The present invention relates to isolated proteins from caligid copepods, mutants thereof and polynucleotides encoding the same, and antigens and vaccines comprising the same, in particular for the treatment or prevention of caligid copepod infection in fish.
Parasitic copepods in the family Caligidae (caligid copepods) infect and cause disease in fish. Collectively, these species are referred to as sea lice. There are three major genera of sea lice: Pseudocaligus, Caligus and Lepeophtheirus. In the northern hemisphere, the salmon louse (Lepeophtheirus salmonis), is responsible for most disease outbreaks on farmed salmonids. This parasite is responsible for substantial indirect and direct losses in aquaculture.
All developmental stages of sea lice, which are attached to the host, feed on host mucus, skin and blood. The attachment and feeding activities of sea lice result in lesions that vary in their nature and severity depending upon: the species of sea lice, their abundance, the developmental stages present and the species of the host (Johnson et al., 2004). In the southern hemisphere, Caligus rogercresseyi, is the primary caligid affecting the salmon farming industry in Chile (Gonzalez and Carvajal, 2003).
Caligid copepods have direct life cycles consisting of two free-living planktonic nauplius stages, one free-swimming infectious copepodid stage, four to six attached chalimus stages, one or two preadult stages, and one adult stage (Kabata, 1970). Each of these developmental stages is separated by a moult. Once the adult stage is reached, caligid copepods do not undergo additional moults. In the case of L. salmonis, eggs hatch into the free-swimming first nauplius stage, which is followed by a second nauplius stage, and then the infectious copepodid stage. Once the copepodid locates a suitable host fish, it continues its development through four chalimus stages, first and second preadult stages, and then a final adult stage (Schram, 1993). The moults are characterized by gradual changes as the animal grows and undertakes physical modifications that enable it to live as a free-roaming parasite, feeding and breeding on the surface of the fish.
Feeding of caligid copepods on the mucus, skin and blood of their hosts leads to lesions that vary in severity based on the developmental stage(s) of the copepods present, the number of copepods present, their site(s) of attachment and the species of host. In situations of severe disease, such as is seen in Atlantic salmon (Salmo salar) when infected by high numbers of L. salmonis, extensive areas of skin erosion and haemorrhaging on the head and back, and a distinct area of erosion and sub-epidermal haemorrhage in the perianal region can be seen (Grimnes et al., 1996). Sea lice can cause physiological changes in their hosts including the development of a stress response, reduced immune function, osmoregulatory failure and death if untreated.
There are several management strategies that have been used for reducing the intensity of caligid copepod (sea lice) infestations. These include: fallowing of sites prior to restocking, year class separation and selection of farm sites to avoid areas where there are high densities of wild hosts or other environmental conditions suitable for sea lice establishment (Pike et al., 1999). Although the use of these strategies can in some cases lessen sea lice infection rates, their use individually or in combination has not been effective in eliminating infection.
A variety of chemicals and drugs have been used to control sea lice. These chemicals were designed for the control of terrestrial pests and parasites of plants and domestic animals. They include compounds such as hydrogen peroxide, organophosphates (e.g., dichlorvos and azamethiphos), ivermectin (and related compounds such as emamectin benzoate), insect molting regulators and pyrethrins (MacKinnon, 1997; Stone et al., 1999). Chemicals used in treatments are not necessarily effective against all of the stages of sea lice found on fish, and can create environmental risk. As seen in terrestrial pest and parasites there is evidence for the development of resistance in L. salmonis to some chemical treatments, especially in frequently-treated populations (Denholm, 2002). To reduce the costs associated with sea lice treatments and to eliminate environmental risks associated with these treatments, new methods of sea lice control such as vaccines are needed.
A characteristic feature of attachment and feeding sites of caligid copepods on many of their hosts is a lack of a host immune response (Johnson et al., 2004; Jones et al., 1990; Jónsdóttir et al., 1992). This lack of an immune response is similar to that reported for other arthropod parasites such as ticks on terrestrial animals. In those instances, suppression of the host immune response is due to the production of immunomodulatory substances by the parasite (Wikel et al., 1996). These substances are being investigated for use as vaccine antigens to control these parasites. Sea lice, such as L. salmonis, like other arthropod ectoparasites, produce biologically active substances at the site of attachment and feeding that limits the host immune response. As these substances have potential for use in a vaccine against sea lice we have identified a number of these substances from L. salmonis and have examined their effects of host immune function in vitro.
Secretory proteins produced by the sea lice may act as immunomodulatory agents or assist in the feeding activities on the host (Fast et al., J Parasitol 89: 7-13, 2003, 2004). Neutralization of these activities by host-derived antibodies may impair sea lice growth and survival on salmon.
Vaccines are generally safer than chemical treatments, both to the fish and to the environment. Vaccine development has been hindered by a lack of knowledge of the host-pathogen interactions between sea lice and their hosts. There is therefore a need for further or improved commercial vaccines against sea lice.
WO 2006/010265 relates to recombinant vaccines against caligid copepods (sea lice) based on antigens isolated from sea lice.
The circum-oral glands are putative exocrine glands related to the mouth parts of sea lice. Isolated proteins from circum-oral glands may provide a source of potential antigens for use in vaccines against caligid copepods.
The present invention aims to provide alternative or improved vaccines and/or antigens for the treatment or prevention of caligid copepod infection in fish.
Accordingly, the present invention provides one or more protein, which is isolated from the circum-oral gland (COG) or the frontal gland complex (FGC) of a caligid copepod, or a mutant thereof, wherein the protein is selected from the group consisting of: a mutant of fructose bisphosphate aldolase (FBP); a mutant of glutathione S-transferase 1, isoform D (GST); peptidyl prolyl cis-trans isomerase 5-precursor (PPIase); glutathione S-transferase 1, isoform D (GST); a mutant of triosephosphate isomerase (TIM); and cystathionine gamma-lyase (CSE).
The or each protein is selected from the group consisting of: a mutant of fructose bisphosphate aldolase (FBP); a mutant of glutathione S-transferase 1, isoform D (GST); peptidyl prolyl cis-trans isomerase 5-precursor (PPIase); native GST; a mutant of triosephosphate isomerase (TIM); and cystathionine gamma-lyase (CSE).
Other proteins of the disclosure are selected from the group consisting of: PRX-2; FBP; enolase; TCTP; and TIM.
In the present invention, the term “native” means a sequence that is naturally found in sea lice, preferably Lepeophtheirus salmonis. In the present invention, the term “mutant” means the native form in which one or more, preferably one, amino acid changes have been made, or equivalent nucleotide changes.
The mutant of FBP may be a N286D mutant as defined herein. The mutant of GST may be a S67A mutant as defined herein. The mutant of TIM may be a E166D mutant as defined herein.
TCTP is a highly conserved protein, expressed in all eukaryotic organisms. The protein sequence places it close to a family of small chaperone proteins and is often designated as a stress-related protein because TCTP expression is up-regulated during stress (Bommer and Thiele, 2004; Gnanasekar et al., 2009). For instance, TCTP can prevent hydrogen peroxide induced cell death (Nagano-Ito et al., 2009; 2012). The protein also functions in several cellular processes, such as cell growth, cell cycle progression, malignant transformation, and apoptosis (Boomer and Thiele, 2004). TCTP is also believed to have an extracellular cytokine-like function whereby it modulates the secretion of cytokines from mast cells, basophils, eosinophils, and T and B-lymphocytes (Boomer and Thiele, 2004; Sun et al., 2008). Parasites actively secrete TCTP proteins during host infection as part of their immune evasion strategy (Meyvis et al., 2009; Gnanasekar et al., 2002). Parasitic TCTP proteins have been shown to cause infiltration of eosinophils and/or histamine release from basophils (Bommer and Thiele, 2004; Gnanasekar et al., 2002). When TCTPs from Brugia malayi (Brug, 1927), a human filarial parasite, were injected intra-peritoneally into mice, an influx of eosinophils into the peritoneal cavity was observed suggesting filarial TCTP may play a role in allergic inflammatory responses in the host (Gnanasekar et al., 2002). In addition, intracellular expression of TCTP was shown to protect B. malayi against oxidative stress (Gnanasekar and Ramaswamy, 2007). The TCTP homolog from the parasite Schistosoma mansoni (Sambon, 1907), a human blood fluke, was shown to bind a variety of denatured proteins and protected the parasite from the effects of thermal shock (Gnanasekar et al., 2009). Knockdown of TCTP in Caenorhabditis elegans (Maupas, 1900), a free living nematode, using RNA interference resulted in the reduction in the number of eggs laid in the F0 and F1 generations by 90% and 72%, respectively, indicating the important role TCTP plays in reproduction (Meyvis et al., 2009). Interestingly, a TCTP from Plasmodium was shown to protect the parasite from the anti-malarial drug, artemisinin. Increased expression of TCTP correlated with increased resistance to the drug (Walker et al., 2000). These results suggest that the parasitic form of TCTP may be involved in certain pathological processes in the host.
