Your search keyword '"Phosphoric Diester Hydrolases/genetics"' showing total 4 results

1. A prenylated dsRNA sensor protects against severe COVID-19

Author

Wickenhagen, A, Sugrue, E, Lytras, S, Kuchi, S, Noerenberg, M, Turnbull, ML, Loney, C, Herder, V, Allan, J, Jarmson, I, Cameron-Ruiz, N, Varjak, M, Pinto, RM, Lee, JY, Iselin, L, Palmalux, N, Stewart, DG, Swingler, S, Greenwood, EJD, Crozier, TWM, Gu, Q, Davies, EL, Clohisey, S, Wang, B, Trindade Maranhão Costa, F, Freire Santana, M, de Lima Ferreira, LC, Murphy, L, Fawkes, A, Meynert, A, Grimes, G, Da Silva Filho, JL, Marti, M, Hughes, J, Stanton, RJ, Wang, ECY, Ho, A, Davis, I, Jarrett, RF, Castello, A, Robertson, DL, Semple, MG, Openshaw, PJM, Palmarini, M, Lehner, PJ, Baillie, JK, Rihn, SJ, Wilson, SJ, ISARIC4C Investigators, Carson, G, Alex, B, Bach, B, Barclay, WS, Bogaert, D, Chand, M, Cooke, GS, Docherty, AB, Dunning, J, da Silva Filipe, A, Fletcher, T, Green, CA, Harrison, EM, Ho, AYW, Horby, PW, Ijaz, S, Khoo, S, Klenerman, P, Law, A, Lim, WS, Mentzer, AJ, Merson, L, Meynert, AM, Noursadeghi, M, Moore, SC, Paxton, WA, Pollakis, G, Price, N, Rambaut, A, Russell, CD, Sancho-Shimizu, V, Scott, JT, de Silva, T, Sigfrid, L, Solomon, T, Sriskandan, S, Stuart, D, Summers, C, Tedder, RS, Thomson, EC, Thompson, AAR, Thwaites, RS, Turtle, LCW, Gupta, RK, Palmieri, C, Swann, OV, Zambon, M, Dumas, M-E, Griffin, JL, Takats, Z, Chechi, K, Andrikopoulos, P, Osagie, A, Olanipekun, M, Liggi, S, Lewis, MR, Dos Santos Correia, G, Sands, CJ, Takis, P, Maslen, L, Hardwick, H, Donohue, C, Griffiths, F, Oosthuyzen, W, Donegan, C, Spencer, RG, Norman, L, Pius, R, Drake, TM, Fairfield, CJ, Knight, SR, Mclean, KA, Murphy, D, Shaw, CA, Dalton, J, Girvan, M, Saviciute, E, Roberts, S, Harrison, J, Marsh, L, Connor, M, Halpin, S, Jackson, C, Gamble, C, Plotkin, D, Lee, J, Leeming, G, Wham, M, Hendry, R, Scott-Brown, J, Greenhalf, W, Shaw, V, McDonald, SE, Keating, S, Ahmed, KA, Armstrong, JA, Ashworth, M, Asiimwe, IG, Bakshi, S, Barlow, SL, Booth, L, Brennan, B, Bullock, K, Catterall, BWA, Clark, JJ, Clarke, EA, Cole, S, Cooper, L, Cox, H, Davis, C, Dincarslan, O, Dunn, C, Dyer, P, Elliott, A, Evans, A, Finch, L, Fisher, LWS, Foster, T, Garcia-Dorival, I, Gunning, P, Hartley, C, Jensen, RL, Jones, CB, Jones, TR, Khandaker, S, King, K, Kiy, RT, Koukorava, C, Lake, A, Lant, S, Latawiec, D, Lavelle-Langham, L, Lefteri, D, Lett, L, Livoti, LA, Mancini, M, McDonald, S, McEvoy, L, McLauchlan, J, Metelmann, S, Miah, NS, Middleton, J, Mitchell, J, Murphy, EG, Penrice-Randal, R, Pilgrim, J, Prince, T, Reynolds, W, Ridley, PM, Sales, D, Shaw, VE, Shears, RK, Small, B, Subramaniam, KS, Szemiel, A, Taggart, A, Tanianis-Hughes, J, Thomas, J, Trochu, E, van