Novel swine Influenza virus subtype H3N1, United States.Influenza A influenza A n. Influenza caused by infection with a strain of influenza virus type A. influenza A Infectious disease An avian virus, especially of ducks–which in China live near the pig reservoir and 'vector'; virus infects various animal species and transmits among different hosts, especially between humans and swine. Swine may serve as a mixing vessel to create new reassortants that could infect humans. Thus, monitoring and characterizing influenza viruses in swine are important in preventing interspecies transmission. We report the emergence and characterization of a novel H3N1 subtype (programming) subtype - If S is a subtype of T then an expression of type S may be used anywhere that one of type T can and an implicit type conversion will be applied to convert it to type T. of swine influenza swine influenza n. A highly contagious form of human influenza caused by a filterable virus identical or related to a virus formerly isolated from infected swine. Also called swine flu. virus (SIV SIV simian immunodeficiency virus. ) in the United States. Phylogenetic phy·lo·ge·net·ic adj. 1. Of or relating to phylogeny or phylogenetics. 2. Relating to or based on evolutionary development or history. analysis showed that the H3N1 SIVs may have acquired the hemagglutinin hemagglutinin /he·mag·glu·ti·nin/ (-gloo´ti-nin) an antibody that causes agglutination of erythrocytes. cold hemagglutinin one which acts only at temperatures near 4° C. gene from an H3N2 turkey isolate, the neuraminidase neuraminidase /neu·ra·min·i·dase/ (-ah-min´i-das) an enzyme of the surface coat of myxoviruses that destroys the neuraminic acid of the cell surface during attachment, thereby preventing hemagglutination. gene from a human H1N1 isolate, and the remaining genes from currently circulating SIVs. The H3N1 SIVs were antigenically related to the turkey virus. Lung lesions and nasal shedding occurred in swine infected with the H3N1 SIVs, suggesting the potential to transmit among swine and to humans. Further surveillance will help determine whether this novel subtype will continue to circulate in swine populations. ********** Influenza A viruses infect many animal species including birds, seals, whales, humans, horses, and swine. Migrating waterfowl waterfowl, common term for members of the order Anseriformes, wild, aquatic, typically freshwater birds including ducks, geese, and screamers. In Great Britain the term is also used to designate species kept for ornamental purposes on private lakes or ponds, while in are the primordial reservoir. They contain a gene pool of all subtypes of influenza A viruses (1), and phylogenetic analysis suggests that transmission of influenza A virus among various species can occur. Interspecies transmission between humans and swine has been documented (1). Both human and swine influenza viruses (SIVs) recognize sialyl [alpha] 2,6-galactose oligosaccharide oligosaccharide: see carbohydrate. oligosaccharide Any carbohydrate with a few (between 3 and about 6 to 10) units of simple sugars (monosaccharides). A wide variety of oligosaccharides are made by partially breaking down polysaccharides. side chains as the receptor on the host cell surface (2,3). In addition, swine cells also contain sialyl [alpha] 2,3-galactose-linkage, the receptor for avian influenza avian influenza: see influenza. viruses. Experimental and epidemiologic evidence demonstrates that different subtypes of avian influenza viruses can replicate in swine (4-6). Therefore, swine can be a vessel for reassortment of human and avian influenza viruses (7). The viral structure that binds to the cellular receptor is the receptor-binding site, which is located on the globular globular resembling a globe. globular heart a spherical cardiac silhouette, usually greatly enlarged and lacking the detailed outline of the right and left atria and apex. Characteristic of pericardial effusion and cardiomyopathy. part of the hemagglutinin (HA) monomer (8). Based on a crystallographic crys·tal·log·ra·phy n. The science of crystal structure and phenomena. crys  tal·log model, the
receptor-binding site of the H3 subtype includes conserved residues
