key: cord-0747527-7dcrycqf authors: Cuéllar-Cruz, Mayra title: The histo-blood group antigens of the host cell may determine the binding of different viruses such as SARS-CoV-2 date: 2021-01-18 journal: Future Microbiol DOI: 10.2217/fmb-2020-0158 sha: 82a83263d11e65d65476a1b0bb9447d5fe04295e doc_id: 747527 cord_uid: 7dcrycqf Viruses have caused the death of millions of people worldwide. Specifically, human viruses are grouped into 21 families, including the family of coronaviruses (CoVs). In December 2019, in Wuhan, China, a new human CoV was identified, SARS-CoV-2. The first step of the infection mechanism of the SARS-CoV-2 in the human host is adhesion, which occurs through the S glycoprotein that is found in diverse human organs. Another way through which SARS-CoV-2 could possibly attach to the host’s cells is by means of the histo-blood group antigens. In this work, we have reviewed the mechanisms by which some viruses bind to the histo-blood group antigens, which could be related to the susceptibility of the individual and are dependent on the histo-blood group. Intermediate host? Figure reprinted , with permission, from El Zowalaty and Järhult (2020) [33] . Orthomyxovirus, Arenavirus, Filovirus, Rhabdovirus, Paramyxovirus and Coronavirus families. Although it has been reported that all genera that comprise these families cause infections, we will focus this review on the family of Coronavirus, as these are the causative agents of respiratory and intestinal infections in human and animals with high mortality rates [18, 19] . intermediates, between bats and humans [33] [34] [35] , this was also observed in the epidemics caused by SARS-CoV, in which, at the beginning, patients had contact with animals; antibodies were found in masked palm civets (Paguma larvata) and in people that handled these animals in public markets [30, 36, 37] . Later on, it was found that bats are the natural host of this CoV [26] . Since then until this date, it has been found that bats are the hosts for at least 30 CoVs [34, 38, 39] . Several events and incidents are involved in viruses switching hosts, like from bats to other animals or humans. For example, one of these events was given by bats being consumed as food in southern China and other countries in Southeast Asia, which is pointed out by the fact that the first reported case of SARS, several years ago, occurred in a chef from Heyuan [26, 40] . Recently, the fact that Wuhan, China, was the site of the first case of the new CoV in humans named SARV-CoV-2 [41, 42] is an additional indication that this type of event represents a possibility, among others, that the β-CoV be transmitted from the bat to the human host. The transmission from one species to another can be the result of several events ( Figure 1 ) [33] . Although the spillover of CoVs from a wild animal to humans can be explained by the handling and consumption of bats or other wild animals, the entry mechanism that the virus has to exert from one cell to the other is of great interest, as it allows understanding which are the proteins and biomolecules implicated in the process. The first step that CoV must perform, like any other pathogen, to be able to infect the host's cells is adhesion. This first step is performed through the glycoprotein S [23] . Protein S divides into two domains known as S1 and S2. Domain S1 contains a receptor binding domain to the host [43] . The ACE2 is a receptor for SARS-CoV [44] . After binding to the ACE2, the conformational change of protein S induces exposure of domain S2, and in this way helps the virus to fuse with cells of the host [45] . For this reason, the receptor binding domain of domain S1 is considered the main target for the design of peptides and antibodies to neutralize infections by this virus [46] . Because SARS-CoV and SARS-CoV-2 adhere to ACE2 in the host's cells, these viruses are able to colonize the heart, kidney, lungs, intestine, mouth, esophagus and the gastrointestinal tracts as these organs express this protein. The SARS-CoV-2 virus invades mainly the alveolar epithelial cells, specifically the ACE2 receptors of the alveolar pneumocytes. An in silico analysis proposed that the binding of SARS-CoV-2 to ACE2 occurs through the binding of the S1 N terminal domain (S1-NTD) of the spike protein to the glycans that contain sialic acid [47] . Despite that the mechanism by which SARS-CoV adheres to the cells of the human host to infect the diverse organs of the patient is known, in other words, by entering the blood stream and from there to the