Your search keyword '"Stuart, David A."' showing total 71 results

1. Broadly neutralizing antibodies against COVID-19

Author

Zhou, Daming, Ren, Jingshan, Fry, Elizabeth E, and Stuart, David I

Published

2023

2. SARS-CoV-2-specific nasal IgA wanes 9 months after hospitalisation with COVID-19 and is not induced by subsequent vaccination

Author

Baillie, J. Kenneth, Openshaw, Peter J.M., Semple, Malcolm G., Alex, Beatrice, Andrikopoulos, Petros, Bach, Benjamin, Barclay, Wendy S., Bogaert, Debby, Chand, Meera, Chechi, Kanta, Cooke, Graham S., da Silva Filipe, Ana, de Silva, Thushan, Docherty, Annemarie B., dos Santos Correia, Gonçalo, Dumas, Marc-Emmanuel, Dunning, Jake, Fletcher, Tom, Green, Christopher A., Greenhalf, William, Griffin, Julian, Gupta, Rishi K., Harrison, Ewen M., Ho, Antonia Y.W., Holden, Karl, Horby, Peter W., Ijaz, Samreen, Khoo, Say, Klenerman, Paul, Law, Andrew, Lewis, Matthew, Liggi, Sonia, Lim, Wei Shen, Maslen, Lynn, Mentzer, Alexander J., Merson, Laura, Meynert, Alison M, Moore, Shona C., Noursadeghi, Mahdad, Olanipekun, Michael, Osagie, Anthonia, Palmarini, Massimo, Palmieri, Carlo, Paxton, William A., Pollakis, Georgios, Price, Nicholas, Rambaut, Andrew, Robertson, David L, Russell, Clark D., Sancho-Shimizu, Vanessa, Sands, Caroline, Scott, Janet T., Sigfrid, Louise, Solomon, Tom, Sriskandan, Shiranee, Stuart, David, Summers, Charlotte, Swann, Olivia V., Takats, Zoltan, Takis, Panteleimon, Tedder, Richard S., Thompson, A.A. Roger, Thomson, Emma C., Thwaites, Ryan S., Turtle, Lance C.W., Zambon, Maria, Drake, Thomas M., Fairfield, Cameron J., Knight, Stephen R., Mclean, Kenneth A., Murphy, Derek, Norman, Lisa, Pius, Riinu, Shaw, Catherine A., Connor, Marie, Dalton, Jo, Gamble, Carrol, Girvan, Michelle, Halpin, Sophie, Harrison, Janet, Jackson, Clare, Lee, James, Marsh, Laura, Plotkin, Daniel, Roberts, Stephanie, Saviciute, Egle, Clohisey, Sara, Hendry, Ross, Knight, Susan, Lahnsteiner, Eva, Leeming, Gary, Norris, Lucy, Scott-Brown, James, Tait, Sarah, Wham, Murray, Clark, Richard, Coutts, Audrey, Donelly, Lorna, Fawkes, Angie, Gilchrist, Tammy, Hafezi, Katarzyna, MacGillivray, Louise, Maclean, Alan, McCafferty, Sarah, Morrice, Kirstie, Murphy, Lee, Wrobel, Nicola, Carson, Gail, Adeniji, Kayode, Agranoff, Daniel, Agwuh, Ken, Ail, Dhiraj, Aldera, Erin L., Alegria, Ana, Allen, Sam, Angus, Brian, Ashish, Abdul, Atkinson, Dougal, Bari, Shahedal, Barlow, Gavin, Barnass, Stella, Barrett, Nicholas, Bassford, Christopher, Basude, Sneha, Baxter, David, Beadsworth, Michael, Bernatoniene, Jolanta, Berridge, John, Berry, Colin, Best, Nicola, Bothma, Pieter, Brittain-Long, Robin, Bulteel, Naomi, Burden, Tom, Burtenshaw, Andrew, Caruth, Vikki, Chadwick, David, Chambler, Duncan, Chee, Nigel, Child, Jenny, Chukkambotla, Srikanth, Clark, Tom, Collini, Paul, Cosgrove, Catherine, Cupitt, Jason, Cutino-Moguel, Maria-Teresa, Dark, Paul, Dawson, Chris, Dervisevic, Samir, Donnison, Phil, Douthwaite, Sam, Drummond, Andrew, DuRand, Ingrid, Dushianthan, Ahilanadan, Dyer, Tristan, Evans, Cariad, Eziefula, Chi, Fegan, Chrisopher, Finn, Adam, Fullerton, Duncan, Garg, Sanjeev, Garg, Atul, Gkrania-Klotsas, Effrossyni, Godden, Jo, Goldsmith, Arthur, Graham, Clive, Grammatikopoulos, Tassos, Hardy, Elaine, Hartshorn, Stuart, Harvey, Daniel, Havalda, Peter, Hawcutt, Daniel B., Hobrok, Maria, Hodgson, Luke, Hormis, Anil, Howard, Joanne, Jacobs, Michael, Jain, Susan, Jennings, Paul, Kaliappan, Agilan, Kasipandian, Vidya, Kegg, Stephen, Kelsey, Michael, Kendall, Jason, Kerrison, Caroline, Kerslake, Ian, Koch, Oliver, Koduri, Gouri, Koshy, George, Laha, Shondipon, Laird, Steven, Larkin, Susan, Leiner, Tamas, Lillie, Patrick, Limb, James, Linnett, Vanessa, Little, Jeff, Lyttle, Mark, MacMahon, Michael, MacNaughton, Emily, Mankregod, Ravish, Masson, Huw, Matovu, Elijah, McCullough, Katherine, McEwen, Ruth, Meda, Manjula, Mills, Gary, Minton, Jane, Mohandas, Kavya, Mok, Quen, Moon, James, Moore, Elinoor, Morgan, Patrick, Morris, Craig, Mortimore, Katherine, Moses, Samuel, Mpenge, Mbiye, Mulla, Rohinton, Murphy, Michael, Nagarajan, Thapas, Nagel, Megan, Nelson, Mark, Norris, Lillian, O'Shea, Matthew K., Ostermann, Marlies, Otahal, Igor, Pais, Mark, Panchatsharam, Selva, Papakonstantinou, Danai, Papineni, Padmasayee, Paraiso, Hassan, Patel, Brij, Pattison, Natalie, Pepperell, Justin, Peters, Mark, Phull, Mandeep, Pintus, Stefania, Planche, Tim, Post, Frank, Price, David, Prout, Rachel, Rae, Nikolas, Reschreiter, Henrik, Reynolds, Tim, Richardson, Neil, Roberts, Mark, Roberts, Devender, Rose, Alistair, Rousseau, Guy, Ruge, Bobby, Ryan, Brendan, Saluja, Taranprit, Sarah, Sarah, Schmid, Matthias, Shah, Aarti, Shankar-Hari, Manu, Shanmuga, Prad, Sharma, Anil, Shawcross, Anna, Singh Pooni, Jagtur, Sizer, Jeremy, Smith, Richard, Snelson, Catherine, Spittle, Nick, Staines, Nikki, Stambach, Tom, Stewart, Richard, Subudhi, Pradeep, Szakmany, Tamas, Tatham, Kate, Thomas, Jo, Thompson, Chris, Thompson, Robert, Tridente, Ascanio, Tupper-Carey, Darell, Twagira, Mary, Vallotton, Nick, Vancheeswaran, Rama, Vincent, Rachel, Vincent-Smith, Lisa, Visuvanathan, Shico, Vuylsteke, Alan, Waddy, Sam, Wake, Rachel, Walden, Andrew, Welters, Ingeborg, Whitehouse, Tony, Whittaker, Paul, Whittington, Ashley, Wijesinghe, Meme, Williams, Martin, Wilson, Lawrence, Winchester, Stephen, Wiselka, Martin, Wolverson, Adam, Wootton, Daniel G, Workman, Andrew, Yates, Bryan, Young, Peter, McDonald, Sarah E., Shaw, Victoria, Ahmed, Katie A., Armstrong, Jane A., Ashworth, Milton, Asiimwe, Innocent G., Bakshi, Siddharth, Barlow, Samantha L, Booth, Laura, Brennan, Benjamin, Bullock, Katie, Carlucci, Nicola, Cass, Emily, Catterall, Benjamin W.A., Clark, Jordan J., Clarke, Emily A., Cole, Sarah, Cooper, Louise, Cox, Helen, Davis, Christopher, Dincarslan, Oslem, Doce Carracedo, Alejandra, Dunn, Chris, Dyer, Philip, Elliott, Angela, Evans, Anthony, Finch, Lorna, Fisher, Lewis W.S., Flaherty, Lisa, Foster, Terry, Garcia-Dorival, Isabel, Gunning, Philip, Hartley, Catherine, Holmes, Anthony, Jensen, Rebecca L., Jones, Christopher B., Jones, Trevor R., Khandaker, Shadia, King, Katharine, Kiy, Robyn T., Koukorava, Chrysa, Lake, Annette, Lant, Suzannah, Latawiec, Diane, Lavelle-Langham, Lara, Lefteri, Daniella, Lett, Lauren, Livoti, Lucia A, Mancini, Maria, Massey, Hannah, Maziere, Nicole, McDonald, Sarah, McEvoy, Laurence, McLauchlan, John, Metelmann, Soeren, Miah, Nahida S., Middleton, Joanna, Mitchell, Joyce, Murphy, Ellen G, Penrice-Randal, Rebekah, Pilgrim, Jack, Prince, Tessa, Reynolds, Will, Ridley, P. Matthew, Sales, Debby, Shaw, Victoria E., Shears, Rebecca K., Small, Benjamin, Subramaniam, Krishanthi S., Szemiel, Agnieska, Taggart, Aislynn, Tanianis-Hughes, Jolanta, Thomas, Jordan, Trochu, Erwan, van