Peroxiredoxins are a family of peroxidase proteins that are highly conserved and ubiquitously found in all living organisms. Their main role is to protect organisms from oxidative damage that can result from the generation of reactive oxygen species. 2-Cys peroxiredoxin produced in Fasciola gigantica (Cobbold, 1855), a parasite of livestock, was shown to reduce hydrogen peroxide levels and provide protection from oxidative damage (Sangpairoj et al., 2014). Some other proposed cellular functions include differentiation, apoptosis, and proliferation. Protein characterization studies in the hard tick have shown that Prx is expressed in all life stages of the parasite (Tsuji, Kamio et al. 2001). Using immunohistochemistry, Tsuji et al. (2001) was able to show strong Prx reactivity in the salivary glands of Haemaphysalis longicornis (tick). A DNA nicking assay showed H. longicornis recombinant Prx inhibits oxidative nicking of plasmid DNA (Tsuji et al., 2001). When the larval secretory-excretory antigens glyceraldehyde 3-phosphate dehydrogenase (G3PDH), a glycolytic enzyme, and Prx of the human trematode parasite S. mansoni were administered subcutaneously with papain, an allergen that induces T-helper 2 mediated responses, worm burdens and worm egg load in the liver and small intestine of mice were reduced 60-78% (El Ridi et al., 2013). Peroxiredoxin-2 secreted by F. hepatica and S. mansoni has been found to activate alternatively activated macrophages and induce a Th2 driven inflammatory response leading to an increase in IL-4, IL-5, and IL-13 secretion from naïve T helper cells (Donnelly et al., 2008).
Enolase is a key glycolytic enzyme found in the cytoplasm of prokaryotic and eukaryotic cells that catalyzes the conversion of D-2-phosphoglycerate to phosphoenolpyruvate (PEP) and water. It is highly conserved and one of the most abundantly expressed cytosolic proteins of organisms and requires magnesium ions (Mg2+) to be enzymatically active (Diaz-Ramos et al., 2012). There are three different isoforms of α, β, and γ. Alpha enolase is found in almost all human tissues whereas β and γ are found in muscle and neuron and/or neuroendocrine tissues, respectively (Diaz-Ramos et al., 2012). During cellular growth α-enolase is significantly upregulated. It has been identified in hematopoietic cells such as T and B cells, neuronal cells, monocytes, and endothelial cells as a plasminogen receptor (Diaz-Ramos et al., 2012). Studies have also shown that α-enolase can act as a heat-shock protein and a hypoxic stress protein. It is often referred to as a “moonlighting protein” because it has multiple functions at different cellular sites (Diaz-Ramos et al., 2012; Pal-Bhowmick et al., 2007). Enolase has been shown to bind plasmin in other parasitic models and aid in the invasion and migration within host tissues through its fibronolytic activity.
Triose phosphate isomerase is a glycolytic enzyme that catalyzes the interconversion of glyceraldehyde 3-phosphate and dihydroxyacetone phosphate. Furthermore, the interaction of TIM on the surface of parasites (e.g. with lamin and fibronectin) suggests it might be an important virulence factor (Pereira et al., 2007). For example, in S. aureus, TIM is displayed at the cell surface and acts as an adhesion molecule (Furuya et al. 2011). Its location outside the cell suggests it might be important in the adherence and invasion of host tissues. The mechanism(s) of protection are not yet fully understood, however, vaccination studies with a TIM DNA vaccine has proven to be protective against S. japonicum in a mouse model. Mice vaccinated with the TIM DNA vaccine observed worm and egg reduction rates of 30.2% and 52.9% compared to the control (Zhu et al., 2004).
Fructose bisphosphate aldolase is a highly conserved enzyme in the glycolytic pathway that catalyzes the reversible cleavage of fructose-1,6-bisphosphate to dihydroxyacetone phosphate and glyceraldehyde 3-phosphate. Its primary importance is energy metabolism for all living things, but it also has been shown to induce strong humoral and cell mediated immune responses in parasitic infection models (McCarthy, Wieseman et al. 2002; Saber, Diab et al. 2013). For example, mice vaccinated with Schistosoma mansoni FBP DNA vaccine observed a significant reduction in worm burden and intestinal egg counts (Saber et al., 2013). Immunolocalization studies have also shown FBP aldolase is most highly expressed in metabolically active tissues and at all developmental stages of the parasite, Onchocerca volvulus (McCarthy et al., 2002).
Glutathione S-transferase is an enzyme whose main functions are to metabolize and detoxify electrophilic chemicals, drugs, environmental carcinogens, and products of oxidative stress (Wu and Dong 2012; Ketterman et al., 2011; Mounsey et al., 2010; Shahein et al., 2013). It is suggested to be involved in resistance to insecticides by degrading insecticides and/or playing a role in anti-oxidant defense against oxidative damage induced by insecticides (Wu and Dong 2012, Ketterman et al., 2011; Mounsey et al., 2010). Other functions include steroid and prostaglandin biosynthesis and cell apoptosis (Wu and Dong 2012). The GST superfamily consists of several different classes (alpha, zeta, theta, sigma, and omega among others) many of which have been shown to be conserved across vertebrates (e.g. humans) and arthropods (e.g. insects). The GST isoform identified in L. salmonis belongs to the C delta epsilon superfamily (Yamamoto et al., 2013). While its role in L. salmonis has not been characterized, the conservation of GST across lineages suggests it shares a similar function in detoxification. In the copepod, Calanus finmarchicus, cytosolic GSTs were shown to be lowly expressed in the cuticle in embryos and highly expressed in the cuticle of copepodites and adult females (Roncalli et al., 2013). A recombinant GST from Trichinella spiralis (nematode) was tested as a vaccine candidate and shown to induce partial protection in mice post challenge (Lui et al., 2017). Mice that were vaccinated with rTSPGST exhibited a 34.38% reduction in adult worm loads in the intestines and a 43.7% reduction of larvae in skeletal muscles compared to mice injected with PBS alone (Lui et al., 2017).
The peptidyl-prolyl cis/trans isomerase class of proteins is present in all known eukaryotes, prokaryotes, and archaea (Pemberton et al., 2006; Fanghänel et al., 2006). It is comprised of three member families (cyclophilins, parvulins, and FKBP) each of which share the ability to catalyze the cis/trans isomerization of a prolyl bond and accelerate protein folding (Pemberton et al., 2006). The PPIase identified in L. salmonis glandular material belongs to the cyclophilin superfamily. Its role in L. salmonis is unknown. However, it has been shown in other models to be required for the growth and virulence of some pathogens which makes PPIase a good vaccine candidate (Humbert et al., 2015; Devasahayam et al., 2002; Ren et al., 2005; Humbert et al., 2015). For example, a recombinant Toxoplasma gondii cyclophilin DNA vaccine (pVAX1-TgCyP) was evaluated in T. gondii challenged mice (Gong et al., 2013). All vaccinated mice were shown to have a high response to the vaccine developing TgCyP-specific antibodies. Survival rates were also shown to significantly increase post vaccination and challenge (Gong et al., 2013).
Cystathionine gamma-lyase (CSE) is an enzyme which is largely responsible for the production of hydrogen sulfide in vivo. Hydrogen sulfide is produced by CSE via the catalysis of L-cysteine using the reverse transulfuration pathway. Through the use of chemical inhibitors and knock out animals CSE has been identified as a major player in maintaining cardiovascular function. Many of its cardioprotective effects include anti-atherosclerosis, anti-hypertension, and pro-angiogenesis (Huang et al., 2015). Genetic deletion of CSE results in significant hypertension and reduced endothelium-dependent vasorelaxation. Highlighting the importance of hydrogen sulfide in blood pressure regulation and as a physiologic vasodilator (Yang et al., 2008). Furthermore, it has been demonstrated that inhibition of CSE alleviates symptoms of inflammatory disease (Du et al., 2018; Lefer 2018).
In embodiments of the invention, the protein comprises the amino acid sequence of one or more of the group consisting of: SEQ ID NO:1; SEQ ID NO:2; SEQ ID NO:3; SEQ ID NO:4; SEQ ID NO:5; SEQ ID NO:6; and homologues thereof.
Other proteins of the disclosure comprise the amino acid sequence of one or more of the group consisting of: SEQ ID NO:7; SEQ ID NO:8; SEQ ID NO:9; SEQ ID NO:10; SEQ ID NO:11; SEQ ID NO:12; and homologues thereof.
In all aspects of the present invention, “homologues” are sequences having at least 60%, at least 70%, at least 80%, at least 90%, at least 95%, at least 98%, or at least 99% identity to the recited sequence.
In embodiments of the invention, the protein is a recombinant protein.
An aspect of the invention provides an antigen comprising one or more protein according to the invention.
An aspect of the invention provides a vaccine against caligid copepod infection in fish, the vaccine comprising an immunologically effective amount of one or more protein according to the invention, and a pharmaceutically-acceptable diluent or carrier, and optionally an adjuvant. The vaccine may optionally further comprise an immunologically effective amount of one or more of another protein according to the disclosure.
An aspect of the invention provides a vaccine against caligid copepod infection in fish, the vaccine comprising an immunologically effective amount of two or more protein according to the invention, and a pharmaceutically-acceptable diluent or carrier, and optionally an adjuvant.
In embodiments of the invention, each of the one or more antigens is different from the other antigen or antigens in the vaccine.
In embodiments of the invention, the vaccine comprises six or more antigens, wherein one of the six antigens comprises a mutant FBP, one of the six antigens comprises a mutant GST, one of the six antigens comprises PPIase, one of the six antigens comprises GST, one of the six antigens comprises TIM, and one of the six antigens comprises CSE.
