Cloning and Expression of the M-Gene from the Human Coronavirus NL-63 in Different Expression Systems.

Lubbe, Lizel

January 2008

<p>In this study, the HCoV-NL63 genome was transcribed from RNA to DNA from which the M gene was amplified with various primers designed for use in specific expression systems. The various genes were cloned into the pGEM vector and confirmed by sequencing. The genes were now expressed in cloning vectors suited for each expression system (pFastBac for baculovirus expression, pFlexi for bacterial expression and pCMV for mammalian expression). Clones were sequenced for a second time. The recombinant clone in pFlexi was expressed in KRX cells and a 36hr time course was performed. The recombinant pFastBac clone was used to infect Sf9 insect cells and P1 and P2 viral stocks were obtained. The recombinant pCMV clone was used to transfect Cos1 mammalian cells.</p>

Genome structure

Structural proteins

Human Coronavirus NL63.

Cloning and Expression of the M-Gene from the Human Coronavirus NL-63 in Different Expression Systems.

Lubbe, Lizel

January 2008

<p>In this study, the HCoV-NL63 genome was transcribed from RNA to DNA from which the M gene was amplified with various primers designed for use in specific expression systems. The various genes were cloned into the pGEM vector and confirmed by sequencing. The genes were now expressed in cloning vectors suited for each expression system (pFastBac for baculovirus expression, pFlexi for bacterial expression and pCMV for mammalian expression). Clones were sequenced for a second time. The recombinant clone in pFlexi was expressed in KRX cells and a 36hr time course was performed. The recombinant pFastBac clone was used to infect Sf9 insect cells and P1 and P2 viral stocks were obtained. The recombinant pCMV clone was used to transfect Cos1 mammalian cells.</p>

Genome structure

Structural proteins

Human Coronavirus NL63.

Cloning and expression of the M-gene from the human coronavirus NL-63 in different expression systems

Lubbe, Lizel

January 2008

Magister Scientiae - MSc / Respiratory tract infections are one of the leading causes of morbidity and mortality across the world. This is especially true for infants, young children, the elderly and the immunocompromised. The strain placed on economies and health care systems of all countries by these diseases are phenomenal. Although we are familiar with various agents leading to these kinds of infections (e.g. rhino-, influenza-, parainfluenza, human metapneumo-, respiratory syncytial-, adeno- and coronaviruses), the cause of a substantial portion, (48-70%) of cases remain unidentified (Van der Hoek et al, 2004; Fouchier et al, 2004; File, 2003; Fine et al, 1999; Shay et al, 1999, Henrickson et al 2004; Murray et al 2001). In the past, human coronaviruses have not been known to cause severe disease in humans. For this reason, little research was performed on these viruses, with research focusing on the animal coronaviruses that are of veterinary importance. However, with the outbreak of SARS in 2003, the field of human coronavirus research has received significantly more attention. Also, the subsequent identification of two additional novel human coronaviruses (NL63 and HKU1) has led to an increased awareness of the potential threat of these viruses. With the discovery of these new human coronaviruses, it has become clear that the potential for another outbreak by a yet unknown human coronavirus is a very real possibility. This has made research into the pathogenesis and the role of the various coronavirus genes in the pathogenesis of these viruses of utmost importance. HCoV-NL63 was first discovered in January 2003 in the Netherlands. It causes upper and lower respiratory tract disease in young children, the elderly and immunocompromised individuals. The disease is also associated with croup and has even been implicated as a possible cause of the childhood vascular ailment Kawasaki Disease. HCoV-NL63 is frequently found in combination with other respiratory viruses leading to superinfections. It is still unclear whether HCoV-NL63 is an opportunistic virus or whether it leads the way for co-infection with other respiratory viruses. This particular virus is also the only coronavirus sharing the same cellular receptor as SARS-CoV. The virus is found all over the world and has been identified in countries like Australia (Arden et al, 2005), Japan (Ebihara et al., 2005; Suzuki et al., 2005), Belgium (Moës et al., 2005), Hong Kong (Chiu et al., 2005), Taiwan (Wu et al.,2007) Korea (Choi et al., 2006), Canada (Bastien et al., 2005), France (Vabret etal., 2005), Switzerland (Kaiser et al., 2005; Garbino et al., 2006), Germany (Vander Hoek et al., 2005), Sweden (Koetz et al., 2006) and South Africa (Smuts andHardie, 2006). In this study, the HCoV-NL63 genome was transcribed from RNA to DNA from which the M gene was amplified with various primers designed for use in specific expression systems. The various genes were cloned into the pGEM vector and confirmed by sequencing. The genes were now expressed in cloning vectors suited for each expression system (pFastBac for baculovirus expression, pFlexi for bacterial expression and pCMV for mammalian expression). Clones were sequenced for a second time. The recombinant clone in pFlexi was expressed in KRX cells and a 36hr time course was performed. The recombinant pFastBac clone was used to infect Sf9 insect cells and P1 and P2 viral stocks were obtained. The recombinant pCMV clone was used to transfect Cos1 mammalian cells. The genome was successfully transcribed and the M gene amplified and cloned into pGEM and confirmed by sequencing. Subsequent cloning of the various M genes into pFastBac for baculovirus expression, pFlexi for bacterial expression and pCMV for mammalian expression was achieved and sequencing confirmed the presence of the inserts in frame. pFlexi clones were successfully expressed in bacterial KRX cells with expression of the M protein in the pellet of the lysed bacterial cells. No M protein was seen in the supernatant of the lysed cells. Sf9 insect cells were infected with the recombinant pFastBac clones and P1 and P2 viral stocks were obtained. Protein expression occurs in KRX bacterial cells with optimal expression at approximately 24 hours. The M protein expresses on the cell membrane as can be concluded from the product obtained in the pellet of the lysed bacterial cells. Very little of the expressed protein is present in the plasma of the cell as evidenced by the absence of protein in the supernatant of the lysate. / South Africa

