Literature DB >> 32546606

The Nucleocapsid Protein of SARS-CoV-2: a Target for Vaccine Development.

Noton K Dutta¹, Kaushiki Mazumdar², James T Gordy³.

Abstract

Entities: Disease Gene Species

Keywords: coronavirus disease 2019 (COVID-19); nucleocapsid protein; severe acute respiratory syndrome coronavirus 2 (SARS–CoV-2); vaccine

Mesh：

Substances：
Nucleocapsid Proteins

Year: 2020 PMID： 32546606 PMCID： PMC7307180 DOI： 10.1128/JVI.00647-20

Source DB: PubMed Journal: J Virol ISSN： 0022-538X Impact factor: 5.103

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LETTER

During the current coronavirus disease 2019 (n class="Disease">COVID-19) pandemic caused by severe acute respiratory syndrome coronavirus 2 (SARS–CoV-2), there has been an unprecedented level of global collaboration that has led to a rapid characterization of SARS–CoV-2 (1). Its sequence shares 79.6% identity to SARS–CoV (1, 2), the infectious virus that caused an epidemic in 2003 (2, 3). SARS–CoV-2 has a single-stranded, plus-sense, RNA genome of approximately 30 kb, which includes five major open reading frames encoding nonstructural replicase polyproteins and structural proteins (1), namely, spike (S) (4–6), envelope (E), membrane (M), and nucleocapsid (N) (7), and they are in the same order and of approximately the same sizes as those in SARS-CoV. The SARS–CoV-2 S protein is being used as the leading target antigen in vaccine development (8, 9). However, the complex molecular details of viral entry may lead to complications with the vaccine response, similar to those seen with HIV type 1 (HIV-1) Env protein vaccine efforts (10). The SARS–CoV-2 S gene has 76% amino acid similarity to the n class="Species">SARS-CoV S gene (11), and nonsynonymous mutations developed in the S protein as the SARS-CoV epidemic progressed (12, 13). In contrast, the N gene is more conserved and stable, with 90% amino acid homology and fewer mutations over time (2, 3, 11, 14–16). N proteins of many coronaviruses are highly immunogenic and are expressed abundantly during infection (17). High levels of IgG antibodies against N have been detected in sera from SARS patients (18), and the N protein is a representative antigen for the T-cell response in a vaccine setting, inducing SARS-specific T-cell proliferation and cytotoxic activity (19, 20). We have already shown that the middle or C-terminal region of the SARS-CoV N protein is important for eliciting antibodies against SARS-CoV during the immune response (21–23). New reports have additionally shown that the crystal structure of the SARS–CoV-2 n class="Gene">nucleocapsid protein is similar to those of previously described coronavirus N proteins, but their surface electrostatic potential characteristics are distinct (7). Sheikh et al. studied the factors influencing N gene variations among 13 coronaviruses and how these affect virus-host relationships, reporting a high AT% and low GC% in the nucleotide contents of SARS coronavirus (24). In this issue, Cong et al. (17) used a mouse hepatitis virus (MHV) model to show that the viral nucleocapsid (N) protein contributes to forming helical ribonucleoproteins during the packaging of the RNA genome, regulating viral RNA synthesis during replication and transcription and modulating metabolism in infected subjects. This study complements others that have shown N to have multiple functions (25). It is becoming more evident just how critical this protein is for multiple steps of the viral life cycle. These reports offer important and timely insights relevant to the SARS–CoV-2 N protein, a vaccine target that has some distinct advantages over other potential SARS–CoV-2 antigens. Because of the conservation of the N protein sequence, the expanding knowledge of its genetics and biochemistry, and its strong immunogenicity, the N protein of SARS–CoV-2 should be strongly considered as a vaccine candidate for SARS–CoV-2.