Tonder, L, Wilcock, E, Zhang, JE, Flaherty, L, Maziere, N, Cass, E, Carracedo, AD, Carlucci, N, Holmes, A, Massey, H, Wrobel, N, McCafferty, S, Morrice, K, MacLean, A, Adeniji, K, Agranoff, D, Agwuh, K, Ail, D, Aldera, EL, Alegria, A, Allen, S, Angus, B, Ashish, A, Atkinson, D, Bari, S, Barlow, G, Barnass, S, Barrett, N, Bassford, C, Basude, S, Baxter, D, Beadsworth, M, Bernatoniene, J, Berridge, J, Berry, C, Best, N, Bothma, P, Chadwick, D, Brittain-Long, R, Bulteel, N, Burden, T, Burtenshaw, A, Caruth, V, Chambler, D, Chee, N, Child, J, Chukkambotla, S, Clark, T, Collini, P, Cosgrove, C, Cupitt, J, Cutino-Moguel, M-T, Dark, P, Dawson, C, Dervisevic, S, Donnison, P, Douthwaite, S, Drummond, A, DuRand, I, Dushianthan, A, Dyer, T, Evans, C, Eziefula, C, Fegan, C, Finn, A, Fullerton, D, Garg, S, Garg, A, Gkrania-Klotsas, E, Godden, J, Goldsmith, A, Graham, C, Hardy, E, Hartshorn, S, Harvey, D, Havalda, P, Hawcutt, DB, Hobrok, M, Hodgson, L, Hormis, A, Jacobs, M, Jain, S, Jennings, P, Kaliappan, A, Kasipandian, V, Kegg, S, Kelsey, M, Kendall, J, Kerrison, C, Kerslake, I, Koch, O, Koduri, G, Koshy, G, Laha, S, Laird, S, Larkin, S, Leiner, T, Lillie, P, Limb, J, Linnett, V, Little, J, Lyttle, M, MacMahon, M, MacNaughton, E, Mankregod, R, Masson, H, Matovu, E, McCullough, K, McEwen, R, Meda, M, Mills, G, Minton, J, Mirfenderesky, M, Mohandas, K, Mok, Q, Moon, J, Moore, E, Morgan, P, Morris, C, Mortimore, K, Moses, S, Mpenge, M, Mulla, R, Murphy, M, Nagel, M, Nagarajan, T, Nelson, M, Norris, L, O'Shea, MK, Otahal, I, Ostermann, M, Pais, M, Panchatsharam, S, Papakonstantinou, D, Paraiso, H, Patel, B, Pattison, N, Pepperell, J, Peters, M, Phull, M, Pintus, S, Singh Pooni, J, Planche, T, Post, F, Price, D, Prout, R, Rae, N, Reschreiter, H, Reynolds, T, Richardson, N, Roberts, M, Roberts, D, Rose, A, Rousseau, G, Ruge, B, Ryan, B, Saluja, T, Schmid, ML, Shah, A, Shanmuga, P, Sharma, A, Shawcross, A, Sizer, J, Shankar-Hari, M, Smith, R, Snelson, C, Spittle, N, Staines, N, Stambach, T, Stewart, R, Subudhi, P, Szakmany, T, Tatham, K, Thompson, C, Thompson, R, Tridente, A, Tupper-Carey, D, Twagira, M, Vallotton, N, Vancheeswaran, R, Vincent-Smith, L, Visuvanathan, S, Vuylsteke, A, Waddy, S, Wake, R, Walden, A, Welters, I, Whitehouse, T, Whittaker, P, Whittington, A, Papineni, P, Wijesinghe, M, Williams, M, Wilson, L, Winchester, S, Wiselka, M, Wolverson, A, Wootton, DG, Workman, A, Yates, B, Young, P, Division of Computational and Systems Medicine, Imperial College London, London, SW7 2AZ, UK, Imperial College London - National Heart and Lung Institute, Centre National de la Recherche Scientifique (CNRS), MRC - University of Glasgow Centre for Virus Research, University of Kent [Canterbury], University of Glasgow, National Institute for Health Research, UK Research and Innovation, UKRI MRC COVID-19 Rapid Response Call, Mentzer, AJ, Investigators, ISARIC4C, Lee, J, and Angus, B