Tonder, Libby, Wilcock, Eve, Zhang, J. Eunice, Keating, Seán, Donegan, Cara, Spencer, Rebecca G., Donohue, Chloe, Griffiths, Fiona, Hardwick, Hayley, Oosthuyzen, Wilna, Abel, K., Adamali, H., Adeloye, D., Adeyemi, O., Adrego, R., Aguilar Jimenez, L.A., Ahmad, S., Ahmad Haider, N., Ahmed, R., Ahwireng, N., Ainsworth, M., Al-Sheklly, B., Alamoudi, A., Ali, M., Aljaroof, M., All, A.M., Allan, L., Allen, R.J., Allerton, L., Allsop, L., Almeida, P., Altmann, D., Alvarez Corral, M., Amoils, S., Anderson, D., Antoniades, C., Arbane, G., Arias, A., Armour, C., Armstrong, L., Armstrong, N., Arnold, D., Arnold, H., Ashish, A., Ashworth, A., Ashworth, M., Aslani, S., Assefa-Kebede, H., Atkin, C., Atkin, P., Aul, R., Aung, H., Austin, L., Avram, C., Ayoub, A., Babores, M., Baggott, R., Bagshaw, J., Baguley, D., Bailey, L., Baillie, J.K., Bain, S., Bakali, M., Bakau, M., Baldry, E., Baldwin, D., Baldwin, M., Ballard, C., Banerjee, A., Bang, B., Barker, R.E., Barman, L., Barratt, S., Barrett, F., Basire, D., Basu, N., Bates, M., Bates, A., Batterham, R., Baxendale, H., Bayes, H., Beadsworth, M., Beckett, P., Beggs, M., Begum, M., Beirne, P., Bell, D., Bell, R., Bennett, K., Beranova, E., Bermperi, A., Berridge, A., Berry, C., Betts, S., Bevan, E., Bhui, K., Bingham, M., Birchall, K., Bishop, L., Bisnauthsing, K., Blaikely, J., Bloss, A., Bolger, A., Bolton, C.E., Bonnington, J., Botkai, A., Bourne, C., Bourne, M., Bramham, K., Brear, L., Breen, G., Breeze, J., Briggs, A., Bright, E., Brightling, C.E., Brill, S., Brindle, K., Broad, L., Broadley, A., Brookes, C., Broome, M., Brown, A., Brown, J., Brown, J.S., Brown, M., Brown, V., Brugha, T., Brunskill, N., Buch, M., Buckley, P., Bularga, A., Bullmore, E., Burden, L., Burdett, T., Burn, D., Burns, G., Burns, A., Busby, J., Butcher, R., Butt, A., Byrne, S., Cairns, P., Calder, P.C., Calvelo, E., Carborn, H., Card, B., Carr, C., Carr, L., Carson, G., Carter, P., Casey, A., Cassar, M., Cavanagh, J., Chablani, M., Chalder, T., Chalmers, J.D., Chambers, R.C., Chan, F., Channon, K.M., Chapman, K., Charalambou, A., Chaudhuri, N., Checkley, A., Chen, J., Cheng, Y., Chetham, L., Childs, C., Chilvers, E.R., Chinoy, H., Chiribiri, A., Chong-James, K., Choudhury, G., Choudhury, N., Chowienczyk, P., Christie, C., Chrystal, M., Clark, D., Clark, C., Clarke, J., Clohisey, S., Coakley, G., Coburn, Z., Coetzee, S., Cole, J., Coleman, C., Conneh, F., Connell, D., Connolly, B., Connor, L., Cook, A., Cooper, B., Cooper, J., Cooper, S., Copeland, D., Cosier, T., Coulding, M., Coupland, C., Cox, E., Craig, T., Crisp, P., Cristiano, D., Crooks, M.G., Cross, A., Cruz, I., Cullinan, P., Cuthbertson, D., Daines, L., Dalton, M., Daly, P., Daniels, A., Dark, P., Dasgin, J., David, A., David, C., Davies, E., Davies, F., Davies, G., Davies, G.A., Davies, K., Davies, M.J., Dawson, J., Daynes, E., De Soyza, A., Deakin, B., Deans, A., Deas, C., Deery, J., Defres, S., Dell, A., Dempsey, K., Denneny, E., Dennis, J., Dewar, A., Dharmagunawardena, R., Diar-Bakerly, N., Dickens, C., Dipper, A., Diver, S., Diwanji, S.N., Dixon, M., Djukanovic, R., Dobson, H., Dobson, S.L., Docherty, A.B., Donaldson, A., Dong, T., Dormand, N., Dougherty, A., Dowling, R., Drain, S., Draxlbauer, K., Drury, K., Dulawan, P., Dunleavy, A., Dunn, S., Dupont, C., Earley, J., Easom, N., Echevarria, C., Edwards, S., Edwardson, C., El-Taweel, H., Elliott, A., Elliott, K., Ellis, Y., Elmer, A., Elneima, O., Evans, D., Evans, H., Evans, J., Evans, R., Evans, R.A., Evans, R.I., Evans, T., Evenden, C., Evison, L., Fabbri, L., Fairbairn, S., Fairman, A., Fallon, K., Faluyi, D., Favager, C., Fayzan, T., Featherstone, J., Felton, T., Finch, J., Finney, S., Finnigan, J., Finnigan, L., Fisher, H., Fletcher, S., Flockton, R., Flynn, M., Foot, H., Foote, D., Ford, A., Forton, D., Fraile, E., Francis, C., Francis, R., Francis, S., Frankel, A., Fraser, E., Free, R., French, N., Fu, X., Fuld, J., Furniss, J., Garner, L., Gautam, N., Geddes, J.R., George, J., George, P., Gibbons, M., Gill, M., Gilmour, L., Gleeson, F., Glossop, J., Glover, S., Goodman, N., Goodwin, C., Gooptu, B., Gordon, H., Gorsuch, T., Greatorex, M., Greenhaff, P.L., Greenhalf, W., Greenhalgh, A., Greening, N.J., Greenwood, J., Gregory, H., Gregory, R., Grieve, D., Griffin, D., Griffiths, L., Guerdette, A-M., Guillen Guio, B., Gummadi, M., Gupta, A., Gurram, S., Guthrie, E., Guy, Z., H Henson, H., Hadley, K., Haggar, A., Hainey, K., Hairsine, B., Haldar, P., Hall, I., Hall, L., Halling-Brown, M., Hamil, R., Hancock, A., Hancock, K., Hanley, N.A., Haq, S., Hardwick, H.E., Hardy, E., Hardy, T., Hargadon, B., Harrington, K., Harris, E., Harris, V.C., Harrison, E.M., Harrison, P., Hart, N., Harvey, A., Harvey, M., Harvie, M., Haslam, L., Havinden-Williams, M., Hawkes, J., Hawkings, N., Haworth, J., Hayday, A., Haynes, M., Hazeldine, J., Hazelton, T., Heaney, L.G., Heeley, C., Heeney, J.L., Heightman, M., Heller, S., Henderson, M., Hesselden, L., Hewitt, M., Highett, V., Hillman, T., Hiwot, T., Ho, L.P., Hoare, A., Hoare, M., Hockridge, J., Hogarth, P., Holbourn, A., Holden, S., Holdsworth, L., Holgate, D., Holland, M., Holloway, L., Holmes, K., Holmes, M., Holroyd-Hind, B., Holt, L., Hormis, A., Horsley, A., Hosseini, A., Hotopf, M., Houchen-Wolloff, L., Howard, K., Howard, L.S., Howell, A., Hufton, E., Hughes, A.D., Hughes, J., Hughes, R., Humphries, A., Huneke, N., Hurditch, E., Hurst, J., Husain, M., Hussell, T., Hutchinson, J., Ibrahim, W., Ilyas, F., Ingham, J., Ingram, L., Ionita, D., Isaacs, K., Ismail, K., Jackson, T., Jacob, J., James, W.Y., Jang, W., Jarman, C., Jarrold, I., Jarvis, H., Jastrub, R., Jayaraman, B., Jenkins, R.G., Jezzard, P., Jiwa, K., Johnson, C., Johnson, S., Johnston, D., Jolley, C.J., Jones, D., Jones, G., Jones, H., Jones, I., Jones, L., Jones, M.G., Jones, S., Jose, S., Kabir, T., Kaltsakas, G., Kamwa, V., Kanellakis, N., Kaprowska, s., Kausar, Z., Keenan, N., Kelly, S., Kemp, G., Kerr, S., Kerslake, H., Key, A.L., Khan, F., Khunti, K., Kilroy, S., King, B., King, C., Kingham, L., Kirk, J., Kitterick, P., Klenerman, P., Knibbs, L., Knight, S., Knighton, A., Kon, O., Kon, S., Kon, S.S., Koprowska, S., Korszun, A., Koychev, I., Kurasz, C., Kurupati, P., Laing, C., Lamlum, H., Landers, G., Langenberg, C., Lasserson, D., Lavelle-Langham, L., Lawrie, A., Lawson, C., Layton, A., Lea, A., Leavy, O.C., Lee, D., Lee, J-H., Lee, E., Leitch, K., Lenagh, R., Lewis, D., Lewis, J., Lewis, K.E., Lewis, V., Lewis-Burke, N., Li, X., Light, T., Lightstone, L., Lilaonitkul, W., Lim, L., Linford, S., Lingford-Hughes, A., Lipman, M., Liyanage, K., Lloyd, A., Logan, S., Lomas, D., Lone, N.I., Loosley, R., Lord, J.M., Lota, H., Lovegrove, W., Lucey, A., Lukaschuk, E., Lye, A., Lynch, C., MacDonald, S., MacGowan, G., Macharia, I., Mackie, J., Macliver, L., Madathil, S., Madzamba, G., Magee, N., Magtoto, M.M., Mairs, N., Majeed, N., Major, E., Malein, F., Malim, M., Mallison, G., Man, W.D.