Your search keyword '"Wibmer, Constantinos Kurt"' showing total 45 results

1. HIV-1 and SARS-CoV-2: Patterns in the evolution of two pandemic pathogens

Author

Fischer, Will, Giorgi, Elena E, Chakraborty, Srirupa, Nguyen, Kien, Bhattacharya, Tanmoy, Theiler, James, Goloboff, Pablo A, Yoon, Hyejin, Abfalterer, Werner, Foley, Brian T, Tegally, Houriiyah, San, James Emmanuel, de Oliveira, Tulio, Africa, Network for Genomic Surveillance in South, Wilkinson, Eduan, Msomi, Nokukhanya, Iranzadeh, Arash, Fonseca, Vagner, Doolabh, Deelan, Mlisana, Koleka, von Gottberg, Anne, Walaza, Sibongile, Allam, Mushal, Ismail, Arshad, Mohale, Thabo, Glass, Allison J, Engelbrecht, Susan, Van Zyl, Gert, Preiser, Wolfgang, Petruccione, Francesco, Sigal, Alex, Hardie, Diana, Marais, Gert, Hsiao, Marvin, Korsman, Stephen, Davies, Mary-Ann, Tyers, Lynn, Mudau, Innocent, York, Denis, Maslo, Caroline, Goedhals, Dominique, Abrahams, Shareef, Laguda-Akingba, Oluwakemi, Alisoltani-Dehkordi, Arghavan, Godzik, Adam, Wibmer, Constantinos Kurt, Sewell, Bryan Trevor, Lourenço, José, Pond, Sergei L Kosakovsky, Weaver, Steven, Giovanetti, Marta, Alcantara, Luiz Carlos Junior, Martin, Darren, Bhiman, Jinal N, Williamson, Carolyn, Gnanakaran, Sandrasegaram, and Korber, Bette

Subjects

Medical Microbiology, Biomedical and Clinical Sciences, Biological Sciences, Pneumonia, Vaccine Related, Emerging Infectious Diseases, Prevention, Genetics, Lung, HIV/AIDS, Infectious Diseases, Infection, Good Health and Well Being, COVID-19, Evolution, Molecular, Genome, Viral, HIV-1, Humans, Immune Evasion, Mutation, Pandemics, Receptors, Virus, Recombination, Genetic, SARS-CoV-2, Selection, Genetic, Spike Glycoprotein, Coronavirus, Viral Proteins, Network for Genomic Surveillance in South Africa, evolution, glycosylation, immune escape, insertions and deletions, recombination, Microbiology, Immunology, Biochemistry and cell biology, Medical microbiology

Abstract

Humanity is currently facing the challenge of two devastating pandemics caused by two very different RNA viruses: HIV-1, which has been with us for decades, and SARS-CoV-2, which has swept the world in the course of a single year. The same evolutionary strategies that drive HIV-1 evolution are at play in SARS-CoV-2. Single nucleotide mutations, multi-base insertions and deletions, recombination, and variation in surface glycans all generate the variability that, guided by natural selection, enables both HIV-1's extraordinary diversity and SARS-CoV-2's slower pace of mutation accumulation. Even though SARS-CoV-2 diversity is more limited, recently emergent SARS-CoV-2 variants carry Spike mutations that have important phenotypic consequences in terms of both antibody resistance and enhanced infectivity. We review and compare how these mutational patterns manifest in these two distinct viruses to provide the variability that fuels their evolution by natural selection.

Published

2021

2. Emergence and phenotypic characterization of the global SARS-CoV-2 C.1.2 lineage

Author

Scheepers, Cathrine, Everatt, Josie, Amoako, Daniel G., Tegally, Houriiyah, Wibmer, Constantinos Kurt, Mnguni, Anele, Ismail, Arshad, Mahlangu, Boitshoko, Lambson, Bronwen E., Martin, Darren P., Wilkinson, Eduan, San, James Emmanuel, Giandhari, Jennifer, Manamela, Nelia, Ntuli, Noxolo, Kgagudi, Prudence, Cele, Sandile, Richardson, Simone I., Pillay, Sureshnee, Mohale, Thabo, Ramphal, Upasana, Naidoo, Yeshnee, Khumalo, Zamantungwa T., Kwatra, Gaurav, Gray, Glenda, Bekker, Linda-Gail, Madhi, Shabir A., Baillie, Vicky, Van Voorhis, Wesley C., Treurnicht, Florette K., Venter, Marietjie, Mlisana, Koleka, Wolter, Nicole, Sigal, Alex, Williamson, Carolyn, Hsiao, Nei-yuan, Msomi, Nokukhanya, Maponga, Tongai, Preiser, Wolfgang, Makatini, Zinhle, Lessells, Richard, Moore, Penny L., de Oliveira, Tulio, von Gottberg, Anne, and Bhiman, Jinal N.

Published

2022

3. The V2 loop of HIV gp120 delivers costimulatory signals to CD4⁺ T cells through Integrin α₄β₇ and promotes cellular activation and infection

Author

Goes, Livia R., Sajani, Alia, Sivro, Aida, Olowojesiku, Ronke, Ray, Jocelyn C., Perrone, Ian, Yolitz, Jason, Girard, Alexandre, Leyre, Louise, Wibmer, Constantinos Kurt, Morris, Lynn, Gorini, Giacomo, Franchini, Genoveffa, Mason, Rosemarie D., Roederer, Mario, Mehandru, Saurabh, Soares, Marcelo A., Cicala, Claudia, Fauci, Anthony S., and Arthos, James

Published

2020

4. HIVR4P 2016, Partnering for Prevention: Conference Summary and Highlights.

Author

Shacklett, Barbara L, Derdeyn, Cynthia A, Folayan, Morenike Oluwatoyin, Landovitz, Raphael J, Anthony, Colin, Behrens, Anna-Janina, Hope, Thomas J, Landais, Elise, Leal, Lorna, Marrazzo, Jeanne M, Morris, Lynn, Mugo, Nelly, Ngure, Kenneth, Noseda, Veronica, Ranasinghe, Srinika, Tully, Damien C, Voronin, Yegor, Warren, Mitchell, Wibmer, Constantinos Kurt, Xie, Irene Y, Scarlatti, Gabriella, and Thyagarajan, Bargavi

Subjects

Humans, HIV Infections, Communicable Disease Control, Biomedical Research, Disease Transmission, Infectious, Global Health, HIV prevention, PrEP, R4P, antibody, microbicide, vaccine, Vaccine Related, HIV/AIDS, Immunization, Infectious Diseases, Prevention, Infection, Good Health and Well Being, Clinical Sciences, Virology

Abstract

HIV Research for Prevention: AIDS Vaccine, Microbicide, and ARV-based Prevention Science (HIVR4P) was built on a growing consensus that effective HIV prevention requires a combination of approaches and that understanding, analyzing, and debating the cross-cutting issues that impact prevention research are all essential to combat the global HIV/AIDS epidemic. To that end, the biennial HIVR4P conference is dedicated to all biomedical HIV prevention research approaches, including HIV vaccines, microbicides, pre-exposure prophylaxis, and treatment as prevention. The HIVR4P 2016 conference was held in Chicago, Illinois (USA), on October 17-21, and included more than 700 scientific presentations and 21 satellite sessions covering the latest and most promising advances across the HIV prevention research field. The theme "Partnering for Prevention" represented the conference's commitment to breaking down silos between research disciplines as well as between researchers, program developers, care providers, advocates, communities, and funders. Delegates spanning 42 countries attended the conference. One-third of those in attendance were early career investigators, which reflects a firm commitment to emerging researchers and ultimately to the goal of developing a sustainable scientific enterprise well into the future. This article presents a concise summary of highlights from the conference. For a more detailed account, one may find full abstracts, daily summaries, and webcasts on the conference website at hivr4p.org.