24 in total

1. Identification of a novel coronavirus in patients with severe acute respiratory syndrome.

Authors: Christian Drosten; Stephan Günther; Wolfgang Preiser; Sylvie van der Werf; Hans-Reinhard Brodt; Stephan Becker; Holger Rabenau; Marcus Panning; Larissa Kolesnikova; Ron A M Fouchier; Annemarie Berger; Ana-Maria Burguière; Jindrich Cinatl; Markus Eickmann; Nicolas Escriou; Klaus Grywna; Stefanie Kramme; Jean-Claude Manuguerra; Stefanie Müller; Volker Rickerts; Martin Stürmer; Simon Vieth; Hans-Dieter Klenk; Albert D M E Osterhaus; Herbert Schmitz; Hans Wilhelm Doerr
Journal: N Engl J Med Date: 2003-04-10 Impact factor: 91.245

2. Detection of antibodies against SARS-Coronavirus using recombinant truncated nucleocapsid proteins by ELISA.

Authors: Hyun-Kyoung Lee; Byoung-Hee Lee; Noton Kumar Dutta; Seung-Hyeok Seok; Min-Won Baek; Hui-Young Lee; Dong-Jae Kim; Yi-Rang Na; Kyoung-Jin Noh; Sung-Hoon Park; Hiroaki Kariwa; Mina Nakauchi; Le Quynh Mai; Suk-Jin Heo; Jae-Hak Park
Journal: J Microbiol Biotechnol Date: 2008-10 Impact factor: 2.351

3. The Genome sequence of the SARS-associated coronavirus.

Authors: Marco A Marra; Steven J M Jones; Caroline R Astell; Robert A Holt; Angela Brooks-Wilson; Yaron S N Butterfield; Jaswinder Khattra; Jennifer K Asano; Sarah A Barber; Susanna Y Chan; Alison Cloutier; Shaun M Coughlin; Doug Freeman; Noreen Girn; Obi L Griffith; Stephen R Leach; Michael Mayo; Helen McDonald; Stephen B Montgomery; Pawan K Pandoh; Anca S Petrescu; A Gordon Robertson; Jacqueline E Schein; Asim Siddiqui; Duane E Smailus; Jeff M Stott; George S Yang; Francis Plummer; Anton Andonov; Harvey Artsob; Nathalie Bastien; Kathy Bernard; Timothy F Booth; Donnie Bowness; Martin Czub; Michael Drebot; Lisa Fernando; Ramon Flick; Michael Garbutt; Michael Gray; Allen Grolla; Steven Jones; Heinz Feldmann; Adrienne Meyers; Amin Kabani; Yan Li; Susan Normand; Ute Stroher; Graham A Tipples; Shaun Tyler; Robert Vogrig; Diane Ward; Brynn Watson; Robert C Brunham; Mel Krajden; Martin Petric; Danuta M Skowronski; Chris Upton; Rachel L Roper
Journal: Science Date: 2003-05-01 Impact factor: 47.728

4. A pneumonia outbreak associated with a new coronavirus of probable bat origin.

Authors: Peng Zhou; Xing-Lou Yang; Xian-Guang Wang; Ben Hu; Lei Zhang; Wei Zhang; Hao-Rui Si; Yan Zhu; Bei Li; Chao-Lin Huang; Hui-Dong Chen; Jing Chen; Yun Luo; Hua Guo; Ren-Di Jiang; Mei-Qin Liu; Ying Chen; Xu-Rui Shen; Xi Wang; Xiao-Shuang Zheng; Kai Zhao; Quan-Jiao Chen; Fei Deng; Lin-Lin Liu; Bing Yan; Fa-Xian Zhan; Yan-Yi Wang; Geng-Fu Xiao; Zheng-Li Shi
Journal: Nature Date: 2020-02-03 Impact factor: 69.504

5. Cryo-EM structure of the 2019-nCoV spike in the prefusion conformation.

Authors: Daniel Wrapp; Nianshuang Wang; Kizzmekia S Corbett; Jory A Goldsmith; Ching-Lin Hsieh; Olubukola Abiona; Barney S Graham; Jason S McLellan
Journal: Science Date: 2020-02-19 Impact factor: 47.728

Review 6. Potential Rapid Diagnostics, Vaccine and Therapeutics for 2019 Novel Coronavirus (2019-nCoV): A Systematic Review.

