While viral replication processes are largely understood, comparably little is known on cellular mechanisms degrading viral RNA. Some viral RNAs bear a 5'-triphosphate (PPP-) group that impairs degradation by the canonical 5'-3' degradation pathway. Here we show that the Nudix hydrolase 2 (NUDT2) trims viral PPP-RNA into monophosphorylated (P)-RNA, which serves as a substrate for the 5'-3' exonuclease XRN1. NUDT2 removes 5'-phosphates from PPP-RNA in an RNA sequence- and overhang-independent manner and its ablation in cells increases growth of PPP-RNA viruses, suggesting an involvement in antiviral immunity. NUDT2 is highly homologous to bacterial RNA pyrophosphatase H (RppH), a protein involved in the metabolism of bacterial mRNA, which is 5'-tri- or diphosphorylated. Our results show a conserved function between bacterial RppH and mammalian NUDT2, indicating that the function may have adapted from a protein responsible for RNA turnover in bacteria into a protein involved in the immune defense in mammals

Andersen, Line Lykke

Binder, Marco

Dächert, Christopher

Emslander, Quirin

Krey, Karsten

Kröger, Andrea

Laudenbach, Beatrice T

Ludwig, Janos

Manske, Katrin

Moser, Markus

Mundigl, Sarah

Pichlmair, Andreas

Reim, Alexander

Scaturro, Pietro

Wohlleber, Dirk

Nature Communications

PubMed

Helmholtz Zentrum für Infektionsforschung Repository

NUDT2 initiates viral RNA degradation by removal of 5'-phosphates.

RNA of some viruses is protected from degradation by a 5′ triphosphate group. Here the authors identify nudix hydrolase 2 (NUDT2) as novel antiviral defense protein that dephosphorylates viral RNA and thereby enables its degradation

Beatrice T. Laudenbach

Karsten Krey

Quirin Emslander

Line Lykke Andersen

Alexander Reim

Pietro Scaturro

Sarah Mundigl

Christopher Dächert

Katrin Manske

Markus Moser

Janos Ludwig

Dirk Wohlleber

Andrea Kröger

Marco Binder

Andreas Pichlmair

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NUDT2 initiates viral RNA degradation by removal of 5′-phosphates

While viral replication processes are largely understood, comparably little is known on cellular mechanisms degrading viral RNA. Some viral RNAs bear a 5 '-triphosphate (PPP-) group that impairs degradation by the canonical 5 '-3 ' degradation pathway. Here we show that the Nudix hydrolase 2 (NUDT2) trims viral PPP-RNA into monophosphorylated (P)-RNA, which serves as a substrate for the 5 '-3 ' exonuclease XRN1. NUDT2 removes 5 '-phosphates from PPP-RNA in an RNA sequence- and overhang-independent manner and its ablation in cells increases growth of PPP-RNA viruses, suggesting an involvement in antiviral immunity. NUDT2 is highly homologous to bacterial RNA pyrophosphatase H (RppH), a protein involved in the metabolism of bacterial mRNA, which is 5 '-tri- or diphosphorylated. Our results show a conserved function between bacterial RppH and mammalian NUDT2, indicating that the function may have adapted from a protein responsible for RNA turnover in bacteria into a protein involved in the immune defense in mammals. RNA of some viruses is protected from degradation by a 5 ' triphosphate group. Here the authors identify nudix hydrolase 2 (NUDT2) as novel antiviral defense protein that dephosphorylates viral RNA and thereby enables its degradation.We thank the core facility of the MPI of biochemistry for support

Laudenbach, B.

Krey, K.

Emslander, Q.

Andersen, L.

Reim, A.

Scaturro, P.

Mundigl, S.

Daechert, C.

Manske, K.

Moser, M.

Ludwig, J.

Wohlleber, D.

Kroeger, A.

Binder, M.

Pichlmair, A.