organs. The precise mechanism by which SARS-CoV adheres to the red blood cells that lack the ACE2 could possibly occur by adhesion to the CD147 receptor, as it has been described that SARS-CoV can bind to the CD147 receptor on the cellular surface [48] , which is found in red blood cells. CD147 is a protein of the immunoglobulins, which exert functions like starting the work of metalloproteinases that reconstruct the extracellular substance in tissues. This receptor, aside of being located in the surface of red blood cells, is also found in epithelial, endothelial and leucocyte cells. These data show that the SARS-CoV possesses mechanisms that allow them to colonize efficiently the human cells. Several works have described that the blood type or the ethnicity of an individual plays a role in being more or less susceptible to the infection by this CoV type, as occurs in other diseases. For example, in candidemia, which is caused by opportunistic pathogen fungi of the Candida genus, people of African descent, children less than a year old and patients older than 65 all have a higher prevalence of the disease [49] [50] [51] . Regarding the participation of the blood type of the individual, it has been described that it influences some diseases either infectious or noninfectious. In this section, we will focus on the blood type and its possible relation with susceptibility to SARS-CoV-2. The ABO was discovered in 1900 by Karl Landsteiner [52] and it is one of the most important systems for transfusions. This system is formed by antigens A, B and their corresponding antibodies, giving rise to four blood groups (A, B, AB and O), in other words, the ABO blood groups, also known as the histo-blood group system. Thanks to the discovery of the ABO system, safe transfusion of blood has been favored and the system has also been used as one of the human hereditary characteristics most important discoveries in medicine, as well as for tests to confirm paternity, in forensic studies, as well as in studies of diverse populations. The distribution of the four blood groups varies in the different populations of the world, group O is the most frequent, followed by group A, group B and group AB [53] [54] [55] . Antigens of the ABO system are formed by sugars that are found on the surface of erythrocytes [56, 57] , bound to the ceramide located in the membrane of erythrocytes. The terminal sugars of each blood group and the antibody they produce are summarized in Table 1 . Antigens of the ABO system have been associated with susceptibility to different diseases and infections; for example, people with blood group A have a greater susceptibility to develop salivary glands carcinoma, stomfuture science group www.futuremedicine.com Table 1 . Characteristics of the ABO system. Anti-A and anti-B None AB Acetylgalactosamine + fucose; galactose + fucose None A and B antigens ach, colon, rectum, ovary, uterus, cervix, bladder carcinomas, idiopathic thrombocytopenic purpura, coronary thrombosis, oral contraceptives-induced thrombosis, giardiasis, meningitis due to meningococcus [58] [59] [60] . Whereas individuals of blood group O present more susceptibility to gastric and duodenal ulcers, rheumatoid arthritis, von Willebrand disease, typhoid and paratyphoid disease, cholera and gastrointestinal infections caused by Escherichia coli 0157 [58, [61] [62] [63] . Individuals of blood type B are more susceptible to urinary infections due to E. coli and blenorragia [58] . For virus-induced infections, it has been reported that viruses of the Caliciviridae family, which are positive-sense RNA viruses comprised in nine genera, Vesivirus, Lagovirus, Norovirus, Sapovirus, Nebovirus, Recovirus, Valovirus, Nacovirus and Bavovirus [64, 65] are found in several hosts [66] [67] [68] [69] . Viruses of the Norovirus genus are capable of infecting a wide number of hosts, including humans, canine, feline, ovine, swine, bovine and murine [64, [66] [67] [68] [69] . Human noroviruses (HuNVs) are responsible for viral gastroenteritis and acute gastroenteritis outbreaks worldwide [65, 70] . Interestingly, HuNVs bind to the carbohydrates of the antigens of histo-blood group antigens (HBGAs) before their internalization; besides, it has been reported the polymorphism of the histo-blood antigens is related to the susceptibility presented by the individual to HuNVs [65] , pointing out the relevance of the HBGAs in the entry mechanism. Noroviruses have been divided in six different geno-groups based on the sequences of their capsids. HuNVs are