Subjects

2',5'-Oligoadenylate Synthetase/genetics, L PATHWAY, viruses, SINGLE-NUCLEOTIDE POLYMORPHISM, RNASE-L, RNA, Viral/chemistry, RNA, Double-Stranded/chemistry, Virus Replication, Severity of Illness Index, COVID-19/enzymology, [SDV.MHEP.MI]Life Sciences [q-bio]/Human health and pathology/Infectious diseases, Chiroptera, Sense (molecular biology), 2',5'-Oligoadenylate Synthetase, MESH: COVID-19, MESH: Animals, MESH: Interferons, ENZYME-ACTIVITY, MESH: 2',5'-Oligoadenylate Synthetase, Endoribonucleases/metabolism, 0303 health sciences, MESH: Protein Prenylation, Multidisciplinary, I INTERFERON, Coronaviridae/enzymology, MESH: Polymorphism, Single Nucleotide, 030302 biochemistry & molecular biology, MESH: Chiroptera, CORONAVIRUS REPLICATION, 3. Good health, Cell biology, Multidisciplinary Sciences, Isoenzymes, RNA silencing, VIRUS NS1 PROTEIN, MESH: RNA, Viral, [SDV.MP.VIR]Life Sciences [q-bio]/Microbiology and Parasitology/Virology, MESH: Isoenzymes, Science & Technology - Other Topics, RNA, Viral, MESH: 5' Untranslated Regions, [SDV.IMM]Life Sciences [q-bio]/Immunology, SARS-CORONAVIRUS, Gene isoform, MESH: Endoribonucleases, Retroelements, RNase P, Coronaviridae, General Science & Technology, Protein Prenylation, Biology, Polymorphism, Single Nucleotide, Chiroptera/genetics, 03 medical and health sciences, MESH: RNA, Double-Stranded, MESH: Retroelements, SARS-CoV-2/genetics, MESH: Severity of Illness Index, Endoribonucleases, Animals, Humans, MESH: SARS-CoV-2, Interferons/immunology, Gene, ISARIC4C Investigators, 030304 developmental biology, RNA, Double-Stranded, Science & Technology, MESH: Humans, ACCEPTOR SITE, Phosphoric Diester Hydrolases, SARS-CoV-2, fungi, MESH: Virus Replication, RNA, COVID-19, Phosphoric Diester Hydrolases/genetics, Viral replication, A549 Cells, Protein prenylation, SPLICE-SITE POLYMORPHISM, Interferons, MESH: A549 Cells, 5' Untranslated Regions, MESH: Phosphoric Diester Hydrolases, Isoenzymes/genetics, MESH: Coronaviridae