MPG.PuRe

NUDT1NUDT2NUDT5NUDT6NUDT9NUDT12NUDT13NUDT14NUDT15NUDT16NUDT17NUDT18NUDT19NUDT20NUDT21NUDT22RIG-I050100150Cell Viability [%]β-actinNUDT2siScrambledsiNUDT2siScrambledsiScrambledsiScrambledsiScrambledsiNUDT2siNUDT12siNUDT14siNUDT17b cSupplementary Figure 1amRNA (-ΔΔCt)20-2-4-6-8Supplementary Figure 1 | Cell viability after NUDT depletion and confirmation of knockdown. (a) Cell viability after siRNA knockdown. 72 h after siRNA transfection into HeLa cells, cell viability was tested using a cell titer glow assay. Relative cell viability was assessed by assuming the average cell viability of the whole siRNA screen set as 100% viable. The graph shows an average of four independent experiments done in technical duplicates ± SD. (b) Cells were treated with siRNA targeting the transcript of NUDT2, NUDT12, NUDT14, NUDT17, or control (siScrambled), and mRNA abundance of the respective cellular targets was quantified using RT-qPCR normalized to GAPDH. Bar graphs show the mean fold change of the targeted sequence vs. control  ± SD of two independent replicates. (c) Expression of NUDT2 in cells transfected with siNUDT2 or control (siScrambled) assessed by western blotting.  NUDT2NUDT12NUDT14NUDT17NUDT2 E58ANUDT12 E369ANUDT14 E121ANUDT17 E124A70 554035100130250Size [kDa]cb10.40 2 4 6 8 10 12 14 16 18 Time [min]01236x10Intens.TIC +, -Constant Bkgrnd UV Chromatogram, 214 nm18197.603918381.3813+MS, 10.4-10.7min, -Constant Bkgrnd, Deconvoluted (MaxEnt, 794.78-2801.05, *0.21875, 10000)02464x10Intens.17000 17500 18000 18500 19000 19500 Mass [Da]Supplementary Figure 2aSupplementary Figure 2 | NUDT2 localization and cross-species sequence alignment. (a) Coomassie-stained SDS-PAGE of His6-MBP-tagged recombinant Nudix hydrolases, including mutants bearing point mutations in the catalytic Nudix box (n = 1). (b) Total mass determination of NUDT2 by top-down LC-MS analysis, including the total ion current chromatogram (TIC, top) and the extracted ion chromatogram (bottom). (c) Sequence alignment of NUDT2 proteins from Homo sapiens, Danio rerio, Caenorhabditis elegans, Mus musculus, Xenopus laevis, Gallus gallus, and Drosophila melanogaster. Colors are depicted as following: red box, white character shows a strict identity of residues; red character shows a similarity in a group; a blue frame shows similarities across groups. cbSupplementary Figure 3aCIPIVT4NUDT2 (100 nM)NUDT2 (300 nM)NUDT2 (600 nM)020400 30 60 90 120Time [min]Phosphate released [µM]A1 A4(AGAA) A8G4(GCAA) G4(GUAA) G8G0 G4(GGAA) G4(GAAA)0 30 60 90 120 0 30 60 90 120 0 30 60 90 120010203040010203040010203040Time [min]Phosphate released [µM]A4(AGAA) mockA4(AGAA) IVT4 mockIVT4051020 40 60Time [min]Phosphate released [µM]Supplementary Figure 3 | Time-resolved phosphate release assay. (a) Time-resolved EnzChek assay to quantify