In embodiments of the invention, the vaccine comprises six or more antigens, wherein one of the six antigens comprises the amino acid sequence of SEQ ID NO:1, one of the six antigens comprises the amino acid sequence of SEQ ID NO:2 or homologues thereof, one of the six antigens comprises the amino acid sequence of SEQ ID NO:3 or homologues thereof, one of the six antigens comprises the amino acid sequence of SEQ ID NO:4 or homologues thereof, one of the six antigens comprises the amino acid sequence of SEQ ID NO:5 or homologues thereof, and one of the six antigens comprises the amino acid sequence of SEQ ID NO:6 or homologues thereof.
In embodiments of the invention, the caligid copepod is Lepeophtheirus salmonis or Caligus rogercresseyi.
In embodiments of the invention, the fish is a salmonid. In embodiments of the invention, the fish is a salmon or trout.
As aspect of the invention provides, the protein, antigen or vaccine according to the invention for use in the treatment or prevention of caligid copepod infection in fish.
In embodiments of the invention, the caligid copepod is Lepeophtheirus salmonis or Caligus rogercresseyi.
In embodiments of the invention, the fish is a salmonid. In embodiments of the invention, the fish is a salmon or trout.
An aspect of the invention provides a polynucleotide comprising DNA encoding a protein isolated from the circum-oral gland (COG) or the frontal gland complex (FGC) of a caligid copepod, or mutants thereof.
The or each encoded protein is selected from the group consisting of: a mutant of fructose bisphosphate aldolase (FBP); a mutant of glutathione S-transferase 1, isoform D (GST); peptidyl prolyl cis-trans isomerase 5-precursor (PPIase); native GST; a mutant of triosephosphate isomerase (TIM); and cystathionine gamma-lyase (CSE).
Other encoded proteins of the disclosure are selected from the group consisting of: PRX-2; FBP; enolase; TCTP; and TIM.
In embodiments of the invention, the caligid copepod is Lepeophtheirus salmonis or Caligus rogercresseyi.
In embodiments of the invention, the polynucleotide according to the invention comprises DNA encoding the amino acid sequence of one or more of the group consisting of: SEQ ID NO:1; SEQ ID NO:2; SEQ ID NO:3; SEQ ID NO:4; SEQ ID NO:5; SEQ ID NO:6; and homologues thereof.
In other embodiments of the disclosure, the polynucleotide comprises DNA encoding the amino acid sequence of one or more of the group consisting of: SEQ ID NO:7; SEQ ID NO:8; SEQ ID NO:9; SEQ ID NO:10; SEQ ID NO:11; SEQ ID NO:12; and homologues thereof.
In embodiments of the invention, the polynucleotide according to the invention comprises DNA comprising the nucleotide sequence of one or more of the group consisting of: SEQ ID NO:13; SEQ ID NO:14; SEQ ID NO:15; SEQ ID NO:16; SEQ ID NO:17; SEQ ID NO:18; SEQ ID NO:19; SEQ ID NO:20; SEQ ID NO:21; and homologues thereof.
In other embodiments of the disclosure, the polynucleotide comprises DNA comprising the nucleotide sequence of one or more of the group consisting of: SEQ ID NO:22; SEQ ID NO:23; SEQ ID NO:24; SEQ ID NO:25; SEQ ID NO:26; SEQ ID NO:27; SEQ ID NO:28; SEQ ID NO:29; SEQ ID NO:30; SEQ ID NO:31; and homologues thereof.
In embodiments of the invention, the DNA is cDNA.
An aspect of the invention provides an antigen comprising the polynucleotide according to the invention.
An aspect of the invention provides a vaccine against caligid copepod infection in fish, the vaccine comprising an immunologically effective amount of one or more polynucleotides according to the invention, or one or more antigen according to the invention, a pharmaceutically-acceptable diluent or carrier, and optionally an adjuvant.
In an embodiment of the invention, the vaccine comprises an immunologically effective amount of a combination of two or more antigens, wherein each of the one or more antigens independently comprises the DNA sequence selected from the group consisting of: SEQ ID NO:13; SEQ ID NO:14; SEQ ID NO:15; SEQ ID NO:16; SEQ ID NO:17; SEQ ID NO:18; SEQ ID NO:19; SEQ ID NO:20; SEQ ID NO:21; and homologues thereof. The vaccine may further comprise an immunologically effective amount of a combination of two or more antigens, wherein each of the one or more antigens independently comprises the DNA sequence selected from the group consisting of: SEQ ID NO:22; SEQ ID NO:23; SEQ ID NO:24; SEQ ID NO:25; SEQ ID NO:26; SEQ ID NO:27; SEQ ID NO:28; SEQ ID NO:29; SEQ ID NO:30; SEQ ID NO:31; and homologues thereof.
In an embodiment of the invention, the one or more antigens is different from the other antigen or antigens in the vaccine.
In an embodiment of the invention, the vaccine comprises six antigens, wherein one of the six antigens comprises the DNA sequence of SEQ ID NO:13 or homologues thereof, one of the six antigens comprises the DNA sequence of SEQ ID NO:14 or homologues thereof, one of the six antigens comprises the DNA sequence of SEQ ID NO:15 or SEQ ID NO:16 or homologues thereof, one of the six antigens comprises the DNA sequence of SEQ ID NO:17 or SEQ ID NO:18 or homologues thereof, one of the six antigens comprises the DNA sequence of SEQ ID NO:19 or homologues thereof, and one of the six antigens comprises the DNA sequence of SEQ ID NO:20 or SEQ ID NO:21 or homologues thereof.
In an embodiment of the invention, the vaccine may further comprise five antigens, wherein one of the five antigens comprises the DNA sequence of SEQ ID NO:22 or SEQ ID NO:23 or homologues thereof, one of the five antigens comprises the DNA sequence of SEQ ID NO:24 or SEQ ID NO:25 or homologues thereof, one of the five antigens comprises the DNA sequence of SEQ ID NO:26 or SEQ ID NO:27 or homologues thereof, one of the five antigens comprises the DNA sequence of SEQ ID NO:28 or SEQ ID NO:29 or homologues thereof, and one of the five antigens comprises the DNA sequence of SEQ ID NO:30 or SEQ ID NO:31 or homologues thereof.
In an embodiment of the invention, the caligid copepod is Lepeophtheirus salmonis or Caligus rogercresseyi.
In an embodiment of the invention, the fish is a salmonid. In an embodiment of the invention, the fish is a salmon or trout.
An aspect of the invention provides, the polynucleotide, antigen or vaccine according to the invention for use in the treatment or prevention of caligid copepod infection in fish.
In an embodiment of the invention, the caligid copepod infection is a Lepeophtheirus salmonis or Caligus rogercresseyi infection.
In an embodiment of the invention, the fish is a salmonid. In an embodiment of the invention, the fish is a salmon or trout.
An aspect of the invention provides, a method of treatment or prevention of caligid copepod infection in fish, comprising administering a therapeutic amount of the protein, polynucleotide, antigen, or vaccine of any one previous claim, optionally with the co-administration of an adjuvant.
In an embodiment of the invention, the caligid copepod infection is a Lepeophtheirus salmonis or Caligus rogercresseyi infection.
In an embodiment of the invention, the fish is a salmonid. In an embodiment of the invention, the fish is a salmon or trout.
The skilled person will appreciate that the claimed invention includes in its scope for the purposes of determining infringement variants of the claimed features that achieve substantially the same result in substantially the same way as the invention.
The invention will now be described by way of example with reference to the drawings in which:
For each of
For each of
Absorbance at 450 nm shown for individual fish (circles, squares or triangles) with line indicating mean±SEM (n=12 fish per group). DM2 cocktail (delivery method 2 cocktail) is a vaccine prime using a cocktail of five recombinant antigens (50 μg) with vaccine boost using cocktail of five recombinant proteins (50 m). DM2 ctrl (delivery method 2 control) is a “prime” using mCherry-His recombinant protein (250 μg) plus flagellin (50 ng) with vaccine boost using mCherry-His recombinant protein (250 m).
The circum-oral glands (COGs) were visualized in L. salmonis at chalimus stages using 3,3′-diaminobenzidine tetrahydrochloride (DAB). COGs were isolated by microdissection and transferred into microcentrifuge tubes containing protease inhibitor cocktail (AEBSF [4-(2-aminoethyl)benzenesulfonyl fluoride] at 2 mM, Aprotinin at 0.3 μM, Bestatin at 116 μM, E-64 at 14 μM, Leupeptin at 1 μM and EDTA at 1 mM in 100 ml stock solution; Sigma-Aldrich Cat. No. P2714) at a 1 to 10 dilution in cold, sterile crustacean Ringers saline. Ringers saline was prepared by dissolving 0.58 M sodium chloride, 0.013 M potassium chloride, 0.013 M calcium chloride, 0.026 M magnesium chloride, 0.00054 M disodium hydrogen phosphate in 0.05M Tris-HCl, pH 7.5. Tissue was homogenised for two minutes at a frequency of 28 hertz using a TissueLyser II (Qiagen) by adding 100 μl 0.5 mm glass beads (BioSpec Products, catalog number 11079105) to 100 μl of sample. The supernatant was collected by centrifuging homogenate at 10,000×g for 30 minutes at 4° C. Protein concentration was determined using a BCA protein assay kit (Pierce Cat. No. 23227). The COG supernatant yielded 610 μg of protein. Samples were stored at −80° C.
Protein samples were concentrated with a 3K MWCO concentrator (Pierce) following manufacturer's instructions, and run on a SDS-PAGE gel. Gel slices containing proteins at 40 and 25 kDa were then analysed by nano-LC MS/MS.
