key: cord-0769118-3jaw7ymu
authors: Woo, Patrick C. Y.; Lau, Susanna K. P.; Yip, Cyril C. Y.; Huang, Yi; Yuen, Kwok-Yung
title: More and More Coronaviruses: Human Coronavirus HKU1
date: 2009-06-11
journal: Viruses
DOI: 10.3390/v1010057
sha: 27b4bbbc97d4660bbfef9e12bf3c3b9790df9014
doc_id: 769118
cord_uid: 3jaw7ymu

After human coronaviruses OC43, 229E and NL63, human coronavirus HKU1 (HCoV-HKU1) is the fourth human coronavirus discovered. HCoV-HKU1 is a group 2a coronavirus that is still not cultivable. The G + C contents of HCoV-HKU1 genomes are 32%, the lowest among all known coronaviruses with complete genome sequences available. Among all coronaviruses, HCoV-HKU1 shows the most extreme codon usage bias, attributed most importantly to severe cytosine deamination. All HCoV-HKU1 genomes contain unique tandem copies of a 30-base acidic tandem repeat of unknown function at the N-terminus of nsp3 inside the acidic domain upstream of papain-like protease 1. Three genotypes, A, B and C, of HCoV-HKU1 and homologous recombination among their genomes, are observed. The incidence of HCoV-HKU1 infections is the highest in winter. Similar to other human coronaviruses, HCoV-HKU1 infections have been reported globally, with a median (range) incidence of 0.9 (0 – 4.4) %. HCoV-HKU1 is associated with both upper and lower respiratory tract infections that are mostly self-limiting. The most common method for diagnosing HCoV-HKU1 infection is RT-PCR or real-time RT-PCR using RNA extracted from respiratory tract samples such as nasopharyngeal aspirates (NPA). Both the pol and nucleocapsid genes have been used as the targets for amplification. Monoclonal antibodies have been generated for direct antigen detection in NPA. For antibody detection, Escherichia coli BL21 and baculovirus-expressed recombinant nucleocapsid of HCoV-HKU1 have been used for IgG and IgM detection in sera of patients and normal individuals, using Western blot and enzyme-linked immunoassay.

Coronaviruses are positive-sense, single-stranded RNA viruses found in humans and a wide variety of animals. In humans, coronaviruses are mainly causes of respiratory tract infections, whereas in animals, they can cause respiratory, enteric, hepatic and neurological diseases of varying severity. As in other RNA viruses, the infidelity of RNA-dependent RNA polymerase results in high mutation rates. In addition, coronaviruses possess a unique mechanism of viral replication that leads to high frequencies of recombination, as well as the largest genome size (26.4 to 31.7 kb) among all known RNA viruses that gives this family of viruses extra plasticity [18, 22, 43] . All these factors have allowed the coronaviruses to adapt to new hosts and ecological niches. Traditionally, coronaviruses were classified into groups 1, 2 and 3, with groups 1 and 2 consisting of mammalian coronaviruses and group 3 being avian coronaviruses [2, 22, 47] . In 2008, the Coronavirus Study Group of the International Committee for Taxonomy of Viruses proposed three genera, Alphacoronavirus, Betacoronavirus and Gamma-coronavirus, to replace these three traditional groups of coronaviruses (http://talk.ictvonline.org/cfs-filesystemfile.ashx/__key/CommunityServer.Components.PostAttachments/00.00.00.06. 26/ 2008 .085_ 2D00_122V.01.Coronaviridae.pdf).

The SARS epidemic that originated from southern China in 2003 has boosted interest in all areas of coronavirus research, most notably, coronavirus biodiversity and genomics. Before 2003, there were only 10 coronaviruses with complete genomes available, including only two human coronaviruses, human coronavirus 229E (HCoV-229E) and human coronavirus OC43 (HCoV-OC43). These two human coronaviruses were discovered in the 1960s, with HCoV-229E being a group 1 coronavirus and HCoV-OC43 a group 2 coronavirus [17, 34] . After the SARS epidemic, up to December 2008, 16 novel coronaviruses were discovered and their complete genomes sequenced. Among these 16 previously unrecognized coronaviruses were two more human coronaviruses, human coronavirus NL63 (HCoV-NL63) and human coronavirus HKU1 (HCoV-HKU1) [37, 39] , ten other mammalian coronaviruses and four avian coronaviruses [7, 16, 23, 24, 27, 28, 33, 40, 41, 44, 46] . HCoV-NL63 is a group 1 coronavirus whereas HCoV-HKU1 is a group 2 coronavirus. In just a few years after their discoveries, numerous reports throughout the world had described the presence of HCoV-NL63 and HCoV-HKU1 in patients with respiratory infections in their corresponding countries. In this article, we reviewed our current understanding of the classification, virology, epidemiology, clinical diseases, laboratory diagnosis, treatment and prevention of HCoV-HKU1.