Published

2017

5. SARS-CoV-2 501Y.V2 escapes neutralization by South African COVID-19 donor plasma

Author

Wibmer, Constantinos Kurt, Ayres, Frances, Hermanus, Tandile, Madzivhandila, Mashudu, Kgagudi, Prudence, Oosthuysen, Brent, Lambson, Bronwen E., de Oliveira, Tulio, Vermeulen, Marion, van der Berg, Karin, Rossouw, Theresa, Boswell, Michael, Ueckermann, Veronica, Meiring, Susan, von Gottberg, Anne, Cohen, Cheryl, and Morris, Lynn

Subjects

Drug resistance in microorganisms -- Research, Protein binding -- Research, Monoclonal antibodies -- Research, Viral proteins -- Genetic aspects -- Physiological aspects, Virus research, Biological sciences, Health

Abstract

SARS-CoV-2 501Y.V2 (B.1.351), a novel lineage of coronavirus causing COVID-19, contains substitutions in two immunodominant domains of the spike protein. Here, we show that pseudovirus expressing 501Y.V2 spike protein completely escapes three classes of therapeutically relevant antibodies. This pseudovirus also exhibits substantial to complete escape from neutralization, but not binding, by convalescent plasma. These data highlight the prospect of reinfection with antigenically distinct variants and foreshadows reduced efficacy of spike-based vaccines. Substitutions in SARS-CoV-2 spike protein present in the B.1.351 variant first detected in South Africa, when expressed in pseudoviruses, mediate escape from neutralization by monoclonal antibodies under clinical development and by plasma from individuals previously infected with SARS-CoV-2, but do not prevent binding of convalescent plasma to recombinant spike protein containing B.1.351 lineage substitutions., Author(s): Constantinos Kurt Wibmer [sup.1] , Frances Ayres [sup.1] , Tandile Hermanus [sup.1] , Mashudu Madzivhandila [sup.1] , Prudence Kgagudi [sup.1] , Brent Oosthuysen [sup.1] , Bronwen E. Lambson [sup.1] [...]

Published

2021

6. Detection of a SARS-CoV-2 variant of concern in South Africa

Author

Tegally, Houriiyah, Wilkinson, Eduan, Giovanetti, Marta, Iranzadeh, Arash, Fonseca, Vagner, Giandhari, Jennifer, Doolabh, Deelan, Pillay, Sureshnee, San, Emmanuel James, Msomi, Nokukhanya, Mlisana, Koleka, von Gottberg, Anne, Walaza, Sibongile, Allam, Mushal, Ismail, Arshad, Mohale, Thabo, Glass, Allison J., Engelbrecht, Susan, Van Zyl, Gert, Preiser, Wolfgang, Petruccione, Francesco, Sigal, Alex, Hardie, Diana, Marais, Gert, Hsiao, Nei-yuan, Korsman, Stephen, Davies, Mary-Ann, Tyers, Lynn, Mudau, Innocent, York, Denis, Maslo, Caroline, Goedhals, Dominique, Abrahams, Shareef, Laguda-Akingba, Oluwakemi, Alisoltani-Dehkordi, Arghavan, Godzik, Adam, Wibmer, Constantinos Kurt, Sewell, Bryan Trevor, Lourenço, José, Alcantara, Luiz Carlos Junior, Kosakovsky Pond, Sergei L., Weaver, Steven, Martin, Darren, Lessells, Richard J., Bhiman, Jinal N., Williamson, Carolyn, and de Oliveira, Tulio

Published

2021

7. Exploiting V-Gene Bias for Rapid, High-Throughput Monoclonal Antibody Isolation from Horses

Author

Wibmer, Constantinos Kurt, primary and Mashilo, Poppy, additional

Published

2022

8. Common helical V1V2 conformations of HIV-1 Envelope expose the α4β7 binding site on intact virions

Author

Wibmer, Constantinos Kurt, Richardson, Simone I., Yolitz, Jason, Cicala, Claudia, Arthos, James, Moore, Penny L., and Morris, Lynn

Published

2018

9. Omicron extensively but incompletely escapes Pfizer BNT162b2 neutralization

Author

Cele, Sandile, Jackson, Laurelle, Khoury, David S., Khan, Khadija, Moyo-Gwete, Thandeka, Tegally, Houriiyah, San, James Emmanuel, Cromer, Deborah, Scheepers, Cathrine, Amoako, Daniel G., Karim, Farina, Bernstein, Mallory, Lustig, Gila, Archary, Derseree, Smith, Muneerah, Ganga, Yashica, Jule, Zesuliwe, Reedoy, Kajal, Hwa, Shi Hsia, Giandhari, Jennifer, Blackburn, Jonathan M., Gosnell, Bernadett I., Abdool Karim, Salim S., Hanekom, Willem, Davies, Mary Ann, Hsiao, Marvin, Martin, Darren, Mlisana, Koleka, Wibmer, Constantinos Kurt, Williamson, Carolyn, York, Denis, Harrichandparsad, Rohen, Herbst, Kobus, Jeena, Prakash, Khoza, Thandeka, Kløverpris, Henrik, Leslie, Alasdair, Madansein, Rajhmun, Magula, Nombulelo, Manickchund, Nithendra, Marakalala, Mohlopheni, Mazibuko, Matilda, Moshabela, Mosa, Mthabela, Ntombifuthi, Naidoo, Kogie, Ndhlovu, Zaza, Ndung’u, Thumbi, Ngcobo, Nokuthula, Nyamande, Kennedy, and Patel, Vinod

Subjects

Multidisciplinary

Abstract

The emergence of the SARS-CoV-2 variant of concern Omicron (Pango lineage B.1.1.529), first identified in Botswana and South Africa, may compromise vaccine effectiveness and lead to re-infections1. Here we investigated Omicron escape from neutralization by antibodies from South African individuals vaccinated with Pfizer BNT162b2. We used blood samples taken soon after vaccination from individuals who were vaccinated and previously infected with SARS-CoV-2 or vaccinated with no evidence of previous infection. We isolated and sequence-confirmed live Omicron virus from an infected person and observed that Omicron requires the angiotensin-converting enzyme 2 (ACE2) receptor to infect cells. We compared plasma neutralization of Omicron relative to an ancestral SARS-CoV-2 strain and found that neutralization of ancestral virus was much higher in infected and vaccinated individuals compared with the vaccinated-only participants. However, both groups showed a 22-fold reduction in vaccine-elicited neutralization by the Omicron variant. Participants who were vaccinated and had previously been infected exhibited residual neutralization of Omicron similar to the level of neutralization of the ancestral virus observed in the vaccination-only group. These data support the notion that reasonable protection against Omicron may be maintained using vaccination approaches.

Published

2021

10. Omicron extensively but incompletely escapes Pfizer BNT162b2 neutralization

Author

Cele, Sandile, Jackson, Laurelle, Khoury, David S., Khan, Khadija, Moyo-Gwete, Thandeka, Tegally, Houriiyah, San, James Emmanuel, Cromer, Deborah, Scheepers, Cathrine, Amoako, Daniel G., Karim, Farina, Bernstein, Mallory, Lustig, Gila, Archary, Derseree, Smith, Muneerah, Ganga, Yashica, Jule, Zesuliwe, Reedoy, Kajal, Hwa, Shi Hsia, Giandhari, Jennifer, Blackburn, Jonathan M., Gosnell, Bernadett I., Abdool Karim, Salim S., Hanekom, Willem, Davies, Mary Ann, Hsiao, Marvin, Martin, Darren, Mlisana, Koleka, Wibmer, Constantinos Kurt, Williamson, Carolyn, York, Denis, Harrichandparsad, Rohen, Herbst, Kobus, Jeena, Prakash, Khoza, Thandeka, Kløverpris, Henrik, Leslie, Alasdair, Madansein, Rajhmun, Magula, Nombulelo, Manickchund, Nithendra, Marakalala, Mohlopheni, Mazibuko, Matilda, Moshabela, Mosa, Mthabela, Ntombifuthi, Naidoo, Kogie, Ndhlovu, Zaza, Ndung’u, Thumbi, Ngcobo, Nokuthula, Nyamande, Kennedy, Patel, Vinod, Cele, Sandile, Jackson, Laurelle, Khoury, David S., Khan, Khadija, Moyo-Gwete, Thandeka, Tegally, Houriiyah, San, James Emmanuel, Cromer, Deborah, Scheepers, Cathrine, Amoako, Daniel G., Karim, Farina, Bernstein, Mallory, Lustig, Gila, Archary, Derseree, Smith, Muneerah, Ganga, Yashica, Jule, Zesuliwe, Reedoy, Kajal, Hwa, Shi Hsia, Giandhari, Jennifer, Blackburn, Jonathan M., Gosnell, Bernadett I., Abdool Karim, Salim S., Hanekom, Willem, Davies, Mary Ann, Hsiao, Marvin, Martin, Darren, Mlisana, Koleka, Wibmer, Constantinos Kurt, Williamson, Carolyn, York, Denis, Harrichandparsad, Rohen, Herbst, Kobus, Jeena, Prakash, Khoza, Thandeka, Kløverpris, Henrik, Leslie, Alasdair, Madansein, Rajhmun, Magula, Nombulelo, Manickchund, Nithendra, Marakalala, Mohlopheni, Mazibuko, Matilda, Moshabela, Mosa, Mthabela, Ntombifuthi, Naidoo, Kogie, Ndhlovu, Zaza, Ndung’u, Thumbi, Ngcobo, Nokuthula, Nyamande, Kennedy, and Patel, Vinod