comprised in geno-groups I (GI), II and IV [64, 65, 70] . Although HuNVs, GI and GII, bind to the HBGAs, to elucidate the interaction mechanisms between HuNVs and the HBGAs, the crystalline structures of the HuNV protruding domains of two rarely identified genotypes were determined, these were the Vietnam026 (026) GII.10 and Hiro G11.12 [70] . The crystalline structures were resolved alone and in a complex with a panel of HBGAs ( Figure 2) . Results from analyzing different crystalline structures revealed that in the interaction of the norovirus GII with the HBGAs participate six hydrogen bonds between the α-1,2-fucose terminal of the HBGAs and a dimeric capsid interface, which is composed of elements of two protruding subdomains ( Figure 3 ) [70] . The interactions of noroviruses with other saccharide units of the HBGAs involve few hydrogen bonds. In norovirus GII, a conserved residue was identified with α-1,2-fucose, on the external surface of the virion capsid [70] . Another study elucidated the crystalline structure of another HuNV genotype, specifically the geno-group II, genotype 4 (GII.4) [71] . These authors mention that noroviruses evolve every 2 years and it is considered that they modify the binding interaction with different HBGA types. The crystalline structures of the capsid protruding (P) domains of the epidemic variants of years 2004, 2006 and 2012 were studied, which were co-crystallized with a panel of HBGAs to elucidate the binding mechanisms of these viruses with the HBGAs [71] . Domain P is important because it contains the determinants for the binding cells and the diversity of strains. This domain is subdivided in subdomains P1 and P2 and each of them is considered to have unique functions. Binding of P domains of noroviruses G11.4 of 2004, 2006 and 2012 to the HBGAs were analyzed through x-ray crystallography. Results showed that the amino acids variations were localized in subdomain P2 [71] . It was also found that GII.4 viruses are able to bind to different types of HBGAs, this binding is achieved by complex interactions, such as movements of the coil of domain P with the consequent alternative conformations of the HBGAs; for example, a coil (residues 391-395) repositioned to allow for the Lewis Y binding. This same coil displaced itself slightly to provide direct links mediated by Lewis B hydrogen and water. Based on these data, the authors conclude that the outbreaks caused by noroviruses GII.4 are due to highly regulated binding mechanisms to the HBGAs, their affinity for the Lewis-type HBGAs, and their amino acids modifications. Once the virus has bound to its cellular target, a series of events are released that allow the virus to enter the cell. In general, the steps followed by the virus are: binding to the cellular target; compromise the host; endocytosis; penetration of the cellular membrane; delivery of the viral genome to the cytoplasm [72, 73] . Once the virus has been successful in entering the cells, cellular tropism and pathogenesis take place [73] . In this mechanism, one of the key points, perhaps the most relevant, is precisely the binding of the virus to the HBGAs. The molecular mechanism by which these molecules promote infection is proposed to occur as described in Figure 4 [73] . . The P1-interface loop was at the dimer interface and surface exposed. (C) The x-ray crystal structure of the unbound GII.12 P domain monomer determined to 1.6-Å resolution (shown here as a modeled dimer) was colored according to monomers and P1 and P2 subdomains, in other words, chain AP1 (hot pink), chain A P2 (orange), chain B P1 (green) and chain B P2 (cyan). As for the GII.10 P1-interface loop, the GII.12 P1-interface loop was at the dimer interface and surface exposed. Another type of identified norovirus is the canine norovirus, which has been classified in genogroups IV (GIV) and VI (GVI). A study determined the binding specificity of these noroviruses to carbohydrates; interestingly, α-1,2-fucose was identified as a key factor for the attachment. Through ELISA and immunohistochemistry it was confirmed that the canine norovirus recognizes HBGAs groups that contain α-1,2-fucose [65] . These data support the idea on the evolution of noroviruses, and this could be the key step in the zoonotic transmission from animals to humans. Another analyzed virus is the BtCalV/A10/USA/2009, which likely represents a novel genus of Caliciviridae. Carbohydrate binding studies were performed with this norovirus and it was found, as with bat noroviruses, that their capsid