Genome structure

Structural proteins

Human Coronavirus NL63

The characterisation of human coronavirus nl63 proteins

Gordon, Bianca

January 2021

Philosophiae Doctor - PhD / Human Coronavirus NL63 (HCoV-NL63) is one of seven coronaviruses (CoVs) that cause respiratory disease in the global population. The Membrane (M) and Nucleocapsid (N) proteins are part of the core CoV-structural proteins, crucial in viral replication and virion assembly. Here the expression of HCoV-NL63 M and N was characterized across multiple in vitro systems including bacterial, insect and mammalian. To detect untagged proteins in viral structural studies, anti-peptide antibodies were generated in a mouse model. Polyclonal antisera and hybridoma-secreted antibodies exhibited specific binding to their respective full length protein antigens. Anti-peptide monoclonal antibodies were successfully generated against the HCoV-NL63 M and N proteins. During CoV infection, the interaction of CoV M and N is necessary for the production of infectious virions. For the first time, co-expressed, full length HCoV-NL63 M and N were assayed for protein-protein interaction in a mammalian cell system, allowing for native protein folding and modification. M protein formed higher order homomultimers in the presence and absence of co-expressed N.

Human coronavirus

Coronavirus

Structural proteins

Nucleocapsid

Interaction

Epidemiology, pathogenesis and surveillance of the pig adapted strain of foot and mouth disease in Taiwan