Eight native proteins identified by the nano-LC MS/MS analysis were selected as candidate antigens: fructose bisphosphate aldolase (FBP; Hu et al., 2015; Lorenzatto et al., 2012); triosephosphate isomerase (TIM; Furuya et al. 2011; Saramago et al., 2012); peroxiredoxin-2 (Prx-2; Knoops et al., 2016; Rhee et al., 2016; Wood et al., 2003); enolase (Diaz-Ramos et al, 2012; Wang et al., 2013); and transitionally-controlled tumour protein homolog (TCTP; Gnanasekar et al., 2009; Gnanasekar and Ramaswamy, 2007; Sun et al., 2008; Nagano-Ito et al., 2009 and 2012); Glutathione S-transferase 1, isoform D (GST; Mounsey et al., 2010; Roncalli et al., 2015); Peptidyl-prolyl cis-trans isomerase 5 precursor (PPIase; Kramer et al., 2004; Ren et al., 2005; Devasahayam et al., 2002); Cystathionine gamma-lyase (CSE; Lee et al., 2014; Sun et al., 2009).
The glycosylation of our protein targets was examined using NetNGlyc 1.0. The server identified one potential N-linked glycosylation site for both FBP and TIM.
NetOGlyc 4.0 software identified two potential O-linked glycosylation sites for Prx-2.
Protein sequencing results from the nano-LC MS/MS analysis were used to blast NCBI database to obtain the complete mRNA coding sequence. As a quality control measure, the NCBI mRNA sequences of FBP, enolase, TIM, TCTP and Prx-2 were validated by performing RACE cDNA synthesis. To perform RACE cDNA synthesis, cDNA was prepared from RNA collected from 10 adult sea lice (RNeasyR Mini kit (Qiagen)). 5′ and 3′-RACE-Ready cDNA was prepared using a SMARTer RACE 5′/3′ cDNA synthesis kit (TaKaRa) for rapid amplification of cDNA ends. Primers were specially designed for each protein to ensure amplification of the 5′ end (5′ RACE PCR) or 3′ end (3′ RACE PCR) of the mRNA (see Table 1 for list of primers used). PCR products were gel extracted using the NucleoSpin Gel and PCR clean up kit (Clontech).
In-Fusion cloning of RACE products was then performed following the manufacturer's instructions. Single colonies (8-10) were isolated from culture plates and grown overnight in selective media (ampicillin) at 37° C. with shaking (˜180 rpm). Plasmid DNA was isolated from bacterial lysates using a QIAprep Spin Miniprep Kit following the manufacturer's instructions (Qiagen). To determine which clones contained our RACE insert, we analyzed the DNA by restriction digest using EcoRI and HindIII which flank the cloning site. Digested products were visualized on a 1% ethidium bromide gel.
Clones containing the largest gene specific inserts were sequenced. The mRNA sequencing results for FBP, enolase, TIM, TCTP and Prx-2, and the mRNA sequences for PPIase, GST and CSE used in the present invention, are shown in below (coding region underlined):
ATCCTTGCTCTTACCCTTTTCGTGACCTTCGCCTATGGGGATGACAATTCCAAGGGTCCCAA
AGTAACAGAAACAGTCACATTCTCCATATCCATCGGAGGCAAACCCGCTGGTGATATTAAGA
TTGGACTGTTTGGAAAGACTGTGCCAAAGACGGTCAAGAACTTTGTTGAGCTCGCAGCAAAG
GAAGACAAAGGCGAGGGTTACAAGGGCTCCAAGTTCCATCGCGTCATTAAGGACTTTATGCT
CCAAGGAGGTGACTTTACTCGTGGAGACGGAACTGGTGGACGATCCATCTACGGAGAGAGAT
TTGCAGATGAAAACTTCAAGCTGAAGCACTACGGGGCTGGATGGTTGTCCATGGCCAATGCC
GGAAAAGACACAAATGGATCTCAATTCTTCATCACTACCAAAAAGACCTCATGGCTCGATGG
GAAACACGTTGTCTTTGGAAAGATCATTGGGGGCATGGACGTTGTTCGAAAAATTGAAAGGT
CCAGTACGGACGGAAGAGATCGTCCTGTTGAGGATGTTGTCATTGAAGCCGCCACGGTTGAA
AAACTTGATAAACCACTCAGTGTTCCCAAGGCGGATGCTGATGAATAAATTTGTTTCCTTTT
AGGATCGCTACAATGACTGCTGAAGTTGTTGGAGCTCCTTATGAAGTTAAGGATGTTGATAT
CTTTAATGGAGGTAGCAAGACACCTGAATTTCTTGAATTGAATCCTCAACACAACATCCCAG
TACTTAAGTATAAGGATTTTGTAATGAACGAGAGTAGAGCTATTGCTGGATTCTTGGCCTCA
GAATTTGATAAAAGTGGCAAACTTTACCCAACCTGTCCCATGGCCCATGCTCGAGTTAATCA
ACGGTTATACTTCGATATGGGAGTTTTTTATAAGGCCTTTGGAGAGTGTGTGTACCCAATAA
TGTTTGCCAATGCTGATGTTCCTGCAGAAAAATACGACAAACTCAAAGAAGTTTTAGGATGG
GCCAATGATATGGTAAAAGAGACAGGATTTGCTGCTGGTACCGAAGAGATGACAATTGCTGA
TATCGCTTGGGTGGCTACATACAGTTCTATAAAGGAAGCTGATGTGATTGACTTAGTTCCTT
ACAAAGAATTGGACGCATGGTTTACCAAATGTGTAGCACTTATTCCAAATTATGAGACGTGC
AATGGAAAGGGAGCCAAAGGATTTGGAGATTTTTACAAATCCAAAAGGAAAGAATAATCTTT
TGGACAAAATCCGGAGCAATGGAAATCTTTGGCTGTCGTTCCTCATATAACCCTCTCCACAA
CCTATAAACAATATCATCCTGGACAACCCAAAGAGTTTGAATACGGAAGAGGTGGAAATCCT
ACTCGTAATATCCTCGAGACATGTATGGCCTCTTTGGATGGTGCTAAACATTGTGTGACTTT
TGCTTCTGGTTTAGCAGCTTTAGATGCTATGACTACTATTTTGTCATGTGGGGATCACATTG
TTGCCATGAATGATTTGTATGGGGGAACTAATCGATTTTTACGACGAGTATCCGCTAAGCAG
GGTCTTACGTCAACTTTTGTCGATATTAATCACGAAGAACTTTTTTCTGCATCGTTTCAAGA
TAACACAAAAATGGTATGGATTGAAAGCCCTACAAATCCAACATTACGTATTGTAGACATCA
AAAAGGCCGTATCCATTGCCAAATCCAAGAATCCCAATATAATTGTTGTAGTTGACAATACA
TTTGTGACCTCATACTTTCAACGGCCCTTGGAATTAGGAGCTGATGTTACATACTATTCATG
TACAAAGTATATGAACGGTCATTCTGATGTTATTATGGGTGCCGTTTGTATAAACAGTGATG
AAATCCACGAAAGAGTTCGATTTGTTCAATATGCTGTGGGTGCTGTTCCTAGTCCTTTTGAT
TGCTTTCTCGTAAATCGTAGTCTCAAGACTCTCAAAGTAAGAATGGTCGAACATCAAAAAAA
TGCTCTTATTGTTGGAAAATTTTTAGAAGGTCATTCCAAGATTACCAAGGTTATACACCCTG
GATTACCATCCCATCCCGACCATGAAATTGTCAAAAAACAACAGTATGGCCATTCTGGCATG
GTATCATTTTATCTCAAGGGTGGACTAGAAGAATCCAACAATTTTTTGAAGGCTGTTAAAGT
ATTTATACTCGCAGAGTCTCTTGGAGGTTTCGAATCTTTAGCGGAGTTACCTTACTCTATGA
CTCATGCTTCTGTTGCAGAAGAGGAACGGGTTGCTCTTGGTGTTACTAATAATCTCATCAGA
CTCTCAATTGGACTTGAAAATGCCGATGATCTCTGTGCAGATTTAGATCAAGCTCTTAATAT
CGCATGTTCATAATAAATATTATATATTTAACATCGACTTTGAAGATATCTAAATCAAGCAT
CGTTGTGAACAAGGAATTCAAGGAGGTGTCACTCAAGGACTATACCGGCAAATACGTGGTTC
TCTTTTTCTACCCCTTGGACTTTACCTTTGTTTGCCCCACAGAAATCATTGCCTTTGGAGAT
CGGGCTGCAGATTTCCGTAAAATTGGATGTGAGGTCCTTGCCTGCTCCACTGACTCCCATTT
TTCTCATCTCCACTGGATCAACACTCCTCGTAAGGAGGGAGGACTTGGGGACATGGACATTC
CCCTCATTGCGGATAAGAACATGGAAATTTCTAGAGCCTATGGCGTGCTCAAGGAAGACGAT