-C., Mandal, S., Mangion, K., Manisty, C., Manley, R., March, K., Marciniak, S., Marino, P., Mariveles, M., Marks, M., Marouzet, E., Marsh, S., Marshall, B., Marshall, M., Martin, J., Martineau, A., Martinez, L.M., Maskell, N., Matila, D., Matimba-Mupaya, W., Matthews, L., Mbuyisa, A., McAdoo, S., McAllister-Williams, H., McArdle, A., McArdle, P., McAulay, D., McCann, G.P., drury, H.J.C., McCormick, J., McCormick, W., McCourt, P., McGarvey, L., McGee, C., Mcgee, K., McGinness, J., McGlynn, K., McGovern, A., McGuinness, H., McInnes, I.B., McIntosh, J., McIvor, E., McIvor, K., McLeavey, L., McMahon, A., McMahon, M.J., McMorrow, L., Mcnally, T., McNarry, M., McNeill, J., McQueen, A., McShane, H., Mears, C., Megson, C., Megson, S., Mehta, P., Meiring, J., Melling, L., Mencias, M., Menzies, D., Merida Morillas, M., Michael, A., Miller, C., Milligan, L., Mills, C., Mills, N.L., Milner, L., Misra, S., Mitchell, J., Mohamed, A., Mohamed, N., Mohammed, S., Molyneaux, P.L., Monteiro, W., Moriera, S., Morley, A., Morrison, L., Morriss, R., Morrow, A., Moss, A.J., Moss, P., Motohashi, K., Msimanga, N., Mukaetova-Ladinska, E., Munawar, U., Murira, J., Nanda, U., Nassa, H., Nasseri, M., Neal, A., Needham, R., Neill, P., Neubauer, S., Newby, D.E., Newell, H., Newman, T., Newton-Cox, A., Nicholson, T., Nicoll, D., Nikolaidis, A., Nolan, C.M., Noonan, M.J., Norman, C., Novotny, P., Nunag, J., Nwafor, L., Nwanguma, U., Nyaboko, J., O'Brien, C., O'Donnell, K., O'Regan, D., O'Brien, L., Odell, N., Ogg, G., Olaosebikan, O., Oliver, C., Omar, Z., Openshaw, P.J.M., Orriss-Dib, L., Osborne, L., Osbourne, R., Ostermann, M., Overton, C., Owen, J., Oxton, J., Pack, J., Pacpaco, E., Paddick, S., Painter, S., Pakzad, A., Palmer, S., Papineni, P., Paques, K., Paradowski, K., Pareek, M., Parekh, D., Parfrey, H., Pariante, C., Parker, S., Parkes, M., Parmar, J., Patale, S., Patel, B., Patel, M., Patel, S., Pattenadk, D., Pavlides, M., Payne, S., Pearce, L., Pearl, J.E., Peckham, D., Pendlebury, J., Peng, Y., Pennington, C., Peralta, I., Perkins, E., Peterkin, Z., Peto, T., Petousi, N., Petrie, J., Pfeffer, P., Phipps, J., Pimm, J., Piper Hanley, K., Pius, R., Plant, H., Plein, S., Plekhanova, T., Plowright, M., Poinasamy, K., Polgar, O., Poll, L., Porter, J.C., Porter, J., Portukhay, S., Powell, N., Prabhu, A., Pratt, J., Price, A., Price, C., Price, D., Price, L., Prickett, A., Propescu, J., Prosper, S., Pugmire, S., Quaid, S., Quigley, J., Quint, J., Qureshi, H., Qureshi, I.N., Radhakrishnan, K., Rahman, N.M., Ralser, M., Raman, B., Ramos, A., Ramos, H., Rangeley, J., Rangelov, B., Ratcliffe, L., Ravencroft, P., Reddington, A., Reddy, R., Redfearn, H., Redwood, D., Reed, A., Rees, M., Rees, T., Regan, K., Reynolds, W., Ribeiro, C., Richards, A., Richardson, E., Richardson, M., Rivera-Ortega, P., Roberts, K., Robertson, E., Robinson, E., Robinson, L., Roche, L., Roddis, C., Rodger, J., Ross, A., Ross, G., Rossdale, J., Rostron, A., Rowe, A., Rowland, A., Rowland, J., Rowland, M.J., Rowland-Jones, S.L., Roy, K., Roy, M., Rudan, I., Russell, R., Russell, E., Saalmink, G., Sabit, R., Sage, E.K., Samakomva, T., Samani, N., Sampson, C., Samuel, K., Samuel, R., Sanderson, A., Sapey, E., Saralaya, D., Sargant, J., Sarginson, C., Sass, T., Sattar, N., Saunders, K., Saunders, R.M., Saunders, P., Saunders, L.C., Savill, H., Saxon, W., Sayer, A., Schronce, J., Schwaeble, W., Scott, J.T., Scott, K., Selby, N., Semple, M.G., Sereno, M., Sewell, T.A., Shah, A., Shah, K., Shah, P., Shankar-Hari, M., Sharma, M., Sharpe, C., Sharpe, M., Shashaa, S., Shaw, A., Shaw, K., Shaw, V., Sheikh, A., Shelton, S., Shenton, L., Shevket, K., Shikotra, A., Short, J., Siddique, S., Siddiqui, S., Sidebottom, J., Sigfrid, L., Simons, G., Simpson, J., Simpson, N., Singapuri, A., Singh, C., Singh, S., Singh, S.J., Sissons, D., Skeemer, J., Slack, K., Smith, A., Smith, D., Smith, S., Smith, J., Smith, L., Soares, M., Solano, T.S., Solly, R., Solstice, A.R., Soulsby, T., Southern, D., Sowter, D., Spears, M., Spencer, L.G., Speranza, F., Stadon, L., Stanel, S., Steele, N., Steiner, M., Stensel, D., Stephens, G., Stephenson, L., Stern, M., Stewart, I., Stimpson, R., Stockdale, S., Stockley, J., Stoker, W., Stone, R., Storrar, W., Storrie, A., Storton, K., Stringer, E., Strong-Sheldrake, S., Stroud, N., Subbe, C., Sudlow, C.L., Suleiman, Z., Summers, C., Summersgill, C., Sutherland, D., Sykes, D.L., Sykes, R., Talbot, N., Tan, A.L., Tarusan, L., Tavoukjian, V., Taylor, A., Taylor, C., Taylor, J., Te, A., Tedd, H., Tee, C.J., Teixeira, J., Tench, H., Terry, S., Thackray-Nocera, S., Thaivalappil, F., Thamu, B., Thickett, D., Thomas, C., Thomas, D.C., Thomas, S., Thomas, A.K., Thomas-Woods, T., Thompson, T., Thompson, A.A.R., Thornton, T., Thorpe, M., Thwaites, R.S., Tilley, J., Tinker, N., Tiongson, G.F., Tobin, M., Tomlinson, J., Tong, C., Toshner, M., Touyz, R., Tripp, K.A., Tunnicliffe, E., Turnbull, A., Turner, E., Turner, S., Turner, V., Turner, K., Turney, S., Turtle, L., Turton, H., Ugoji, J., Ugwuoke, R., Upthegrove, R., Valabhji, J., Ventura, M., Vere, J., Vickers, C., Vinson, B., Wade, E., Wade, P., Wain, L.V., Wainwright, T., Wajero, L.O., Walder, S., Walker, S., Wall, E., Wallis, T., Walmsley, S., Walsh, J.A., Walsh, S., Warburton, L., Ward, T.J.C., Warwick, K., Wassall, H., Waterson, S., Watson, E., Watson, L., Watson, J., Weir McCall, J., Welch, C., Welch, H., Welsh, B., Wessely, S., West, S., Weston, H., Wheeler, H., White, S., Whitehead, V., Whitney, J., Whittaker, S., Whittam, B., Whitworth, V., Wight, A., Wild, J., Wilkins, M., Wilkinson, D., Williams, B., Williams, N., Williams, J., Williams-Howard, S.A., Willicombe, M., Willis, G., Willoughby, J., Wilson, A., Wilson, D., Wilson, I., Window, N., Witham, M., Wolf-Roberts, R., Wood, C., Woodhead, F., Woods, J., Wootton, D.G., Wormleighton, J., Worsley, J., Wraith, D., Wrey Brown, C., Wright, C., Wright, L., Wright, S., Wyles, J., Wynter, I., Xu, M., Yasmin, N., Yasmin, S., Yates, T., Yip, K.P., Young, B., Young, S., Young, A., Yousuf, A.J., Zawia, A., Zeidan, L., Zhao, B., Zheng, B., Zongo, O., Liew, Felicity, Talwar, Shubha, Cross, Andy, Willett, Brian J., Scott, Sam, Logan, Nicola, Siggins, Matthew K., Swieboda, Dawid, Sidhu, Jasmin K., Efstathiou, Claudia, Davis, Chris, Mohamed, Noura, Nunag, Jose, King, Clara, Rowland-Jones, Sarah L., Chalmers, James D., Ho, Ling-Pei, Horsley, Alexander, Raman, Betty, Poinasamy, Krisnah, Marks, Michael, Kon, Onn Min, Howard, Luke, Wootton, Daniel G., Dunachie, Susanna, Quint, Jennifer K., Evans, Rachael A., Wain, Louise V., Fontanella, Sara, de Silva, Thushan I., Ho, Antonia, Harrison, Ewen, Brightling, Christopher, and Turtle, Lance

