The cytosolic antibody receptor TRIM21 possesses unique ubiquitination activity that drives broad-spectrum anti-pathogen targeting and underpins the protein depletion technology Trim-Away. This activity is dependent on formation of self-anchored, K63-linked ubiquitin chains by the heterodimeric E2 enzyme Ube2N/Ube2V2. Here we reveal how TRIM21 facilitates ubiquitin transfer and differentiates this E2 from other closely related enzymes. A tri-ionic motif provides optimally distributed anchor points that allow TRIM21 to wrap an Ube2N~Ub complex around its RING domain, locking the closed conformation and promoting ubiquitin discharge. Mutation of these anchor points inhibits ubiquitination with Ube2N/Ube2V2, viral neutralization and immune signalling. We show that the same mechanism is employed by the anti-HIV restriction factor TRIM5 and identify spatially conserved ionic anchor points in other Ube2N-recruiting RING E3s. The tri-ionic motif is exclusively required for Ube2N but not Ube2D1 activity and provides a generic E2-specific catalysis mechanism for RING E3s

Boland, Andreas

Dickson, Claire F

James, Leo C

Kiss, Leo

Mallery, Donna L

McLaughlin, Stephen H

Neuhaus, David

Yang, Ji-Chun

Zeng, Jingwei

English

Apollo (Cambridge)