Abstract

The emergence of the SARS-CoV-2 variant of concern Omicron (Pango lineage B.1.1.529), first identified in Botswana and South Africa, may compromise vaccine effectiveness and lead to re-infections1. Here we investigated Omicron escape from neutralization by antibodies from South African individuals vaccinated with Pfizer BNT162b2. We used blood samples taken soon after vaccination from individuals who were vaccinated and previously infected with SARS-CoV-2 or vaccinated with no evidence of previous infection. We isolated and sequence-confirmed live Omicron virus from an infected person and observed that Omicron requires the angiotensin-converting enzyme 2 (ACE2) receptor to infect cells. We compared plasma neutralization of Omicron relative to an ancestral SARS-CoV-2 strain and found that neutralization of ancestral virus was much higher in infected and vaccinated individuals compared with the vaccinated-only participants. However, both groups showed a 22-fold reduction in vaccine-elicited neutralization by the Omicron variant. Participants who were vaccinated and had previously been infected exhibited residual neutralization of Omicron similar to the level of neutralization of the ancestral virus observed in the vaccination-only group. These data support the notion that reasonable protection against Omicron may be maintained using vaccination approaches.

Published

2022

11. A combination of potently neutralizing monoclonal antibodies isolated from an Indian convalescent donor protects against the SARS-CoV-2 Delta variant

Author

Hingankar, Nitin, primary, Deshpande, Suprit, additional, Das, Payel, additional, Rizvi, Zaigham Abbas, additional, Wibmer, Constantinos Kurt, additional, Mashilo, Poppy, additional, Ansari, Mohammed Yousuf, additional, Burns, Alison, additional, Barman, Shawn, additional, Zhao, Fangzhu, additional, Mukherjee, Sohini, additional, Torres, Jonathan L., additional, Chattopadhyay, Souvick, additional, Mehdi, Farha, additional, Sutar, Jyoti, additional, Rathore, Deepak Kumar, additional, Pargai, Kamal, additional, Singh, Janmejay, additional, Sonar, Sudipta, additional, Jakhar, Kamini, additional, Dandotiya, Jyotsna, additional, Bhattacharyya, Sankar, additional, Mani, Shailendra, additional, Samal, Sweety, additional, Singh, Savita, additional, Kshetrapal, Pallavi, additional, Thiruvengadam, Ramachandran, additional, Batra, Gaurav, additional, Medigeshi, Guruprasad, additional, Ward, Andrew B., additional, Bhatnagar, Shinjini, additional, Awasthi, Amit, additional, Sok, Devin, additional, and Bhattacharya, Jayanta, additional

Published

2022

12. Developmental pathway for potent V1V2-directed HIV-neutralizing antibodies

Author

Doria-Rose, Nicole A., Schramm, Chaim A., Gorman, Jason, Moore, Penny L., Bhiman, Jinal N., DeKosky, Brandon J., Ernandes, Michael J., Georgiev, Ivelin S., Kim, Helen J., Pancera, Marie, Staupe, Ryan P., Altae-Tran, Han R., Bailer, Robert T., Crooks, Ema T., Cupo, Albert, Druz, Aliaksandr, Garrett, Nigel J., Hoi, Kam H., Kong, Rui, Louder, Mark K., Longo, Nancy S., McKee, Krisha, Nonyane, Molati, O’Dell, Sijy, Roark, Ryan S., Rudicell, Rebecca S., Schmidt, Stephen D., Sheward, Daniel J., Soto, Cinque, Wibmer, Constantinos Kurt, Yang, Yongping, Zhang, Zhenhai, Mullikin, James C., Binley, James M., Sanders, Rogier W., Wilson, Ian A., Moore, John P., Ward, Andrew B., Georgiou, George, Williamson, Carolyn, Abdool Karim, Salim S., Morris, Lynn, Kwong, Peter D., Shapiro, Lawrence, and Mascola, John R.

Published

2014

13. SARS-CoV-2 501Y.V2 (B.1.351) elicits cross-reactive neutralizing antibodies

Author

Moyo-Gwete, Thandeka, primary, Madzivhandila, Mashudu, additional, Makhado, Zanele, additional, Ayres, Frances, additional, Mhlanga, Donald, additional, Oosthuysen, Brent, additional, Lambson, Bronwen E., additional, Kgagudi, Prudence, additional, Tegally, Houriiyah, additional, Iranzadeh, Arash, additional, Doolabh, Deelan, additional, Tyers, Lynn, additional, Chinhoyi, Lionel R., additional, Mennen, Mathilda, additional, Skelem, Sango, additional, Marais, Gert, additional, Wibmer, Constantinos Kurt, additional, Bhiman, Jinal N, additional, Ueckermann, Veronica, additional, Rossouw, Theresa, additional, Boswell, Michael, additional, de Oliveira, Tulio, additional, Williamson, Carolyn, additional, Burgers, Wendy A, additional, Ntusi, Ntobeko, additional, Morris, Lynn, additional, and Moore, Penny L, additional

Published

2021

14. SARS-CoV-2 501Y.V2 escapes neutralization by South African COVID-19 donor plasma

Author

Wibmer, Constantinos Kurt, primary, Ayres, Frances, additional, Hermanus, Tandile, additional, Madzivhandila, Mashudu, additional, Kgagudi, Prudence, additional, Oosthuysen, Brent, additional, Lambson, Bronwen E., additional, de Oliveira, Tulio, additional, Vermeulen, Marion, additional, van der Berg, Karin, additional, Rossouw, Theresa, additional, Boswell, Michael, additional, Ueckermann, Veronica, additional, Meiring, Susan, additional, von Gottberg, Anne, additional, Cohen, Cheryl, additional, Morris, Lynn, additional, Bhiman, Jinal N., additional, and Moore, Penny L., additional

Published

2021

15. Emergence and rapid spread of a new severe acute respiratory syndrome-related coronavirus 2 (SARS-CoV-2) lineage with multiple spike mutations in South Africa

Author

Tegally, Houriiyah, primary, Wilkinson, Eduan, additional, Giovanetti, Marta, additional, Iranzadeh, Arash, additional, Fonseca, Vagner, additional, Giandhari, Jennifer, additional, Doolabh, Deelan, additional, Pillay, Sureshnee, additional, San, Emmanuel James, additional, Msomi, Nokukhanya, additional, Mlisana, Koleka, additional, von Gottberg, Anne, additional, Walaza, Sibongile, additional, Allam, Mushal, additional, Ismail, Arshad, additional, Mohale, Thabo, additional, Glass, Allison J, additional, Engelbrecht, Susan, additional, Van Zyl, Gert, additional, Preiser, Wolfgang, additional, Petruccione, Francesco, additional, Sigal, Alex, additional, Hardie, Diana, additional, Marais, Gert, additional, Hsiao, Marvin, additional, Korsman, Stephen, additional, Davies, Mary-Ann, additional, Tyers, Lynn, additional, Mudau, Innocent, additional, York, Denis, additional, Maslo, Caroline, additional, Goedhals, Dominique, additional, Abrahams, Shareef, additional, Laguda-Akingba, Oluwakemi, additional, Alisoltani-Dehkordi, Arghavan, additional, Godzik, Adam, additional, Wibmer, Constantinos Kurt, additional, Sewell, Bryan Trevor, additional, Lourenço, José, additional, Alcantara, Luiz Carlos Junior, additional, Pond, Sergei L Kosakovsky, additional, Weaver, Steven, additional, Martin, Darren, additional, Lessells, Richard J, additional, Bhiman, Jinal N, additional, Williamson, Carolyn, additional, and de Oliveira, Tulio, additional