GGAGTGTCCTTCAGAGGACTTTTCATCATTGACGGCACTCAGAAACTCCGTCAAATCACAAT
CAATGATCTTCCTGTCGGAAGATGCGTAGACGAAACCTTAAGACTTGTACAAGCCTTCCAAT
ACACAGACGTGCATGGCGAGGTTTGCCCTGCGGGATGGAAGCCAGGAAAGAAGTCTATGAAG
CCCAGCAAGGAAGGTGTCTCATCTTACCTCGCAGATGCTGAACAATCAAAGAAATAATACAG
AATCTTATTAAGTTGTTCGAATACTGTAGAGACCATAAAGTTGCTCTCCCTGCTTTCAACTG
CACGTCTTCTTCAACCATCAATGCAGTTTTGCAAGCAGCACGGGACATTAAATCCCCTGTGA
TTGTTCAATTTTCCAATGGTGGAGCTGCTTTTATGGCCGGCAAAGGCATCAAAAATGACGGT
CAAAAGGCTAGTGTCCTTGGTGCAATTGCTGGGGCTCAACATGTTCGTTTAATGGCAAAGCA
CTATGGTGTTCCTGTAGTTCTTCACTCTGATCACTGTGCTAAAAAACTCCTCCCATGGTTTG
ATGGAATGCTTGAAGCTGATGAAGAGTATTTCAAACAAAATGGTGAACCTCTTTTCTCCAGT
CACATGCTTGATCTCTCGGAGGAGTTTGATGAAGAAAATATTTCCACTTGTGCAAAATATTT
TACTCGCATGACTAAAATGAAAATGTGGTTAGAAATGGAAATTGGAATCACTGGGGGCGAAG
AGGATGGTGTTGACAATACCAATGTGAAAGCGGAGTCTCTTTACACCAAACCCGAACAAGTT
TACAACGTGTACAAAACACTCAGCGAAATTGGACCAATGTTTTCCATTGCTGCCGCTTTTGG
AAACGTACATGGTGTATACAAGGCAGGTAACGTTGTTCTTTCCCCACATTTGTTGGCTGATC
ATCAAAAATACATCAAGGAGCAAATTAACTCCCCACTTGATAAACCCGCCTTCCTTGTCATG
CACGGAGGCTCCGGCTCCACCAGAGAAGAAATTGCTGAAGCAGTAAGCAACGGTGTGATCAA
AATGAATATTGATACGGATACTCAATGGGCTTACTGGGATGGTCTCAGAAAGTTTTATGAAG
AAAAGAAGGAGTATCTTCAAGGACAGGTTGGAAATCCAGAAGGCGCTGACAAGCCAAACAAA
AAGTTTTACGATCCACGAGTTTGGGTTCGTGCTGCTGAGGAGTCTATGATTAAGAGAGCCAA
TGAATCCTTTGAATCATTAAACGCTGTGAATGTCCTTGGTGACTCCTGGAAACACTAAATAC
GCCTATTAAACACATTCATGCACGTCAAATCTACGACTCTCGTGGTAACCCTACAGTGGAGG
TGGATCTCACCACTGAGCGAGGGATTTTCCGCGCTGCCGTCCCCAGTGGAGCTTCCACAGGG
GTTCATGAGGCCCTGGAACTGCGCGACAAGGACTCTACCTGGCACGGGAAGAGTGGTCTCAA
GGCTGTGAAGAATGTGAACGACGTCCTTGGGCCCGAGTTGGTGAAGAAGAACCTTGACCCCG
TGAAGCAAGAGGAGATCGATGATTTCATGATCAGCCTCGACGGGACGGATAACAAGAGCAAA
TTTGGGGCTAATTCTATTTTGGGAATCTCGATGGCTGTGTGCAAGGCTGGTGCCGCCCACAA
GGGTGTTCCCCTCTACCGCCATATCGCTGACTTGGCGGGTGTGAAGGAAGTGATGATGCCGG
TGCCCGCATTTAATGTCATTAACGGAGGTTCTCATGCTGGAAATAAGTTGGCGATGCAAGAA
TTCATGATCCTTCCAACTGGAGCTCCCTCCTTCACTGAAGCCATGAGGATGGGATCTGAAAT
CTATCACCATCTCAAGGCTCTTATCAAGAAGAAGTACGGGTTGGATGCTACAGCCGTTGGAG
ATGAGGGTGGCTTTGCTCCCAACTTCCAAGCCAACGGCGAGGCTATCGACCTTCTTGTTGGA
GCCATTGAAAAGGCTGGATACACTGGAAAAATCAAGATCGGAATGGATGTTGCTGCTTCAGA
ATTTTACAAAAATGGAAAGTACGATTTAGATTTCAAAAATGAAGAATCCAAAGAGGCCGATT
GGCTAACTTCCGAGGCTCTTGGTGAAATGTACAAAGGATTCATCAAGGATGCACCTGTCATT
TCCATTGAAGATCCCTACGATCAAGATGATTGGGAGGGATGGACTGCATTGACATCACAAAC
TGACATTCAGATTGTCGGAGATGATCTCACAGTCACAAACCCCAAGCGTATTCAAATGGCTG
TTGACAAGAAATCTTGCAACTGCCTCCTCTTGAAAGTAAATCAAATTGGTTCAGTAACTGAA
TCTATTCGGGCCCACAATCTTGCTAAGAGCAACGGCTGGGGTACCATGGTCTCTCATAGATC
TGGTGAGACAGAGGATTGTTTCATCGCTGATCTCGTCGTTGGTCTCTGCACTGGTCAAATCA
AGACTGGAGCTCCTTGCAGATCCGAACGTTTGTCTAAATACAATCAATTGTTGCGTATTGAA
AGATGAATTATTTTCCGACACCTACAAGTTCAAGTTGTTGGATGATTGCTTGTACGAGGTGT
ATGGAAAGTATGTCACACGGACTGAAGGAGATGTGGTTCTTGATGGAGCCAACGCATCTGCT
GAAGAGGCCATGGATGACTGTGATTCCTCTTCCACCTCTGGTGTCGATGTTGTCCTTAACCA
CCGTCTGGTCGAAACTGGGTTCGGTTCCAAGAAGGACTACACCGTATACCTTAAGGACTACA
TGAAGAAGGTAGTGACATATTTAGAAGAAAATGGCAAACAAGCCGAAGTAGATACCTTCAAG
ACCAACATCAACAAGGTCATGAAGGAACTTTTACCACGGTTTAAGGATCTTCAATTCTATAC
TGGAGAAACGATGGACCCTGAGGCCATGATCATCATGCTTGAATACAAGGAAGTTGATGGAA
AGGATATTCCCGTCCTCTACTTTTTTAAACATGGATTAAATGAAGAAAAATTTTAAACATTA
GAAAATGAATGGAGACAAGAAATCTATTGATGGAATCGTAGATTTTTTGAGCAAGGGGGATT
TGGACCCAAATTGTGAGGTTGTTGTTGGAGCCTCACCCTGCTATTTGGACTATTCCCGTTCT
AAACTTCCTGCCAATATCGGAGTGGCTGCACAAAATTGTTATAAGGTGGCCAAAGGAGCATT
TACCGGAGAAATCAGTCCTCAAATGATTAAAGATGTTGGTTGTGAATGGGCGATTCTTGGTC
ATTCAGAGCGTAGAAATGTCTTTGGGGAATCTGATGAGCTCATTGGCGAAAAGGTTGCTTTT
GCACTTGAGTCTGGTCTCAAAATTATTCCATGCATTGGAGAAAAATTAGACGAACGTGAATC
TGGGAAGACTGAGGAGGTCTGCTTTAAGCAACTTAAAGCCATTTCTGACAAAGTATCTGATT
GGGATCTTGTCGTCTTAGCTTATGAACCAGTTTGGGCCATTGGAACTGGCAAAACAGCTACA
CCTGCTCAGGCTCAAGAAACACATCTTGCTCTTCGTAAATGGCTAAAGGAGAACGTTTCTGA
GGAAGTTTCACAAAAAGTGCGAATCCTCTATGGAGGTTCCGTGAGTGCTGGTAATTGCAAGG
AACTTGGCACTCAGCCTGATATTGACGGCTTCCTTGTTGGAGGAGCCTCTCTCAAACCTGAC
TTTGTTCAAATCATCAACGCTACTAAGTAAACAAAATACTGGATATTCGACTCTTCTATAAT
The mRNA sequencing data of the target proteins was aligned and compared with the corresponding NCBI mRNA sequence using the Clustal Omega multiple sequence alignment tool (EMBL-EBI).
In most cases, mRNA sequence data matched exactly or very closely (only single base pair differences) to the NCBI database, however, for one protein, enolase, an additional isoform was identified (new start codon identified upstream from the start site of the NCBI sequence). Using UniProt (Universal Protein Resource) the sequence matched with 99% identity to Tribolium castaneum, the red flour beetle. Both the red flour beetle (hexapod) and sea louse (crustacean) belong to the clade Pancrustacea in the phylum arthropoda (www.uniprot.org).
The mRNA sequences of PPIase, CSE and GST were obtained from NCBI (National Center for Biotechnology Information; Bethesda, Md., United States), but not validated by performing RACE cDNA synthesis. The PPIase mRNA sequence has the NCBI accession number BT078668.1. The CSE mRNA sequence has the NCBI accession number BT078138.1. The GST mRNA sequence has the NCBI accession number BT078543.1.
In addition to the eight native proteins, mutant versions of GST, FBP and TIM were evaluated as vaccine antigen candidates. Mutant nucleotide sequences comprising mutations were generated using standard molecular techniques, such that each mutant produced a single amino acid substitution at the amino acid level. Thus, a mutant GST in which the S at position 67 is replaced with an A (i.e. the GST S67A), a mutant FBP in which the N at position 286 is replaced with an D (i.e. the FBP N286D) and a mutant TIM in which the E at position 166 is replaced with an D (i.e. the TIM E166D) were produced.