Supplementary Information A tri-ionic anchor mechanism drives Ube2N-specific recruitment and K63-chain ubiquitination in TRIM ligases Kiss et al. This PDF includes: Supplementary Tables 1 and 2 Supplementary Figures 1-13 Supplementary Table 1  Data collection and refinement statistics (molecular replacement) TRIM21-RING:Ube2N~ubiquitin (6S53)Data collection Space group P1 Cell dimensions   a, b, c (Å) 49.75, 83.31, 86.75     a, b, g  (°)  89.90, 89.05, 88.70 Resolution (Å) 86.74 - 2.8 (2.9 - 2.8) Rmerge 0.03857 (0.3994) I / sI 12.83 (1.69) Completeness (%) 95.74 (96.05) Redundancy 1.8 (1.8) Refinement Resolution (Å) 19.76 - 2.8 (2.9 - 2.8) No. reflections 58804 (5933) Rwork / Rfree 0.21/0.25 No. atoms 9476   Protein 9454   Ligand/ion 16   Water 6 B-factors 79.03 Protein 79.04 Ligand/ion 77.24 Water 59.79 R.m.s. deviations   Bond lengths (Å) 0.009   Bond angles (°) 1.31 Data originated from one single crystal. Values in parentheses are for highest-resolution shell. Supplementary Table 2 Primers used in this study. Primer description Primer sequence 5'-3' TRIM21 E12A FWD ATGTGGGCCGAGGTCACATGCCCTATCTGCCTG  TRIM21 E12A REV CCTCGGCCCACATCATTGTCAAGCGTGCTGCTGA TRIM21 E12R FWD ATGTGGCGCGAGGTCACATGCCCTATCTGCCTG TRIM21 E12R REV CCTCGCGCCACATCATTGTCAAGCGTGCTGCTGA TRIM21 E13A FWD GGGAGGCGGTCACATGCCCTATCTGCCTGGAC TRIM21 E13A REV TGTGACCGCCTCCCACATCATTGTCAAGCGTGCT TRIM21 E13R FWD GGGAGCGAGTCACATGCCCTATCTGCCTGGAC TRIM21 E13R REV TGTGACTCGCTCCCACATCATTGTCAAGCGTGCT TRIM21 D21R FWD GCCTGCGGCCCTTCGTGGAGCCTGTGAG TRIM21 D21R REV GAAGGGCCGCAGGCAGATAGGGCATGTGACCTC TRIM21 R55A FWD CGCTGAGCGCACACAGGACAGACGCTGCC TRIM21R55A REV TCTGTCCTGTGTGCGCTCAGCGCTTTCTGCTCAAG hTRIM5 E11R fwd      GTTAATGTAAAGCGCGAGGTGACCTGCCCCATCTG      hTRIM5  E11R rev      GGTCACCTCGCGCTTTACATTAACCAGGATTCC        hTRIM5  E12A fwd  AGGAGGCCGTGACCTGCCCCATCTGCCTG        hTRIM5  E12A rev GGTCACGGCCTCCTTTACATTAACCAGGATTCCAGAAGCC hTRIM5  E20R rev  CAGGAGGCGCAGGCAGATGGGGCAGGTC        hTRIM5  E20R fwd    TGCCTGCGCCTCCTGACACAACCCCTGAGCCTG        hTRIM5  R59A fwd      CCCTGTGTGCGCTATCAGTTACCAGCCTGAGAAC       hTRIM5  R59A rev      GGTAACTGATAGCGCACACAGGGCAGCTACTCTCTCC    Gibson fwd TTAACGGCACACTTGACAATGGCTTCAGCAGCACGC Gibson rev TCGACTCTAGAGTCGCGGCCGCTCAATAGTCAGTGGATCCTTGTGATCCAATATTCAG Ube2D1-D12R-fwd GAGGATTCAGAAAGAATTGAGTcgcCTACAGCGCGATCCACCTGC Ube2D1-D12R-rev GCAGGTGGATCGCGCTGTAGgcgACTCAATTCTTTCTGAATCCTC Ube2N-R14D-fwd GCAGGATCATCAAGGAAACCCAGgatTTGCTGGCAGAACCAGTTCC Ube2N-R14D-rev GGAACTGGTTCTGCCAGCAAatcCTGGGTTTCCTTGATGATCCTGC Ub-K11E-fwd CTTCGTGAAGACCCTGACTGGTgaaACCATCACTCTCGAAGTGGAGCC Ub-K11E-rev GGCTCCACTTCGAGAGTGATGGTttcACCAGTCAGGGTCTTCACGAAG TRIM21-RL-M10E/E12R-fwd GCACGCTTGACAATGgaGTGGcgtGAGGTCACATGCCCTATCTGCC TRIM21-RL-M10E/E12R-rev GGCAGATAGGGCATGTGACCTCacgCCACtcCATTGTCAAGCGTGC TRIM21-RL-M10E/E12A-fwd CAGCACGCTTGACAATGgaGTGGgcgGAGGTCACATGCCCTATCTGCCTG TRIM21-RL-M10E/E12A-rev CAGGCAGATAGGGCATGTGACCTCcgcCCACtcCATTGTCAAGCGTGCTG TRIM21-RL-M10E/E13A-fwd GCACGCTTGACAATGgaGTGGGAGgcgGTCACATGCCCTATCTGCCTGGAC TRIM21-RL-M10E/E13A-rev GTCCAGGCAGATAGGGCATGTGACcgcCTCCCACtcCATTGTCAAGCGTGC 