In the current system of classification in which group 2 coronaviruses are classified into group 2a, group 2b and the recently proposed groups 2c and 2d, HCoV-HKU1 is a group 2a coronavirus. Phylogenetically, no close relative with less than 10% nucleotide difference in any of the genes is present (Figure 1 ). At the moment, 22 HCoV-HKU1 genomes have been sequenced [43] . The sizes of the genomes of HCoV-HKU1 range from 29,295 to 30,097 nucleotides. The G + C contents of HCoV-HKU1 genomes are 32%, the lowest among all known coronaviruses with complete genome sequences available. The genome organization of HCoV-HKU1 is similar to that of other coronaviruses, with the characteristic gene order 5'-replicase ORF1ab, spike (S), envelope (E), membrane (M), nucleocapsid (N)-3' ( Figure  2 ). Additional genomic features of HCoV-HKU1 that are similar to all other group 2a coronaviruses include a putative transcription regulatory sequence (TRS) of CUAAAC, two papain-like protease domains (PL1 pro and PL2 pro ) in nsp3 of ORF1ab, a haemagglutinin esterase (HE) gene between ORF1ab and S, and an internal ribosomal entry site upstream to the initiation codon of E [39] . Among all coronaviruses with complete genomes available, HCoV-HKU1 shows the most extreme codon usage bias, attributed most importantly to severe cytosine deamination that has led to C → U changes [45] . The ORF1ab replicase polyprotein is putatively cleaved by its papain-like proteases and 3C-like protease (3CL pro ) into 16 nonstructural proteins (nsp1 to nsp16) homologous to the corresponding ones in other coronaviruses. Analysis of the putative cleavage sites of the 3CL pro revealed a unique putative cleavage site at the junction between nsp13 and nsp14, which was also recognized in HCoV-NL63 [38] . In addition to this unique putative cleavage site, all HCoV-HKU1 genomes contain tandem copies of a 30-base acidic tandem repeat (ATR) (variable numbers of perfect repeats of NDDEDVVTGD in the amino acid sequence followed by variable numbers of imperfect repeats) at the N-terminus of nsp3 inside the acidic domain upstream of PL1 pro [43] . This phenomenon was also observed in the two strains of HCoV-HKU1 found in France with this region of the genome characterized [35] . Although the function of the ATR is not known, these tandem copies of ATR have made the nsp3 of HCoV-HKU1 the longest nsp3 among all coronaviruses with complete genomes available.

At least three genotypes, genotype A, B and C, of HCoV-HKU1, with inter-genotypic homologous recombination, have been observed. When the pol, S and N genes of clinical strains HCoV-HKU1 were analyzed, it was observed that the strains fell into two clusters, designated genotypes A and B [25, 42] . Interestingly, there were a few strains in which the sequences of pol genes were clustered with genotype A but those of S and N genes were clustered with genotype B [25, 42] . Subsequent sequencing and analysis of 22 complete HCoV-HKU1 genomes found that there were three genotypes of HCoV-HKU1 and significant numbers of homologous recombination events have occurred among the three genotypes [43] . The most notable example was in a stretch of 29 bases at the 3' end of nsp16, in which recombination between genotype A and genotype B has led to the generation of genotype C [43] . This represented the first example of homologous recombination in human coronavirus, and was also the first study to describe a distribution of natural recombination spots in the entire genome of field isolates of a coronavirus [43] . Although no complete genome sequence is available for HCoV-HKU1 strains found outside Hong Kong, sequences of fragments of pol, S and N of the strains suggested that all three genotypes are probably distributed globally. Analysis of a single gene is not sufficient for genotyping of HCoV-HKU1, but would require sequencing of at least two gene loci, one from nsp10 to nsp16, such as pol or helicase, and another from HE to N, such as S or N.