spchen@mail.atit.org.tw, Shih-Ping Chen

January 2008

Foot-and-mouth disease (FMD) is one of the most contagious infectious diseases of domestic and wild cloven-hoofed animals, particular in cattle, sheep, pigs, goats and domestic buffalo, as well as wild ruminants such as deer. In Taiwan, there was a severe outbreak of FMD after more than 60 years freedom from the disease. The virus strain, O Taiwan 97 from the March 1997 outbreak of FMD in Taiwan, however, has been shown to have a species-specific adaptation to pigs. Although there are 7 distinct serotypes of FMD found in different regions of the world, this study focuses on the pig-adapted type O strain of FMD. After the FMD outbreak commenced in Taiwan, the spread of disease was very rapid and the whole of the western parts of Taiwan was affected within a few days after the diagnosis of FMD was confirmed. In some situations airborne transmission of FMD virus was suspected and it was speculated that this was the explanation for such rapid spread in Taiwan. Therefore, studies were conducted to investigate the transmissibility of O Taiwan/97 FMDV to susceptible pigs by direct and indirect spread including airborne spread in an enclosed animal house. This study showed that pigs in direct contact with challenged pigs became infected but none of the close-contact pigs became infected. These experiments clearly demonstrated that the pig adapted strain O Taiwan/97 was only efficiently transmitted by direct contact. This indicates that effective control against future outbreaks of pig adapted FMDV strains could be achieved by restriction of pig movement and stamping out if the outbreak has been detected in the early stages and prior to the movements of pigs from the infected premises. The measures used to control the Taiwanese FMD outbreak in 1997 were initially the slaughter of whole herds in the infected premises. However, with the rapid spread and large numbers of cases, the decision was taken to use universal compulsory vaccination of pig herds to control the outbreak when sufficient supply of vaccines was organized. Type O FMD vaccines were imported from a number of major FMD vaccine manufactures from around the world. Initially, vaccine efficacy for the imported vaccines was tested by measurement of neutralizing antibody titers in vaccinated pigs. To establish the relationship between serum neutralizing titers and protection from foot and mouth disease in pigs after vaccination, challenge studies were conducted with O/Taiwan/97 FMD in vaccinated pigs. Additionally, antibody responses to structural (neutralizing antibody) and non-structural proteins (NSP) were evaluated in vaccinated pig herds after primary and secondary vaccination in herds infected before and after vaccination. In order to be able to monitor the circulation of virus in vaccinated pig populations, valid diagnostic kits based on the detection of antibody against NSP were required. These tests needed to be evaluated against pig sera derived from challenge studies and natural FMD outbreaks. Three commercially available ELISAs (Cedi, UBI and Checkit), which were available to differentiate infected from vaccinated pigs, were tested and results showed that the Cedi test had the optimal sensitivity and specificity for pig adapted type O FMD testing. This test was used to retrospectively evaluate the sera collected from infected and non-infected pig herds collected sequentially in the year after the 1997 FMD outbreak in Taiwan. These studies also showed that the early vaccines used, stimulated NSP antibody production in swine herds that were vaccinated but not infected. This resulted in the requirement for purified FMD vaccines to be used when monitoring programs for FMD infection by NSP testing were in place. In these studies, it was also demonstrated that the purified FMD vaccines used later in the control program did not induce NSP antibody after multiple double dosage to pigs. Although clinical FMD appeared to be successfully controlled with vaccination program in Taiwan it was essential for the eradication plan to maintain active surveillance for NSP reactors in the pig population. The UBI and Cedi NSP kits were applied as screening and confirmatory tests, respectively, to pig sera collected in auction markets distributed around Taiwan to monitor for evidence of the circulation of FMD virus. Herds with positive reactors were followed-up by clinical inspection and 15 sera from suspected herds were further sampled. Negative results were obtained from all these investigation. With the absence of clinical outbreaks and the lack of evidence of FMDV circulation in the field from the NSP reactor surveillance, the Taiwanese government has progressed the eradication plan to a progressive cessation of vaccination, commencing with banning of vaccination on one isolated island in December 2006. The absence of outbreaks on that island, paved the way for further cessation of FMD vaccination in Taiwan from July 2008.

foot and mouth disease

Neutralizing antibodies

Vaccines

Non-structural proteins

Myší polyomavirus: Role buněčného cytoskeletu v endozomálním transportu viru a vlastnosti minoritních kapsidových proteinů / Mouse polyomavirus: The role of cell cytoskeleton in virus endosomal trafficking and properties of the minor capsid proteins

Žíla, Vojtěch

January 2014

Mouse polyomavirus (MPyV) is a non-enveloped DNA tumor virus, which replicates in the host cell nucleus. MPyV enters cells by receptor-mediated endocytosis and its subsequent transport towards the nucleus requires acidic environment of endosomes and intact microtubules, which are important for virus delivery to endoplasmic reticulum (ER). In ER, capsid disassembly and uncoating of viral genome take place. The mechanism of subsequent translocation of viral genome from ER into nucleoplasm is still only poorly understood process with predicted involvement of cellular factors and viral minor capsid proteins VP2 and VP3. Once the genome appears in the nucleus, early viral antigens are produced and mediate suitable environment for replication of viral genomes. After replication of viral DNA and morphogenesis of virions, virus progeny is released from the cells during its lysis. The research presented in the first part of thesis focused on intracellular transport of MPyV and involvement of cytoskeletal networks during virus delivery to the ER. In particular, we investigated still unclear role of microtubules during virus trafficking in endosomes, and involvement of microtubular motors. We found that MPyV trafficking leading to productive infection does not require the function of kinesin-1 and kinesin-2,...