10152037507510013025025IB: TRIM2110152037507510013025025IB: TRIM21Ube2AUbe2B Ube2CUbe2D1Ube2D2Ube2D3Ube2D4Ube2E1Ube2E3Ube2FUbe2G1Ube2HUbe2J1101520375075100130250 25IB: TRIM21101520375075100130250 25IB: TRIM21Ube2AUbe2B Ube2CUbe2D1Ube2D2Ube2D3Ube2D4Ube2E1Ube2E3Ube2FUbe2G1Ube2HUbe2J1Ube2J2Ube2KUbe2L3Ube2N/V1Ube2N/V2Ube2Q1-2Ube2Q2-1Ube2R1Ube2R2Ube2SUbe2TUbe2WUbe2Z10152037507510013025025IB: TRIM2110152037507510013025025IB: TRIM21Ube2AUbe2B Ube2CUbe2D1Ube2D2Ube2D3Ube2D4Ube2E1Ube2E3Ube2FUbe2G1Ube2HUbe2J1101520375075100130250 25IB: TRIM21101520375075100130250 25IB: TRIM21Ube2AUbe2B Ube2CUbe2D1Ube2D2Ube2D3Ube2D4Ube2E1Ube2E3Ube2FUbe2G1Ube2HUbe2J1Ube2J2Ube2KUbe2L3Ube2N/V1Ube2N/V2Ube2Q1-2Ube2Q2-1Ube2R1Ube2R2Ube2SUbe2TUbe2WUbe2Z10152037507510013025025IB: Ub10152037507510013025025IB: Ub+ TRIM21-RING- TRIM21-RING10152037507510013025025IB: TRIM2110152037507510013025025IB: TRIM21Ube2AUbe2B Ube2CUbe2D1Ube2D2Ube2D3Ube2D4Ube2E1Ube2E3Ube2FUbe2G1Ube2HUbe2J1101520375075100130250 25IB: TRIM21101520375075100130250 25IB: TRIM21Ube2AUbe2B Ube2CUbe2D1Ube2D2Ube2D3Ube2D4Ube2E1Ube2E3Ube2FUbe2G1Ube2HUbe2J1Ube2J2Ube2KUbe2L3Ube2N/V1Ube2N/V2Ube2Q1-2Ube2Q2-1Ube2R1Ube2R2Ube2SUbe2TUbe2WUbe2Z10152037507510013025025IB: TRIM2110152037507510013025025IB: TRIM21Ube2AUbe2B Ube2CUbe2D1Ube2D2Ube2D3Ube2D4Ube2E1Ube2E3Ube2FUbe2G1Ube2HUbe2J1101520375075100130250 25IB: TRIM21101520375075100130250 25IB: TRIM21Ube2AUbe2B Ube2CUbe2D1Ube2D2Ube2D3Ube2D4Ube2E1Ube2E3Ube2FUbe2G1Ube2HUbe2J1Ube2J2Ube2KUbe2L3Ube2N/V1Ube2N/V2Ube2Q1-2Ube2Q2-1Ube2R1Ube2R2Ube2SUbe2TUbe2WUbe2Z10152037507510013025025IB: TRIM2110152037507510013025025IB: TRIM21 (short)250 IB: TRIM21 (long)+ TRIM21-RING- TRIM21-RING10152037507510013025025IB: TRIM2110152037507510013025025IB: TRIM21Ube2AUbe2B Ube2CUbe2D1Ube2D2Ube2D3Ube2D4Ube2E1Ube2E3Ube2FUbe2G1Ube2HUbe2J1101520375075100130250 25IB: TRIM21101520375075100130250 25IB: TRIM21Ube2AUbe2B Ube2CUbe2D1Ube2D2Ube2D3Ube2D4Ube2E1Ube2E3Ube2FUbe2G1Ube2HUbe2J1Ube2J2Ube2KUbe2L3Ube2N/V1Ube2N/V2Ube2Q1-2Ube2Q2-1Ube2R1Ube2R2Ube2SUbe2TUbe2WUbe2Z101520375071001302502IB: TRIM2110152037507510013025025IB: TRIM21Ube2AUbe2B Ube2CUbe2D1Ube2D2Ube2D3Ube2D4Ube2E1Ube2E3Ube2FUbe2G1Ube2HUbe2J1101520375075100130250 25IB: TRIM21101520375075100130250 25IB: TRIM21Ube2AUbe2B Ube2CUbe2D1Ube2D2Ube2D3Ube2D4Ube2E1Ube2E3Ube2FUbe2G1Ube2HUbe2J1Ube2J2Ube2KUbe2L3Ube2N/V1Ube2N/V2Ube2Q1-2Ube2Q2-1Ube2R1Ube2R2Ube2SUbe2TUbe2WUbe2Z+ TRIM21-RING- TRIM21-RINGabcd1520375075100130250251 5 10 20 40 60 80 100 40 100Time (min):(Ub)nIB: UbUbe2D1 no E3Supplementary	Fig.	1	E2	screen.	Full	western	blots	and	gels	of	the	biochemical	E2	screen	(Boston	Biochem,	Cambridge,	MA,	USA)	are	shown.	a	AnA-Ub	and	b	anA-T21-R	western	blots	are	shown.	c	The	gels	that	were	used	for	bloFng	and	stained	aGerwards	and	are	shown	(without	markers,	as	they	were	transferred	to	the	membrane).	The	anA-T21-R	western	blot	is	shown	for	two	different	developing	Ames,	demonstraAng	that	interacAon	of	T21-R	with	Ube2D1	can	result	in	the	formaAon	of	anchored	chains	in	addiAon	to	free	ubiquiAn	chains.	The	anA-ubiquiAn	blot	shows	a	band	for	Ube2T	in	presence	of	TRIM21.	