Although HCoV-HKU1 is still not cultivable using a wide variety of cell lines, neuron-glia culture and intracerebral inoculation of suckling mice, the biogenesis, subcellular localization and intracellular trafficking of S in HCoV-HKU1 as well as its interaction with major histocompatibility complex class I C molecule (HLA-C) were characterized recently [4, 6] . Results of these studies confirmed that S of HCoV-HKU1 was N-glycosylated in the endoplasmic reticulum (ER) with high-mannose N-glycans, and it was first distributed in the ER and Golgi, subsequently also detected in vesicles throughout the cytoplasm, and finally on the cell surface. Cleavage of S into S1 (Endo H deglycosylation resistant) and S2 (Endo H deglycosylation sensitive) that was inhibited by the furin or furin-like enzyme inhibitor, peptidyl chloromethylketone was also observed, confirming the bioinformatics prediction of the presence of cleavage site between S1 and S2 [6] . Using HCoV-HKU1 S pseudotyped virus, human alveolar epithelial A549 cells were shown to be the most susceptible cell line [4] . Using an A549 cDNA expression library transduced into the non-permissive, baby hamster kidney cell line BHK-21 for detecting proteins that bind HCoV-HKU1 S 1-600 glycoprotein, independent clones with inserts encoding HLA-C were fished out. Further experiments also suggested that HLA-C is involved in the attachment of HCoV-HKU1 to A549 cells and is a potential candidate to facilitate cell entry [4] . 

In our studies on animal coronaviruses, no HCoV-HKU1 was detected in screening more than 10,000 animal specimens in a variety of mammalian and avian species [23, 40, 41, 44] . The dn/ds ratios of all ORFs in the genomes of HCoV-HKU1 are low. Therefore, HCoV-HKU1 is stably evolving in humans, probably the only known reservoir. Similar to other respiratory viruses, HCoV-HKU1 is presumably transmitted through exchange of respiratory secretions. The incidence of HCoV-HKU1 infections is the highest in winter. Similar to other human coronaviruses, HCoV-HKU1 infections have been reported globally (Table 1) [1, 3, 8, 9, [11] [12] [13] [14] [15] 20, 21, 25, 29, 30, 32, 35, 36, 42] . From the studies with the incidence of all four human coronaviruses examined (Table 1) , the median (range) incidence of HCoV-HKU1 was 0.9 (0 -4.4) %, with no significant difference to those of HCoV-OC43 The seroprevalence of HCoV-HKU1 antibody varied widely in different studies that used different antigens and methodologies for antibody detection. In a recent study on seroepidemiology of HCoV-HKU1 using Escherichia coli BL21 expressed recombinant S-based enzyme-linked immunosorbent assay (ELISA) and line immunoassay, it was observed that the seroprevalence of HCoV-HKU1 antibody increased from 0% in patients who were <10 years old to a plateau of 22% in patients who were 31 to 40 years old [5] . In another study on seroepidemiology of the four human coronaviruses in Germany using E. coli BL21-expressed recombinant N-based line immunoassay, it was noted that the seropositivity for HCoV-HKU1 in 25 healthy blood donors was 48%, similar to those for HCoV-OC43 (52%), HCoV-229E (56%) and HCoV-NL63 (60%) [26] . On the other hand, in another study of a US metropolitan population using baculovirus-expressed recombinant N-based ELISA, it was observed that the proportion of HCoV-HKU1 seropositive adults was 59.2%, significantly lower than those for HCoV-OC43 (90.8%), HCoV-229E (91.3%) and HCoV-NL63 (91.8%) [31] . Moreover, it was also observed that significantly different seropositivity rates for the various human coronaviruses were observed in individuals of different races, smoking status and socioeconomic status [31] . Further studies have to be performed to delineate whether these demographic factors confer differential risks of susceptibility to different human coronaviruses.

