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Literature DB >> 34203435

Man-Specific Lectins from Plants, Fungi, Algae and Cyanobacteria, as Potential Blockers for SARS-CoV, MERS-CoV and SARS-CoV-2 (COVID-19) Coronaviruses: Biomedical Perspectives.

Annick Barre¹, Els J M Van Damme², Mathias Simplicien¹, Sophie Le Poder³, Bernard Klonjkowski³, Hervé Benoist¹, David Peyrade⁴, Pierre Rougé¹.

Abstract

Betacoronaviruses, responsible for the "Severe Acute Respiratory Syndrome" (SARS) and the "Middle East Respiratory Syndrome" (MERS), use the spikes protruding from the virion envelope to attach and subsequently infect the host cells. The coronavirus spike (S) proteins contain receptor binding domains (RBD), allowing the specific recognition of either the dipeptidyl peptidase CD23 (MERS-CoV) or the angiotensin-converting enzyme ACE2 (SARS-Cov, SARS-CoV-2) host cell receptors. The heavily glycosylated S protein includes both complex and high-mannose type N-glycans that are well exposed at the surface of the spikes. A detailed analysis of the carbohydrate-binding specificity of mannose-binding lectins from plants, algae, fungi, and bacteria, revealed that, depending on their origin, they preferentially recognize either complex type N-glycans, or high-mannose type N-glycans. Since both complex and high-mannose glycans substantially decorate the S proteins, mannose-specific lectins are potentially useful glycan probes for targeting the SARS-CoV, MERS-CoV, and SARS-CoV-2 virions. Mannose-binding legume lectins, like pea lectin, and monocot mannose-binding lectins, like snowdrop lectin or the algal lectin griffithsin, which specifically recognize complex N-glycans and high-mannose glycans, respectively, are particularly adapted for targeting coronaviruses. The biomedical prospects of targeting coronaviruses with mannose-specific lectins are wide-ranging including detection, immobilization, prevention, and control of coronavirus infection.

Entities: CellLine Chemical Disease Gene Mutation Species

Keywords: COVID-19; MERS-CoV; SARS-CoV; SARS-CoV-2; algae lectins; artocarpin; biomedical applications; coronaviruses; cyanobacteria lectins; fungi lectins; mannose-specific lectins; pea lectin; plant lectins; snowdrop lectin

Mesh：

Substances：

Year: 2021 PMID： 34203435 DOI： 10.3390/cells10071619

Source DB: PubMed Journal: Cells ISSN： 2073-4409 Impact factor: 6.600

150 in total

1. Purification, characterization, and molecular cloning of lectin from winter buds of Lysichiton camtschatcensis (L.) Schott.

Authors: Yuichiro Nakagawa; Hikaru Sakamoto; Hiroaki Tateno; Jun Hirabayashi; Suguru Oguri
Journal: Biosci Biotechnol Biochem Date: 2012-01-07 Impact factor: 2.043

2. Structural analysis of the jacalin-related lectin MornigaM from the black mulberry (Morus nigra) in complex with mannose.

Authors: Anja Rabijns; Annick Barre; Els J M Van Damme; Willy J Peumans; Camiel J De Ranter; Pierre Rougé
Journal: FEBS J Date: 2005-07 Impact factor: 5.542

3. The evolutionarily conserved family of cyanovirin-N homologs: structures and carbohydrate specificity.

Authors: Leonardus M I Koharudin; Arturo R Viscomi; Jun-Goo Jee; Simone Ottonello; Angela M Gronenborn
Journal: Structure Date: 2008-04 Impact factor: 5.006

4. Crystal structure of the lectin of Camptosema pedicellatum: implications of a conservative substitution at the hydrophobic subsite.

Authors: Claudener Souza Teixeira; Helton Colares da Silva; Tales Rocha de Moura; Francisco N Pereira-Júnior; Kyria Santiago do Nascimento; Celso Shiniti Nagano; Alexandre Holanda Sampaio; Plinio Delatorre; Bruno Anderson Matias Rocha; Benildo Sousa Cavada
Journal: J Biochem Date: 2012-05-02 Impact factor: 3.387

5. Structural basis of flocculin-mediated social behavior in yeast.

Authors: Maik Veelders; Stefan Brückner; Dimitri Ott; Carlo Unverzagt; Hans-Ulrich Mösch; Lars-Oliver Essen
Journal: Proc Natl Acad Sci U S A Date: 2010-12-13 Impact factor: 11.205

6. Purification, characterization, molecular cloning, and expression of novel members of jacalin-related lectins from rhizomes of the true fern Phlebodium aureum (L) J. Smith (Polypodiaceae).