released phosphate from incubated IVT4 RNA with different concentrations of NUDT2. Spectrophotometric measurements of the samples were performed every 3 min. The line graph shows the mean of three independent experiments with the ribbon indicating ± SD. (b) Complementary to Fig. 3c. RNA substrates depicted in Fig. 3b were incubated with NUDT2 E58A mutant at a concentration of 600 nM over a time-course of 2 h utilizing the EnzChek assay to quantify phosphate release. Spectrophotometric measurements were performed every 3 min. The line graph shows the mean of three independent experiments with the ribbon indicating ± SD. (c) As (a) but using RppH to dephosphorylate an RNA substrate which is base-paired on its 5’-end (IVT4) and one that has an unpaired 5’-overhang (A4(AGAA)) in comparison to untreated RNA substrates. The line graph shows the mean of three independent experiments with the ribbon indicating ± SD.  Nudt2-/-Nudt2+/+DAPI NUDT2 mergeSupplementary Figure 4a01020304050Phosphate released [µM]HEKmutNS1 (IAV)NUDT2NUDT2 E58A***cSize[kDa]554035NUDT2 E58ANUDT2mutNS1 (IAV)mockbSupplementary Figure 4 | Human NUDT2 subcellular localization and function. (a) Huh7.5 and Huh7.5 deficient for NUDT2 cells were stained for NUDT2 and analyzed by confocal microscopy. Representative images of three biological repeats are shown. The scale bars represent 10 µm. (b) HEK293T cells were transfected with plasmids encoding Myc-tagged NUDT2, NUDT2 E58A, and the control mutNS1 (IAV) or left untransfected (mock). Myc-tagged proteins were precipitated, and precipitation efficiency was evaluated by western blotting against Myc. (c) Precipitates from (b) were incubated with PPP-RNA (IVT4) for 3 h and phosphate release evaluated using a malachite green assay. Bar graphs show the mean of three independent replicates ± SD, *** p<0.001 as analyzed by nonparametric two-tailed t-test.  bdGenotype Oberserved538752(27.6%) (45.3%)(27.1%)Preweaning mortality:  22%Weaned Animals489648(25%)(50%)(25%)ExpectedlacZ neoEnS 2Aexon 2loxPFRTFRT loxP3exon 1 exon 31 23`5`loxPIRES pA pAhbactPf5001000400100Nudt2+/+Nudt2+/-Nudt2-/-Nudt2+/+Nudt2+/-Nudt2-/-PBS Ap4A PBS AP4A PBS P(I:C)01234567MockSFV-nanoLucRLU (log10)MET 2 µL MET 1 µLNudt2+/+0.00.10.20.30.4Nudt2+/-Nudt2-/-1.01.52.02.50.00.51.01.5Ifit3U1 snRNAlL-6HeartNudt2+/+Nudt2+/-Nudt2-/-Nudt2+/+Nudt2+/-Nudt2-/-0.00.20.40.60.801230.00.51.01.52.02.5LiverNudt2+/+Nudt2+/-Nudt2-/-Nudt2+/+Nudt2+/-Nudt2-/-Nudt2+/+Nudt2+/-Nudt2-/-0.60.81.01.21.4012340123LungNudt2+/+Nudt2+/-Nudt2-/-Nudt2+/+Nudt2+/-Nudt2-/-Nudt2+/+Nudt2+/-Nudt2-/-0.00.20.40.60.80.00.20.40.60.00.51.01.52.0SpleenNudt2+/+Nudt2+/-Nudt2-/-Nudt2+/+Nudt2+/-Nudt2-/-Nudt2+/+Nudt2+/-Nudt2-/-Supplementary Figure 5ac elog2 fold change (Nudt2+/+ / Nudt2-/-)−log10(p value)NUDT2024-4 -2 0 2 468 10 Size[bp]log 10(2-ΔCt )log 10(2-ΔCt )log 10(2-ΔCt )Supplementary Figure 5 | Characterization of NUDT2 deficient mice. (a) Schematic overview of Nudt2 targeting in mice. Depicted is the Nudt2 gene locus with a tm1a cassette inserted after the first exon and encoding for the lacZ gene, with a splice acceptor, a polyA site, and a neomycin resistance gene. (b) Genotyping PCR of Nudt2tm1a/tm1a (Nudt2-/-) mice. PCR amplification results in a wild-type allele detectable at 492 bp, whereas the inserted tm1a cassette is detectable as bands of 417 bp and 912 bp. (c) Mendelian ratios were observed from 192 weaned animals originating from Nudt2+/- breeding pairs compared to the expected Mendelian distribution. (d) Proteome analysis of bone marrow cells isolated from NUDT2 knockout (Nudt2-/-) and control mice. Volcano plots display proteins that were significantly up-or down-regulated in cells lacking NUDT2 (right) or wild-type (left) bone marrows (student´s t-test, FDR ≤ 0.05, 6 biological replicates). (e) Influence of extracellular applied or intracellular delivered Ap4A or poly(I:C) on the growth of SFV6-2SG Nano-Luc (SFV) at an MOI of 0.0035. Virus growth was assessed by the measurement of renilla luciferase. The bar plot shows the mean ± SD of four independent replicates. (f) Levels of Ifit3, Il6, or U1 snRNA in the heart, liver, lung, or spleen of wild-type mice or Nudt2-/- mice were quantified by RT-qPCR analysis. Data were normalized to murine Tbp RNA. Shown is the mean ± SEM. Every dot represents an individual mouse (n = 5 for Nudt2+/+ and Nudt2+/- and n = 4 for Nudt2-/-).  -10123 VSV-NNudt2-/-Nudt2+/-0123 Ifit30.00.51.01.52.02.5 IL-6 b2 42 4days post infection2 4Nudt2-/-Nudt2+/+day post infectionSurvival (%)0 2 4 6 8 10 12 14020406080100VSV-N vs. TbpIfit3 vs. TbpIL-6 vs TbpSupplementary Figure 6alog 10(2-ΔCt )log 10(2-ΔCt )log 10(2-ΔCt )Supplementary Figure 6 | in vivo infection experiments. (a) Survival rates of 8–12 week old wild-type (Nudt2+/+) (9 animals) or NUDT2 knockout (Nudt2-/-) mice (8 animals) infected intranasally with 5e6 PFU of VSV in 20 µL PBS. (b) Viral RNA load and levels of Ifit3 and Il-6 in the cerebrum of wild-type and knockout mice infected with VSV. RNA levels were quantified by RT-qPCR analysis using specific primers for the N-transcript of VSV. Data were normalized to murine Tbp RNA. Shown is the mean ± SD. Every dot represents an individual infected mouse (n = 2 for NUDT2-/- at 2 days post infection and n = 6 for the other conditions). Sequence Name siRNA target sequence 5’->3’ Hs_NUDT1_3 CTCCTGCTTCAGAAGAAGAAA Hs_NUDT1_4 CCGGGTTTCATCTGGAATTAA Hs_NUDT1_5 CCGCGAGGTGGACACGGTCTA Hs_NUDT2_10 CAGGCATCAGATGGCATTCAT Hs_NUDT2_7 TGCCAGGGTCCTGCAGTTATA Hs_NUDT2_8 AGGATCCTTGTGGGCCTTCTA Hs_NUDT5_2 CAGGCTTGTCAAACTGTACTA Hs_NUDT5_3 TACATGGATCCTACTGGTAAA Hs_NUDT5_6 TTCCTACGCTCTAGCACTGAA