Published

2023

3. Development of a cost-effective ovine antibody-based therapy against SARS-CoV-2 infection and contribution of antibodies specific to the spike subunit proteins

Author

Findlay-Wilson, Stephen, Easterbrook, Linda, Smith, Sandra, Pope, Neville, Humphries, Gareth, Schuhmann, Holger, Ngabo, Didier, Rayner, Emma, Otter, Ashley David, Coleman, Tom, Hicks, Bethany, Graham, Victoria Anne, Halkerston, Rachel, Apostolakis, Kostis, Taylor, Stephen, Fotheringham, Susan, Horton, Amanda, Tree, Julia Anne, Wand, Matthew, Hewson, Roger, and Dowall, Stuart David

Published

2022

4. Changes in chemsex and sexual behaviour over time, among a cohort of MSM in London and Brighton: Findings from the AURAH2 study

Author

Sewell, Janey, Cambiano, Valentina, Speakman, Andrew, Lampe, Fiona C., Phillips, Andrew, Stuart, David, Gilson, Richard, Asboe, David, Nwokolo, Nneka, Clarke, Amanda, and Rodger, Alison J.

Published

2019

5. Poly drug use, chemsex drug use, and associations with sexual risk behaviour in HIV-negative men who have sex with men attending sexual health clinics

Author

Sewell, Janey, Miltz, Ada, Lampe, Fiona C., Cambiano, Valentina, Speakman, Andrew, Phillips, Andrew N., Stuart, David, Gilson, Richard, Asboe, David, Nwokolo, Nneka, Clarke, Amanda, Collins, Simon, Hart, Graham, Elford, Jonathan, and Rodger, Alison J.

Published

2017

6. Efficient production of foot-and-mouth disease virus empty capsids in insect cells following down regulation of 3C protease activity

Author

Porta, Claudine, Xu, Xiaodong, Loureiro, Silvia, Paramasivam, Saravanan, Ren, Junyuan, Al-Khalil, Tara, Burman, Alison, Jackson, Terry, Belsham, Graham J., Curry, Stephen, Lomonossoff, George P., Parida, Satya, Paton, David, Li, Yanmin, Wilsden, Ginette, Ferris, Nigel, Owens, Ray, Kotecha, Abhay, Fry, Elizabeth, Stuart, David I., Charleston, Bryan, and Jones, Ian M.

Published

2013

7. Structure and functionality in flavivirus NS-proteins: Perspectives for drug design

Author

Bollati, Michela, Alvarez, Karin, Assenberg, René, Baronti, Cécile, Canard, Bruno, Cook, Shelley, Coutard, Bruno, Decroly, Etienne, de Lamballerie, Xavier, Gould, Ernest A., Grard, Gilda, Grimes, Jonathan M., Hilgenfeld, Rolf, Jansson, Anna M., Malet, Hélène, Mancini, Erika J., Mastrangelo, Eloise, Mattevi, Andrea, Milani, Mario, Moureau, Grégory, Neyts, Johan, Owens, Raymond J., Ren, Jingshan, Selisko, Barbara, Speroni, Silvia, Steuber, Holger, Stuart, David I., Unge, Torsten, and Bolognesi, Martino

Published

2010

8. Some lessons from the systematic production and structural analysis of soluble αβ T-cell receptors

Author

van Boxel, Gijs I., Stewart-Jones, Guillaume, Holmes, Samantha, Sainsbury, Sarah, Shepherd, Dawn, Gillespie, G.M.A., Harlos, Karl, Stuart, David I., Owens, Ray, and Jones, E. Yvonne

Published

2009

9. Utility of recombinant integrin αvβ6 as a capture reagent in immunoassays for the diagnosis of foot-and-mouth disease

Author

Ferris, Nigel P., Abrescia, Nicola G.A., Stuart, David I., Jackson, Terry, Burman, Alison, King, Donald P., and Paton, David J.

Published

2005

10. The crystal structure of plasma gelsolin: implications for actin severing, capping and nucleation

Author

Burtnick, Leslie D., Koepf, Edward K., Grimes, Jonathan, Jones, E. Yvonne, Stuart, David I., McLaughlin, Paul J., and Robinson, Robert C.

Subjects

Crystallography -- Usage, Actin -- Research, Proteins -- Research, Biological sciences

Abstract

Crystallography was employed to determine the crystal structure of plasma gelsolin. Six structurally-related domains were observed. Ca2+ binding was proposed for releasing the connections that bind gelsolin's N- and C-terminal halves and enable each half to independently bind actin. Domain shifts are also proposed for modeling the function of gelsolin to to cap, sever and nucleate F-actin filaments.

Published

1997

11. The structure of a Ca2+ -binding epidermal growth factor-like domain: its role in protein-protein interactions

Author

Rao, Zihe, Handford, Penny, Mayhew, Mark, Knott, Vroni, Brownlee, George G., and Stuart, David

Subjects

Calcium-binding proteins -- Research, Proteins -- Structure, Biological sciences

Abstract

The crystal structure of Ca2+ binding to epidermal growth factor-like (EGF-like) domains was determined at high resolution using human clotting factor IX complexed with Ca2+. Seven calcium ligands were identified indicating that Ca2+ binds to EGF-like domains, stabilizes the protein and mediates protein-protein interactions. EGF-like domains are common in many extracellular proteins.

Published

1995

12. Safety climate

Author

Coyle, Ian R., Sleeman, Stuart David, and Adams, Neil

Subjects

Australia -- Health aspects, Occupational health and safety -- Research, Office workers -- Beliefs, opinions and attitudes, Transportation industry

Abstract

A report on safety climate factors in two clerical and service organizations in Australia shows that both the organizations lack stable safety climate factors. Employees' responses to questionnaires reveal that organizations have different perceptions of occupational health and safety. The current safety climate factors of an organization must be taken into consideration in order to design effective occupational health and safety programs.

Published

1995

13. Tick histamine-binding proteins: lipocalins with a second binding cavity

Author

Paesen, Guido C., Adams, Peter L., Nuttall, Patricia A., and Stuart, David L.

Published

2000

14. Lipofectin increases the specific activity of cypovirus particles for cultured insect cells

Author

Hill, Claire L., Booth, Timothy F., Stuart, David I., and Mertens, Peter P.C.

Published

1999

15. HEPT: From an investigation of lithiation of nucleosides towards a rational design of non-nucleoside reverse transcriptase inhibitors of HIV-1

Author

Tanaka, Hiromichi, Hayakawa, Hiroyuki, Haraguchi, Kazuhiro, Miyasaka, Tadashi, Walker, Richard T., De Clercq, E., Baba, Masanori, Stammers, David K., and Stuart, David I.

Published

1999

16. Potent antiviral agents fail to elicit genetically-stable resistance mutations in either enterovirus 71 or Coxsackievirus A16

Author

Kelly, James T., De Colibus, Luigi, Elliott, Lauren, Fry, Elizabeth E., Stuart, David I., Rowlands, David J., and Stonehouse, Nicola J.

Published

2015

17. Atomic snapshots of an RNA packaging motor reveal conformational changes linking ATP hydrolysis to RNA translocation

Author

Kainov, Denis E., Mancini, Erika J., Tuma, Roman, Stuart, David I., Grimes, Jonathan M, and Bamford, Dennis H

Subjects

Hydrolysis -- Research, Crystallography -- Research, RNA -- Research, Biological sciences

Abstract

The crystallographic structures of ATPase P4 are examined along the catalytic pathway, including apo, substrate analog bound, and product bound. These structures reveal large movements of the putative RNA binding loop.

Published

2004

18. A plate-based high-throughput assay for virus stability and vaccine formulation

Author

Walter, Thomas S., Ren, Jingshan, Tuthill, Tobias J., Rowlands, David J., Stuart, David I., and Fry, Elizabeth E.

Published

2012

19. A comparison of fluorescent DNA binding dyes for flow cytometric analysis of sporulating Saccharomyces cerevisiae

Author

Raithatha, Sheetal A. and Stuart, David T.

Published

2009

20. Disruption of α-mannosidase processing induces non-canonical hybrid-type glycosylation

Author

Crispin, Max, Aricescu, A. Radu, Chang, Veronica T., Jones, E. Yvonne, Stuart, David I., Dwek, Raymond A., Davis, Simon J., and Harvey, David J.

Published

2007

21. The highly ordered double-stranded RNA genome of bluetongue virus revealed by crystallography

Author

Gouet, Patrice, Diprose, Jonathan M., Grimes, Jonathan M., Malby, Robyn, Burroughs, J. Nicholas, Zientara, Stephan, Stuart, David I., and Mertens, Peter P. C.