The characteristics of sea lice antigens are provided in Table 2.
The edited sequences were used to produce the protein antigens by recombinant protein production in E. coli. The DNA sequence for each protein was codon optimized prior to gene synthesis and cloned into the pET-30a (+) expression vector with N-terminal His tag along with TEV cleavage site. Recombinant plasmids were then transformed into E. coli BL21 (DE3) cells and grown overnight at 37° C. A single colony was selected and inoculated into 1 litre of LB media containing kanamycin and incubated at 200 rpm at 37° C.
The expression DNA sequences were as set out below:
To evaluate the level of expression of our targets, small-scale cultures (4 ml) were grown to optimize the temperature, expression time, and Isopropyl β-D-1-thiogalactopyranoside (IPTG) concentration. SDS-PAGE and western blot were used to monitor expression over the different conditions. Once the optimum conditions were identified, culture volume was scaled up to 1 L to ensure ≥10 mg of protein per target.
After IPTG induction, the 1 L culture was spun down to collect cell pellets. Pellets were then lysed with lysis buffer and sonicated. Both supernatant and pellet fractions were collected and evaluated by SDS-PAGE to identify which fractions contained the target protein. For all proteins except for enolase, the proteins were located in the supernatant and therefore were soluble.
Soluble proteins were purified by adding the supernatant of the cell lysate to several millilitres of Ni-NTA (nickel-nitrilotriacetic acid) resin for high capacity, high performance nickel-IMAC (immobilized metal affinity chromatography), which is used for routine affinity purification of His-tagged proteins.
For insoluble proteins, pellets from the cell lysate were solubilized with urea, purified by N-column purification under denaturing conditions, and then refolded. Protein fractions were pooled and filter sterilized (0.22 μm).
To ensure ≥90% purity of the proteins, an additional two steps of purification by densitometric analysis of Coomassie blue stained SDS-PAGE gel was performed. Proteins were further analysed by western blot using primary mouse-anti-His mAb (GenScript, Cat. No. A00186). Protein concentration was determined using the Bradford protein assay with BSA standards (Pierce).
Aliquots were prepared in 1×PBS buffer with 10% glycerol (pH 7.4) and stored in −80° C. The expression product of the FBP N286D expression DNA sequence (SEQ ID NO:40) is SEQ ID NO:51, which has the following sequence (TEV protease cleavage site is underlined, and the leading 6His tag is apparent):
The expression product of the GST S67A expression DNA sequence (SEQ ID NO:41) is SEQ ID NO:52, which has the following sequence (TEV protease cleavage site is underlined, and the leading 6His tag is apparent):
The expression product of the PPIase expression DNA sequence (SEQ ID NO:42) is SEQ ID NO:53, which has the following sequence (TEV protease cleavage site is underlined, and the leading 6His tag is apparent):
The expression product of the GST expression DNA sequence (SEQ ID NO:43) is SEQ ID NO:54, which has the following sequence (TEV protease cleavage site is underlined, and the leading 6His tag is apparent):
The expression product of the TIM E166D expression DNA sequence (SEQ ID NO:44) is SEQ ID NO:55, which has the following sequence (TEV protease cleavage site is underlined, and the leading 6His tag is apparent):
The expression product of the CSE expression DNA sequence (SEQ ID NO:45) is SEQ ID NO:56, which has the following sequence (TEV protease cleavage site is underlined, and the leading 6His tag is apparent):
The expression product of the Prx-2 expression DNA sequence (SEQ ID NO:46) is SEQ ID NO:57, which has the following sequence (TEV protease cleavage site is underlined, and the leading 6His tag is apparent):
The expression product of the FBP aldolase expression DNA sequence (SEQ ID NO:47) is SEQ ID NO:58, which has the following sequence (TEV protease cleavage site is underlined, and the leading 6His tag is apparent):
The expression product of the Enolase expression DNA sequence (SEQ ID NO:48) is SEQ ID NO:59, which has the following sequence (TEV protease cleavage site is underlined, and the leading 6His tag is apparent):
The expression product of the TCTP expression DNA sequence (SEQ ID NO:49) is SEQ ID NO:60, which has the following sequence (TEV protease cleavage site is underlined, and the leading 6His tag is apparent):
The expression product of the TIM expression DNA sequence (SEQ ID NO:50) is SEQ ID NO:61, which has the following sequence (TEV protease cleavage site is underlined, and the leading 6His tag is apparent):
The expression products were typically applied as antigens. Antigens may also be applied after 6His tag removal using TEV protease. Thus, the antigens may have a leading G residue. The variants of SEQ ID NOs:27 to 31 produced by TEV protease cleavage or as defined by SEQ ID NOs:1-6 are considered to achieve substantially the same result in substantially the same way as SEQ ID NOs:27 to 31 and as defined by SEQ ID NOs:1-6 with a leading G residue. Polynucleotide antigens encoding the same proteins are also considered to achieve substantially the same result in substantially the same way as their polynucleotide variants.
Thus, the presence or absence of a His tag or an equivalent standard tag and the present or absence of a TEV cleavage site, an equivalent cleavage site or the post-cleavage remnants thereof, are not considered to affect the antigenic properties of the protein or polynucleotide antigens.
For DNA vaccine production, each of the five antigens were cloned into the pVAX1™ plasmid vector (Invitrogen). A 3 kb vector was designed to promote high-copy number replication in E. coli and high level expression in most mammalian cell lines.
TIM was additionally cloned into the pVAC1 vector (InvivoGen). pVAC1 is a DNA vector vaccine plasmid designed to stimulate a humoral immune response via intramuscular injection. Antigenic proteins are targeted and anchored to the cell surface by cloning the gene of interest in frame upstream of the C-terminal transmembrane anchoring domain of placental alkaline phosphatase (InvivoGen). The antigenic peptide produced on the surface of muscle cells is believed to be taken up by antigen presenting cells and processed through the major histocompatibility complex class II pathway (InvivoGen).
The pVAC1-mcs backbone was selected over pVAC2-mcs for cloning because 1) the gene of interest does not contain a signal peptide even though it is secreted in vivo and 2) the vector induces a humoral immune response. The signal sequence IL-2 and the 3′ glycosyl-phosphatidylinositol (GPI) anchoring domain of human placental alkaline phosphatase directs cell surface expression of the antigenic protein (InvivoGen). The 3737 bp vector contains a Zeocin™ resistance gene and was designed for high-copy number replication in E. coli. The EF1-α gene of the pVAC1 vector ensures high levels of expression in skeletal muscle cells and antigen presenting cells. Furthermore, the SV40 enhancer gene heightens the ability of the plasmid to be transported into the nucleus, especially in non-diving cells (InvivoGen).
The vectors, pVAX1 and pVAC1, are non-fusion vectors, therefore, the inserts needed to include a Kozak translation initiation sequence (e.g. ANNATGG) containing the initiation codon and a stop codon for proper translation and termination of the gene. Primers were designed using SnapGene software to amplify a region that included the restriction enzyme site, the start codon, and the stop codon of the mRNA sequence of our target proteins. The primers are as set out in Table 3. The primers were used to amplify gene products from L. salmonis cDNA via PCR. PCR products of the expected size were PCR or gel purified, digested with the appropriate restriction enzymes, and then PCR purified again.
Vectors were linearized with the appropriate restriction enzymes for each insert. Linearized vector and insert were ligated with T4 DNA ligase (Invitrogen) and transformed into E. coli Stellar competent cells (Clontech). Transformants were cultured on LB plates containing 50 μg/ml kanamycin overnight at 37° C.
Single colonies were isolated and cultured overnight in 5 ml LB media+kanamycin (50 μg/ml) at 37° C. with shaking. Glycerol stocks were prepared and stored at −80° C. for each clone. Plasmid DNA was isolated from bacterial lysates using a QIAprep Spin Miniprep Kit (Qiagen) and then digested with the appropriate restriction enzymes and ran on a 1% ethidium bromide gel. Digested clones showing two bands corresponding to the size of the vector and insert were submitted for sequencing using T7 forward and BGH reverse primers (pVAX1 vector) or pVAC1 forward and pVAC1 reverse primers (pVAC1 vector)—see Table 4 for primer sequences.
Clones containing inserts that shared high sequence similarity with the target sequence and in the correct orientation were selected for large-scale plasmid isolation. Two different kits were used for large-scale DNA vaccine preparation: Invitrogen's PureLink™ HiPure Expi Megaprep kit and Qiagen's QIAfilter plasmid giga kit. Due to the low plasmid yields obtained from the Invitrogen kit, the Qiagen Giga kit was the preferred method of isolation.
A 500 ml (PureLink™ kit) or 2.5 L culture (Qiagen Giga kit) was prepared following the manufacturer's instructions. Briefly, glycerol stocks of positive clones were used to streak a LB+kanamycin plate. A single colony was selected to inoculate 5 ml LB media+kanamycin and grown for 8 h at 37° C. with shaking (˜180 rpm). One milliliter was then transferred to 5-500 ml aliquots of LB media+kanamycin and grown overnight (12-14 h) for large-scale plasmid isolation the following day. All steps were performed following the manufacturer's instructions. Plasmid DNA was resuspended in nanopure water and the total amount (mg) of plasmid DNA was quantified using the NanoDrop 8000 Spectrophotometer (Thermo Scientific). Aliquots were prepared and stored at −20° C. As a quality control measure all plasmids were ran on a 1% ethidium bromide gel to check for bacterial contamination and insert. All DNA vaccines were re-sequenced before use in vaccine trial.