Published

2020

16. The V2 loop of HIV gp120 delivers costimulatory signals to CD4+T cells through Integrin α4β7and promotes cellular activation and infection

Author

Goes, Livia R., primary, Sajani, Alia, additional, Sivro, Aida, additional, Olowojesiku, Ronke, additional, Ray, Jocelyn C., additional, Perrone, Ian, additional, Yolitz, Jason, additional, Girard, Alexandre, additional, Leyre, Louise, additional, Wibmer, Constantinos Kurt, additional, Morris, Lynn, additional, Gorini, Giacomo, additional, Franchini, Genoveffa, additional, Mason, Rosemarie D., additional, Roederer, Mario, additional, Mehandru, Saurabh, additional, Soares, Marcelo A., additional, Cicala, Claudia, additional, Fauci, Anthony S., additional, and Arthos, James, additional

Published

2020

17. Genome Sequencing of a Severe Acute Respiratory Syndrome Coronavirus 2 Isolate Obtained from a South African Patient with Coronavirus Disease 2019

Author

Allam, Mushal, primary, Ismail, Arshad, additional, Khumalo, Zamantungwa T. H., additional, Kwenda, Stanford, additional, van Heusden, Peter, additional, Cloete, Ruben, additional, Wibmer, Constantinos Kurt, additional, Mtshali, Phillip Senzo, additional, Mnyameni, Florah, additional, Mohale, Thabo, additional, Subramoney, Kathleen, additional, Walaza, Sibongile, additional, Ngubane, Wendy, additional, Govender, Nevashan, additional, Motaze, Nkengafac V., additional, and Bhiman, Jinal N., additional

Published

2020

18. Rapid Induction of Multifunctional Antibodies in Rabbits and Macaques by Clade C HIV-1 CAP257 Envelopes Circulating During Epitope-Specific Neutralization Breadth Development

Author

Malherbe, Delphine C., primary, Wibmer, Constantinos Kurt, additional, Nonyane, Molati, additional, Reed, Jason, additional, Sather, D. Noah, additional, Spencer, David A., additional, Schuman, Jason T., additional, Guo, Biwei, additional, Pandey, Shilpi, additional, Robins, Harlan, additional, Park, Byung, additional, Fuller, Deborah H., additional, Sacha, Jonah B., additional, Moore, Penny L., additional, Hessell, Ann J., additional, and Haigwood, Nancy L., additional

Published

2020

19. Neutralization Breadth and Potency of Single-Chain Variable Fragments Derived from Broadly Neutralizing Antibodies Targeting Multiple Epitopes on the HIV-1 Envelope

Author

van Dorsten, Rebecca T., primary, Lambson, Bronwen E., additional, Wibmer, Constantinos Kurt, additional, Weinberg, Marc S., additional, Moore, Penny L., additional, and Morris, Lynn, additional

Published

2020

20. V2-Directed Vaccine-like Antibodies from HIV-1 Infection Identify an Additional K169-Binding Light Chain Motif with Broad ADCC Activity

Author

van Eeden, Charmaine, primary, Wibmer, Constantinos Kurt, additional, Scheepers, Cathrine, additional, Richardson, Simone I., additional, Nonyane, Molati, additional, Lambson, Bronwen, additional, Mkhize, Nonhlanhla N., additional, Vijayakumar, Balakrishnan, additional, Sheng, Zizhang, additional, Stanfield-Oakley, Sherry, additional, Bhiman, Jinal N., additional, Bekker, Valerie, additional, Hermanus, Tandile, additional, Mabvakure, Batsirai, additional, Ismail, Arshad, additional, Moody, M. Anthony, additional, Wiehe, Kevin, additional, Garrett, Nigel, additional, Karim, Salim Abdool, additional, Dirr, Heini, additional, Fernandes, Manuel A., additional, Sayed, Yasien, additional, Shapiro, Lawrence, additional, Ferrari, Guido, additional, Haynes, Barton F., additional, Moore, Penny L., additional, and Morris, Lynn, additional

Published

2018

21. The V2 loop of HIV gp120 delivers costimulatory signals to CD4+ T cells through Integrin α4β7 and promotes cellular activation and infection.

Author

Goes, Livia R., Sajani, Alia, Sivro, Aida, Olowojesiku, Ronke, Ray, Jocelyn C., Perrone, Ian, Yolitz, Jason, Girard, Alexandre, Leyre, Louise, Wibmer, Constantinos Kurt, Morris, Lynn, Gorini, Giacomo, Franchini, Genoveffa, Mason, Rosemarie D., Roederer, Mario, Mehandru, Saurabh, Soares, Marcelo A., Cicala, Claudia, Fauci, Anthony S., and Arthos, James

Subjects

T cells, HIV infections, INTEGRINS, HIV infection transmission, HIV

Abstract

Acute HIV infection is characterized by rapid viral seeding of immunologic inductive sites in the gut followed by the severe depletion of gut CD4+ T cells. Trafficking of α4β7-expressing lymphocytes to the gut is mediated by MAdCAM, the natural ligand of α4β7 that is expressed on gut endothelial cells. MAdCAM signaling through α4β7 costimulates CD4+ T cells and promotes HIV replication. Similar to MAdCAM, the V2 domain of the gp120 HIV envelope protein binds to α4β7. In this study, we report that gp120 V2 shares with MAdCAM the capacity to signal through α4β7 resulting in CD4+ T cell activation and proliferation. As with MAdCAM-mediated costimulation, cellular activation induced by gp120 V2 is inhibited by anti-α4β7 monoclonal antibodies (mAbs). It is also inhibited by anti-V2 domain antibodies including nonneutralizing mAbs that recognize an epitope in V2 that has been linked to reduced risk of acquisition in the RV144 vaccine trial. The capacity of the V2 domain of gp120 to mediate signaling through α4β7 likely impacts early events in HIV infection. The capacity of nonneutralizing V2 antibodies to block this activity reveals a previously unrecognized mechanism whereby such antibodies might impact HIV transmission and pathogenesis. [ABSTRACT FROM AUTHOR]

Published

2020

22. Structure and Recognition of a Novel HIV-1 gp120-gp41 Interface Antibody that Caused MPER Exposure through Viral Escape

Author

Wibmer, Constantinos Kurt, Gorman, Jason, Ozorowski, Gabriel, Bhiman, Jinal N, Sheward, Daniel J, Joyce, M Gordon, Asokan, Mangai, Burton, Dennis R, Connors, Mark, Abdool Karim, Salim S, Mascola, John R, Robinson, James E, Ward, Andrew B, Kwong, Peter D, Morris, Lynn, Moore, Penny L, Institute of Infectious Disease and Molecular Medicine, and Faculty of Health Sciences

Subjects

RNA viruses, Physiology, viruses, Immunology, Pathology and Laboratory Medicine, Biochemistry, Microbiology, Antibodies, Immunodeficiency Viruses, Immune Physiology, Retroviruses, Medicine and Health Sciences, Microbial Pathogens, Immune System Proteins, Physics, Lentivirus, Organisms, Biology and Life Sciences, Proteins, HIV, Medical Microbiology, Viral Pathogens, Viruses, Physical Sciences, HIV-1, Pathogens

Abstract

A comprehensive understanding of the regions on HIV-1 envelope trimers targeted by broadly neutralizing antibodies may contribute to rational design of an HIV-1 vaccine. We previously identified a participant in the CAPRISA cohort, CAP248, who developed trimer-specific antibodies capable of neutralizing 60% of heterologous viruses at three years post-infection. Here, we report the isolation by B cell culture of monoclonal antibody CAP248-2B, which targets a novel membrane proximal epitope including elements of gp120 and gp41. Despite low maximum inhibition plateaus, often below 50% inhibitory concentrations, the breadth of CAP248-2B significantly correlated with donor plasma. Site-directed mutagenesis, X-ray crystallography, and negative-stain electron microscopy 3D reconstructions revealed how CAP248-2B recognizes a cleavage-dependent epitope that includes the gp120 C terminus. While this epitope is distinct, it overlapped in parts of gp41 with the epitopes of broadly neutralizing antibodies PGT151, VRC34, 35O22, 3BC315, and 10E8. CAP248-2B has a conformationally variable paratope with an unusually long 19 amino acid light chain third complementarity determining region. Two phenylalanines at the loop apex were predicted by docking and mutagenesis data to interact with the viral membrane. Neutralization by CAP248-2B is not dependent on any single glycan proximal to its epitope, and low neutralization plateaus could not be completely explained by N- or O-linked glycosylation pathway inhibitors, furin co-transfection, or pre-incubation with soluble CD4. Viral escape from CAP248-2B involved a cluster of rare mutations in the gp120-gp41 cleavage sites. Simultaneous introduction of these mutations into heterologous viruses abrogated neutralization by CAP248-2B, but enhanced neutralization sensitivity to 35O22, 4E10, and 10E8 by 10-100-fold. Altogether, this study expands the region of the HIV-1 gp120-gp41 quaternary interface that is a target for broadly neutralizing antibodies and identifies a set of mutations in the gp120 C terminus that exposes the membrane-proximal external region of gp41, with potential utility in HIV vaccine design.