Subjects

RNA -- Physiological aspects, Genomes -- Research, Reoviruses -- Research, X-ray crystallography -- Usage, Diffraction patterns -- Analysis, Biological sciences

Abstract

A study was conducted to examine the structure of the bluetongue virus core serotype 10. Using X-Ray crystallography, it was revealed that the blue tongue virus' core contains a highly-ordered double-stranded RNA genome. Measurements provided by power diffraction rings showed that the double-stranded RNA maintains a 30 A separation between strands. The study also found that genome segments' local ordering occur during genetic transcription.

Published

1999

22. Structure of a Pestivirus Envelope Glycoprotein E2 Clarifies Its Role in Cell Entry

Author

El Omari, Kamel, Iourin, Oleg, Harlos, Karl, Grimes, Jonathan M., and Stuart, David I.

Subjects

PESTIVIRUS diseases, GLYCOPROTEINS, FLAVIVIRUSES, ALPHAVIRUSES, CRYSTAL structure, PH effect

Abstract

Summary: Enveloped viruses have developed various adroit mechanisms to invade their host cells. This process requires one or more viral envelope glycoprotein to achieve cell attachment and membrane fusion. Members of the Flaviviridae such as flaviviruses possess only one envelope glycoprotein, E, whereas pestiviruses and hepacivirus encode two glycoproteins, E1 and E2. Although E2 is involved in cell attachment, it has been unclear which protein is responsible for membrane fusion. We report the crystal structures of the homodimeric glycoprotein E2 from the pestivirus bovine viral diarrhea virus 1 (BVDV1) at both neutral and low pH. Unexpectedly, BVDV1 E2 does not have a class II fusion protein fold, and at low pH the N-terminal domain is disordered, similarly to the intermediate postfusion state of E2 from sindbis virus, an alphavirus. Our results suggest that the pestivirus and possibly the hepacivirus fusion machinery are unlike any previously observed. [Copyright &y& Elsevier]

Published

2013

23. Geodesics and the Einstein nonlinear wave system

Author

Stuart, David M.A.

Subjects

*GEODESICS, *EINSTEIN field equations, *NONLINEAR theories, *WAVE equation

Abstract

The system under consideration is Einstein''s equation Rμν(g)−gμνR(g)/2=8πGTμν for a pseudo-Riemannian metric g coupled to a semi-linear wave equation for a complex function φ. Assume that this wave equation on Minkowski space admits a stable solitary wave of the type known as nontopological solitons. The system is studied in the scaling limit in which the solitons have small size ϵ and amplitude δ with δ⩽δ0ϵ7/4. It is proved that, for ϵ sufficiently small, given a solution of the vacuum Einstein equation, i.e., a Ricci flat pseudo-Riemannian metric γ, there exists a finite time interval, independent of ϵ,δ, on which there is a solution of the full system (g,φ) with (g−γ) small and φ close to a nontopological soliton centred on a time-like geodesic (in appropriate Sobolev norms). [Copyright &y& Elsevier]

Published

2004

24. “4D Biology for health and disease” workshop report

Author

Abrahams, Jan-Pieter, Apweiler, Rolf, Balling, Rudi, Bertero, Michela G., Bujnicki, Janusz M., Chayen, Naomi E., Chène, Patrick, Corthals, Gary L., Dyląg, Tomasz, Förster, Friedrich, Heck, Albert J.R., Henderson, Peter J.F., Herwig, Ralf, Jehenson, Philippe, Kokalj, Sasa Jenko, Laue, Ernest, Legrain, Pierre, Martens, Lennart, Migliorini, Cristiano, Musacchio, Andrea, Podobnik, Marjetka, Schertler, Gebhard F.X., Schreiber, Gideon, Sixma, Titia K., Smit, August B., Stuart, David, Svergun, Dmitri I., and Taussig, Michael J.

Published

2011

25. Saccharomyces cerevisiae Δ9-desaturase Ole1 forms a supercomplex with Slc1 and Dga1.

Author

Greenwood, Brianna L., Zijun Luo, Ahmed, Tareq, Huang, Daniel, and Stuart, David T.

Subjects

*ACYLTRANSFERASES, *SACCHAROMYCES cerevisiae, *AMINO acid residues, *MEMBRANE lipids, *CELL membranes, *PROTEIN-protein interactions

Abstract

Biosynthesis of the various lipid species that compose cellular membranes and lipid droplets depends on the activity of multiple enzymes functioning in coordinated pathways. The flux of intermediates through lipid biosynthetic pathways is regulated to respond to nutritional and environmental demands placed on the cell necessitating that there be flexibility in pathway activity and organization. This flexibility can in part be achieved through the organization of enzymes into metabolon supercomplexes. However, the composition and organization of such supercomplexes remain unclear. Here, we identified protein-protein interactions between acyltransferases Sct1, Gpt2, Slc1, Dga1, and the Δ9 acyl-CoA desaturase Ole1 in Saccharomyces cerevisiae. We further determined that a subset of these acyltransferases interact with each other independent of Ole1. We show that truncated versions of Dga1 lacking the carboxyl-terminal 20 amino acid residues are nonfunctional and unable to bind Ole1. Furthermore, charged-to-alanine scanning mutagenesis revealed that a cluster of charged residues near the carboxyl terminus was required for the interaction with Ole1. Mutation of these charged residues disrupted the interaction between Dga1 and Ole1 but allowed Dga1 to retain catalytic activity and to induce lipid droplet formation. These data support the formation of a complex of acyltransferases involved in lipid biosynthesis that interacts with Ole1, the sole acyl-CoA desaturase in S. cerevisiae, that can channel unsaturated acyl chains toward phospholipid or triacylglycerol synthesis. This desaturasome complex may provide the architecture that allows for the necessary flux of de novo-synthesized unsaturated acyl-CoA to phospholipid or triacylglycerol synthesis as demanded by cellular requirements. [ABSTRACT FROM AUTHOR]

Published

2023

26. Presence of type 1 choledochal cyst in donor graft and liver transplantation

Author

Stuart, David and Ranjan, Dinesh

Published

2005

27. Somatic embryogenesis from cell cultures of medicago sativa L. II. the interaction of amino acids with ammonium

Author

Stuart, David A. and Strickland, Steven G.

Published

1984

28. Somatic embryogenesis from cell cultures of medicago sativa L.I. the role of amino acid additions to the regeneration medium

Author

Stuart, David A. and Strickland, Steven G.

Published

1984

29. Crystallization of human tumour necrosis factor

Author

Walker, Nigel, Marcinowski, Stefan, Hillen, Heinz, Mächtle, Walter, Jones, Yvonne, and Stuart, David

Published

1990

30. Production and crystallization of MHC class I B allele single peptide complexes

Author

Reid, Scott W., Smith, Kathrine J., Jakobsen, Bent K., O'Callaghan, Chris A., Reyburn, Hugh, Harlos, Karl, Stuart, David I., McMichael, Andrew J., Bell, John I., and Jones, E.Yvonne

Published

1996

31. An economic analysis of humans and teleoperators for space construction

Author

Stuart, David G.

Published

1986

32. Concerted deletions eliminate a neutralizing supersite in SARS-CoV-2 BA.2.87.1 spike.

Author

Duyvesteyn, Helen M.E., Dijokaite-Guraliuc, Aiste, Liu, Chang, Supasa, Piyada, Kronsteiner, Barbara, Jeffery, Katie, Stafford, Lizzie, Klenerman, Paul, Dunachie, Susanna J., Mongkolsapaya, Juthathip, Fry, Elizabeth E., Ren, Jingshan, Stuart, David I., and Screaton, Gavin R.

Subjects

*SARS-CoV-2, *PROTEIN structure, *VACCINATION, *GLYCANS

Abstract

BA.2.87.1 represents a major shift in the BA.2 lineage of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) and is unusual in having two lengthy deletions of polypeptide in the spike (S) protein, one of which removes a beta-strand. Here we investigate its neutralization by a variety of sera from infected and vaccinated individuals and determine its spike (S) ectodomain structure. The BA.2.87.1 receptor binding domain (RBD) is structurally conserved and the RBDs are tightly packed in an "all-down" conformation with a small rotation relative to the trimer axis as compared to the closest previously observed conformation. The N-terminal domain (NTD) maintains a remarkably similar structure overall; however, the rearrangements resulting from the deletions essentially destroy the so-called supersite epitope and eliminate one glycan site, while a mutation creates an additional glycan site, effectively shielding another NTD epitope. BA.2.87.1 is relatively easily neutralized but acquisition of additional mutations in the RBD could increase antibody escape allowing it to become a dominant sub-lineage. [Display omitted] • The BA.2.87.1 RBD structure is conserved • Despite large deletions, the BA.2.87.1 NTD structure is similar overall • The NTD supersite epitope is destroyed and modifications to glycans alter others • BA.2.87.1 is relatively easily neutralized by sera from infected and vaccinated donors BA.2.87.1 is a SARS-CoV-2 variant with unusually large deletions in the surface spike N-terminal domain. Duyvesteyn et al. investigated its structure and found the main antibody binding "supersite" was destroyed and variations in glycan sites altered other epitopes. Despite these changes, BA.2.87.1 was relatively easily neutralized by sera from infected and vaccinated individuals. [ABSTRACT FROM AUTHOR]

Published

2024

33. Insights into the Evolution of a Complex Virus from the Crystal Structure of Vaccinia Virus D13

Author

Bahar, Mohammad W., Graham, Stephen C., Stuart, David I., and Grimes, Jonathan M.