However,	no	difference	could	be	detected	in	the	gel.	d	Catalysis	of	Ube2D1	to	confirm	that	the	high	molecular	weight		species	for	Ube2D1-4	represent	ubiquiAn	chains.	Source	data	are	provided	as	a	Source	Data	file.	36142838496297188172A12A21E82A3UbUbe2NC87K/K92A~Ub2A42A52A62A82B12A72B22B32C12C22C32C4a bE12D21E13K11R14K10R6c dE12E13D21R6K10R14K1120-20Electrostatic potential (kT/e)eSupplementary	Fig.	2	X-ray	structure	of	TRIM21-RING	in	complex	with	Ube2N~Ub.	a	Gel	filtraAon	chromatogram	and	b	LDS-gel	of	the	purificaAon	of	isopepAde-linked	Ube2NC87K/K92A~Ub,	which	was	used	for	structural	studies.	c	Anchor	points	moAf	close-up	as	in	Fig.	2e,	showing	the	2FO-FC	density	at	1.0	sigma	for	the	residues	involved.	d	ElectrostaAc	potenAal	surfaces	from	-20	(red)	to	+20	kV	e-1	(blue).	ElectrostaAc	potenAal	surfaces	were	generated	with	the	APBS	2.1	tool	in	PyMol.	PQR	files	were	generated	by	PDB2PQR	using	the	Amber	force	field.	e	Shown	is	the	protein	in	the	asymmetric	unit	(two	full	complexes)	as	cartoon	and	the	2FO-FC	density	at	1.0	sigma.	/Users/lkiss/Desktop/untitled folder/20180702-R-2N-comparison-C51-lvl2p5-linew1p0.pdf19.059.109.159.20126.5127.0127.5/Users/lkiss/Desktop/untitled folder/20180702-R-2N-comparison-I18-lvl2p5-linew1p0.pdf19.09.19.2117.5118.0118.5119.0I18117.5118.0118.5119.09.19.2 9.0100 µM 15N-RM10E + 100 µM 2N100 µM 15N-RM10E/E13A + 100 µM 2N100 µM 15N-RM10E/E12A + 100 µM 2N100 µM 15N-RM10E/E12R + 100 µM 2N100 µM 15N-RM10E126.5127.0127.59.159.20 9.10 9.05⍵2-1H (ppm)⍵ 1-15N (ppm)C5120 40 60 80 20 40 60 800 000.30.30.60.6000.20.60.410 20 30 400 50 60 70 80Residue∆δN,HN (ppm)ab15N-RM10E + Ube2N (1:1) 15N-RM10E/E12A + Ube2N (1:1)15N-RM10E/E12R + Ube2N (1:1)15N-RM10E/E13A + Ube2N (1:1)00.20.60.4∆δN,HN (ppm)0.8100 200 300 4000Ube2N (µM)KD = 14.8 ± 4 µMT21-RM10E + Ube2N00.20.60.40.8100 200 300 4000Ube2N (µM)KD = 56.5 ± 13.3 µMT21-RM10E/E12R + Ube2NI18L20C39C51V53100 µM 15N-RM10E(/E12R) + 150 µM 2N100 µM 15N-RM10E(/E12R) + 100 µM 2N100 µM 15N-RM10E(/E12R) + 40 µM 2N100 µM 15N-RM10E100 µM 15N-RM10E(/E12R) + 200 µM 2N100 µM 15N-RM10E(/E12R) + 400 µM 2N100 µM 15N-RM10E(/E12R) + 300 µM 2Nc T21-RM10E T21-RM10E/E12R⍵ 1-15 N (ppm)⍵2-1H (ppm)I18V27/Users/lkiss/Desktop/untitled folder/20180925-R-2N-I18-lvl2p5-linew1p0.pdf19.009.059.109.159.20117.0117.5118.0118.5119.0I18V27/Users/lkiss/Desktop/untitled folder/20180925-R-E12R-2N-I18-lvl2p5-linew1p0.pdf19.009.059.109.159.20117.0117.5118.0118.5119.09.2 9.1 9.0117.0117.5118.0118.5119.09.2 9.1 9.0Supplementary	Fig.	3	The	effect	of	the	tandem	glutamates	in	binding	Ube2N.	a	Histograms	for	the	AtraAons	of	Ube2N	into	T21-RM10E,	showing	CSP	vs.	sequence	posiAon.	Blue	circles	indicate	proline	residues,	white	circles	missing	assignments.	b	Isolated	peaks	of	selected	amides	(I18	and	C51)	of	T21-RM10E	(abbreviated	RM10E)	are	shown	in	absence	of	Atrant	and	different	RING	mutants	in	presence	of	1	molar	equivalent	of	Ube2N	(abbreviated	2N).	Full	spectra	are	shown	in	Supplementary	Fig.	4.	c	DissociaAon	constant	fiFng	plots	and	peak	of	amide	I18	are	shown	for	T21-RM10E	and	T21-RM10E/E12R	AtraAon	with	Ube2N.	