sequences resembled those of HuNVs, as they retained the binding to the host's ligand within binding domains to the receptor similarly to HuNVs. This calicivirus binds to the HBGAs, as observed with human and animal noroviruses. These data indicate the ability of bat caliciviruses to bind to HBGAs and, thereby, overcome the significant barrier for transmission among species [64] . Another virus from the Caliciviridae family is the bovine nebovirus, causative agent of acute gastroenteritis in cattle. This virus binds to the HBGAs specifically to those of the type A/H type 2/Le y expressed in the bovine digestive tract; interestingly, they are related to the HBGAs expressed in humans and in other host species [74] . Results also showed that the bovine nebovirus binds to α-1,2-fucose, indicating that this virus can be transmitted to other hosts like humans. Regarding the binding mechanisms of SARS-CoV-2 to the different HBGAs, it has been shown that depending on the antibodies of the blood groups, these can or not block the interaction between the SARS-CoV-S protein and ACE2 [75] . In this way, it has been shown in experimental models that the binding between ACE2 and SAR-CoV S protein can be blocked specifically by anti-A blood group antibodies, when the S protein was synthetized by cells future science group www.futuremedicine.com that express the A histo-blood group antigen [75, 76] . These data suggest that for the people with the O blood type, by having anti-A and anti-B antibodies, it could be possible to avoid the infection by blocking the binding and entrance of the virus [75, 76] . This observation agrees with a study performed in 2173 patients with COVID-19, which found that individuals with blood type A exhibit a higher susceptibility to become infected with SAR-CoV-2, in contrast to those with the O blood type, which seem to be least susceptible [77] . Data obtained in this type of studies suggest that this could be one of the binding mechanisms of HBGAs to different types of viruses, like CoVs, SARS-CoV and SARS-CoV-2, which could be related to the susceptibility of the individual, dependent on the histo-blood group. HBGAs are important for the adhesion of viruses to the host's cells, as this is the key point to be able to enter the cell and cause the infection. Additionally, binding of the virus to HBGAs is possibly the mechanism used by the virus to go from one host to another, for example, from bats to humans or from bats to an intermediate animal and, finally, to humans. For SARS-CoV and SARS-CoV-2 viruses, formal studies have been started to ascertain whether the binding of these CoVs to HBGAs favors or not the susceptibility of each individual to these CoVs and whether it is an alternative pathway for the binding of SARS-CoV-2 to human cells. This knowledge will allow for the development of a potential vaccine, as well as for the design of new drugs for the treatment of this novel CoV. • Microorganisms are the cause of pandemics that have affected mankind along its history. • Viruses have caused the death of millions of people worldwide, as happened with the influenza A of the H1N1 subtype during 1918-1920. • The 20th century witnessed the discovery of many diseases caused by viruses and their classification. • Viruses have evolved to reproduce inside the infected cell, because by themselves they are not capable of doing so because they lack the necessary molecular machinery. Coronaviruses • Viruses are classified according to their morphology, chemical composition and replication mechanisms. • Specifically, human viruses are grouped into 21 families, among them is the family of coronaviruses (CoVs). • These viruses were first identified in the 70s and are responsible for respiratory and intestinal infections in humans and animals with high mortality rates. • One of the CoV types that appeared in humans was the SARS-CoV responsible for the acute respiratory distress, which infected approximately 8000 people. • Recently, in December 2019, in Wuhan, China, a new human CoV was identified, called SARS-CoV-2, which has a mortality of approximately 2-3%. • Several events and incidents are involved in viruses switching hosts, like from bats to other animals or humans. • The first step of the infection mechanism of the SARS-CoV-2 in the human host is adhesion, which occurs through the S glycoprotein that is found in diverse human organs. • Another way through which SARS-CoV-2 could possibly attach to the host's cells is by means of the histo-blood group antigens (HBGAs). • The ABO was