PDB-7mvx: Crystal structure of the Chaetomium thermophilum Nup188-Nic96 com...

基本情報

• 登録情報: データベース: PDB / ID: 7mvx
• タイトル: Crystal structure of the Chaetomium thermophilum Nup188-Nic96 complex (Nup188 residues 1-1858; Nic96 residues 240-301)

要素

• Nucleoporin NIC96
• Nucleoporin NUP188

• キーワード: TRANSPORT PROTEIN / nuclear pore complex / nucleocytoplasmic transport / alpha-helical solenoid / nuclear pore

機能・相同性

分子機能:

nuclear pore inner ring / structural constituent of nuclear pore / RNA export from nucleus / poly(A)+ mRNA export from nucleus / mRNA transport / nuclear pore / protein import into nucleus / nuclear membrane

ドメイン・相同性:

Nup188 SH3-like domain / Nuclear pore protein Nup188, C-terminal / Nuclear pore protein NUP188 C-terminal domain / Nucleoporin Nup188, N-terminal / Nucleoporin Nup188, N-terminal / Nucleoporin Nup188 / : / Nucleoporin Nup188, N-terminal subdomain III / Nucleoporin interacting component Nup93/Nic96 / Nup93/Nic96

構成要素:

Nucleoporin NIC96 / Nucleoporin NUP188

• 生物種: Chaetomium thermophilum (菌類)
• 手法: X線回折 / シンクロトロン / 単波長異常分散 / 解像度: 4.35 Å
• データ登録者: Petrovic, S. / Samanta, D. / Perriches, T. / Bley, C.J. / Thierbach, K. / Brown, B. / Nie, S. / Mobbs, G.W. / Stevens, T.A. / Liu, X. / Tomaleri, G.P. / Schaus, L. / Hoelz, A.

資金援助

米国, 4件

組織	認可番号	国
National Institutes of Health/National Institute of General Medical Sciences (NIH/NIGMS)	GM117360	米国
National Institutes of Health/National Institute of General Medical Sciences (NIH/NIGMS)	GM111461	米国
Howard Hughes Medical Institute (HHMI)	55108534	米国
Heritage Medical Research Institute

• 引用: ジャーナル: Science / 年: 2022; タイトル: Architecture of the linker-scaffold in the nuclear pore.; 著者: Stefan Petrovic / Dipanjan Samanta / Thibaud Perriches / Christopher J Bley / Karsten Thierbach / Bonnie Brown / Si Nie / George W Mobbs / Taylor A Stevens / Xiaoyu Liu / Giovani Pinton Tomaleri / Lucas Schaus / André Hoelz / ; 要旨: INTRODUCTION In eukaryotic cells, the selective bidirectional transport of macromolecules between the nucleus and cytoplasm occurs through the nuclear pore complex (NPC). Embedded in nuclear envelope pores, the ~110-MDa human NPC is an ~1200-Å-wide and ~750-Å-tall assembly of ~1000 proteins, collectively termed nucleoporins. Because of the NPC's eightfold rotational symmetry along the nucleocytoplasmic axis, each of the ~34 different nucleoporins occurs in multiples of eight. Architecturally, the NPC's symmetric core is composed of an inner ring encircling the central transport channel and two outer rings anchored on both sides of the nuclear envelope. Because of its central role in the flow of genetic information from DNA to RNA to protein, the NPC is commonly targeted in viral infections and its nucleoporin constituents are associated with a plethora of diseases. RATIONALE Although the arrangement of most scaffold nucleoporins in the NPC's symmetric core was determined by quantitative docking of crystal structures into cryo-electron tomographic (cryo-ET) maps of intact NPCs, the topology and molecular details of their cohesion by multivalent linker nucleoporins have remained elusive. Recently, in situ cryo-ET reconstructions of NPCs from various species have indicated that the NPC's inner ring is capable of reversible constriction and dilation in response to variations in nuclear envelope membrane tension, thereby modulating the diameter of the central transport channel by ~200 Å. We combined biochemical reconstitution, high-resolution crystal and single-particle cryo-electron microscopy (cryo-EM) structure determination, docking into cryo-ET maps, and physiological validation to elucidate the molecular architecture of the linker-scaffold interaction network that not only is essential for the NPC's integrity but also confers the plasticity and robustness necessary to allow and withstand such large-scale conformational changes. RESULTS By biochemically mapping scaffold-binding regions of all fungal and human linker nucleoporins and determining crystal and single-particle cryo-EM structures of linker-scaffold complexes, we completed the characterization of the biochemically tractable linker-scaffold network and established its evolutionary conservation, despite considerable sequence divergence. We determined a series of crystal and single-particle cryo-EM structures of the intact Nup188 and Nup192 scaffold hubs bound to their Nic96, Nup145N, and Nup53 linker nucleoporin binding regions, revealing that both proteins form distinct question mark-shaped keystones of two evolutionarily conserved hetero‑octameric inner ring complexes. Linkers bind to scaffold surface pockets through short defined motifs, with flanking regions commonly forming additional disperse interactions that reinforce the binding. Using a structure‑guided functional analysis in , we confirmed the robustness of linker‑scaffold interactions and established the physiological relevance of our biochemical and structural findings. The near-atomic composite structures resulting from quantitative docking of experimental structures into human and cryo-ET maps of constricted and dilated NPCs structurally disambiguated the positioning of the Nup188 and Nup192 hubs in the intact fungal and human NPC and revealed the topology of the linker-scaffold network. The linker-scaffold gives rise to eight relatively rigid inner ring spokes that are flexibly interconnected to allow for the formation of lateral channels. Unexpectedly, we uncovered that linker‑scaffold interactions play an opposing role in the outer rings by forming tight cross-link staples between the eight nuclear and cytoplasmic outer ring spokes, thereby limiting the dilatory movements to the inner ring. CONCLUSION We have substantially advanced the structural and biochemical characterization of the symmetric core of the and human NPCs and determined near-atomic composite structures. The composite structures uncover the molecular mechanism by which the evolutionarily conserved linker‑scaffold establishes the NPC's integrity while simultaneously allowing for the observed plasticity of the central transport channel. The composite structures are roadmaps for the mechanistic dissection of NPC assembly and disassembly, the etiology of NPC‑associated diseases, the role of NPC dilation in nucleocytoplasmic transport of soluble and integral membrane protein cargos, and the anchoring of asymmetric nucleoporins. [Figure: see text].