Authors: Junxiong Pang; Min Xian Wang; Ian Yi Han Ang; Sharon Hui Xuan Tan; Ruth Frances Lewis; Jacinta I-Pei Chen; Ramona A Gutierrez; Sylvia Xiao Wei Gwee; Pearleen Ee Yong Chua; Qian Yang; Xian Yi Ng; Rowena Ks Yap; Hao Yi Tan; Yik Ying Teo; Chorh Chuan Tan; Alex R Cook; Jason Chin-Huat Yap; Li Yang Hsu
Journal: J Clin Med Date: 2020-02-26 Impact factor: 4.241

7. Analysis of preferred codon usage in the coronavirus N genes and their implications for genome evolution and vaccine design.

Authors: Abdullah Sheikh; Abdulla Al-Taher; Mohammed Al-Nazawi; Abdullah I Al-Mubarak; Mahmoud Kandeel
Journal: J Virol Methods Date: 2020-01-05 Impact factor: 2.014

8. The development of vaccines against SARS corona virus in mice and SCID-PBL/hu mice.

Authors: Masaji Okada; Yuji Takemoto; Yoshinobu Okuno; Satomi Hashimoto; Shigeto Yoshida; Yukari Fukunaga; Takao Tanaka; Yoko Kita; Sachiko Kuwayama; Yumiko Muraki; Noriko Kanamaru; Hiroko Takai; Chika Okada; Yayoi Sakaguchi; Izumi Furukawa; Kyoko Yamada; Makoto Matsumoto; Tetsuo Kase; Daphne E Demello; J S M Peiris; Pei-Jer Chen; Naoki Yamamoto; Yoshiyuki Yoshinaka; Tatsuji Nomura; Isao Ishida; Shigeru Morikawa; Masato Tashiro; Mitsunori Sakatani
Journal: Vaccine Date: 2005-03-18 Impact factor: 3.641

9. Comparative full-length genome sequence analysis of 14 SARS coronavirus isolates and common mutations associated with putative origins of infection.

Authors: Yi Jun Ruan; Chia Lin Wei; Ai Ling Ee; Vinsensius B Vega; Herve Thoreau; Se Thoe Yun Su; Jer-Ming Chia; Patrick Ng; Kuo Ping Chiu; Landri Lim; Tao Zhang; Chan Kwai Peng; Ean Oon Lynette Lin; Ng Mah Lee; Sin Leo Yee; Lisa F P Ng; Ren Ee Chee; Lawrence W Stanton; Philip M Long; Edison T Liu
Journal: Lancet Date: 2003-05-24 Impact factor: 79.321

10. Structure, Function, and Antigenicity of the SARS-CoV-2 Spike Glycoprotein.

Authors: Alexandra C Walls; Young-Jun Park; M Alejandra Tortorici; Abigail Wall; Andrew T McGuire; David Veesler
Journal: Cell Date: 2020-03-09 Impact factor: 41.582

112 in total

1. Diagnosis of COVID-19, vitality of emerging technologies and preventive measures.

Authors: Muhammad Asif; Yun Xu; Fei Xiao; Yimin Sun
Journal: Chem Eng J Date: 2021-05-07 Impact factor: 13.273

2. Microchip-based structure determination of low-molecular weight proteins using cryo-electron microscopy.

Authors: Michael A Casasanta; G M Jonaid; Liam Kaylor; William Y Luqiu; Maria J Solares; Mariah L Schroen; William J Dearnaley; Jarad Wilson; Madeline J Dukes; Deborah F Kelly
Journal: Nanoscale Date: 2021-04-12 Impact factor: 7.790

3. Induction of Humoral and Cellular Immunity by Intradermal Delivery of SARS-CoV-2 Nucleocapsid Protein Using Dissolvable Microneedles.

Authors: Chaiyaporn Kuwentrai; Jinming Yu; Bao-Zhong Zhang; Ye-Fan Hu; Ying Dou; Hua-Rui Gong; Jian-Dong Huang; Chenjie Xu
Journal: J Immunol Res Date: 2021-05-17 Impact factor: 4.818

Review 4. Review of Current COVID-19 Diagnostics and Opportunities for Further Development.