discovered in 1900 by Karl Landsteiner. • The distribution of the four blood groups varies in the different populations of the world. • Antigens of the ABO system have been associated with susceptibility to different diseases and infections. ovine, swine, bovine and murine. • Human noroviruses (HuNVs) are responsible for viral gastroenteritis and acute gastroenteritis outbreaks worldwide. • Interestingly, HuNVs bind to the carbohydrates of the antigens of HBGAs before their internalization. • Noroviruses have been divided in six different geno-groups based on the sequences of their capsids. HuNVs are comprised in geno-groups I (GI), II, and IV. • Results from analyzing different crystalline structures revealed that in the interaction of the norovirus GII with the HBGAs participate six hydrogen bonds between the α-1,2-fucose terminal of the HBGAs and a dimeric capsid interface, which is composed of elements of two protruding subdomains. Future perspective • HBGAs are important for the adhesion of viruses to the host's cells, as this is the key point to be able to enter the cell and cause the infection. • Besides, binding of the virus to HBGAs is possibly the mechanism used by the virus to go from one host to another, for example, from bats to humans. • For SARS-CoV and SARS-CoV-2 viruses, it has been formally studied whether the binding of these coronaviruses to HBGAs favors or not the susceptibility of each individual to these CoVs. This article is dedicated to the loving memory of my mother, Herlinda Cruz-Ramírez, who will always be remembered as the beloved mother whom inspired me all the time to pursue my goals and who was an example of perseverance to all our family members. M Cuéllar-Cruz acknowledges A Moreno for the revision and suggestions made on this work. The author thanks I Mascher and J Dye for the grammar and English style revision of the present manuscript. M Cuéllar-Cruz acknowledges to DAIP-UGTO project 009/2020 for the partial support of this article. The author has no other relevant affiliations or financial involvement with any organization or entity with a financial interest in or financial conflict with the subject matter or materials discussed in the manuscript apart from those disclosed. No writing assistance was utilized in the production of this manuscript. Vaccines, coming of age after 200 years The current challenges for vaccine development Teaching the history of microbiology and the transformation of the laboratory: a study in miniature Genome and evolution of Yersinia pestis Microevolution and history of the plague bacillus, Yersinia pestis Yersinia pestis and plague Influenza cataclysm 1918 Where are we, a century after the "Spanish Flu"? Spanish influenza redux: revisiting the mother of all pandemics The Invisible Enemy: a Natural History of Viruses Viruses: a Very Short Introduction A Planet of Viruses Jenner and the history of smallpox and vaccination Describes the origins of smallpox, the deaths caused by this disease and how immunity has been acquired along time Tobacco mosaic virus: pioneering research for a century A brief history of discovering virus The discovery of viruses: advancing science and medicine by challenging dogma Structure and classification of viruses, chapter 41 Origin and evolution of pathogenic coronaviruses •• Describes the origin and evolution of coronaviruses and the transmission events among species Comparative sequence analysis to revise the current taxonomy of the family Coronaviridae Fields Virology Evolutionary insights into the ecology of coronaviruses The genome sequence of the SARS-associated coronavirus Comparative full-length genome sequence analysis of 14 SARS coronavirus isolates and common mutations associated with putative origins of infection Virus Taxonomy, Classification and Nomenclature of Viruses. Ninth Report of the International Committee on Taxonomy of Viruses Global epidemiology of bat coronaviruses Discovery of seven novel mammalian and avian coronaviruses in the genus deltacoronavirus supports bat coronaviruses as the gene source of alphacoronavirus and betacoronavirus and avian coronaviruses as the gene source of gammacoronavirus and deltacoronavirus A pneumonia outbreak associated with a new coronavirus of probable bat origin •• Describes the identification and characterization of the novel coronavirus SARS-CoV-2 WHO. Summary of probable SARS cases with onset of illness from 1 Isolation and characterization of viruses related to the SARS coronavirus from animals in southern China Understanding bat