Similar to other human coronaviruses, HCoV-HKU1 is associated with both upper and lower respiratory tract infections. Respiratory tract infections associated with HCoV-HKU1 are indistinguishable from those associated with other respiratory viruses. For upper respiratory tract infections, most patients present with fever, running nose and cough; while for lower respiratory tract infections, fever, productive cough and dyspnea are common presenting symptoms. Most HCoV-HKU1 infections are self-limiting, with only two deaths reported in patients with HCoV-HKU1 pneumonia [42] . Both had underlying diabetes mellitus, cardiovascular diseases (myocardial infarction in one and cerebrovascular accident in the other) and cancers (gastric lymphoma in one and prostatic carcinoma in the other), lymphopenia and airspace shadows in both lungs [42] . Interestingly, a recent study from rural Thailand that involved control patients showed the presence of human coronaviruses in >2% of control patients, which raised questions about the role of human coronaviruses in pneumonia [9] . At the moment, no antiviral drugs or vaccines for HCoV-HKU1 and the other human coronaviruses are available. Symptomatic and supportive treatment is the mainstay of therapy given to patients suffering from infections caused by these viruses.

In addition to respiratory tract infections, HCoV-HKU1 has been found in other illnesses. In our one-year prospective study, it was observed that HCoV-HKU1 infection was associated with febrile seizures [25] . On the other hand, in another French study, although six (17.6%) of the 34 HCoV-HKU1 infected children were admitted for epileptic seizures, HCoV-HKU1 infections were not shown to be associated with febrile seizures [36] . In one study, HCoV-HKU1 was detected in the stool samples of two patients with respiratory tract infections but no gastrointestinal tract symptoms, but it was not detected in patients with diarrhea [35] . In another study, HCoV-HKU1 was detected in a liver transplant recipient with hepatitis, which other causes of hepatitis, such as graft rejection, cytomegalovirus, etc. were excluded [11] . The significance of HCoV-HKU1 febrile seizures, gastroenteritis and hepatitis remains to be determined.

The most common method for making a diagnosis of HCoV-HKU1 infection is RT-PCR or realtime RT-PCR using RNA extracted from respiratory tract samples such as nasopharyngeal aspirates (NPA). Both the pol and N genes have been used as the targets for amplification ( Table 2 ). In our index patient, the viral loads in the NPA of the patient were 10 6 to 10 7 and 10 5 copies/ml of NPA in the first and second weeks of illness respectively, and became undetectable from the third week of illness onwards [39] . Recently, DNA microarrays have also been used for detection of HCoV-HKU1 and other human coronaviruses, and the sensitivity was found to be similar to that of individual real-time RT-PCR [10] . In addition to nucleic acid detection, monoclonal antibodies have been generated for direct antigen detection in NPA, although the targets for the binding of the monoclonal antibodies are still not known [15] .

For antibody detection, E. coli BL21-and baculovirus-expressed recombinant N of HCoV-HKU1 has been used for IgG and IgM detection in sera of patients and normal individuals, using Western blot and ELISA [5, 26, 31, 39, 42] . In our index patient, his serum IgG titer rose from <1:1,000 in the first week of his illness to 1:2,000 and 1:8,000 in the second and fourth weeks of his illness respectively, whereas the IgM titers in the first, second and fourth weeks were 1:20, 1:40, and 1:80 respectively [39] . Furthermore, in our retrospective study of patients with community acquired pneumonia, all the six patients with serum samples available showed four-fold changes in IgG titer and/or presence of IgM against HCoV-HKU1 [42] . Although HCoV-HKU1 is still not cultivable, a neutralization antibody test was also developed recently using HCoV-HKU1 pseudotyped virus [5] . 

The discovery of SARS coronavirus marked the beginning of the race of coronavirus hunting in humans and animals. In just a few years, the number of "coronavirus" papers found by Medline search has doubled and the number of coronaviruses with complete genomes available has tripled. With this increase in the number of coronaviruses and genomes, we are starting to appreciate the diversity of coronaviruses. Moreover, comprehensive and user-friendly databases for efficient sequence retrieval and the ever-improving bioinformatics tools have further enabled us to improve our understanding of the phylogeny and genomics of coronaviruses [19] . With the increasing number of coronaviruses, more and more closely related coronaviruses from distantly related animals have been observed. The most notable example related to human coronaviruses is the clustering of HCoV-OC43, bovine coronavirus and porcine hemagglutinating encephalomyelitis virus. With more and more coronaviruses discovered, we will be able to understand the origin of the various human coronaviruses, and more importantly, the secret behind their mechanisms of interspecies transmission.