KD	values	represent	the	mean	±	s.d.	of	5	different	peaks	that	were	fifed	as	described	in	Methods.	ab0 20 40 60 80 1000204060[Ube2N~Ub] (µM)Response (RU)0 100 200020406080Time (s)Response (RU)Ube2N~Ub vs Trim21-RING0 20 40 60 80 100010203040[Ube2N~Ub] (µM)Response (RU)0 100 2000204060Time (s)Response (RU)Ube2N~Ub vs Trim21-RING0 100 20001020Time (s)Response (RU)Ube2N vs Trim21-RING0 20 40 60 80 10001020[Ube2N] (µM)Response (RU)cSupplementary	Fig.	4	Surface	plasmon	resonance	measurements.	Replicate	surface	plasmon	resonance	data	(sensograms	and	binding	plots)	for	a	Ube2N	AtraAon	into	GST-T21-R	and	b,c	Ube2N~Ub.		0 10 20 30 40 50 60 700.00.20.4Residue NumberΔδ N, NH (ppm)2N~Ub CSP (1:1 T21-R-M10E)0 10 20 30 40 50 60 700.00.51.01.5Residue NumberΔδ N, NH (ppm)2N~Ub vs Ub CSPUbe2N~15N-Ub + T21-RM10E (1:1)⍵2-1H (ppm)⍵ 1-15 N (ppm)Ube2N~15N-Ub + T21-RM10E (1:0.5)Ube2N~15N-Ub/Users/lkiss/Desktop/PhD/Manuscripts/E2-selection story/Nature Communications/2N-Ub-and-Ub_2.pdfThu Jun 27 14:05:22 20192N-Ub and Ub6.06.57.07.58.08.59.09.5105110115120125130135/Users/lkiss/Desktop/PhD/Manuscripts/E2-selection story/Nature Communications/2N-Ub-R-titratiom-2.pdfThu Jun 27 14:04:26 20192N-Ub R titration6.06.57.07.58.08.59.09.510511011512012513013515N-UbUbe2N~15N-Ub00.1∆δN,HN (ppm)RINGUbe2NUbiquitinabc⍵2-1H (ppm)def00.3∆δN,HN (ppm)Ube2NUbiquitinSupplementary	Fig.	5	FormaAon	of	the	closed	Ube2N~Ub	conformaAon	in	soluAon.	Overlay	of	the	15N-BEST-TROSY	spectra	of	a	free	15N-ubiquiAn	(orange)	and	Ube2N~15N-Ub	(blue)	and	d	the	AtraAon	of	T21-RM10E	into	Ube2N~15N-Ub	(blue,	free;	green,	half	molar	equivalent;	red,	one	molar	equivalent).	b,e	The	CSPs	are	plofed	against	the	residue	number.	In	case	of	the	AtraAon,	the	CSP	are	calculated	between	the	free	and	one	molar	equivalent	added	Atrant.	Blue	circles	indicate	proline	residues,	white	circles	missing	assignments.	c,f	The	amide	CSP	between	c	15N-Ub	and	f	Ube2N~15N-Ub	are	mapped	onto	the	structure	in	orange.	/Users/lkiss/Desktop/PhD/Manuscripts/E2-selection story/Nature Communications/2N-Ub-HSQC.pdfWed Jul  3 14:19:12 20192N-Ub-HSQC6.06.57.07.58.08.59.09.5105110115120125130 I13K6L67A46V5I44?Q2F45L15L43R42L50Q31E51R72T14L8H68E64V17E18T12I23L69D21D58A28Q62K11I36N25K48K29E16K63R74L71I30D52 D32L56F4T66Q41R54I61Y59K33S65Q40N60I3E34D39S57G75G76T55 G35G47 S20T9G10T22V26⍵2-1H (ppm)⍵ 1-15 N (ppm)Supplementary	Fig.	6	Assignment	of	ubiquiAn	charged	onto	Ube2N.	15N-HSQC	spectrum	of	Ube2N~15N-/13C-Ub.	Assignments	for	amide	peaks	are	given	in	the	spectrum.	Unassigned	residues	are	marked	by	quesAon	marks.		7.58.08.59.0108110112114116118120122124126128 C15C55R68A2 K84A74L6? E88L26Q24 C35D29A37I60L85K10L22C58L28Q36N8E11?E12A41H32L48V73?L80?E78V83?R71E82K79?E76L21E20 L39M47V77V7R81V9V57I5K45K44?E52N70T23H43I17N75S86D49L19C18N42N66S53F34S54S27S3T40S46I67S61 T14 S33?C30G31G51G4?⍵2-1H (ppm)⍵ 1-15 N (ppm)Supplementary	Fig.	7	Assignment	of	TRIM5-RINGI76E.	15N-HSQC	spectrum	of	15N-/13C-T5-RI76E.	Assignments	for	amide	peaks	are	given	in	the	spectrum.	Unassigned	residues	are	marked	by	quesAon	marks.	