Subjects

*POXVIRUSES, *VIRAL vaccines, *BIOLOGICAL evolution, *MOLECULAR structure, *EMBRYOLOGY, *PROTEINS

Abstract

Summary: The morphogenesis of poxviruses such as vaccinia virus (VACV) sees the virion shape mature from spherical to brick-shaped. Trimeric capsomers of the VACV D13 protein form a transitory, stabilizing lattice on the surface of the initial spherical immature virus particle. The crystal structure of D13 reveals that this major scaffolding protein comprises a double β barrel “jelly-roll” subunit arranged as pseudo-hexagonal trimers. These structural features are characteristic of the major capsid proteins of a lineage of large icosahedral double-stranded DNA viruses including human adenovirus and the bacteriophages PRD1 and PM2. Structure-based phylogenetic analysis confirms that VACV belongs to this lineage, suggesting that (analogously to higher organism embryogenesis) early poxvirus morphogenesis reflects their evolution from a lineage of viruses sharing a common icosahedral ancestor. [ABSTRACT FROM AUTHOR]

Published

2011

34. What does structure tell us about virus evolution?

Author

Bamford, Dennis H, Grimes, Jonathan M, and Stuart, David I

Subjects

*VIRUSES, *ORGANISMS, *BIOLOGY, *GENETIC vectors, *MICROORGANISMS, *MOBILE genetic elements

Abstract

Viruses are the most abundant life form and infect practically all organisms. Consequently, these obligate parasites are a major cause of human suffering and economic loss. The organization and origins of this enormous virosphere are profound open questions in biology. It has generally been considered that viruses infecting evolutionally widely separated organisms (e.g. bacteria and humans) are also distinct. However, recent research contradicts this picture. Structural analyses of virion architecture and coat protein topology have revealed unexpected similarities, not visible in sequence comparisons, suggesting a common origin for viruses that infect hosts residing in different domains of life (bacteria, archaea and eukarya). [Copyright &y& Elsevier]

Published

2005

35. Structural comparison of typical and atypical E2 pestivirus glycoproteins.

Author

Aitkenhead, Hazel, Riedel, Christiane, Cowieson, Nathan, Rümenapf, Hans Tillmann, Stuart, David I., and El Omari, Kamel

Subjects

*GLYCOPROTEINS, *RATTUS norvegicus, *MEMBRANE glycoproteins, *VETERINARY virology, *CRYSTAL structure

Abstract

Pestiviruses, within the family Flaviviridae , are economically important viruses of livestock. In recent years, new pestiviruses have been reported in domestic animals and non-cloven-hoofed animals. Among them, atypical porcine pestivirus (APPV) and Norway rat pestivirus (NRPV) have relatively little sequence conservation in their surface glycoprotein E2. Despite E2 being the main target for neutralizing antibodies and necessary for cell attachment and viral fusion, the mechanism of viral entry remains elusive. To gain further insights into the pestivirus E2 mechanism of action and to assess its diversity within the genus, we report X-ray structures of the pestivirus E2 proteins from APPV and NRPV. Despite the highly divergent structures, both are able to dimerize through their C-terminal domain and contain a solvent-exposed β-hairpin reported to be involved in host receptor binding. Functional analysis of this β-hairpin in the context of BVDV revealed its ability to rescue viral infectivity. [Display omitted] • The X-ray crystal structures of APPV and NRPV E2 glycoproteins were determined • APPV and NRPV E2 form a dimer in solution Aitkenhead et al. report the X-ray crystal structures of pestivirus E2 surface glycoproteins from atypical porcine pestivirus and Norway rat pestivirus. These glycoproteins serve as primary targets for neutralizing antibodies and play crucial roles in cell attachment and viral fusion. [ABSTRACT FROM AUTHOR]

Published

2024

36. The role of the light chain in the structure and binding activity of two cattle antibodies that neutralize bovine respiratory syncytial virus.

Author

Ren, Jingshan, Nettleship, Joanne E., Harris, Gemma, Mwangi, William, Rhaman, Nahid, Grant, Clare, Kotecha, Abhay, Fry, Elizabeth, Charleston, Bryan, Stuart, David I., Hammond, John, and Owens, Raymond J.

Subjects

*RESPIRATORY syncytial virus, *CATTLE, *IMMUNOGLOBULINS, *IMMUNE recognition, *CARRIER proteins

Abstract

• The Fab structures of two cattle antibodies (B4 and B13) that neutralise bRSV have been solved. • The light chain plays a critical role in the folding and positioning of CDR H3 of the heavy chains. • The H3 loop plays a dominant role in antigen-binding. Cattle antibodies have unusually long CDR3 loops in their heavy chains (HCs), and limited light chain (LC) diversity, raising the question of whether these mask the effect of LC variation on antigen recognition. We have investigated the role of the LC in the structure and activity of two neutralizing cattle antibodies (B4 and B13) that bind the F protein of bovine respiratory syncytial virus (bRSV). Recombinant Fab fragments of B4 and B13 bound bRSV infected cells and showed similar affinities for purified bRSV F protein. Exchanging the LCs between the Fab fragments produced hybrid Fabs: B13* (B13 HC/B4 LC) and B4* (B4 HC/B13 LC). The affinity of B13* to the F protein was found to be two-fold lower than B13 whilst the binding affinity of B4* was reduced at least a hundred-fold compared to B4 such that it no longer bound to bRSV infected cells. Comparison of the structures of B4 and B13 with their LC exchanged counterparts B4* and B13* showed that paratope of the HC variable domain (VH) of B4 was disrupted on pairing with the B13 LC, consistent with the loss of binding activity. By contrast, B13 H3 adopts a similar conformation when paired with either B13 or B4 LCs. These observations confirm the expected key role of the extended H3 loop in antigen-binding by cattle antibodies but also show that the quaternary LC/HC subunit interaction can be crucial for its presentation and thus the LC variable domain (VL) is also important for antigen recognition. [ABSTRACT FROM AUTHOR]

Published

2019

37. The Structure of HIV-1 Rev Filaments Suggests a Bilateral Model for Rev-RRE Assembly.

Author

DiMattia, Michael A., Watts, Norman R., Cheng, Naiqian, Huang, Rick, Heymann, J. Bernard, Grimes, Jonathan M., Wingfield, Paul T., Stuart, David I., and Steven, Alasdair C.

Subjects

*HIV, *VIRAL proteins, *RNA, *PROTEIN structure, *OLIGOMERIZATION

Abstract

Summary HIV-1 Rev protein mediates the nuclear export of viral RNA genomes. To do so, Rev oligomerizes cooperatively onto an RNA motif, the Rev response element (RRE), forming a complex that engages with the host nuclear export machinery. To better understand Rev oligomerization, we determined four crystal structures of Rev N-terminal domain dimers, which show that they can pivot about their dyad axis, giving crossing angles of 90° to 140°. In parallel, we performed cryoelectron microscopy of helical Rev filaments. Filaments vary from 11 to 15 nm in width, reflecting variations in dimer crossing angle. These structures contain additional density, indicating that C-terminal domains become partially ordered in the context of filaments. This conformational variability may be exploited in the assembly of RRE/Rev complexes. Our data also revealed a third interface between Revs, which offers an explanation for how the arrangement of Rev subunits adapts to the “A”-shaped architecture of the RRE in export-active complexes. [ABSTRACT FROM AUTHOR]

Published

2016

38. Plate Tectonics of Virus Shell Assembly and Reorganization in Phage Φ8, a Distant Relative of Mammalian Reoviruses.

Author

El?Omari, Kamel, Sutton, Geoff, Ravantti, Janne?J., Zhang, Hanwen, Walter, Thomas?S., Grimes, Jonathan?M., Bamford, Dennis?H., Stuart, David?I., and Mancini, Erika?J.

Subjects

*REOVIRUSES, *VIRAL genomes, *DOUBLE-stranded RNA, *MOLECULAR structure of viral capsids, *VIRAL proteins, *PROTEIN conformation

Abstract

Summary: The hallmark of a virus is its capsid, which harbors the viral genome and is formed from protein subunits, which assemble following precise geometric rules. dsRNA viruses use an unusual protein multiplicity (120 copies) to form their closed capsids. We have determined the atomic structure of the capsid protein (P1) from the dsRNA cystovirus Φ8. In the crystal P1 forms pentamers, very similar in shape to facets of empty procapsids, suggesting an unexpected assembly pathway that proceeds via a pentameric intermediate. Unlike the elongated proteins used by dsRNA mammalian reoviruses, P1 has a compact trapezoid-like shape and a distinct arrangement in the shell, with two near-identical conformers in nonequivalent structural environments. Nevertheless, structural similarity with the analogous protein from the mammalian viruses suggests a common ancestor. The unusual shape of the molecule may facilitate dramatic capsid expansion during phage maturation, allowing P1 to switch interaction interfaces to provide capsid plasticity. [ABSTRACT FROM AUTHOR]

Published

2013

39. Bacteriophage P23-77 Capsid Protein Structures Reveal the Archetype of an Ancient Branch from a Major Virus Lineage.

Author

Rissanen, Ilona, Grimes, Jonathan?M., Pawlowski, Alice, Mäntynen, Sari, Harlos, Karl, Bamford, Jaana?K.H., and Stuart, David?I.