履歴

登録	2021年5月15日	登録サイト: RCSB / 処理サイト: RCSB
改定 1.0	2022年6月15日	Provider: repository / タイプ: Initial release
改定 1.1	2022年6月22日	Group: Database references / カテゴリ: citation / citation_author Item: _citation.journal_id_CSD / _citation.journal_volume / _citation.page_first / _citation.page_last / _citation.pdbx_database_id_PubMed / _citation.title / _citation_author.identifier_ORCID
改定 1.2	2024年10月9日	Group: Data collection / Structure summary カテゴリ: chem_comp_atom / chem_comp_bond / pdbx_entry_details / pdbx_modification_feature Item: _pdbx_entry_details.has_protein_modification

集合体

登録構造単位

A: Nucleoporin NUP188

B: Nucleoporin NIC96

概要:

• 213 kDa, 2 ポリマー

構成要素の詳細:

	分子量 (理論値)	分子数
合計 (水以外)	213,198	2
ポリマ－	213,198	2
非ポリマー	0	0
水	0	0

1

概要:

• 登録構造と同一
• 登録者・ソフトウェアが定義した集合体
• 根拠: gel filtration, SEC-MALS

対称操作:

タイプ	名称	対称操作	数
identity operation	1_555	x,y,z	1

計算値:

Buried area	3560 Å2
ΔGint	-31 kcal/mol
Surface area	78660 Å2
手法	PISA

単位格子

Length a, b, c (Å)	302.648, 302.648, 152.675
Angle α, β, γ (deg.)	90.000, 90.000, 120.000
Int Tables number	155
Space group name H-M	H32
Symmetry operation	#1: x,y,z #2: -y,x-y,z #3: -x+y,-x,z #4: x-y,-y,-z #5: -x,-x+y,-z #6: y,x,-z #7: x+1/3,y+2/3,z+2/3 #8: -y+1/3,x-y+2/3,z+2/3 #9: -x+y+1/3,-x+2/3,z+2/3 #10: x-y+1/3,-y+2/3,-z+2/3 #11: -x+1/3,-x+y+2/3,-z+2/3 #12: y+1/3,x+2/3,-z+2/3 #13: x+2/3,y+1/3,z+1/3 #14: -y+2/3,x-y+1/3,z+1/3 #15: -x+y+2/3,-x+1/3,z+1/3 #16: x-y+2/3,-y+1/3,-z+1/3 #17: -x+2/3,-x+y+1/3,-z+1/3 #18: y+2/3,x+1/3,-z+1/3