Abstract

International audience; INTRODUCTIONInterferons (IFNs) are cytokines that are rapidly deployed in response to invading pathogens. By initiating a signaling cascade that stimulates the expression of hundreds of genes, IFNs create an antiviral state in host cells. Because IFNs heavily influence COVID-19 outcomes, and severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) replication can be inhibited by the antiviral state, it is important to understand how the individual antiviral effectors encoded by IFN-stimulated genes (ISGs) inhibit SARS-CoV-2.RATIONALEWe hypothesized that IFN-stimulated antiviral effectors can inhibit SARS-CoV-2, and that variation at the loci encoding these defenses underlies why some people are more susceptible to severe COVID-19.RESULTSWe used arrayed ISG expression screening to reveal that 2′-5′-oligoadenylate synthetase 1 (OAS1) consistently inhibited SARS-CoV-2 in different contexts. Using CRISPR-Cas9, we found that endogenous OAS1 makes a substantial contribution to the antiviral state by recognizing short stretches of double-stranded RNA (dsRNA) and activating RNase L. We globally mapped where OAS1 binds to SARS-CoV-2 viral RNAs and found that OAS1 binding is remarkably specific, with two conserved stem loops in the SARS-CoV-2 5′-untranslated region (UTR) constituting the principal viral target.OAS1 expression was readily detectable at the sites of infection in individuals who died of COVID-19, and specific OAS1 alleles are known to be associated with altered susceptibility to infection and severe disease. It had previously been reported that alleles containing a common splice-acceptor single nucleotide polymorphism in OAS1 (Rs10774671) were associated with less severe COVID-19. We determined that people with at least one allele with a G at this position could express a prenylated form of OAS1 (p46), whereas other individuals could not. Using a series of mutants, we found that C-terminal prenylation was necessary for OAS1 to initiate a block to SARS-CoV-2. Furthermore, confocal microscopy revealed that prenylation targeted OAS1 to perinuclear structures rich in viral dsRNA, whereas non-prenylated OAS1 was diffusely localized and unable to initiate a detectable block to SARS-CoV-2 replication.The realization that prenylation is essential for OAS1-mediated sensing of SARS-CoV-2 allowed us to examine the transcriptome of infected patients and investigate whether there was a link between the expression of prenylated OAS1 and SARS-CoV-2 disease progression. Analysis of the OAS1 transcripts from 499 hospitalized COVID-19 patients revealed that expressing prenylated OAS1 was associated with protection from severe COVID-19.Because prenylated OAS1 was so important in human cases, we wanted to determine whether horseshoe bats, the likely source of SARS-CoV-2, possessed the same defense. When we examined the genomic region where the prenylation signal should reside, retrotransposition of a long terminal repeat sequence had ablated this signal, preventing the expression of prenylated anti-CoV OAS1 in these bats.CONCLUSIONC-terminal prenylation targets OAS1 to intracellular sites rich in viral dsRNA, which are likely the SARS-CoV-2 replicative organelles. Once in the right place, OAS1 binds to dsRNA structures in the SARS-CoV-2 5′-UTR and initiates a potent block to SARS-CoV-2 replication. Thus, the correct targeting of OAS1 and the subsequent inhibition of SARS-CoV-2 likely underpins the genetic association of alleles containing a G at Rs10774671 with reduced susceptibility to infection and severe disease in COVID-19. Moreover, the conspicuous absence of this antiviral defense in horseshoe bats potentially explains why SARS-CoV-2 is so sensitive to this defense in humans.

Published

2021

2. Familial Micronodular Adrenocortical Disease, Cushing Syndrome, and Mutations of the Gene Encoding Phosphodiesterase 11A4 (PDE11A)

Author

Jérôme Bertherat, Constantine A. Stratakis, Rolf C. Gaillard, and J. Aidan Carney

Subjects

Adrenal Cortex Diseases, Adult, medicine.medical_specialty, Pathology, medicine.medical_treatment, Biology, Article, Pathology and Forensic Medicine, chemistry.chemical_compound, Cushing syndrome, Young Adult, 3',5'-Cyclic-GMP Phosphodiesterases, Internal medicine, Cortex (anatomy), Adrenal Glands, medicine, Humans, Cyclic adenosine monophosphate, Genetic Predisposition to Disease, Child, Cyclic guanosine monophosphate, Cushing Syndrome, Family Health, Adrenal Cortex/metabolism, Adrenal Cortex/pathology, Adrenal Cortex Diseases/genetics, Adrenal Cortex Diseases/pathology, Adrenal Cortex Diseases/surgery, Adrenal Glands/pathology, Cushing Syndrome/genetics, Cushing Syndrome/pathology, Cushing Syndrome/surgery, Phosphoric Diester Hydrolases/genetics, Phosphoric Diester Hydrolases/metabolism, Adrenal cortex, Phosphoric Diester Hydrolases, Adrenalectomy, Cushing's disease, Organ Size, medicine.disease, medicine.anatomical_structure, Endocrinology, chemistry, Adrenal Cortex, Surgery, Female, Anatomy, Primary pigmented nodular adrenocortical disease

Abstract

We present the pathologic findings in the adrenal glands of 4 patients, aged 10 to 38 years, with Cushing syndrome and germline inactivating mutations of the gene PDE11A4 that encodes phosphodiesterase11A4. The gene is expressed in the adrenal cortex and catalyses the hydrolysis of cyclic adenosine monophosphate and cyclic guanosine monophosphate. Two of the patients were mother and daughter; the third had no affected relative; the fourth patient inherited the mutation from her father. Three of the group, including the mother and daughter, had the same pathology, primary pigmented nodular adrenocortical disease, a disorder known to be caused by inactivating mutations of the PRKAR1A gene. In these cases, the adrenal glands were small and the pathologic change was deep in the cortex in which numerous pigmented micronodules developed. In the remaining patient, the glands were slightly enlarged primarily owing to a diffuse hyperplasia of the superficial cortex that extended into the epi-adrenal fat.