Published

2017

23. Select gp120 V2 domain specific antibodies derived from HIV and SIV infection and vaccination inhibit gp120 binding to α4β7

Author

Lertjuthaporn, Sakaorat, primary, Cicala, Claudia, additional, Van Ryk, Donald, additional, Liu, Matthew, additional, Yolitz, Jason, additional, Wei, Danlan, additional, Nawaz, Fatima, additional, Doyle, Allison, additional, Horowitch, Brooke, additional, Park, Chung, additional, Lu, Shan, additional, Lou, Yang, additional, Wang, Shixia, additional, Pan, Ruimin, additional, Jiang, Xunqing, additional, Villinger, Francois, additional, Byrareddy, Siddappa N., additional, Santangelo, Philip J., additional, Morris, Lynn, additional, Wibmer, Constantinos Kurt, additional, Biris, Kristin, additional, Mason, Rosemarie D., additional, Gorman, Jason, additional, Hiatt, Joseph, additional, Martinelli, Elena, additional, Roederer, Mario, additional, Fujikawa, Dai, additional, Gorini, Giacomo, additional, Franchini, Genoveffa, additional, Arakelyan, Anush, additional, Ansari, Aftab A., additional, Pattanapanyasat, Kovit, additional, Kong, Xiang-Peng, additional, Fauci, Anthony S., additional, and Arthos, James, additional

Published

2018

24. Structure and Recognition of a Novel HIV-1 gp120-gp41 Interface Antibody that Caused MPER Exposure through Viral Escape

Author

Wibmer, Constantinos Kurt, primary, Gorman, Jason, additional, Ozorowski, Gabriel, additional, Bhiman, Jinal N., additional, Sheward, Daniel J., additional, Elliott, Debra H., additional, Rouelle, Julie, additional, Smira, Ashley, additional, Joyce, M. Gordon, additional, Ndabambi, Nonkululeko, additional, Druz, Aliaksandr, additional, Asokan, Mangai, additional, Burton, Dennis R., additional, Connors, Mark, additional, Abdool Karim, Salim S., additional, Mascola, John R., additional, Robinson, James E., additional, Ward, Andrew B., additional, Williamson, Carolyn, additional, Kwong, Peter D., additional, Morris, Lynn, additional, and Moore, Penny L., additional

Published

2017

25. Structure of an N276-Dependent HIV-1 Neutralizing Antibody Targeting a Rare V5 Glycan Hole Adjacent to the CD4 Binding Site

Author

Wibmer, Constantinos Kurt, primary, Gorman, Jason, additional, Anthony, Colin S., additional, Mkhize, Nonhlanhla N., additional, Druz, Aliaksandr, additional, York, Talita, additional, Schmidt, Stephen D., additional, Labuschagne, Phillip, additional, Louder, Mark K., additional, Bailer, Robert T., additional, Abdool Karim, Salim S., additional, Mascola, John R., additional, Williamson, Carolyn, additional, Moore, Penny L., additional, Kwong, Peter D., additional, and Morris, Lynn, additional

Published

2016

26. New Member of the V1V2-Directed CAP256-VRC26 Lineage That Shows Increased Breadth and Exceptional Potency

Author

Doria-Rose, Nicole A., primary, Bhiman, Jinal N., additional, Roark, Ryan S., additional, Schramm, Chaim A., additional, Gorman, Jason, additional, Chuang, Gwo-Yu, additional, Pancera, Marie, additional, Cale, Evan M., additional, Ernandes, Michael J., additional, Louder, Mark K., additional, Asokan, Mangaiarkarasi, additional, Bailer, Robert T., additional, Druz, Aliaksandr, additional, Fraschilla, Isabella R., additional, Garrett, Nigel J., additional, Jarosinski, Marissa, additional, Lynch, Rebecca M., additional, McKee, Krisha, additional, O'Dell, Sijy, additional, Pegu, Amarendra, additional, Schmidt, Stephen D., additional, Staupe, Ryan P., additional, Sutton, Matthew S., additional, Wang, Keyun, additional, Wibmer, Constantinos Kurt, additional, Haynes, Barton F., additional, Abdool-Karim, Salim, additional, Shapiro, Lawrence, additional, Kwong, Peter D., additional, Moore, Penny L., additional, Morris, Lynn, additional, and Mascola, John R., additional

Published

2016

27. Select gp120 V2 domain specific antibodies derived from HIV and SIV infection and vaccination inhibit gp120 binding to α4β7.

Author

Lertjuthaporn, Sakaorat, Cicala, Claudia, Van Ryk, Donald, Liu, Matthew, Yolitz, Jason, Wei, Danlan, Nawaz, Fatima, Doyle, Allison, Horowitch, Brooke, Park, Chung, Lu, Shan, Lou, Yang, Wang, Shixia, Pan, Ruimin, Jiang, Xunqing, Villinger, Francois, Byrareddy, Siddappa N., Santangelo, Philip J., Morris, Lynn, and Wibmer, Constantinos Kurt

Subjects

PATHOGENIC microorganisms, RECOMBINANT proteins, PEPTIDES, PROTEINS, VACCINES

Abstract

The GI tract is preferentially targeted during acute/early HIV-1 infection. Consequent damage to the gut plays a central role in HIV pathogenesis. The basis for preferential targeting of gut tissues is not well defined. Recombinant proteins and synthetic peptides derived from HIV and SIV gp120 bind directly to integrin α4β7, a gut-homing receptor. Using both cell-surface expressed α4β7 and a soluble α4β7 heterodimer we demonstrate that its specific affinity for gp120 is similar to its affinity for MAdCAM (its natural ligand). The gp120 V2 domain preferentially engages extended forms of α4β7 in a cation -sensitive manner and is inhibited by soluble MAdCAM. Thus, V2 mimics MAdCAM in the way that it binds to α4β7, providing HIV a potential mechanism to discriminate between functionally distinct subsets of lymphocytes, including those with gut-homing potential. Furthermore, α4β7 antagonists developed for the treatment of inflammatory bowel diseases, block V2 binding to α4β7. A 15-amino acid V2 -derived peptide is sufficient to mediate binding to α4β7. It includes the canonical LDV/I α4β7 binding site, a cryptic epitope that lies 7–9 amino acids amino terminal to the LDV/I, and residues K169 and I181. These two residues were identified in a sieve analysis of the RV144 vaccine trial as sites of vaccine -mediated immune pressure. HIV and SIV V2 mAbs elicited by both vaccination and infection that recognize this peptide block V2-α4β7 interactions. These mAbs recognize conformations absent from the β- barrel presented in a stabilized HIV SOSIP gp120/41 trimer. The mimicry of MAdCAM-α4β7 interactions by V2 may influence early events in HIV infection, particularly the rapid seeding of gut tissues, and supports the view that HIV replication in gut tissue is a central feature of HIV pathogenesis. [ABSTRACT FROM AUTHOR]

Published

2018

28. South African HIV-1 subtype C transmitted variants with a specific V2 motif show higher dependence on α4β7 for replication

Author

Richardson, Simone I, primary, Gray, Elin S, additional, Mkhize, Nonhlanhla N, additional, Sheward, Daniel J, additional, Lambson, Bronwen E, additional, Wibmer, Constantinos Kurt, additional, Masson, Lindi, additional, Werner, Lise, additional, Garrett, Nigel, additional, Passmore, Jo-Ann S, additional, Karim, Quarraisha Abdool, additional, Karim, Salim S Abdool, additional, Williamson, Carolyn, additional, Moore, Penny L, additional, and Morris, Lynn, additional