Authors: Hiroaki Tateno; Harry C Winter; Jerzy Petryniak; Irwin J Goldstein
Journal: J Biol Chem Date: 2003-01-21 Impact factor: 5.157

7. The closely related homomeric and heterodimeric mannose-binding lectins from garlic are encoded by one-domain and two-domain lectin genes, respectively.

Authors: E J van Damme; K Smeets; S Torrekens; F van Leuven; I J Goldstein; W J Peumans
Journal: Eur J Biochem Date: 1992-06-01

8. Structural characterization of two isolectins from the marine red alga Solieria filiformis (Kützing) P.W. Gabrielson and their anticancer effect on MCF-7 breast cancer cells.

Authors: Renata Pinheiro Chaves; Suzete Roberta da Silva; Luiz Gonzaga Nascimento Neto; Romulo Farias Carneiro; André Luis Coelho da Silva; Alexandre Holanda Sampaio; Bruno Lopes de Sousa; Maria Guadalupe Cabral; Paula Alexandra Videira; Edson Holanda Teixeira; Celso Shiniti Nagano
Journal: Int J Biol Macromol Date: 2017-09-29 Impact factor: 6.953

9. Broad-spectrum in vitro activity and in vivo efficacy of the antiviral protein griffithsin against emerging viruses of the family Coronaviridae.

Authors: Barry R O'Keefe; Barbara Giomarelli; Dale L Barnard; Shilpa R Shenoy; Paul K S Chan; James B McMahon; Kenneth E Palmer; Brian W Barnett; David K Meyerholz; Christine L Wohlford-Lenane; Paul B McCray
Journal: J Virol Date: 2009-12-23 Impact factor: 5.103

10. Targeting N-glycan cryptic sugar moieties for broad-spectrum virus neutralization: progress in identifying conserved molecular targets in viruses of distinct phylogenetic origins.

Authors: Denong Wang; Jin Tang; Jiulai Tang; Lai-Xi Wang
Journal: Molecules Date: 2015-03-12 Impact factor: 4.411

9 in total

Review 1. Plant lectins as prospective antiviral biomolecules in the search for COVID-19 eradication strategies.

Authors: Md Nasir Ahmed; Rownak Jahan; Veeranoot Nissapatorn; Polrat Wilairatana; Mohammed Rahmatullah
Journal: Biomed Pharmacother Date: 2021-12-07 Impact factor: 7.419

Review 2. Legume Lectins with Different Specificities as Potential Glycan Probes for Pathogenic Enveloped Viruses.

Authors: Annick Barre; Els J M Van Damme; Bernard Klonjkowski; Mathias Simplicien; Jan Sudor; Hervé Benoist; Pierre Rougé
Journal: Cells Date: 2022-01-20 Impact factor: 6.600

Review 3. Production of Lectins from Marine Algae: Current Status, Challenges, and Opportunities for Non-Destructive Extraction.

Authors: Intan Mariana Maliki; Mailin Misson; Peik Lin Teoh; Kenneth Francis Rodrigues; Wilson Thau Lym Yong
Journal: Mar Drugs Date: 2022-01-26 Impact factor: 5.118

Review 4. Lectins and lectibodies: potential promising antiviral agents.

Authors: Mohsen Nabi-Afjadi; Morteza Heydari; Hamidreza Zalpoor; Ibrahim Arman; Arezoo Sadoughi; Parisa Sahami; Safiyeh Aghazadeh
Journal: Cell Mol Biol Lett Date: 2022-05-13 Impact factor: 5.787

Review 5. Plant lectins as potent Anti-coronaviruses, Anti-inflammatory, antinociceptive and antiulcer agents.

Authors: Emadeldin Konozy; Makarim Osman; Amina Dirar
Journal: Saudi J Biol Sci Date: 2022-04-22 Impact factor: 4.052

6. Urtica dioica Agglutinin: A plant protein candidate for inhibition of SARS-COV-2 receptor-binding domain for control of Covid19 Infection.

Authors: Fatemeh Sabzian-Molaei; Mohammad Ali Nasiri Khalili; Mohammad Sabzian-Molaei; Hosein Shahsavarani; Alireza Fattah Pour; Ahmad Molaei Rad; Amin Hadi
Journal: PLoS One Date: 2022-07-28 Impact factor: 3.752