Published

2010

3. Selective blockade of phosphodiesterase types 2, 5 and 9 results in cyclic 3′5′ guanosine monophosphate accumulation in retinal pigment epithelium cells

Author

E. C. La Heij, Fred Hendrikse, Roselie M.H. Diederen, M. Markerink-van Ittersum, Aize Kijlstra, J. de Vente, and Ophthalmology

Subjects

RNA, Messenger/genetics, Exonucleases, Male, Phosphodiesterase Inhibitors, Gene Expression, Exonucleases/antagonists & inhibitors, chemistry.chemical_compound, 3',5'-Cyclic-AMP Phosphodiesterases/antagonists & inhibitors, 5'-Cyclic-GMP Phosphodiesterases/antagonists & inhibitors, Laboratory Science - Extended Report, Pigment Epithelium of Eye, Cyclic GMP, Cells, Cultured, In Situ Hybridization, Cultured, Inbred Lew, Pigment Epithelium of Eye/drug effects, Phosphodiesterase, Sensory Systems, medicine.anatomical_structure, Type 5, Retina/drug effects, Phosphodiesterase Inhibitors/pharmacology, Cyclic Nucleotide Phosphodiesterases, medicine.medical_specialty, Cells, Phosphodiesterase 3, Biology, Retina, Cellular and Molecular Neuroscience, 3',5'-Cyclic-GMP Phosphodiesterases, Internal medicine, Guanosine monophosphate, medicine, 3', Animals, Humans, RNA, Messenger, Cyclic Nucleotide Phosphodiesterases, Type 5, Retinal pigment epithelium, Phosphoric Diester Hydrolases, 5'-Cyclic-AMP Phosphodiesterases/antagonists & inhibitors, Phosphoric Diester Hydrolases/genetics, Molecular biology, eye diseases, Rats, Ophthalmology, Cyclic GMP/metabolism, Endocrinology, chemistry, Cell culture, 3',5'-Cyclic-AMP Phosphodiesterases, Rats, Inbred Lew, RNA, Messenger/genetics, sense organs, PDE10A, Soluble guanylyl cyclase, 3',5'-Cyclic-GMP Phosphodiesterases/antagonists & inhibitors

Abstract

Aim: To investigate which phosphodiesterase (PDE) is involved in regulating cyclic 3′5′ guanosine monophosphate breakdown in retinal pigment epithelium (RPE) cells. Methods: cGMP content in the cultured RPE cells (D407 cell line) was evaluated by immunocytochemistry in the presence of non-selective or isoform-selective PDE inhibitors in combination with the particulate guanylyl cyclase stimulator atrial natriuretic peptide (ANP) or the soluble guanylyl cyclase stimulator sodium nitroprusside (SNP). mRNA expression of PDE2, PDE5 and PDE9 was studied in cultured human RPE cells and rat RPE cell layers using non-radioactive in situ hybridisation. Results: In the absence of PDE inhibitors, cGMP levels in cultured RPE cells are very low. cGMP accumulation was readily detected in cultured human RPE cells after incubation with Bay60–7550 as a selective PDE2 inhibitor, sildenafil as a selective PDE5 inhibitor or Sch51866 as a selective PDE9 inhibitor. In the presence of PDE inhibition, cGMP content increased markedly after stimulation of the particulate guanylyl cyclase. mRNA of PDE2,PDE5 and PDE9 was detected in all cultured human RPE cells and also in rat RPE cell layers. Conclusions: PDE2, PDE5 and PDE9 have a role in cGMP metabolism in RPE cells.

Published

2006

4. Single-stranded oligonucleotide-mediated in vivo gene repair in the rd1 retina

Author

Andrieu-Soler, C., Halhal, M., Boatright, J. H., Padove, S. A., Nickerson, J. M., Stodulkova, E., Stewart, R. E., Ciavatta, V. T., Doat, M., Jeanny, J. -C, Bizemont, T., Florian Sennlaub, Courtois, Y., and Behar-Cohen, F.