Published

2015

29. HIV broadly neutralizing antibody targets

Author

Wibmer, Constantinos Kurt, primary, Moore, Penny L., additional, and Morris, Lynn, additional

Published

2015

30. Viral Escape Pathways from Broadly Neutralising Antibodies Targeting the HIV Envelope Cleavage Site Enhance MPER Mediated Neutralisation

Author

Wibmer, Constantinos Kurt, primary, Sheward, Daniel J., additional, Bhiman, Jinal N., additional, Ndabambi, Nonkululeko, additional, Elliot, Debra H., additional, Rouelle, Julie, additional, Smira, Ashley, additional, Karim, Salim S. Abdool, additional, Robinson, James E., additional, Morris, Lynn, additional, Williamson, Carolyn, additional, and Moore, Penny L., additional

Published

2014

31. Maturation of Broadly Neutralizing V1V2-directed Antibodies in the Context of Autologous Viral Escape

Author

Bhiman, Jinal N., primary, Doria-Rose, Nicole A., additional, Wibmer, Constantinos Kurt, additional, Sheward, Daniel J., additional, Williamson, Carolyn, additional, Karim, Salim S. Abdool, additional, Kwong, Peter D., additional, Mascola, John R., additional, Morris, Lynn, additional, and Moore, Penny L., additional

Published

2014

32. Viral Escape from HIV-1 Neutralizing Antibodies Drives Increased Plasma Neutralization Breadth through Sequential Recognition of Multiple Epitopes and Immunotypes

Author

Wibmer, Constantinos Kurt, primary, Bhiman, Jinal N., additional, Gray, Elin S., additional, Tumba, Nancy, additional, Abdool Karim, Salim S., additional, Williamson, Carolyn, additional, Morris, Lynn, additional, and Moore, Penny L., additional

Published

2013

33. UCLA1, a Synthetic Derivative of a gp120 RNA Aptamer, Inhibits Entry of Human Immunodeficiency Virus Type 1 Subtype C

Author

Mufhandu, Hazel T., primary, Gray, Elin S., additional, Madiga, Maphuti C., additional, Tumba, Nancy, additional, Alexandre, Kabamba B., additional, Khoza, Thandeka, additional, Wibmer, Constantinos Kurt, additional, Moore, Penny L., additional, Morris, Lynn, additional, and Khati, Makobetsa, additional

Published

2012

34. Polyclonal B Cell Responses to Conserved Neutralization Epitopes in a Subset of HIV-1-Infected Individuals

Author

Tomaras, Georgia D., primary, Binley, James M., additional, Gray, Elin S., additional, Crooks, Emma T., additional, Osawa, Keiko, additional, Moore, Penny L., additional, Tumba, Nancy, additional, Tong, Tommy, additional, Shen, Xiaoying, additional, Yates, Nicole L., additional, Decker, Julie, additional, Wibmer, Constantinos Kurt, additional, Gao, Feng, additional, Alam, S. Munir, additional, Easterbrook, Philippa, additional, Abdool Karim, Salim, additional, Kamanga, Gift, additional, Crump, John A., additional, Cohen, Myron, additional, Shaw, George M., additional, Mascola, John R., additional, Haynes, Barton F., additional, Montefiori, David C., additional, and Morris, Lynn, additional

Published

2011

35. Isolation of a Monoclonal Antibody That Targets the Alpha-2 Helix of gp120 and Represents the Initial Autologous Neutralizing-Antibody Response in an HIV-1 Subtype C-Infected Individual

Author

Gray, Elin S., primary, Moody, M. Anthony, additional, Wibmer, Constantinos Kurt, additional, Chen, Xi, additional, Marshall, Dawn, additional, Amos, Joshua, additional, Moore, Penny L., additional, Foulger, Andrew, additional, Yu, Jae-Sung, additional, Lambson, Bronwen, additional, Abdool Karim, Salim, additional, Whitesides, John, additional, Tomaras, Georgia D., additional, Haynes, Barton F., additional, Morris, Lynn, additional, and Liao, Hua-Xin, additional

Published

2011

36. Antibody Specificities Associated with Neutralization Breadth in Plasma from Human Immunodeficiency Virus Type 1 Subtype C-Infected Blood Donors

Author

Gray, Elin S., primary, Taylor, Natasha, additional, Wycuff, Diane, additional, Moore, Penny L., additional, Tomaras, Georgia D., additional, Wibmer, Constantinos Kurt, additional, Puren, Adrian, additional, DeCamp, Allan, additional, Gilbert, Peter B., additional, Wood, Blake, additional, Montefiori, David C., additional, Binley, James M., additional, Shaw, George M., additional, Haynes, Barton F., additional, Mascola, John R., additional, and Morris, Lynn, additional

Published

2009

37. Identification of broadly neutralizing antibody epitopes in the HIV-1 envelope glycoprotein using evolutionary models.

Author

Lacerda, Miguel, Moore, Penny L., Ngandu, Nobubelo K., Seaman, Michael, Gray, Elin S., Murrell, Ben, Krishnamoorthy, Mohan, Nonyane, Molati, Madiga, Maphuti, Wibmer, Constantinos Kurt, Sheward, Daniel, Bailer, Robert T., Gao, Hongmei, Greene, Kelli M., Karim, Salim S. Abdool, Mascola, John R., Korber, Bette T. M., Montefiori, David C., Morris, Lynn, and Williamson, Carolyn

Subjects

IMMUNOGLOBULINS, GENETIC mutation, VACCINATION, GLYCOPROTEINS, AMINO acids

Abstract

Background Identification of the epitopes targeted by antibodies that can neutralize diverse HIV-1 strains can provide important clues for the design of a preventative vaccine. Methods We have developed a computational approach that can identify key amino acids within the HIV-1 envelope glycoprotein that influence sensitivity to broadly cross-neutralizing antibodies. Given a sequence alignment and neutralization titers for a panel of viruses, the method works by fitting a phylogenetic model that allows the amino acid frequencies at each site to depend on neutralization sensitivities. Sites at which viral evolution influences neutralization sensitivity were identified using Bayes factors (BFs) to compare the fit of this model to that of a null model in which sequences evolved independently of antibody sensitivity. Conformational epitopes were identified with a Metropolis algorithm that searched for a cluster of sites with large Bayes factors on the tertiary structure of the viral envelope. Results We applied our method to ID50 neutralization data generated from seven HIV-1 subtype C serum samples with neutralization breadth that had been tested against a multi-clade panel of 225 pseudoviruses for which envelope sequences were also available. For each sample, between two and four sites were identified that were strongly associated with neutralization sensitivity (2ln(BF) > 6), a subset of which were experimentally confirmed using sitedirected mutagenesis. Conclusions Our results provide strong support for the use of evolutionary models applied to crosssectional viral neutralization data to identify the epitopes of serum antibodies that confer neutralization breadth. [ABSTRACT FROM AUTHOR]

Published

2013

38. Structure and Recognition of a Novel HIV-1 gp120-gp41 Interface Antibody that Caused MPER Exposure through Viral Escape

Author

Wibmer, Constantinos Kurt, Gorman, Jason, Ozorowski, Gabriel, Bhiman, Jinal N., Sheward, Daniel J., Elliott, Debra H., Rouelle, Julie, Smira, Ashley, Joyce, M. Gordon, Ndabambi, Nonkululeko, Druz, Aliaksandr, Asokan, Mangai, Burton, Dennis R., Karim, Salim Abdool, Connors, Mark, Mascola, John R., Robinson, James E., Ward, Andrew B., Williamson, Carolyn, Kwong, Peter D., Morris, Lynn, and Moore, Penny L.