Authors: Yan Mardian; Herman Kosasih; Muhammad Karyana; Aaron Neal; Chuen-Yen Lau
Journal: Front Med (Lausanne) Date: 2021-05-07

5. Heterogeneity of SARS-CoV-2 virus produced in cell culture revealed by shotgun proteomics and supported by genome sequencing.

Authors: Fabrice Gallais; Olivier Pible; Jean-Charles Gaillard; Stéphanie Debroas; Hélène Batina; Sylvie Ruat; Florian Sandron; Damien Delafoy; Zuzana Gerber; Robert Olaso; Fabienne Gas; Laurent Bellanger; Jean-François Deleuze; Lucia Grenga; Jean Armengaud
Journal: Anal Bioanal Chem Date: 2021-05-20 Impact factor: 4.142

6. Highly specific monoclonal antibodies and epitope identification against SARS-CoV-2 nucleocapsid protein for antigen detection tests.

Authors: Yutaro Yamaoka; Kei Miyakawa; Sundararaj Stanleyraj Jeremiah; Rikako Funabashi; Koji Okudela; Sayaka Kikuchi; Junichi Katada; Atsuhiko Wada; Toshiki Takei; Mayuko Nishi; Kohei Shimizu; Hiroki Ozawa; Shuzo Usuku; Chiharu Kawakami; Nobuko Tanaka; Takeshi Morita; Hiroyuki Hayashi; Hideaki Mitsui; Keita Suzuki; Daisuke Aizawa; Yukihiro Yoshimura; Tomoyuki Miyazaki; Etsuko Yamazaki; Tadaki Suzuki; Hirokazu Kimura; Hideaki Shimizu; Nobuhiko Okabe; Hideki Hasegawa; Akihide Ryo
Journal: Cell Rep Med Date: 2021-05-16

7. The preparation of N-IgY targeting SARS-CoV-2 and its immunomodulation to IFN-γ production in vitro.

Authors: Jinglu Lyu; Lirong Bao; Xin Shen; Caixia Yan; Cheng Zhang; Wei Wei; Yutao Yang; Jia Li; Jiajia Dong; Liying Xiao; Xuedong Zhou; Yan Li
Journal: Int Immunopharmacol Date: 2021-05-19 Impact factor: 5.714

8. A comparison of SARS-CoV-2 nucleocapsid and spike antibody detection using three commercially available automated immunoassays.

Authors: Brad Poore; Robert D Nerenz; Dina Brodis; Charles I Brown; Mark A Cervinski; Jacqueline A Hubbard
Journal: Clin Biochem Date: 2021-06-09 Impact factor: 3.281

Review 9. Environmental Risk Assessment of Recombinant Viral Vector Vaccines against SARS-Cov-2.

Authors: Aline Baldo; Amaya Leunda; Nicolas Willemarck; Katia Pauwels
Journal: Vaccines (Basel) Date: 2021-05-03

10. Profiling SARS-CoV-2 HLA-I peptidome reveals T cell epitopes from out-of-frame ORFs.

Authors: Shira Weingarten-Gabbay; Susan Klaeger; Siranush Sarkizova; Leah R Pearlman; Da-Yuan Chen; Kathleen M E Gallagher; Matthew R Bauer; Hannah B Taylor; W Augustine Dunn; Christina Tarr; John Sidney; Suzanna Rachimi; Hasahn L Conway; Katelin Katsis; Yuntong Wang; Del Leistritz-Edwards; Melissa R Durkin; Christopher H Tomkins-Tinch; Yaara Finkel; Aharon Nachshon; Matteo Gentili; Keith D Rivera; Isabel P Carulli; Vipheaviny A Chea; Abishek Chandrashekar; Cansu Cimen Bozkus; Mary Carrington; Nina Bhardwaj; Dan H Barouch; Alessandro Sette; Marcela V Maus; Charles M Rice; Karl R Clauser; Derin B Keskin; Daniel C Pregibon; Nir Hacohen; Steven A Carr; Jennifer G Abelin; Mohsan Saeed; Pardis C Sabeti
Journal: Cell Date: 2021-06-03 Impact factor: 66.850