Hs_NUDT6_5 CACGCAGAATCGGATTCATCA Hs_NUDT6_6 CTGGTTGTACAAGATCGAAAT Hs_NUDT6_7 GAGCTGTATTTGATGAAAGTA Hs_NUDT9_5 ATGGATAATCTTATGCTAGAA Hs_NUDT9_6 CACGCTGCAGATCCCATTATA Hs_NUDT9_3 AAGATTAGTGCCACACTGAAA Hs_NUDT12_6 AGCCGAGCTATTGCACATCAA Hs_NUDT12_7 ATGATTGGTTGCTTAGCTCTA Hs_NUDT12_5 AAGGTCGGATATTAAATAAGT Hs_NUDT13_6 CAGGGAACGGAAGCCGTTGAA Hs_NUDT13_5 CCACAACGTGTTGATTAACAA Hs_NUDT13_7 TAGCCCGGATCAAGTCACTTA Hs_NUDT14_1 CAGCGTGACCGTTCTCTTATT Hs_NUDT14_2 AAAGGCTTGCATAGCTCCAAA Hs_NUDT14_4 CTCCAGACAGACCATGTTCTA Hs_NUDT15_4 CAGCAGTACTCTTCTCACTAA Hs_NUDT15_6 CTCAAGAGCCTTTCAAGGGTA Hs_NUDT15_7 ATCTGGTGTGATATTGTAATA Hs_NUDT16_1 CTCCCTGTTTATATGCGTACA Hs_NUDT16_2 CAGGTCAACACTAATACCACT Hs_NUDT16_3 ATGTATGAAGGTGGTTCTCAA Hs_NUDT17_7 CCCAACCATGGCAGAGGACAA Hs_NUDT17_6 CCCGGATCCAACCAAACCCAA Hs_NUDT17_5 TACCATCACATTGTTCTGTAT Hs_NUDT18_1 CTGGGCCGAGATCACAGTGAT Hs_NUDT18_2 AAGCGAGGAGTCCAAAGCTCA Hs_NUDT18_3 ATCCTGCACCTGGTTGAACTA Hs_NUDT19_4 TACGAAGTGAGAAGACTTGCA Hs_NUDT19_3 CACGTTTATCCTAAGAACTCT Hs_NUDT19_2 CACCGGATAGTGACATACCAT Hs_DCP2_5 CCGGTGATTCATGTTTGTGAA Hs_DCP2_6 CTGCTTATAAATGTTATTGTA Hs_DCP2_1 CTGGGTTATCAGAGTAATGAA Hs_NUDT21_5 CTGCACATATTACAAAGCCTA Hs_NUDT21_1 ATCGTGATGAGAAACCTAATA Hs_NUDT21_3 CCAAGTGTAGCTGAGCAATTA Hs_NUDT22_4 AGGCGCCATCATCCTCTACAA Hs_NUDT22_1 CTGGGCCTTACTTCCTACCGA Hs_NUDT22_3 CCGAGACTTCCTGGGCACCAA Hs_DDX58_6  (RIG-I) AACGTTTACAACCAGAATTTA Hs_DDX58_10 (RIG-I)  TTCTACAGATTTGCTCTACTA Hs_DDX58_11 (RIG-I) CTCCTCCTACCCGGCTTTAAA Scrambled (control) AAGGTAATTGCGCGTGCAACT Supplementary Table 1 siRNA target sequences used in the siRNA screenSupplementary Table 2 Proteomic analysis of bone-marrow cells drived from Nudt2-/- animals and Nudt2+/+ littermate controls (WT_1-3 and KO_1-3). Three individual mice per genotype were analyzed. Table shows Protein IDs and label free quantification levels (LFQ) of individual measurements. (two-tailed Student’s t-test, FDR 0.05, S0 = 0.1) Sequence Name Sequence 5’ -> 3’ dsRNA IVT4 TTGTAATACGACTCACTATAGGGACGCTGACCCAGAAGATCTACTAGAAATAGTAGATCTTCTGGGTCAGCGTCCC dsRNA IVT4_as GGGACGCTGACCCAGAAGATCTACTATTTCTAGTAGATCTTCTGGGTCAGCGTCCCTATAGTGAGTCGTATTACAA G0 AATTCCTGCAGTAATACGACTCACTATAGGCGCCGCGGTAACGCGGCGCCACGCGGAAACGCGCC G0_as GGCGCGTTTCCGCGTGGCGCCGCGTTACCGCGGCGCCTATAGTGAGTCGTATTACTGCAGGAATT G8 AATTCCTGCAGTAATACGACTCACTATAGGAACAACGGCGCCGCGGTAACGCGGCGCCACGCGGAAACGCGCC G8_as GGCGCGTTTCCGCGTGGCGCCGCGTTACCGCGGCGCCGTTGTTCCTATAGTGAGTCGTATTACTGCAGGAATT G4[GGAA] AATTCCTGCAGTAATACGACTCACTATAGGAAGGCGCCGCGGTAACGCGGCGCCACGCGGAAACGCGCC G4[GGAA]_as GGCGCGTTTCCGCGTGGCGCCGCGTTACCGCGGCGCCTTCCTATAGTGAGTCGTATTACTGCAGGAATT G4[GAAA] AATTCCTGCAGTAATACGACTCACTATAGAAAGGCGCCGCGGTAACGCGGCGCCACGCGGAAACGCGCC  G4[GAAA]_as GGCGCGTTTCCGCGTGGCGCCGCGTTACCGCGGCGCCTTTCTATAGTGAGTCGTATTACTGCAGGAATT G4[GCAA] AATTCCTGCAGTAATACGACTCACTATAGCAAGGCGCCGCGGTAACGCGGCGCCACGCGGAAACGCGCC G4[GCAA]_as