要素

#1: タンパク質

A Nucleoporin NUP188 / Nuclear pore protein NUP188

詳細:

分子量: 205977.188 Da / 分子数: 1 / 由来タイプ: 組換発現
由来: (組換発現) Chaetomium thermophilum (strain DSM 1495 / CBS 144.50 / IMI 039719) (菌類)
株: DSM 1495 / CBS 144.50 / IMI 039719 / 遺伝子: NUP188, CTHT_0070850 / 発現宿主: Escherichia coli (大腸菌) / 参照: UniProt: G0SFH5

#2: タンパク質

B Nucleoporin NIC96 / Nuclear pore protein NIC96

詳細:

分子量: 7220.833 Da / 分子数: 1 / 由来タイプ: 組換発現
由来: (組換発現) Chaetomium thermophilum (strain DSM 1495 / CBS 144.50 / IMI 039719) (菌類)
株: DSM 1495 / CBS 144.50 / IMI 039719 / 遺伝子: NIC96, CTHT_0008480 / 発現宿主: Escherichia coli (大腸菌) / 参照: UniProt: G0S024

• 研究の焦点であるリガンドがあるか: N
• Has protein modification: Y

実験情報

実験

• 実験: 手法: X線回折 / 使用した結晶の数: 1

試料調製

• 結晶: マシュー密度: 3.16 ų/Da / 溶媒含有率: 61.06 %
• 結晶化: 温度: 294 K / 手法: 蒸気拡散法, ハンギングドロップ法 / pH: 7.5 / 詳細: 0.05 M HEPES pH 7.5, 6.5 % (w/v) PEG 20000

データ収集

• 回折: 平均測定温度: 100 K / Serial crystal experiment: N
• 放射光源: 由来: シンクロトロン / サイト: SSRL / ビームライン: BL12-2 / 波長: 0.97944 Å
• 検出器: タイプ: DECTRIS PILATUS 6M / 検出器: PIXEL / 日付: 2017年6月22日
• 放射: モノクロメーター: Liquid nitrogen-cooled double crystal Si(111); プロトコル: SINGLE WAVELENGTH / 単色(M)・ラウエ(L): M / 散乱光タイプ: x-ray
• 放射波長: 波長: 0.97944 Å / 相対比: 1
• 反射: 解像度: 4.35→25 Å / Num. obs: 17578 / % possible obs: 99.5 % / 冗長度: 19.6 % / B_iso Wilson estimate: 221 Ų / CC_1/2: 1 / CC star: 1 / R_merge(I) obs: 0.247 / R_pim(I) all: 0.057 / R_rim(I) all: 0.253 / Net I/σ(I): 11.3
• 反射 シェル: 解像度: 4.35→4.86 Å / 冗長度: 19.7 % / R_merge(I) obs: 2.429 / Num. unique obs: 4981 / CC_1/2: 0.777 / CC star: 0.935 / R_pim(I) all: 0.559 / R_rim(I) all: 2.493 / % possible all: 100

解析

ソフトウェア

名称	バージョン	分類
PHENIX	1.17.1_3660	精密化
Blu-Ice		データ収集
DIALS		データ削減
DIALS		データスケーリング
Aimless		データスケーリング
pointless		データスケーリング
PHASER		位相決定
Coot		モデル構築

精密化

構造決定の手法: 単波長異常分散 / 解像度: 4.35→24.93 Å / SU ML: 0.78 / 交差検証法: FREE R-VALUE / σ(F): 1.41 / 位相誤差: 37.38 / 立体化学のターゲット値: MLHL

	Rfactor	反射数	%反射
Rfree	0.3167	895	5.09 %
Rwork	0.2723	16672	-
obs	0.2745	17567	99.9 %

• 溶媒の処理: 減衰半径: 0.9 Å / VDWプローブ半径: 1.11 Å / 溶媒モデル: FLAT BULK SOLVENT MODEL
• 原子変位パラメータ: B_iso max: 413.2 Ų / B_iso mean: 255.6425 Ų / B_iso min: 144.94 Ų

精密化ステップ

サイクル: final / 解像度: 4.35→24.93 Å

	タンパク質	核酸	リガンド	溶媒	全体
原子数	13265	0	0	0	13265
残基数	-	-	-	-	1699

LS精密化 シェル

Refine-ID: X-RAY DIFFRACTION / R_factor R_free error: 0 / Total num. of bins used: 6 / % reflection obs: 100 %