Subjects

*BACTERIOPHAGES, *CAPSIDS, *PROTEIN structure, *AMINO acid sequence, *CRYSTAL structure, *ELECTRON microscopy

Abstract

Summary: It has proved difficult to classify viruses unless they are closely related since their rapid evolution hinders detection of remote evolutionary relationships in their genetic sequences. However, structure varies more slowly than sequence, allowing deeper evolutionary relationships to be detected. Bacteriophage P23-77 is an example of a newly identified viral lineage, with members inhabiting extreme environments. We have solved multiple crystal structures of the major capsid proteins VP16 and VP17 of bacteriophage P23-77. They fit the 14 Å resolution cryo-electron microscopy reconstruction of the entire virus exquisitely well, allowing us to propose a model for both the capsid architecture and viral assembly, quite different from previously published models. The structures of the capsid proteins and their mode of association to form the viral capsid suggest that the P23-77-like and adeno-PRD1 lineages of viruses share an extremely ancient common ancestor. [ABSTRACT FROM AUTHOR]

Published

2013

40. Antigenic Switching of Hepatitis B Virus by Alternative Dimerization of the Capsid Protein

Author

DiMattia, Michael A., Watts, Norman R., Stahl, Stephen J., Grimes, Jonathan M., Steven, Alasdair C., Stuart, David I., and Wingfield, Paul T.

Subjects

*VIRAL antigens, *HEPATITIS B virus, *DIMERIZATION, *CAPSIDS, *VIRAL proteins, *CHRONIC diseases, *VIRUS diseases, *CIRRHOSIS of the liver

Abstract

Summary: Chronic hepatitis B virus (HBV) infection afflicts millions worldwide with cirrhosis and liver cancer. HBV e-antigen (HBeAg), a clinical marker for disease severity, is a nonparticulate variant of the protein (core antigen, HBcAg) that forms the building-blocks of capsids. HBeAg is not required for virion production, but is implicated in establishing immune tolerance and chronic infection. Here, we report the crystal structure of HBeAg, which clarifies how the short N-terminal propeptide of HBeAg induces a radically altered mode of dimerization relative to HBcAg (∼140° rotation), locked into place through formation of intramolecular disulfide bridges. This structural switch precludes capsid assembly and engenders a distinct antigenic repertoire, explaining why the two antigens are cross-reactive at the T cell level (through sequence identity) but not at the B cell level (through conformation). The structure offers insight into how HBeAg may establish immune tolerance for HBcAg while evading its robust immunogenicity. [Copyright &y& Elsevier]

Published

2013

41. Mapping the IκB Kinase β (IKKβ)-binding Interface of the B14 Protein, a Vaccinia Virus Inhibitor of IKKβ-mediated Activation of Nuclear Factor κW.

Author

Benfield, Camilla T. O., Mansur, Daniel S., McCoy, Laura E., Ferguson, Brian J., Bahar, Mohammad W., Oldring, Asa P., Grimes, Jonathan M., Stuart, David I., Graham, Stephen C., and Smith, Geoffrey L.

Subjects

*PROTEINS, *INFLAMMATION, *NF-kappa B, *LIGHT scattering, *TRANSCRIPTION factors

Abstract

The IκB kinase (IKK) complex regulates activation of NF-κB, a critical transcription factor in mediating inflammatory and immune responses. Not surprisingly, therefore, many viruses seek to inhibit NF-κB activation. The vaccinia virus B14 protein contributes to virus virulence by binding to the IKKβ subunit of the IKK complex and preventing NF-κB activation in response to proinflammatory stimuli. Previous crystallographic studies showed that the B14 protein has a Bcl-2-like fold and forms homodimers in the crystal. However, multi-angle light scattering indicated that B14 is in monomer-dimer equilibrium in solution. This transient self-association suggested that the hydrophobic dimerization interface of B14 might also mediate its interaction with IKKβ, and this was investigated by introducing amino acid substitutions on the dimer interface. One mutant (Y35E) was entirely monomeric but still co-immunoprecipitated with IKKβ and blocked both NF-κB nuclear translocation and NF-κB-dependent gene expression. Therefore, B14 homodimerization is nonessential for binding and inhibition of IKKβ. In contrast, a second monomeric mutant (F130K) neither bound IKKβ nor inhibited NF-κB-dependent gene expression, demonstrating that this residue is required for the B14-IKKβ interaction. Thus, the dimerization and IKKβ-binding interfaces overlap and lie on a surface used for protein-protein interactions in many viral and cellular Bcl-2-like proteins. [ABSTRACT FROM AUTHOR]

Published

2011

42. Rigid-body Ligand Recognition Drives Cytotoxic T-lymphocyte Antigen 4 (CTLA-4) Receptor Triggering.

Author

Chao Yu, Sonnen, Andreas F.-P., George, Roger, Dessailly, Benoit H., Stagg, Loren J., Evans, Edward J., Orengo, Christine A., Stuart, David I., Ladbury, John E., Ikemizu, Shinji, Gilbert, Robert J. C., and Davis, Simon J.

Subjects

*LIGANDS (Biochemistry), *T cells, *PROTEIN-tyrosine kinases, *IMMUNOGLOBULINS, *CALORIMETRY

Abstract

The inhibitory T-cell surface-expressed receptor, cytotoxic T lymphocyte-associated antigen-4 (CTLA-4), which belongs to the class of cell surface proteins phosphorylated by extrinsic tyrosine kinases that also includes antigen receptors, binds the related ligands, B7-1 and B7-2, expressed on antigen-presenting cells. Conformational changes are commonly invoked to explain ligand-induced "triggering" of this class of receptors. Crystal structures of ligand-bound CTLA-4 have been reported, but not the apo form, precluding analysis of the structural changes accompanying ligand binding. The 1.8-Å resolution structure of an apo human CTLA-4 homodimer emphasizes the shared evolutionary history of the CTLA-4/CD28 subgroup of the immunoglobulin superfamily and the antigen receptors. The ligand-bound and unbound forms of both CTLA-4 and B7-1 are remarkably similar, in marked contrast to B7-2, whose binding to CTLA-4 has elements of induced fit. Isothermal titration calorimetry reveals that ligand binding by CTLA-4 is enthalpically driven and accompanied by unfavorable entropic changes. The similarity of the thermodynamic parameters determined for the interactions of CTLA-4 with B7-1 and B7-2 suggests that the binding is not highly specific, but the conformational changes observed for B7-2 binding suggest some level of selectivity. The new structure establishes that rigid-body ligand interactions are capable of triggering CTLA-4 phosphorylation by extrinsic kinase(s). [ABSTRACT FROM AUTHOR]

Published

2011

43. Structural Plasticity of Eph Receptor A4 Facilitates Cross-Class Ephrin Signaling

Author

Bowden, Thomas A., Aricescu, A. Radu, Nettleship, Joanne E., Siebold, Christian, Rahman-Huq, Nahid, Owens, Raymond J., Stuart, David I., and Jones, E. Yvonne

Subjects

*PHENOTYPIC plasticity, *CELL receptors, *CELLULAR signal transduction, *X-ray crystallography, *LIGAND binding (Biochemistry), *MOLECULAR structure

Abstract

Summary: The EphA4 tyrosine kinase cell surface receptor regulates an array of physiological processes and is the only currently known class A Eph receptor that binds both A and B class ephrins with high affinity. We have solved the crystal structure of the EphA4 ligand binding domain alone and in complex with (1) ephrinB2 and (2) ephrinA2. This set of structures shows that EphA4 has significant conformational plasticity in its ligand binding face. In vitro binding data demonstrate that it has a higher affinity for class A than class B ligands. Structural analyses, drawing on previously reported Eph receptor structures, show that EphA4 in isolation and in complex with ephrinA2 resembles other class A Eph receptors but on binding ephrinB2 assumes structural hallmarks of the class B Eph receptors. This interactive plasticity reveals EphA4 as a structural chameleon, able to adopt both A and B class Eph receptor conformations, and thus provides a molecular basis for EphA-type cross-class reactivity. [Copyright &y& Elsevier]

Published

2009

44. Structure of Signal-regulatory Protein α: A LINK TO ANTIGEN RECEPTOR EVOLUTION.

Author

Hatherley, Deborah, Graham, Stephen C., Harlos, Karl, Stuart, David I., and Barclay, A. Neil

Subjects

*ANTIGENS, *BIOMOLECULES, *IMMUNOGLOBULINS, *X-ray crystallography, *TRANSPLANTATION immunology, *CELL membranes

Abstract

Signal-regulatory protein α (SIRPα) is a myeloid membrane receptor that interacts with the membrane protein CD47, a marker of self. We have solved the structure of the complete extracellular portion of SIRPα, comprising three immunoglobulin superfamily domains, by x-ray crystallography to 2.5 Å resolution. These data, together with previous data on the N-terminal domain and its ligand CD47 (possessing a single immunoglobulin superfamily domain), show that the CD47-SIRPα interaction will span a distance of around 14 nm between interacting cells, comparable with that of an immunological synapse. The N-terminal (V-set) domain mediates binding to CD47, and the two others are found to be constant (C1-set) domains. C1-set domains are restricted to proteins involved in vertebrate antigen recognition: T cell antigen receptors, immunoglobulins, major histocompatibility complex antigens, tapasin, and β2-microglobulin. The domains of SIRPα (domains 2 and 3) are structurally more similar to C1-set domains than any cell surface protein not involved in antigen recognition. This strengthens the suggestion from sequence analysis that SIRP is evolutionarily closely related to antigen recognition proteins. [ABSTRACT FROM AUTHOR]

Published

2009

45. A Human Embryonic Kidney 293T Cell Line Mutated at the Golgi α-Mannosidase II Locus.

Author

Crispin, Max, Chang, Veronica T., Harvey, David J., Dwek, Raymond A., Evans, Edward J., Stuart, David I., Jones, E. Yvonne, Lord, J. Michael, Spooner, Robert A., and Davis, Simon J.