The	I76E	mutaAon	was	introduced	to	remove	dimerizaAon	of	the	RING	domain,	which	leads	to	line	broadening.	15N-RM10E 15N-RM10E/Users/lkiss/Desktop/untitled folder/20180702-R-2N-lvl2p5-linew0p516.57.07.58.08.59.09.510.010.5105110115120125130/Users/lkiss/Desktop/untitled folder/20180702-R-2N-Ub-lvl2p5-linew0p516.57.07.58.08.59.09.510.010.5105110115120125130/Users/lkiss/Desktop/untitled folder/20180702-R-E12A-2N-lvl2p5-linew0p516.57.07.58.08.59.09.510.010.5105110115120125130/Users/lkiss/Desktop/NMR Spectra/T21-R-E12R/20180927-R-E12R-2N-full-spectrum-lvl2p5-linew0p5.pdf20180927-R-2N-full-spectrum-lvl2p5-linew0p56.57.07.58.08.59.09.510.010.5105110115120125130/Users/lkiss/Desktop/untitled folder/T21-R-M10E:E13A/20180702-R-E13A-2N-lvl2p5-linew0p5.pdf16.57.07.58.08.59.09.510.010.5105110115120125130/Users/lkiss/Desktop/untitled folder/T21-R-M10E:E13A/20180702-R-E13A-2N-Ub-lvl2p5-linew0p5.pdf16.57.07.58.08.59.09.510.010.5105110115120125130/Users/lkiss/Desktop/NMR Spectra/T21-R-E12A/full spectrum/20180928-R-E12A-2N-Ub-lvl2p5-linew0p5.pdf20180928-R-E12A-2N-Ub-Ub-full-spectrum-lvl2p5-linew0p56.57.07.58.08.59.09.510.010.510511011512012513015N-RM10E + 2N (1:0.4)15N-RM10E + 2N (1:1)15N-RM10E + 2N~Ub (1:0.4)15N-RM10E + 2N~Ub (1:1)15N-RM10E/E12A15N-RM10E/E12A + 2N~Ub (1:0.4)15N-RM10E/E12A + 2N~Ub (1:1)15N-RM10E/E12A15N-RM10E/E12A + 2N (1:0.4)15N-RM10E/E12A + 2N (1:1)15N-RM10E/E12R15N-RM10E/E12R + 2N (1:0.4)15N-RM10E/E12R + 2N (1:1)15N-RM10E/E12R15N-RM10E/E12R + 2N~Ub (1:0.4)15N-RM10E/E12R + 2N~Ub (1:1)15N-RM10E/E13A15N-RM10E/E13A + 2N (1:0.4)15N-RM10E/E13A + 2N (1:1)15N-RM10E/E13A15N-RM10E/E13A + 2N~Ub (1:0.4)15N-RM10E/E13A + 2N~Ub (1:1)⍵2-1H (ppm)⍵ 1-15N (ppm)/Users/lkiss/Desktop/NMR Spectra/T21-R-E12R/20180927-R-E12R-2N-Ub-full-spectrum-lvl2p5-linew0p5.pdf20180927-R-2N-Ub-full-spectrum-lvl2p5-linew0p56.57.07.58.08.59.09.510.010.5105110115120125130/Users/lkiss/Desktop/BIF_NMR_3.pdf Thu Mar  7 14:32:40 20196.06.57.07.58.08.59.09.510.010.510511011512012513015N-RM10E15N-RM10E + 2D1 (1:0.5)15N-RM10E + 2D1 (1:1)/Users/lkiss/Desktop/PhD/Manuscripts/T21-2N-Ub-selection-stroy/Figures/20190322-2N-E12R.pdf20190322-R-2N-lvl4p0-linew0p56.57.07.58.08.59.09.510.010.511.0105110115120125130/Users/lkiss/Desktop/PhD/Manuscripts/T21-2N-Ub-selection-stroy/Figures/20190322-2N-wt.pdf20190322-R-2N-lvl4p0-linew0p56.57.07.58.08.59.09.510.010.511.0105110115120125130100 µM 15N-RM10E + 150 µM 2N100 µM 15N-RM10E + 200 µM 2N100 µM 15N-RM10E + 400 µM 2N100 µM 15N-RM10E + 300 µM 2N100 µM 15N-RE12R + 150 µM 2N100 µM 15N-RE12R + 200 µM 2N100 µM 15N-RE12R + 400 µM 2N100 µM 15N-RE12R + 300 µM 2N/Users/lkiss/Desktop/PhD/Manuscripts/T21-2N-Ub-selection-stroy/Figures/T5-titrationFri Mar 22 16:31:03 20197.07.58.08.59.010811011211411611812012212412612813015N-T5-RI76E15N-RI76E + 2N (1:0.3)15N-RI76E + 2N (1:1)Supplementary	Fig.	8	NMR	spectra.	All	the	full	15N-HSQC	spectra	corresponding	to	results	discussed	in	the	text.	Constructs	and	molar	raAos	are	given	in	the	Figure.	T21-RM10E	constructs	are	abbreviated	as	RM10E.	Supplementary	Fig.	9	Alignment	of	E2	enzymes.	