To evaluate the ability of the five candidate sea lice antigens identified in Example 1 to produce an immunological response in Atlantic salmon, the fish were vaccinated with five antigens simultaneously and the systemic antibody titer at 600 degree days after vaccination.
In more detail, Atlantic salmon of around 40 g in weight were divided into five treatment groups, each group consisting of two duplicate tanks of six salmon. The treatment groups were as follows:
Thus, treatment groups 3 and 4 received sham treatments that contained none of the five antigens, and treatment group 5 served as a control for any non-specific immune responses to injury at vaccination of naïve fish.
The control mCherry recombinant protein was produced using the following mRNA (SEQ ID NO:62):
The recombinant mCherry protein had the following sequence (SEQ ID NO:63):
Thus, mCherry may have the sequence recited above, which has a His tag (HHHHHH; SEQ ID NO:88) and a TEV cleavage site (ENLYFQG; SEQ ID NO:89), a TEV cleaved variant sequence, or another tagged or untagged variant sequence.
A further 12 Atlantic salmon were held in duplicate tanks of 6 fish each. These fish were acclimatized for 25 days in the system prior to sampling for basal level immune responses of the population prior to vaccination. This group served as a control for basal specific antibody responses to the antigens.
All the immune sampling (i.e. blood and mucus sampling post-vaccination) occurred at 602 degree days post-priming vaccination, which the period after which you can begin to detect specific antibody titers to the vaccine antigens. Degree day was calculated by multiplying the average temperature by the number of days (DD=((T0+T1+ . . . )/no. of days)×no. of days).
Atlantic salmon parr approximately 40 g in weight were obtained from the USDA, Franklin, Me. facility. Fish were maintained in a recirculating fresh water flow through system in 100-gallon tanks at a stocking density of 25 kg/m3 and were fed at a rate of 1.5% body weight per day. Water quality and fish condition were monitored daily.
After a 25-day acclimation period, Atlantic salmon parr were vaccinated. Atlantic salmon were anaesthetized prior to tagging and vaccination by netting fish into 100 mg/L of MS222 supplemented with 200 mg/L sodium bicarbonate as a buffer to sustain neutral pH. The fish were tagged with elastomer along the jaw line for ease of identification.
The fish were primed by intramuscular injection of the vaccine at a dose of 10 μg per antigen per fish (DM1), a cocktail recombinant protein vaccine at a dose of 50 μg per antigen per fish in a total volume of 30 μl in sterile phosphate buffered saline with 50 ng ultrapure flagellin from Pseudomonas aeruginosa (InvivoGen; “DM2”; n=48 fish per treatment group; duplicate tanks of 24 fish per group), or with the control formulation as appropriate. Post-tagging and vaccination the fish were returned to their respective housing tanks and monitored continuously until full recovery.
Two weeks after prime vaccination, the fish were anaesthetized and received a boost vaccination of recombinant proteins intraperitoneally at a dose of 50 μg per protein per fish, adjuvanted with Montanide™ ISA 763 A VG in a total volume of 100 μl (DM1 and DM2).
To measure the specific antibody response to louse antigens post-vaccination the blood and mucus of 12 Atlantic salmon per treatment group were sampled at 602-degree days for ELISA and dot blot analysis, respectively. Fish were euthanized with a lethal dose of 250 mg/L MS-222 buffered with 100 mg/L sodium bicarbonate. Blood was collected by bleeding the fish via the caudal vein. Blood samples were incubated at 4° C. overnight and serum was isolated by centrifugation at 3716×g for 10 min at 4° C. Serum was isolated and stored at −80° C. until further use. Skin mucus samples were collected by placing the fish in a bag containing 10 ml phosphate buffered saline and massaging the fish for 2 minute each to wash off mucus. Mucus was centrifuged at 3716×g for 10 minutes at 4° C. and the supernatant transferred into sterile tubes and stored at −80° C.
The efficacies of the vaccines in eliciting a systemic immune response were evaluated for each vaccine candidate. All ELISA's were optimized prior to running serum samples from each fish. Optimal protein concentration, primary, and secondary antibody concentrations were determined for each antigen by running a checkerboard assay (Table 5).
One hundred microliters of antigen (2 μg per well in carbonate:bicarbonate coating buffer; Sigma) was coated onto the wells of a 96-well polystyrene microtiter plate (Thermo Scientific). Plates were washed with low salt wash buffer (3×) and then blocked overnight at 4° C. with 3% (w/v) casein in deionized water. After three more washes with low salt wash buffer, serum dilutions (1/100) in PBS were added to each well and allowed to incubate overnight at 4° C. (100 μl per well). Plates were washed 5× with high salt wash buffer to remove residual serum and unbound antibodies. Primary antibody, mouse anti salmonid Ig monoclonal (Biorad; cat #MCA2182), was diluted to the appropriate concentration in PBS (Table 5) and added to each well (100 μl/well) and incubated at room temperature for 1 h. Plates were washed with high salt wash buffer (5×) to remove unbound antibody. The secondary antibody, goat anti-mouse IgG peroxidase (Sigma; cat #A4416), was diluted to the appropriate concentration with conjugate buffer (1% (w/v) bovine serum albumin diluted in low salt wash buffer) and added to the wells. After a 1 hr incubation at room temperature followed by 5× wash with high salt wash buffer, 100 μl of the chromogen (TMB) was added to each well and incubated for 10 min at room temperature. The reaction was stopped by adding 50 μl 2 M sulfuric acid to each well. Plates were mixed and the absorbance was recorded at 450 nm using a spectrophotometer. Each plate contained relevant controls: 1) pooled positive serum, 2) pooled negative serum, and 3) no serum controls (PBS). The coefficient of variation of the A450 nm of sample replicates within a plate, and the pooled positive serum between plates was always <20%.
At 602 degree days after vaccination, Atlantic salmon serum antibody levels were measured to the five sea louse antigens included in the vaccine. ELISA analysis data showed Atlantic salmon responded to all five antigens delivered in the cocktail vaccine with a DNA prime (
An immunological response was also induced by prime vaccination with 10 μg TIM DNA antigen either in a pVAX1 vector or a pVAC1 vector, following by a boost using 50 μg of TIM recombinant protein.
Thus, TIM, FBP, Prx-2, TCTP and Enolase each provides an antigen that elicits an immunogenic response in fish.
The efficacy of sea lice vaccine candidates against Lepeophtheirus salmonis (salmon louse) infection in Atlantic salmon (Salmo salar) was evaluated.
The specific antibody response was measured across 12 treatments (n=15 fish per treatment). Controls included a control for the His-tag as well as a no injection control (phosphate buffered saline [PBS]). The His-tag control served as a control for the His tag on the bacterially expressed sea louse antigens. PBS served as a control for any non-specific immune responses to injury at vaccination and to allow for the evaluation of sea lice settlement of non-vaccinated fish. An additional 42 fish per treatment were vaccinated and sampled to measure vaccine efficacy post sea lice challenge.
For the prime vaccination, each recombinant protein vaccine contained 100 ng of purified flagellin from Pseudomonas aeruginosa (FLA-PA Ultrapure, InvivoGen) and was adjuvanted (Montanide™ ISA 763 A VG; Seppic™). For the boost vaccination, each vaccine formulation was adjuvanted (Montanide™ ISA 763 A VG; Seppic™)
Recombinant protein vaccines were prepared by inoculating lysogenic broth (LB)-kanamycin (50 μg) agar plates with glycerol stocks of E. coli BL21 (DE3) cells, which contain the pET-30a (+) expression plasmid (Novagen) with gene insert, and growing each vaccine candidate overnight at 37° C. Single colonies were isolated and used to inoculate 2-50 ml flasks of LB with kanamycin (50 μg). Cultures were allowed to grow at 37° C. with shaking for 2-4 hours or until the optical density at 600 nm was reached (0.6 to 0.8). Approximately 16.6 ml of culture media was added to 500 ml of LB with kanamycin (50 μg) in a flask for overnight growth at 200 rpm and 37° C. Once target optical densities were reached (i.e. 0.6 to 0.8), IPTG was added at 1 mM dose to each 500 ml flask and temperature was reduced to 18° C. with shaking at 200 rpm. After 15-18 hr of induction, the optical density was measured (target optical densities of 1-7) and cultures were centrifuged at 10,000×g for 10 min at 4° C. The weight of each pellet was measured in each centrifugation bottle. Based on that weight, the amount of lysis buffer was calculated (2 ml of lysis buffer per 100 mg of cell pellet), and pellets were resuspended with vortexing. DNase was added (2 U per ml of lysis buffer) to each bottle and mixed gently. Pellets were sonicated on ice in 20 second bursts for a total of 4 min and then incubated on ice for 15 min with intermittent mixing followed by centrifugation for 20 min at 10,000×g at 4° C. The supernatant was decanted and added to a nickel-iminodiacetic acid-based protein purification resin (His60 Ni Superflow Resin; Takara), and allowed to incubate for 2 to 24 hours with gently stirring at 4° C.