Role of respiratory pathogens in infants hospitalized for a first episode of wheezing and their impact on recurrences

Coronavirus genome structure and replication

Two-year prospective study of single infections and co-infections by respiratory syncytial virus and viruses identified recently in infants with acute respiratory disease

Identification of major histocompatibility complex class I C molecule as an attachment factor that facilitates coronavirus HKU1 spike-mediated infection

Examination of seroprevalence of coronavirus HKU1 infection with S protein-based ELISA and neutralization assay against viral spike pseudotyped virus

Spike protein, S, of human coronavirus HKU1: role in viral life cycle and application in antibody detection

Genomic characterizations of bat coronaviruses (1A, 1B and HKU8) and evidence for co-infections in Miniopterus bats

Detection of viruses identified recently in children with acute wheezing

Human coronavirus infections in rural Thailand: a comprehensive study using real-time reversetranscription polymerase chain reaction assays

Generic detection of coronaviruses and differentiation at the prototype strain level by reverse transcription-PCR and nonfluorescent lowdensity microarray

Coronavirus HKU1 infection in the United States

Impact of human coronavirus infections in otherwise healthy children who attended an emergency department

Materno-fetal transmission of human coronaviruses: a prospective pilot study

A prospective hospital-based study of the clinical impact of nonsevere acute respiratory syndrome (Non-SARS)-related human coronavirus infection

Human respiratory coronavirus HKU1 versus other coronavirus infections in Italian hospitalised patients

Complete genomic sequence of turkey coronavirus

A new virus isolated from the human respiratory tract

Feline coronavirus type II strains 79-1683 and 79-1146 originate from a double recombination between feline coronavirus type I and canine coronavirus

CoVDB: a comprehensive database for comparative analysis of coronavirus genes and genomes

Molecular epidemiology and disease severity of respiratory syncytial virus in relation to other potential pathogens in children hospitalized with acute respiratory infection in Jordan

Clinical disease in children associated with newly described coronavirus subtypes

The molecular biology of coronaviruses

Severe acute respiratory syndrome coronavirus-like virus in Chinese horseshoe bats

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

Coronavirus HKU1 and other coronavirus infections in Hong Kong

A line immunoassay utilizing recombinant nucleocapsid proteins for detection of antibodies to human coronaviruses

Bats are natural reservoirs of SARS-like coronaviruses

Identification of a novel coronavirus from a beluga whale by using a panviral microarray

Detection and typing by molecular techniques of respiratory viruses in children hospitalized for acute respiratory infection in

Viral etiology of acute respiratory infections with cough in infancy: a community-based birth cohort study

Development of a nucleocapsid-based human coronavirus immunoassay and estimates of individuals exposed to coronavirus in a U.S. metropolitan population

Evidence of human coronavirus HKU1 and human bocavirus in Australian children

Prevalence and genetic diversity of coronaviruses in bats from China

Cultivation of a Novel Type of Common-Cold Virus in Organ Cultures

Detection of the new human coronavirus HKU1: a report of 6 cases

Human (nonsevere acute respiratory syndrome) coronavirus infections in hospitalised children in France

Identification of a new human coronavirus

In silico analysis of ORF1ab in coronavirus HKU1 genome reveals a unique putative cleavage site of coronavirus HKU1 3C-like protease

Characterization and complete genome sequence of a novel coronavirus, coronavirus HKU1, from patients with pneumonia

Comparative analysis of complete genome sequences of three avian coronaviruses reveals a novel group 3c coronavirus

Molecular diversity of coronaviruses in bats

Clinical and molecular epidemiological features of coronavirus HKU1-associated community-acquired pneumonia

Comparative analysis of 22 coronavirus HKU1 genomes reveals a novel genotype and evidence of natural recombination in coronavirus HKU1

Comparative analysis of twelve genomes of three novel group 2c and group 2d coronaviruses reveals unique group and subgroup features

Cytosine deamination and selection of CpG suppressed clones are the two major independent biological forces that shape codon usage bias in coronaviruses

Genomic characterization of equine coronavirus

Molecular biology of severe acute respiratory syndrome coronavirus

This work was partly supported by the Research Grant Council Grant, University Development Fund, Outstanding Young Researcher Award, The University of Hong Kong.