Minoritní strukturní proteiny polyomavirů: Vlastnosti a interakce s buněčnými strukturami / Minor Structural Proteins of Polyomaviruses: Attributes and Interactions with Cellular Structures

Vinšová, Barbora

January 2016

Even though polyomaviruses have been intensively studied for more than 60 years, the role of minor structural proteins VP2 and VP3 in some important steps of viral life cycle has still not been fully elucidated, explicitly their role in viral genome delivery to the cell nucleus and their involvement in late phases of viral life cycle. This diploma thesis focuses on the study of minor proteins of Mouse polyomavirus (MPyV) and Human polyomavirus BK (BKV). Four rabbit polyclonal antibodies against minor proteins of polyomaviruses MPyV or BKV have been prepared within this diploma thesis. Two of these prepared antibodies target minor proteins of MPyV (α-MPyV VP2/3) or BKV virus (α-BKV VP2/3), other two prepared antibodies recognize C-terminal sequence common to minor proteins VP2 and VP3 of MPyV (α-MPyV C-termVP2/3) or BKV virus (α-BKV C-termVP2/3). In the second part of this diploma thesis we aimed to study toxicity of BKV virus minor proteins during individual production in mammalian cells. Obtained results suggest that minor proteins of BKV virus might not exhibit as high levels of cytotoxicity as minor proteins of MPyV virus. Third part of this diploma thesis is devoted to investigation of interactions of BKV and MPyV minor proteins with cellular proteins and within one another respectively....

Bacteriophage P22 scaffolding protein functions and mechanisms in procapsid assembly /

Marion, William R.

January 2007

Thesis (M.S.)--University of Alabama at Birmingham, 2007. / Title from first page of PDF file (viewed on June 25, 2009). Includes bibliographical references (p. 52-56).

Analysis of the pseudorabies virus tegument proteins Us3, VP22 and Us2 /

Lyman, Mathew G.

January 2005

Thesis (Ph.D. in Microbiology) -- University of Colorado at Denver and Health Sciences Center, 2005. / Typescript. Includes bibliographical references (leaves 142-168). Free to UCDHSC affiliates. Online version available via ProQuest Digital Dissertations;

Analysis of Simian Hemorragic Fever Virus Proteins and the Host Cell Responses of Disease Resistant and Susceptible Primates

Vatter, Heather

15 April 2013

African monkey species are natural hosts of simian hemorrhagic fever virus (SHFV) and develop persistent, asymptomatic infections. SHFV was previously shown to also cause a rapid onset fatal hemorrhagic fever disease in macaques. Infection of macaques with a new isolate of SHFV from persistently infected baboon sera, that showed high nucleotide identity with the lab strain LVR, resulted in viremia, pro-inflammatory cytokine and tissue factor production, and symptoms of coagulation defects. Primary macrophages and myeloid dendritic cell cultures from disease-susceptible macaques efficiently replicated SHFV and produced pro-inflammatory cytokines, including IL-6 and TNF-α, as well as tissue factor. Cells from disease resistant baboons produced low virus yields and the immunomodulatory cytokine IL-10. IL-10 treatment of macaque cells decreased IL-6 levels but had no effect on TNF-α levels, tissue factor or virus production suggesting that IL-10 plays a role in modulating immunopathology in disease-resistant baboons but not in regulating the efficiency of virus replication. SHFV is a member of the family Arteriviridae. The SHFV genome encodes 8 minor structural proteins. Other arteriviruses encode 4 minor structural proteins. Amino acid sequence comparisons suggest that the four additional SHFV minor structural proteins resulted from gene duplication. A full-length infectious clone of SHFV was constructed and produced virus with replication kinetics comparable to the parental virus. Mutant infectious clones, each with the start codon of one of the minor structural proteins substituted, were analyzed. All eight SHFV proteins were required for infectious virus production. The SHFV nonstructural polyprotein is processed into the mature replicase proteins by several viral proteases including papain-like cysteine proteases (PLPs). Only one or two PLP domains are present in other arteriviruses but SHFV has three PLP domains. Analysis of in vitro proteolytic processing of C- and N-terminally tagged polyproteins indicated that the PLP in each of the three SHFV nsp1 proteins is active. However, the nsp1α protease is more similar to a cysteine protease than a PLP. Analysis of the subcellular localization of the three SHFV nsp1 proteins indicated they have divergent functions.

Simian hemorrhagic fever virus (SHFV)

Arterivirus replication

Pro-inflammatory cytokines

Interleukin-10 (IL-10)

Infectious clone

Minor structural proteins