Some proteins (e.g. Prx-2 and GST) were shown to have a high affinity for the resin and therefore lower incubation times were preferred (˜2 h). Lower affinity proteins (e.g. FBP and TCTP) were allowed to mix with the resin for at least 24 h. Resin and supernatant (˜250-300 ml) was added to 4-10 ml polypropylene gravity flow purification columns (Thermo Scientific, catalog #29924). Once the resin settled to the bottom of the column, 10 ml of equilibration buffer was added (×2). This was followed by 10 ml of wash buffer (×2). The protein was eluted from the column by adding multiple 10 ml aliquots of elution buffer until protein detection by 280 nm light absorbance was negligible. For high affinity proteins, elution buffer containing 400 mM imidazole was added. For lower affinity proteins, 300 mM imidazole elution buffer was used. The eluate for each protein was combined and concentrated using 20 ml, 5 kDa, MWCO concentrators (GE Healthcare catalog #28-9329-59). Excess imidazole was removed by adding concentrates to PD-10 desalting columns (GE Healthcare). Protein was concentrated briefly again and then filter sterilized with 0.22 μM, 13 mm diameter, PVDF syringe filters (Celltreat® catalog #229742). A sterile 80% glycerol solution was added to each protein aliquot to give 8-10% glycerol per tube prior to storage at −80° C. (Acros Organics CAS 56-81-5). Protein concentration was determined using a Pierce® BCA Protein Assay Kit (Thermo Scientific catalog #23227). Proteins that were difficult to express at the quantities required (e.g. enolase) were produced by enhanced methods known to the skilled person (GenScript® protein expression service).
Atlantic salmon post smolts (n=684) approximately 70 to 100 grams in weight were maintained in a recirculating artificial salt water system on a 12:12 hr light:dark cycle in 100-gallon tanks at a stocking density of 25 kg/m3. Water quality, ammonia, nitrite, and fish condition were monitored daily. Salmon were fed a daily ration of BioTrout 3 mm pellets (Bio-Oregon®) at 1.5% body weight per day and maintained at temperatures of 13±1° C., 32±±1‰ salinity, and 8±1 mg/L dissolved oxygen (means±standard deviations).
Fish size ranged from 98 to 295 grams at prime vaccination (average size 180 g). There were two vaccine treatments per tank (n=19 fish per antigen) in replicates of three tanks (n=38 fish per tank). During the vaccination phase, fish stocking density was <18.1 kg/m3. Prior to vaccination, 20 fish were euthanized for mucus and blood collection with a lethal dose of MS-222 (250 mg/L). These fish served as a measure of the basal level of immunity of the fish. Fish to be vaccinated were anaesthetized with 100 mg/L MS-222 and then primed intradermally using a sterile 25-gauge needle and syringe. A 200 μg dose was prepared for the following recombinant proteins: enolase, Prx-2, TIM, FBP and TCTP (n=57 fish per treatment). The number of injections per antigen ranged between two to three 10-0 injections per fish to achieve the target dose. For the PBS control, a single 10 μl dose was injected into each fish (n=57). To distinguish fish between vaccine groups, an elastomer tag (Northwest Marine Technology, Inc.) was injected under the skin along the jawline following the intradermal injection of antigen. Each recombinant protein vaccine contained 100 ng of FLA-PA Ultrapure flagellin from P. aeruginosa (InvivoGen cat #tlrl-pafla). Each vaccine formulation was adjuvanted with Montanide™ ISA 763 A VG (Seppic™). Once primed, fish were returned to their respective treatment tanks to recover.
Two weeks post-prime vaccination, fish were anesthetized and boosted with an intraperitoneal (i.p.) injection of the recombinant protein vaccines, except for Prx-2 proteins, which was boosted 3 weeks and 4 days post-prime vaccination (n=11). One hundred microliters of a 200 μg dose was prepared for the following recombinant proteins: enolase, Prx-2, TIM, FBP and TCTP (n=57 fish per treatment). Each vaccine formulation was adjuvanted with Montanide™ ISA 763 A VG (Seppic™ Lot #36017Z). One hundred microliters of antigen at the described doses (above) plus Montanide was i.p. injected into each fish. For the PBS control, 100 μl PBS was added with adjuvant. Once boosted, fish were returned to their respective treatment tanks to recover.
At least three weeks prior to sea lice challenge, Atlantic salmon approximately 240 g in size were cohabitated into eight replicate tanks. Around 5 fish per treatment were transferred into each tank giving a total of 65 fish per tank or a stalking density of 41.3 kg/m3.
At 602 degree days, 43 days after boost vaccination and 588 degree days (42 days after boost), 15 fish per treatment were euthanized by exposing fish to an overdose of M-S222 (250 mg/L) to measure specific antibody responses after vaccination (n=180 fish). Serum was collected by bleeding the fish via the caudal vein using a sterile 23-gauge needle with a 3 ml syringe. Samples were processed by incubating samples at 4° C. overnight and then centrifuging the blood at 3000×g for 10 min at 4° C. The supernatant containing the plasma was collected and transferred into 2-1.5 ml microcentrifuge tubes and stored at −80° C. for ELISA analysis. Skin mucus samples were collected by placing each fish into a bag containing 10 ml phosphate buffered saline and massaging the fish for 2 minute each to wash off mucus. Samples were centrifuged for 15 minutes at 1500×g at 4° C. Mucus was transferred into two 1.5 ml microcentrifuge tubes and stored at −80° C. for dot blot analysis.
L. salmonis Challenge
Two thousand L. salmonis egg strings were collected from gravid females and transferred to a sea lice hatchery. L. salmonis copepodids of similar age (3-4 days old) were pooled and the number of copepodids were calculated by counting ten 1-ml aliquots of lice using a dissecting scope to give the mean number of copepodids per ml of seawater. Infections were performed by reducing the volume of the tank holding the fish to a third of the original volume and copepodids were added to each of the replicate tanks to give an infection density of 80 copepodids per fish. The dissolved oxygen was monitored continuously throughout the 1-hour bath infection to maintain dissolved oxygen at 8.5±1.0 mg/L (means±standard deviation). After one hour, the tank water level was restored. Dissolved oxygen was monitored for another 1.5 hours before turning the flow back on to each tank. Fish were monitored for an additional hour to ensure dissolved oxygen and flow rate were maintained in each tank at the appropriate levels.
To evaluate vaccine efficacy against salmon louse attachment, Atlantic salmon (n=42 fish per treatment; n=504) were challenged with L. salmonis copepodids 980 or 994 degree days after boost vaccination). Eight to eleven days after sea lice challenge, the salmon were exposed to an overdose of MS-222 to perform sea lice counts. Blind counts of the chalimus stages were recorded from the skin and gills of each fish for each treatment using a dissecting microscope and forceps. To reduce count variation, the same four individuals manually counted the number of lice on each fish. After counts were completed, the length (mm) and weight (g) of each fish was recorded.
The relative intensity (RI), which is the total number of lice per gram body weight [RI=total number lice/total weight (g)], was calculated for each individual fish subject to a vaccine treatment (Myksvoll et al., 2018). The RI values between vaccine treatments were compared. The average relative intensity (ARI=average number of lice/average weight [g]) was calculated to determine the percent change in lice intensity between vaccinated treatments and the PBS control (Myksvoll et al., 2018). Using these values, the % change was calculated (ARI PBS control−ARI vaccine antigen)/(ARI PBS control)×100).
The data from the sea lice vaccine trial showed that vaccination with recombinant protein antigens identified from the circum-oral glands of the chalimus stages reduced the number of chalimus per fish caused by the sea lice challenge.
FBP N286D and GST S67A were shown to be the most protective of the tested antigens, as shown in the RI values reported in Table 6 and
The percent reduction in chalimus counts ranged from 9.1% to 33.0% (Table 7).
Atlantic salmon were vaccinated with 11 different L. salmonis candidate antigens and challenged with the infective stage of the parasite. Using the average relative intensity, the percent change between the PBS control and candidate vaccine was calculated.
The antigens had no negative effect on the growth of the vaccinated fish.
Thus, vaccination with the L. salmonis antigens identified from the circum-oral glands of the chalimus stages reduced the relative intensity of chalimus infestation on Atlantic salmon.
The immunogenicity of the candidate antigens was assessed by western blot. Data showed that the pooled serum samples from vaccinated and sea lice challenged fish contained antibodies to the sea lice vaccine antigens. Protein bands of the correct sizes were detected on the nitrocellulose membrane after development (FBP, 42.1 kDa; TCTP, 21.6 kDa; enolase, 48.9 kDa; TIM, 28.7 kDa; Prx-2, 24.0; PPIasse, 24.6 kDa; CSE, 45.2 kDa; GST 26.2, kDa; GST S67A, 26.2 kDa; FBP N2867D, 42.1 kDa; and TIM E166D, 28.7 kDa). These results suggest that the monovalent recombinant protein vaccines, Prx-2, FBP, Enolase, TIM, TIM E166D, FBP N286D, GST, GST S67A, PPIase, CSE, and TCTP induced an antibody response in the host. Furthermore, the results show that the antigenic response to the vaccines by the host was protective upon secondary challenge with sea lice.
Number | Date | Country | Kind |
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1902425.6 | Feb 2019 | GB | national |
Filing Document | Filing Date | Country | Kind |
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PCT/GB2020/050154 | 1/23/2020 | WO | 00 |
Number | Date | Country | |
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62796676 | Jan 2019 | US |