All	E2	enzymes	in	the	biochemical	screen	in	Fig.	1a	were	aligned	using	clustal	omega.		50 TRIM2115 COX IV6010empty vectorWT20 µL35 µL50 µL70 µLWT 293TR55A50 TRIM2115 COX IV6010empty vectorWTE12AE12RE13AE13R50 TRIM2150beta-Actin60empty vectorWTD21Ra b cSupplementary	Fig.	10	TRIM21	Expression	levels.	TRIM21	expression	level	in	stably	reconsAtuted	293T	cell	lines	that	were	used	for	cell	biological	assays	shown	in	Fig.	5.	a	Shown	are	the	di-glutamate	mutants	and	b	D21R.	c	The	amount	of	lenAvirus	vector	containing	supernatant	was	Atrated	for	the	TRIM21R55A	mutants	and	the	cell	line	that	was	transduced	with	20	µL	was	used	in	our	assays.	The	empty	vector	cells	represent	TRIM21-KO	293T	cells,	that	were	transduced	with	either	WT	or	TRIM21	mutants.	d	Example	contour	plots	of	the	gaAng	for	live	cells	and	GFP	posiAve	cells.	Source	data	are	provided	as	a	Source	Data	file.	Live cell gating of whole population GFP +ve gating of live populationNegative controlGFP +ve populationGreenlaserForwardsdTRIM21 1TRIM5 18588abTRIM5 RINGTRIM5 RINGUbe2NUbNCNCCNNCNUbUbe2NN10 20 30 400 50 60 70 800.250.500.00∆δN,HN (ppm)Residue/Users/lkiss/Desktop/PhD/Manuscripts/T21-2N-Ub-selection-stroy/Figures/Figure 6/20190311_T5-2N-zoom3.pdfMon Mar 1 18: 6:46 20197.58.08.59.01081101121141161181201221241261281 6101129 8.5 8⍵ 1-15N (ppm)7.5⍵2-1H (ppm)I171281212L19T5-RI76ET5-RI76E 1:0.3 Ube2NT5-RI76E 1:1 Ube2NcSupplementary	Fig.	11	a	Sequence	alignment	of	TRIM21	and	TRIM5	RING	domains.	b	Structural	model	of	TRIM5-RING	Ube2N~Ub	complex	based	on	superposiAon	of	the	T5-R	Ube2N	(4TKP)1	and	our	T21-R	Ube2N~Ub	structure.	c	NMR	AtraAon	spectra	of	15N-T5-RI76E	 with	Ube2N.	Histogram	of	the	chemical	shiG	perturbaAon	against	the	T5-R	primary	structure.	Blue	circles	indicate	proline	residues,	white	circles	missing	assignments.	The	assigned	T5I76E	spectrum	is	shown	in	Supplementary	Fig.	7.	I236D230R14R6E289K11Supplementary Fig. 12 Model of the CHIPU-box:Ube2N~Ub complex. Close-ups of CHIPU-box:Ube2N~Ub model based on theCHIPU-box:Ube2N/Ube2V2 structure (2C2V)2 and the TRIM21RING:Ube2N~Ub structure presented in this paper, as explained for the TRIM5-RING:Ube2N~Ub model. a bCopies / U2OS cellCopies / HeLa cellSupplementary	Fig.	13	ConcentraAons	of	E2	enzymes	in	cells.	Copies	of	E2	enzymes	per	cell	are	shown	for	a	HeLa	and	b	U2OS	cells,	as	 determined	by	mass	spectrometry.	Data	comes	from3,4,	respecAvely.	Supplementary References1 Yudina, Z. et al. RING Dimerization Links Higher-Order Assembly of TRIM5alpha to Synthesis of K63-Linked      Polyubiquitin. Cell Rep 12, 788-797, doi:10.1016/j.celrep.2015.06.072 (2015).2 Zhang, M. et al. Chaperoned ubiquitylation--crystal structures of the CHIP U box E3 ubiquitin ligase and a CHIP-Ubc13-Uev1a complex. Mol Cell 20, 525-538, doi:10.1016/j.molcel.2005.09.023 (2005).3 Beck, M. et al. The quantitative proteome of a human cell line. Mol Syst Biol 7, 549, doi:10.1038/msb.2011.82 (2011).4 Hein, M. Y. et al. A human interactome in three quantitative dimensions organized by stoichiometries and abundances. Cell 163, 712-723, doi:10.1016/j.cell.2015.09.053 (2015).