SARS-like coronaviruses for the preparation of future coronavirus outbreaks -implications for coronavirus vaccine development Severe acute respiratory syndrome From SARS to COVID-19: a previously unknown SARS-related coronavirus (SARS-CoV-2) of pandemic potential infecting humans-Call for a one health approach Rooting the phylogenetic tree of middle east respiratory syndrome coronavirus by characterization of a conspecific virus from an african bat Further evidence for bats as the evolutionary source of middle east respiratory syndrome coronavirus Molecular evolution analysis and geographic investigation of severe acute respiratory syndrome coronavirus-like virus in palm civets at an animal market and on farms Ecoepidemiology and complete genome comparison of different strains of severe acute respiratory syndrome-related rhinolophus bat coronavirus in China reveal bats as a reservoir for acute, self-limiting infection that allows recombination events Complete genome sequence of bat coronavirus HKU2 from Chinese horseshoe bats revealed a much smaller spike gene with a different evolutionary lineage from the rest of the genome SARS molecular epidemiology: a Chinese fairy tale of controlling an emerging zoonotic disease in the genomics era The COVID-19 epidemic The origin, transmission and clinical therapies on coronavirus disease 2019 (COVID-19) outbreakan update on the status Coronavirus spike proteins in viral entry and pathogenesis Angiotensin-converting enzyme 2 is a functional receptor for the SARS coronavirus Receptor-induced conformational changes of murine coronavirus spike protein Cell adhesion as a novel approach to determining the cellular binding motif on the severe acute respiratory syndrome coronavirus spike protein Bioinformatics studies on a function of the SARS-CoV-2 spike glycoprotein as the binding of host sialic acid glycans Function of HAb18G/CD147 in invasion of host cells by severe acute respiratory syndrome coronavirus Incidence of bloodstream infections due to Candida species and in vitro susceptibilities of isolates collected from 1998 to 2000 in a population-based active surveillance program The epidemiology of candidemia in two United States cities: results of a population-based active surveillance Candidemia at a tertiary-care hospital: epidemiology, treatment, clinical outcome and risk factors for death Karl Landsteiner and his major contributions to haematology ABO and Rh(D) phenotype frequencies of different racial/ethnic groups in the United States The Distribution of the Human Blood Groups and Other Biochemical Polymorphisms Quantative subgroups of the B antigen in man and their occurrence in three racial groups Biological and clinical aspects of ABO blood group system Molecular basis of antigenic specificity in the ABO, H and Lewis blood group systems Erytrocyte antigens and antibodies Common susceptibility alleles are unlikely to contribute as strongly as the FV and ABO loci to VTE risk: results from a GWAS approach ABO blood group determines plasma von Willebrand factor levels: a biologic function after all? Blood group and susceptibility to disease caused by Escherichia coli O157 Blood group, immunity, and risk of infection with Vibrio cholerae in an area of endemicity Bat caliciviruses and human noroviruses are antigenically similar and have overlapping histo-blood group antigen binding profiles Genogroup IV and VI canine noroviruses interact with histo-blood group antigens Characterization of a rhesus monkey calicivirus representing a new genus of Caliciviridae Genomic characterization of swine caliciviruses representing a new genus of Caliciviridae Metagenomic analysis of the turkey gut RNA virus community Genetic characterization of a novel calicivirus from a chicken Crystal structures of GII.10 and GII.12 norovirus protruding domains in complex with histo-blood group antigens reveal details for a potential site of vulnerability Human noroviruses' fondness for histo-blood group antigens Virus entry: open sesame Norovirus attachment and entry Bovine nebovirus interacts with a wide spectrum of histo-blood group antigens Harnessing the natural anti-glycan immune response to limit the transmission of enveloped viruses such as SARS-CoV-2 •• Describes the relation between the blood group with the susceptibility of the individual to become infected with SARS-CoV Inhibition of the interaction between the SARS-CoV spike protein and its cellular receptor by anti-histo-blood group antibodies Relationship between the ABO blood group and the COVID-19 susceptibility