GGCGCGTTTCCGCGTGGCGCCGCGTTACCGCGGCGCCTTGCTATAGTGAGTCGTATTACTGCAGGAATT G4[GUAA] AATTCCTGCAGTAATACGACTCACTATAGTAAGGCGCCGCGGTAACGCGGCGCCACGCGGAAACGCGCC G4[GUAA]_as GGCGCGTTTCCGCGTGGCGCCGCGTTACCGCGGCGCCTTACTATAGTGAGTCGTATTACTGCAGGAATT A8 AATTCCTGCAGTAATACGACTCACTATTAGAACAACGGCGCCGCGGTAACGCGGCGCCACGCGGAAACGCGCC A8_as GGCGCGTTTCCGCGTGGCGCCGCGTTACCGCGGCGCCGTTGTTCTAATAGTGAGTCGTATTACTGCAGGAATT  A4[AGAA] AATTCCTGCAGTAATACGACTCACTATTAGAAGGCGCCGCGGTAACGCGGCGCCACGCGGAAACGCGCC A4[AGAA]_as GGCGCGTTTCCGCGTGGCGCCGCGTTACCGCGGCGCCTTCTAATAGTGAGTCGTATTACTGCAGGAATT A1 AATTCCTGCAGTAATACGACTCACTATTAGGCGCCGCGGTAACGCGGCGCCACGCGGAAACGCGCC A1_as GGCGCGTTTCCGCGTGGCGCCGCGTTACCGCGGCGCCTAATAGTGAGTCGTATTACTGCAGGAATT  Supplementary Table 3 Nucleotide sequences used as templates in in vitro transcriptionsT7(φ2.5)_fwd AATTCCTGCAGTAATACGACTCACTATAG  T7(φ6.5)_fwd AATTCCTGCAGTAATACGACTCACTATTA    Ren_IVT_PCR TTAAGGACGTCATTATGCTGAGTGAT   Sequence Name Sequence 5’ -> 3’-  hu_NUDT2_fw CACTGGACTCCTCCCAAAGG hu_NUDT2_rv TCCTCTTGGGTCTCCCTCAG hu_NUDT12_fw TTGGGCAAAACTTGTATCGAC hu_NUDT12_rv CTTCATCCTCCTATGCCAGC hu_NUDT14_fw AAGAGAACGGTCACGCTGTC hu_NUDT14_rv CCGCCTCACCCTACCTG hu_NUDT17_fw GACTGTCTTGCTAACCCGAAG hu_NUDT17_rv GGCAGGTGTAGTCCACTCTC VSV-N_fw ATCGGAATATTTGACCTTGTA VSV-N_rv ACTGTTCATTGATCATTTTGC ms_ActB_fw CTCTGGCTCCTAGCACCATGAAGA ms_ActB_rv GTAAAACGCAGCTCAGTAACAGTCCG SFV-nsp3_fw GCAAGAGGCAAACGAACAGA SFV-nsp3_rev GGGAAAAGATGAGCAAACCA HSV-DNA Polymerase I_fw AGCCTGTACCCCAGCATCAT HSV-DNA Polymerase I_rv TGGGCCTTCACGAAGAACA Firefly Luc_fw CTCACTGAGACTACATCAGC Firefly Luc_rv TCCAGATCCACAACCTTCGC hu_GAPDH_fw GATTCCACCCATGGCAAATTC hu_GAPDH_fw AGCATCGCCCCACTTGATT Supplementary Table 4 qRT-PCR primers used in this study Renilla Luc_fwRenilla Luc_rvGAATTTGCAGCATATCTTGAACCATGGATTTCACGAGGCCATGATAAGGATCTGCTGCATCTGCTTGGCGACCTGGAAGTCCAACTACCTTCACCAATGACTCCTATGAChu_RPLP0_fwhu_RPLP0_rvmu_TBP_fwmu_TBP_rvTGGTCATGTGCCGTTACAGGGCTGCGAGGTCTTCAGACTTTAGTCCTTCCTACCCCAATTTCCTTGGTCCTTAGCCACTCCTTCACTTACCTGGCAGGGGAGATACACATCCGGAGTGCAATGGATAAmu_Ifit3_fwmu_Ifit3_rvmu_Il6_fwmu_Il6_rvU1 RNA_fwU1 RNA_rvSequence Name Sequence 5’ -> 3’NUDT2_gRNA1 ATGAGCACCAAGCCTACCGC NUDT2_gRNA2 AATTGCATTGTTGTCCACTT NUDT2_gRNA3 TAACTAGGCCATGTGGAACC NUDT2_gRNA4 CATCAGATGGCATTCATCAC NUDT2_gRNA5 TCTCCTTGAACTGAGCCAAC NUDT2_gRNA6 CCATTATTGAGGGGTTCAAA XRN1_gRNA1 TTAAGAGAAGAAGTTCGATT XRN1_gRNA2 TAAAACGCCTCCCACGCTGC XRN1_gRNA3 GCTTGGATTAACAAGTCATG XRN1_gRNA4 TAATGCGAAACAACACCTCC XRN1_gRNA5 GTATCCCTGTCTCAGCGAAG XRN1_gRNA6 TTTCACCACTTCGCTGAGAC  Supplementary Table 5Nucleotide guide sequences cloned in pLentiCRISPRv2

English

NUDT2 initiates viral RNA degradation by removal of 5′-phosphates.

http://dx.doi.org/10.1038/s41467-021-27239-y

NUDT2 initiates viral RNA degradation by removal of 5'-phosphates.

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MPG.PuRe