A tri-ionic anchor mechanism drives Ube2N-specific recruitment and K63-chain ubiquitination in TRIM ligases.

The cytosolic antibody receptor TRIM21 possesses unique ubiquitination activity that drives broad-spectrum anti-pathogen targeting and underpins the protein depletion technology Trim-Away. This activity is dependent on formation of self-anchored, K63-linked ubiquitin chains by the heterodimeric E2 enzyme Ube2N/Ube2V2. Here we reveal how TRIM21 facilitates ubiquitin transfer and differentiates this E2 from other closely related enzymes. A tri-ionic motif provides optimally distributed anchor points that allow TRIM21 to wrap an Ube2N~Ub complex around its RING domain, locking the closed conformation and promoting ubiquitin discharge. Mutation of these anchor points inhibits ubiquitination with Ube2N/Ube2V2, viral neutralization and immune signalling. We show that the same mechanism is employed by the anti-HIV restriction factor TRIM5 and identify spatially conserved ionic anchor points in other Ube2N-recruiting RING E3s. The tri-ionic motif is exclusively required for Ube2N but not Ube2D1 activity and provides a generic E2-specific catalysis mechanism for RING E3s.</p

Dickson, Claire F.

Mallery, Donna L.

McLaughlin, Stephen H.

James, Leo C.

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A tri-ionic anchor mechanism drives Ube2N-specific recruitment and K63-chain ubiquitination in TRIM ligases

https://www.repository.cam.ac.uk/bitstream/1810/311002/2/41467_2019_12388_MOESM1_ESM.pdf

A tri-ionic anchor mechanism drives Ube2N-specific recruitment and K63-chain ubiquitination in TRIM ligases.

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