解像度 (Å)	Rfactor Rfree	Num. reflection Rfree	Rfactor Rwork	Num. reflection Rwork	Num. reflection all
4.35-4.62	0.3686	172	0.3503	2737	2909
4.62-4.97	0.3693	139	0.3351	2757	2896
4.98-5.47	0.3699	148	0.3339	2769	2917
5.47-6.25	0.3873	142	0.3514	2770	2912
6.25-7.84	0.353	150	0.316	2784	2934
7.84-24.93	0.2516	144	0.2074	2855	2999

精密化 TLS

手法: refined / Refine-ID: X-RAY DIFFRACTION

ID	L11 (°2)	L12 (°2)	L13 (°2)	L22 (°2)	L23 (°2)	L33 (°2)	S11 (Å °)	S12 (Å °)	S13 (Å °)	S21 (Å °)	S22 (Å °)	S23 (Å °)	S31 (Å °)	S32 (Å °)	S33 (Å °)	T11 (Å2)	T12 (Å2)	T13 (Å2)	T22 (Å2)	T23 (Å2)	T33 (Å2)	Origin x (Å)	Origin y (Å)	Origin z (Å)
1	2.3243	-0.2828	-0.4887	0.0288	0.0589	0.0986	0.4081	-0.4846	-1.1168	0.9022	-0.1993	-0.8005	0.0007	0.5124	-0.1455	5.4137	-0.0831	-0.7013	3.2133	0.6887	2.7503	209.3059	297.0163	80.8019
2	2.7135	0.5764	0.0192	2.3054	1.774	2.8149	0.1657	-0.6361	-1.7137	-0.4318	-1.485	0.1793	0.6992	-0.6002	1.6645	2.637	-0.2826	0.0632	2.7982	0.2173	3.2624	222.7022	284.1398	65.9552
3	3.7513	-2.779	-1.0645	3.617	-0.0806	7.1744	0.923	-0.7566	-0.8172	-0.7397	1.7644	0.821	0.6422	0.6401	-1.8557	4.4169	0.9372	-0.5129	3.1093	-0.1627	2.4175	217.0108	257.5078	48.5143
4	2.7891	0.2414	-1.1036	1.7904	-0.2391	2.5824	-0.1714	-0.4555	0.6168	0.9168	0.4838	0.6904	0.0424	-1.6852	-0.3038	2.024	0.5112	0.194	2.6152	0.1279	1.8828	220.6081	340.4385	84.2584
5	0.5917	1.0511	-0.0536	2.6001	0.3998	1.802	-0.0829	-0.2098	0.0306	0.5954	0.1531	-0.7144	-0.6809	0.0026	-0.0565	2.1283	0.23	-0.1673	2.2121	0.0692	1.9194	254.7797	350.4469	77.2946
6	1.8281	1.3693	-0.2254	3.5852	1.0267	0.3784	0.2045	0.4259	0.3128	0.275	-0.1491	0.1205	0.0486	-0.098	-0.0565	2.2943	0.1507	-0.1715	2.4816	0.1926	2.5692	228.3691	311.7525	62.6029
7	1.4713	0.0847	0.0675	3.4371	1.58	0.6468	-0.148	-0.2988	-0.0067	0.2697	0.0222	-0.0793	-0.2155	-0.125	0.0858	2.777	0.0324	0.0337	2.6807	0.1561	2.2845	232.0809	267.8154	50.6332
8	2.3232	0.1414	-0.467	0.8504	-0.7099	2.6199	0.0602	1.163	0.2182	-0.318	-0.985	1.1424	-0.1163	-1.4739	-0.4511	1.9487	-0.4113	0.4056	1.9967	-0.3641	2.2966	214.6871	248.4399	60.1739

精密化 TLSグループ

ID	Refine-ID	Refine TLS-ID	Selection details	Auth asym-ID	Auth seq-ID
1	X-RAY DIFFRACTION	1	chain B and resid 246:255	B	246 - 255
2	X-RAY DIFFRACTION	2	chain B and resid 256:282	B	256 - 282
3	X-RAY DIFFRACTION	3	chain B and resid 283:299	B	283 - 299
4	X-RAY DIFFRACTION	4	chain A and resid 3:205	A	3 - 205
5	X-RAY DIFFRACTION	5	chain A and resid 206:1091	A	206 - 1091
6	X-RAY DIFFRACTION	6	chain A and resid 1092:1399	A	1092 - 1399
7	X-RAY DIFFRACTION	7	chain A and resid 1400:1720	A	1400 - 1720
8	X-RAY DIFFRACTION	8	chain A and resid 1745:1850	A	1745 - 1850