Subjects

Aging, Cyclic Nucleotide Phosphodiesterases, Type 6, Mice, Inbred C3H, Rhodopsin, Staining and Labeling, genetic structures, Phosphoric Diester Hydrolases, Retinal Degeneration, Oligonucleotides, hemic and immune systems, Iontophoresis, respiratory system, Eye, Immunohistochemistry, Mice, Mutant Strains, Retina, eye diseases, Aging/metabolism, Animals, Animals, Newborn, Eye/enzymology, Immunohistochemistry/methods, Mice, Oligonucleotides/administration & dosage, Oligonucleotides/therapeutic use, Phosphoric Diester Hydrolases/genetics, Phosphoric Diester Hydrolases/metabolism, Point Mutation, Retina/enzymology, Retina/pathology, Retinal Degeneration/enzymology, Retinal Degeneration/genetics, Rhodopsin/metabolism, Targeted Gene Repair, sense organs, Research Article

Abstract

PURPOSE: The aim of this study was to test whether oligonucleotide-targeted gene repair can correct the point mutation in genomic DNA of PDE6b(rd1) (rd1) mouse retinas in vivo. METHODS: Oligonucleotides (ODNs) of 25 nucleotide length and complementary to genomic sequence subsuming the rd1 point mutation in the gene encoding the beta-subunit of rod photoreceptor cGMP-phosphodiesterase (beta-PDE), were synthesized with a wild type nucleotide base at the rd1 point mutation position. Control ODNs contained the same nucleotide bases as the wild type ODNs but with varying degrees of sequence mismatch. We previously developed a repeatable and relatively non-invasive technique to enhance ODN delivery to photoreceptor nuclei using transpalpebral iontophoresis prior to intravitreal ODN injection. Three such treatments were performed on C3H/henJ (rd1) mouse pups before postnatal day (PN) 9. Treatment outcomes were evaluated at PN28 or PN33, when retinal degeneration was nearly complete in the untreated rd1 mice. The effect of treatment on photoreceptor survival was evaluated by counting the number of nuclei of photoreceptor cells and by assessing rhodopsin immunohistochemistry on flat-mount retinas and sections. Gene repair in the retina was quantified by allele-specific real time PCR and by detection of beta-PDE-immunoreactive photoreceptors. Confirmatory experiments were conducted using independent rd1 colonies in separate laboratories. These experiments had an additional negative control ODN that contained the rd1 mutant nucleotide base at the rd1 point mutation site such that the sole difference between treatment with wild type and control ODN was the single base at the rd1 point mutation site. RESULTS: Iontophoresis enhanced the penetration of intravitreally injected ODNs in all retinal layers. Using this delivery technique, significant survival of photoreceptors was observed in retinas from eyes treated with wild type ODNs but not control ODNs as demonstrated by cell counting and rhodopsin immunoreactivity at PN28. Beta-PDE immunoreactivity was present in retinas from eyes treated with wild type ODN but not from those treated with control ODNs. Gene correction demonstrated by allele-specific real time PCR and by counts of beta-PDE-immunoreactive cells was estimated at 0.2%. Independent confirmatory experiments showed that retinas from eyes treated with wild type ODN contained many more rhodopsin immunoreactive cells compared to retinas treated with control (rd1 sequence) ODN, even when harvested at PN33. CONCLUSIONS: Short ODNs can be delivered with repeatable efficiency to mouse photoreceptor cells in vivo using a combination of intravitreal injection and iontophoresis. Delivery of therapeutic ODNs to rd1 mouse eyes resulted in genomic DNA conversion from mutant to wild type sequence, low but observable beta-PDE immunoreactivity, and preservation of rhodopsin immunopositive cells in the outer nuclear layer, suggesting that ODN-directed gene repair occurred and preserved rod photoreceptor cells. Effects were not seen in eyes treated with buffer or with ODNs having the rd1 mutant sequence, a definitive control for this therapeutic approach. Importantly, critical experiments were confirmed in two laboratories by several different researchers using independent mouse colonies and ODN preparations from separate sources. These findings suggest that targeted gene repair can be achieved in the retina following enhanced ODN delivery.