression and cellular localization of the voltage-gated calcium channel Î±2Î´3 in the rodent retina. J Comp Neurol. 2015;523:1443-60 pubmed 出版商
Lee J, Lee E, Lee H. Hypothalamic, feeding/arousal-related peptidergic projections to the paraventricular thalamic nucleus in the rat. Brain Res. 2015;1598:97-113 pubmed 出版商
Atasoy D, Betley J, Li W, Su H, Sertel S, Scheffer L, et al. A genetically specified connectomics approach applied to long-range feeding regulatory circuits. Nat Neurosci. 2014;17:1830-9 pubmed 出版商

外链

问题和意见