Subjects

viruses, Vaccines--Design, AIDS vaccines, Biochemistry, 3. Good health, HIV infections

Abstract

A comprehensive understanding of the regions on HIV-1 envelope trimers targeted by broadly neutralizing antibodies may contribute to rational design of an HIV-1 vaccine. We previously identified a participant in the CAPRISA cohort, CAP248, who developed trimerspecific antibodies capable of neutralizing 60% of heterologous viruses at three years postinfection. Here, we report the isolation by B cell culture of monoclonal antibody CAP248-2B, which targets a novel membrane proximal epitope including elements of gp120 and gp41. Despite low maximum inhibition plateaus, often below 50% inhibitory concentrations, the breadth of CAP248-2B significantly correlated with donor plasma. Site-directed mutagenesis, X-ray crystallography, and negative-stain electron microscopy 3D reconstructions revealed how CAP248-2B recognizes a cleavage-dependent epitope that includes the gp120 C terminus. While this epitope is distinct, it overlapped in parts of gp41 with the epitopes of broadly neutralizing antibodies PGT151, VRC34, 35O22, 3BC315, and 10E8. CAP248-2B has a conformationally variable paratope with an unusually long 19 amino acid light chain third complementarity determining region. Two phenylalanines at the loop apex were predicted by docking and mutagenesis data to interact with the viral membrane.Neutralization by CAP248-2B is not dependent on any single glycan proximal to its epitope, and low neutralization plateaus could not be completely explained by N- or O-linked glycosylation pathway inhibitors, furin co-transfection, or pre-incubation with soluble CD4. Viral escape from CAP248-2B involved a cluster of rare mutations in the gp120-gp41 cleavage sites. Simultaneous introduction of these mutations into heterologous viruses abrogated neutralization by CAP248-2B, but enhanced neutralization sensitivity to 35O22, 4E10, and 10E8 by 10-100-fold. Altogether, this study expands the region of the HIV-1 gp120-gp41 quaternary interface that is a target for broadly neutralizing antibodies and identifies a set of mutations in the gp120 C terminus that exposes the membrane-proximal external region of gp41, with potential utility in HIV vaccine design.

39. Maturation of Broadly Neutralizing V1V2-directed Antibodies in the Context of Autologous Viral Escape.

Author

Doria-Rose, Nicole A., Wibmer, Constantinos Kurt, Sheward, Daniel J., Williamson, Carolyn, Karim, Salim S. Abdool, Kwong, Peter D., Mascola, John R., Morris, Lynn, and Moore, Penny L.

Abstract

An abstract of the article "Maturation of Broadly Neutralizing V1V2-directed Antibodies in the Context of Autologous Viral Escape" by Jinal N. Bhiman, Nicole A. Doria-Rose, Constantinos Kurt Wibmer and colleagues is presented.

Published

2014

40. Select gp120 V2 domain specific antibodies derived from HIV and SIV infection and vaccination inhibit gp120 binding to α4β7.

Author

Lertjuthaporn, Sakaorat, Cicala, Claudia, Van Ryk, Donald, Liu, Matthew, Yolitz, Jason, Wei, Danlan, Nawaz, Fatima, Doyle, Allison, Horowitch, Brooke, Park, Chung, Lu, Shan, Lou, Yang, Wang, Shixia, Pan, Ruimin, Jiang, Xunqing, Villinger, Francois, Byrareddy, Siddappa N., Santangelo, Philip J., Morris, Lynn, and Wibmer, Constantinos Kurt

Subjects

*PATHOGENIC microorganisms, *RECOMBINANT proteins, *PEPTIDES, *PROTEINS, *VACCINES

Abstract

The GI tract is preferentially targeted during acute/early HIV-1 infection. Consequent damage to the gut plays a central role in HIV pathogenesis. The basis for preferential targeting of gut tissues is not well defined. Recombinant proteins and synthetic peptides derived from HIV and SIV gp120 bind directly to integrin α4β7, a gut-homing receptor. Using both cell-surface expressed α4β7 and a soluble α4β7 heterodimer we demonstrate that its specific affinity for gp120 is similar to its affinity for MAdCAM (its natural ligand). The gp120 V2 domain preferentially engages extended forms of α4β7 in a cation -sensitive manner and is inhibited by soluble MAdCAM. Thus, V2 mimics MAdCAM in the way that it binds to α4β7, providing HIV a potential mechanism to discriminate between functionally distinct subsets of lymphocytes, including those with gut-homing potential. Furthermore, α4β7 antagonists developed for the treatment of inflammatory bowel diseases, block V2 binding to α4β7. A 15-amino acid V2 -derived peptide is sufficient to mediate binding to α4β7. It includes the canonical LDV/I α4β7 binding site, a cryptic epitope that lies 7–9 amino acids amino terminal to the LDV/I, and residues K169 and I181. These two residues were identified in a sieve analysis of the RV144 vaccine trial as sites of vaccine -mediated immune pressure. HIV and SIV V2 mAbs elicited by both vaccination and infection that recognize this peptide block V2-α4β7 interactions. These mAbs recognize conformations absent from the β- barrel presented in a stabilized HIV SOSIP gp120/41 trimer. The mimicry of MAdCAM-α4β7 interactions by V2 may influence early events in HIV infection, particularly the rapid seeding of gut tissues, and supports the view that HIV replication in gut tissue is a central feature of HIV pathogenesis. [ABSTRACT FROM AUTHOR]

Published

2018

41. The Neutralization Breadth of HIV-1 Develops Incrementally over Four Years and Is Associated with CD4+ T Cell Decline and High Viral Load during Acute Infection.

Author

Gray, Elin S., Madiga, Maphuti C., Hermanus, Tandile, Moore, Penny L., Wibmer, Constantinos Kurt, Tumba, Nancy L., Werner, Lise, Mlisana, Koleka, Sibeko, Sengeziwe, Williamson, Carolyn, Abdool Karim, Salim S., and Morris, Lynn

Subjects

*HIV infections, *T cells, *SERUM, *MULTIVARIATE analysis, *IMMUNOGLOBULINS

Abstract

An understanding of how broadly neutralizing activity develops in HIV-1-infected individuals is needed to guide vaccine design and immunization strategies. Here we used a large panel of 44 HIV-1 envelope variants (subtypes A, B, and C) to evaluate the presence of broadly neutralizing antibodies in serum samples obtained 3 years after seroconversion from 40 women enrolled in the CAPRISA 002 acute infection cohort. Seven of 40 participants had serum antibodies that neutralized more than 40% of viruses tested and were considered to have neutralization breadth. Among the samples with breadth, CAP257 serum neutralized 82% (36/44 variants) of the panel, while CAP256 serum neutralized 77% (33/43 variants) of the panel. Analysis of longitudinal samples showed that breadth developed gradually starting from year 2, with the number of viruses neutralized as well as the antibody titer increasing over time. Interestingly, neutralization breadth peaked at 4 years postinfection, with no increase thereafter. The extent of cross-neutralizing activity correlated with CD4+ T cell decline, viral load, and CD4+ T cell count at 6 months postinfection but not at later time points, suggesting that early events set the stage for the development of breadth. However, in a multivariate analysis, CD4 decline was the major driver of this association, as viral load was not an independent predictor of breadth. Mapping of the epitopes targeted by cross-neutralizing antibodies revealed that in one individual these antibodies recognized the membrane-proximal external region (MPER), while in two other individuals, cross-neutralizing activity was adsorbed by monomeric gp120 and targeted epitopes that involved the N-linked glycan at position 332 in the C3 region. Serum antibodies from the other four participants targeted quaternary epitopes, at least 2 of which were PG9/16-like and depended on the N160 and/or L165 residue in the V2 region. These data indicate that fewer than 20% of HIV-1 subtype C-infected individuals develop antibodies with cross-neutralizing activity after 3 years of infection and that these antibodies target different regions of the HIV-1 envelope, including as yet uncharacterized epitopes. [ABSTRACT FROM AUTHOR]

Published

2011

42. SARS-CoV-2 501Y.V2 (B.1.351) elicits cross-reactive neutralizing antibodies.

Author

Moyo-Gwete T, Madzivhandila M, Makhado Z, Ayres F, Mhlanga D, Oosthuysen B, Lambson BE, Kgagudi P, Tegally H, Iranzadeh A, Doolabh D, Tyers L, Chinhoyi LR, Mennen M, Skelem S, Marais G, Wibmer CK, Bhiman JN, Ueckermann V, Rossouw T, Boswell M, de Oliveira T, Williamson C, Burgers WA, Ntusi N, Morris L, and Moore PL

Abstract

Neutralization escape by SARS-CoV-2 variants, as has been observed in the 501Y.V2 (B.1.351) variant, has impacted the efficacy of first generation COVID-19 vaccines. Here, the antibody response to the 501Y.V2 variant was examined in a cohort of patients hospitalized with COVID-19 in early 2021 - when over 90% of infections in South Africa were attributed to 501Y.V2. Robust binding and neutralizing antibody titers to the 501Y.V2 variant were detected and these binding antibodies showed high levels of cross-reactivity for the original variant, from the first wave. In contrast to an earlier study where sera from individuals infected with the original variant showed dramatically reduced potency against 501Y.V2, sera from 501Y.V2-infected patients maintained good cross-reactivity against viruses from the first wave. Furthermore, sera from 501Y.V2-infected patients also neutralized the 501Y.V3 (P.1) variant first described in Brazil, and now circulating globally. Collectively these data suggest that the antibody response in patients infected with 501Y.V2 has a broad specificity and that vaccines designed with the 501Y.V2 sequence may elicit more cross-reactive responses.