Subjects

*GOLGI apparatus, *AUTOIMMUNITY, *MANNOSIDASES, *LABORATORY mice, *SWAINSONINE, *GLYCOPROTEINS, *GLYCOSYLATION

Abstract

Disruption of Golgi α-mannosidase II activity can result in type II congenital dyserythropoietic anemia and induce lupus-like autoimmunity in mice. Here, we isolated a mutant human embryonic kidney (HEK) 293T cell line called Lec36, which displays sensitivity to ricin that lies between the parental HEK 293T cells, in which the secreted and membrane-expressed proteins are dominated by complex-type glycosylation, and 293S Led cells, which produce only oligomannose-type N-linked glycans. Stem cell marker 19A was transiently expressed in the HEK 293T Lec36 cells and in parental HEK 293T cells with and without the potent Golgi α-mannosidase II inhibitor, swainsonine. Negative ion nano-electrospray ionization mass spectra of the 19A N-linked glycans from HEK 293T Lec36 and swainsonine-treated HEK 293T cells were qualitatively indistinguishable and, as shown by coffision-induced dissociation spectra, were dominated by hybrid-type glycosylation. Nucleotide sequencing revealed mutations in each allele of MAN2A1, the gene encoding Golgi a-mannosidase II: a point mutation that mapped to the active site was found in one allele, and an in-frame deletion of 12 nucleotides was found in the other allele. Expression of the wild type but not the mutant MAN2A1 alleles in Lec36 cells restored processing of the 19A reporter glycoprotein to complex-type glycosylation. The Lec36 cell line will be useful for expressing therapeutic glycoproteins with hybrid-type glycans and as a sensitive host for detecting mutations in human MAN2AJ causing type II congenital dyserythropoietic anemia. [ABSTRACT FROM AUTHOR]

Published

2009

46. The Mechanics of Translocation: A Molecular “Spring-and-Ratchet” System

Author

Moran, Stephen J., Flanagan, John F., Namy, Olivier, Stuart, David I., Brierley, Ian, and Gilbert, Robert J.C.

Subjects

*TRANSFER RNA, *RNA, *AMINOACYL-tRNA, *ORGANIC acids

Abstract

The translation of genetic information into proteins is a fundamental process of life. Stepwise addition of amino acids to the growing polypeptide chain requires the coordinated movement of mRNA and tRNAs through the ribosome, a process known as translocation. Here, we review current understanding of the kinetics and mechanics of translocation, with particular emphasis on the structure of a functional mammalian ribosome stalled during translocation by an mRNA pseudoknot. In the context of a pseudoknot-stalled complex, the translocase EF-2 is seen to compress a hybrid-state tRNA into a strained conformation. We propose that this strain energy helps overcome the kinetic barrier to translocation and drives tRNA into the P-site, with EF-2 biasing this relaxation in one direction. The tRNA can thus be considered a molecular spring and EF-2 a Brownian ratchet in a “spring-and-ratchet” system within the translocation process. [Copyright &y& Elsevier]

Published

2008

47. Structural Basis of Mechanochemical Coupling in a Hexameric Molecular Motor.

Author

Kainov, Denis E., Mancini, Erika J., Telenius, Jelena, Lísal, Jiř í, Grimes, Jonathan M., Bamford, Dennis H., Stuart, David I., and Tuma, Roman

Subjects

*DNA helicases, *ISOMERASES, *ADENOSINE triphosphate, *BINDING sites, *CELL receptors, *GENETIC regulation

Abstract

The P4 protein of bacteriophage ɸ12 is a hexameric molecular motor closely related to superfamily 4 helicases. P4 converts chemical energy from ATP hydrolysis into mechanical work, to translocate single-stranded RNA into a viral capsid. The molecular basis of mechanochemical coupling, i.e. how small ∼1 Å changes in the ATP-binding site are amplified into nanometer scale motion along the nucleic acid, is not understood at the atomic level. Here we study in atomic detail the mechanochemical coupling using structural and biochemical analyses of P4 mutants. We show that a conserved region, consisting of superfamily 4 helicase motifs H3 and H4 and loop L2, constitutes the moving lever of the motor. The lever tip encompasses an RNA-binding site that moves along the mechanical reaction coordinate. The lever is flanked by γ-phosphate sensors (Asn-234 and Ser-252) that report the nucleotide state of neighboring subunits and control the lever position. Insertion of an arginine finger (Arg-279) into the neighboring catalytic site is concomitant with lever movement and commences ATP hydrolysis. This ensures cooperative sequential hydrolysis that is tightly coupled to mechanical motion. Given the structural conservation, the mutated residues may play similar roles in other hexameric helicases and related molecular motors. [ABSTRACT FROM AUTHOR]

Published

2008

48. The Structure of the Macrophage Signal Regulatory Protein α (SIRP) Inhibitory Receptor Reveals a Binding Face Reminiscent of That Used by T Cell Receptors.

Author

Hatherley, Deborah, Harlos, Karl, Dunlop, D. Cameron, Stuart, David I., and Barclay, A. Neil

Subjects

*MACROPHAGES, *PROTEINS, *T cell receptors, *CELL membranes, *LIGANDS (Biochemistry), *IMMUNOGLOBULINS

Abstract

Signal regulatory protein (SIRP) a is a membrane receptor that sends inhibitory signals to myeloid cells by engagement of CD47. The high resolution x-ray structure of the N-terminal ligand binding domain shows it to have a distinctive immunoglobulin superfamily V-like fold. Site-directed mutagenesis suggests that CD47 is bound at a surface involving the BC, FG, and DE loops, which distinguishes it from other immunoglobulin superfamily surface proteins that use the faces of the fold, but resembles antigen receptors. The SIRP interaction is confined to a single domain, and its use of an extended DE loop strengthens the similarity with T cell receptor binding and the suggestion that they are closely related in evolution. The employment of loops to form the CD47-binding surface provides a mechanism for small sequence changes to modulate binding specificity, explaining the different binding properties of SIRP family members. [ABSTRACT FROM AUTHOR]

Published

2007

49. αVj36 Is a Novel Receptor for Human Fibrillin-1.

Author

Iovanovie, Jelena, Takagi, Junichi, Chouiier, Laurence, Abrescia, Nicola G. A., Stuart, David I., Van Der Merwe, P. Anton, Mardon, Helen J., and Handford, Penny A.

Subjects

*PROTEINS, *MICROFIBRILS, *CELLS, *EPIDERMAL growth factor, *SURFACE plasmon resonance

Abstract

Human fibrillin-1, the major structural protein of connective tissue 10-12 nm microfibrils, contains multiple calcium binding epidermal growth factor-like domains interspersed with transforming growth factor β-binding protein-like (TB) domains. TB4 contains a flexible RGD loop that mediates cell adhesion via αVα3 and α5β1 integrins. This study identifies integrin αVα6 as a novel cellular receptor for fibrillin-1 with a Kd of ~0.45 µM. Analyses of this interaction by surface plasmon resonance and immunocytochemistry reveal different module requirements for αVβ6 activation compared with those of αVβ3, suggesting that a covalent linkage of an N-terminal calcium binding epidermal growth factor-like domain to TB4 can modulate αV integrin binding specificity. Furthermore, our data suggest α5β1 is a low affinity fibrillin-1 receptor (Kd > 1 µM), thus providing a molecular explanation for the different α5β1 distribution patterns seen when human keratinocytes and fibroblasts are plated on recombinant fibrillin fragments versus those derived from the physiological ligand fibronectin. Non-focal contact distribution of α5β1 suggests that its engagement by fibrillin-1 may elicit a lesser degree and/or different type of intracellular signaling compared with that seen with a high affinity ligand. [ABSTRACT FROM AUTHOR]

Published

2007

50. Glycoprotein Structural Genomics: Solving the Glycosylation Problem

Author

Chang, Veronica T., Crispin, Max, Aricescu, A. Radu, Harvey, David J., Nettleship, Joanne E., Fennelly, Janet A., Yu, Chao, Boles, Kent S., Evans, Edward J., Stuart, David I., Dwek, Raymond A., Jones, E. Yvonne, Owens, Raymond J., and Davis, Simon J.

Subjects

*GLYCOPROTEINS, *ESTERIFICATION, *GENETIC research, *MOLECULAR genetics

Abstract

Summary: Glycoproteins present special problems for structural genomic analysis because they often require glycosylation in order to fold correctly, whereas their chemical and conformational heterogeneity generally inhibits crystallization. We show that the “glycosylation problem” can be solved by expressing glycoproteins transiently in mammalian cells in the presence of the N-glycosylation processing inhibitors, kifunensine or swainsonine. This allows the correct folding of the glycoproteins, but leaves them sensitive to enzymes, such as endoglycosidase H, that reduce the N-glycans to single residues, enhancing crystallization. Since the scalability of transient mammalian expression is now comparable to that of bacterial systems, this approach should relieve one of the major bottlenecks in structural genomic analysis. [Copyright &y& Elsevier]

Published

2007