Published

2021

43. SARS-CoV-2 501Y.V2 escapes neutralization by South African COVID-19 donor plasma.

Author

Wibmer CK, Ayres F, Hermanus T, Madzivhandila M, Kgagudi P, Oosthuysen B, Lambson BE, de Oliveira T, Vermeulen M, van der Berg K, Rossouw T, Boswell M, Ueckermann V, Meiring S, von Gottberg A, Cohen C, Morris L, Bhiman JN, and Moore PL

Abstract

SARS-CoV-2 501Y.V2 (B.1.351), a novel lineage of coronavirus causing COVID-19, contains substitutions in two immunodominant domains of the spike protein. Here, we show that pseudovirus expressing 501Y.V2 spike protein completely escapes three classes of therapeutically relevant antibodies. This pseudovirus also exhibits substantial to complete escape from neutralization, but not binding, by convalescent plasma. These data highlight the prospect of reinfection with antigenically distinct variants and foreshadows reduced efficacy of spike-based vaccines., Competing Interests: Competing interests The authors declare that they have no competing interests.

Published

2021

44. The V2 loop of HIV gp120 delivers costimulatory signals to CD4 + T cells through Integrin α 4 β 7 and promotes cellular activation and infection.

Author

Goes LR, Sajani A, Sivro A, Olowojesiku R, Ray JC, Perrone I, Yolitz J, Girard A, Leyre L, Wibmer CK, Morris L, Gorini G, Franchini G, Mason RD, Roederer M, Mehandru S, Soares MA, Cicala C, Fauci AS, and Arthos J

Subjects

Anti-HIV Agents immunology, Anti-HIV Agents pharmacology, Antibodies, Monoclonal immunology, Antibodies, Monoclonal pharmacology, Antibodies, Neutralizing immunology, CD4-Positive T-Lymphocytes drug effects, CD4-Positive T-Lymphocytes metabolism, Cell Proliferation, Epitopes immunology, Epitopes metabolism, HIV Envelope Protein gp120 chemistry, HIV Envelope Protein gp120 immunology, HIV Infections pathology, HIV Infections virology, Host-Pathogen Interactions physiology, Humans, Lymphocyte Activation, Protein Domains, Signal Transduction, Simian Immunodeficiency Virus immunology, Tretinoin pharmacology, CD4-Positive T-Lymphocytes virology, HIV Envelope Protein gp120 metabolism, HIV Infections metabolism, Integrins metabolism

Abstract

Acute HIV infection is characterized by rapid viral seeding of immunologic inductive sites in the gut followed by the severe depletion of gut CD4 + T cells. Trafficking of α 4 β 7 -expressing lymphocytes to the gut is mediated by MAdCAM, the natural ligand of α 4 β 7 that is expressed on gut endothelial cells. MAdCAM signaling through α 4 β 7 costimulates CD4 + T cells and promotes HIV replication. Similar to MAdCAM, the V2 domain of the gp120 HIV envelope protein binds to α 4 β 7 In this study, we report that gp120 V2 shares with MAdCAM the capacity to signal through α 4 β 7 resulting in CD4 + T cell activation and proliferation. As with MAdCAM-mediated costimulation, cellular activation induced by gp120 V2 is inhibited by anti-α 4 β 7 monoclonal antibodies (mAbs). It is also inhibited by anti-V2 domain antibodies including nonneutralizing mAbs that recognize an epitope in V2 that has been linked to reduced risk of acquisition in the RV144 vaccine trial. The capacity of the V2 domain of gp120 to mediate signaling through α 4 β 7 likely impacts early events in HIV infection. The capacity of nonneutralizing V2 antibodies to block this activity reveals a previously unrecognized mechanism whereby such antibodies might impact HIV transmission and pathogenesis., Competing Interests: The authors declare no competing interest.

Published

2020

45. New Member of the V1V2-Directed CAP256-VRC26 Lineage That Shows Increased Breadth and Exceptional Potency.

Author

Doria-Rose NA, Bhiman JN, Roark RS, Schramm CA, Gorman J, Chuang GY, Pancera M, Cale EM, Ernandes MJ, Louder MK, Asokan M, Bailer RT, Druz A, Fraschilla IR, Garrett NJ, Jarosinski M, Lynch RM, McKee K, O'Dell S, Pegu A, Schmidt SD, Staupe RP, Sutton MS, Wang K, Wibmer CK, Haynes BF, Abdool-Karim S, Shapiro L, Kwong PD, Moore PL, Morris L, and Mascola JR

Subjects

Antibodies, Neutralizing genetics, Antibodies, Neutralizing isolation & purification, Epitope Mapping, Female, HIV Antibodies genetics, HIV Antibodies isolation & purification, HIV Envelope Protein gp120 immunology, Humans, Inhibitory Concentration 50, Molecular Sequence Data, Sequence Analysis, DNA, Antibodies, Neutralizing immunology, Cross Reactions, HIV Antibodies immunology, HIV Infections immunology, HIV Infections virology, HIV-1 immunology

Abstract

Unlabelled: The epitopes defined by HIV-1 broadly neutralizing antibodies (bNAbs) are valuable templates for vaccine design, and studies of the immunological development of these antibodies are providing insights for vaccination strategies. In addition, the most potent and broadly reactive of these bNAbs have potential for clinical use. We previously described a family of 12 V1V2-directed neutralizing antibodies, CAP256-VRC26, isolated from an HIV-1 clade C-infected donor at years 1, 2, and 4 of infection (N. A. Doria-Rose et al., Nature 509:55-62, 2014, http://dx.doi.org/10.1038/nature13036). Here, we report on the isolation and characterization of new members of the family mostly obtained at time points of peak serum neutralization breadth and potency. Thirteen antibodies were isolated from B cell culture, and eight were isolated using trimeric envelope probes for differential single B cell sorting. One of the new antibodies displayed a 10-fold greater neutralization potency than previously published lineage members. This antibody, CAP256-VRC26.25, neutralized 57% of diverse clade viral isolates and 70% of clade C isolates with remarkable potency. Among the viruses neutralized, the median 50% inhibitory concentration was 0.001 μg/ml. All 33 lineage members targeted a quaternary epitope focused on V2. While all known bNAbs targeting the V1V2 region interact with the N160 glycan, the CAP256-VRC26 antibodies showed an inverse correlation of neutralization potency with dependence on this glycan. Overall, our results highlight the ongoing evolution within a single antibody lineage and describe more potent and broadly neutralizing members with potential clinical utility, particularly in areas where clade C is prevalent., Importance: Studies of HIV-1 broadly neutralizing antibodies (bNAbs) provide valuable information for vaccine design, and the most potent and broadly reactive of these bNAbs have potential for clinical use. We previously described a family of V1V2-directed neutralizing antibodies from an HIV-1 clade C-infected donor. Here, we report on the isolation and characterization of new members of the family mostly obtained at time points of peak serum neutralization breadth and potency. One of the new antibodies, CAP256-VRC26.25, displayed a 10-fold greater neutralization potency than previously described lineage members. It neutralized 57% of diverse clade viral isolates and 70% of clade C isolates with remarkable potency: the median 50% inhibitory concentration was 0.001 μg/ml. Our results highlight the ongoing evolution within a single antibody lineage and describe more potent and broadly neutralizing members with potential clinical utility, particularly in areas where clade C is prevalent., (Copyright © 2015, American Society for Microbiology. All Rights Reserved.)

Published

2015