Tyr98, His 193, Glu190, Trp53, and Leu Leu leucine. Leu abbr. leucine Leu leucine. 194 (8). Two other conserved residues at positions 226 and 228 within the binding pocket determine host range specificity (3). Leu226 and Ser228 selectively bind to [alpha] 2,6 sialosides found on human and swine cells, while Gln226 and Gly228 bind to the [alpha] 2,3 sialosides found predominantly on avian cells (3, 9,10). Influenza viruses currently circulating in North American North American named after North America. North American blastomycosis see North American blastomycosis. North American cattle tick see boophilusannulatus. swine are subtypes H1N1, H3N2, and H1N2 (11). The classical H1N1 viruses have been circulating in the swine population since the Spanish flu pandemic pandemic /pan·dem·ic/ (pan-dem´ik) 1. a widespread epidemic of a disease. 2. widely epidemic. pan·dem·ic adj. Epidemic over a wide geographic area. n. of 1918 (1). The first SIV, A/SW/IA/15/30, was isolated in 1930 and is antigenically similar to the 1918 human influenza virus (12). From 1930 to 1998, classic H1N1 viruses were the predominantly isolated subtype from US swine. In 1998, a new SIV subtype H3N2 emerged and became established in the North American swine population (13,14). Genetic analysis showed that it was a triple reassortant virus containing genes from swine, human, and avian influenza viruses. The H3N2 SIV acquired the polymerase basic (PB) protein 1, HA, and neuraminidase (NA) genes from a recent human virus, the PB2 and polymerase acidic (PA) protein genes from avian viruses, and the nucleocapsid nucleocapsid /nu·cleo·cap·sid/ (noo?kle-o-kap´sid) a unit of viral structure, consisting of a capsid with the enclosed nucleic acid. nu·cle·o·cap·sid n. protein (NP), matrix (M), and nonstructural (NS) genes from the classic H1N1 swine virus (13-16). A year later, reassortment between the H3N2 and classic H1N1 SIV resulted in a new subtype H1N2, where the HA of the H3N2 subtype was replaced by the HA from the classic H1N1 virus (1 7). This H1N2 subtype caused respiratory disease in swine and continues to circulate in swine populations (18). Recently, wholly avian influenza viruses, subtypes H4N6 (5), H3N3, and H1N1 (19), from water fowl were isolated from diseased swine in Canada; however, no evidence shows that these viruses can be successfully maintained in swine populations. We identified and characterized a new SIV subtype H3N1 that may have arisen from reassortment of an H3N2 turkey isolate, a human H1N1 isolate, and currently circulating swine influenza viruses. Materials and Methods Clinical Samples Two SIV isolates, A/SW/MI/PU243/04 (PU243) and A/SW/IN/PU542/04 (PU542), were obtained from 1 swine herd in southern Michigan and 1 in central Indiana, respectively. A/SW/MI/PU243/04 was isolated from lung tissue of a dead 7-week-old, cross-bred swine that was clinically and histologically diagnosed with viral pneumonia viral pneumonia Pulmonology Pneumonia of viral origin, which is more severe in the very young and very old Common pathogens Adenovirus, influenza virus, parainfluenza virus, RSV, rhinovirus, HS, CMV. See Influenza, Pneumonia, Respiratory syncytial virus. . A/SW/IN/PU542/04 was isolated from the nasal swab of a 14-week-old, cross-bred swine that was coughing, had dyspnea dyspnea /dysp·nea/ (disp-ne´ah) labored or difficult breathing.dyspne´ic paroxysmal nocturnal dyspnea , and was lethargic. Both isolates were submitted for virus isolation to the Animal Disease Diagnostic Laboratory of Purdue University. Virus Isolation and Subtype Determination Madin-Darby canine kidney (MDCK MDCK Madin-Darby Canine Kidney Cells (virus tissue culture) ) cells were grown in Eagle's minimum essential medium supplemented with 2% fetal bovine serum Fetal bovine serum ( or foetal bovine serum) is serum taken from the fetuses of cows. Fetal Bovine Serum (or FBS) is the most widely used serum in the culturing of cells. In some papers the expression foetal calf serum is used. . The 10% lung homogenate homogenate /ho·mog·e·nate/ (ho-moj´in-at) material obtained by homogenization. homogenate material obtained by homogenization. (PU243) and nasal swab preparation (PU542) were applied onto MDCK cells maintained in Eagle's minimum essential medium containing 4 [micro]g/mL trypsin trypsin, enzyme that acts to degrade protein; it is often referred to as a proteolytic enzyme, or proteinase. Trypsin is one of the three principal digestive proteinases, the other two being pepsin and chymotrypsin. and 0.3% bovine serum albumin serum albumin n. See seralbumin. (Sigma, St. Louis, MO, USA). Cytopathic effect was observed, and the culture supernatant supernatant /su·per·na·tant/ (-na´tant) the liquid lying above a layer of precipitated insoluble material. supernatant the liquid lying above a layer of precipitated insoluble material. was tested with an HA assay using turkey erythrocytes Erythrocytes Red blood cells. Mentioned in: Bartonellosis erythrocytes (ē·rithˑ·rō·sīts), n.pl red blood cells. . RNA RNA: see nucleic acid. RNA in full ribonucleic acid One of the two main types of nucleic acid (the other being DNA), which functions in cellular protein synthesis in all living cells and replaces DNA as the carrier of genetic was isolated from the supernatant of virus-infected cells by using Trizol (Invitrogen, Carlsbad, CA, USA), and the viral subtype was determined by using 2 different multiplex SIV subtype-specific reverse transcription-polymerase chain reactions (RT-PCR RT-PCR reverse transcriptase-polymerase chain reaction. See PCR1. ) (20). One set of 4 primers was used to differentiate H1 and H3 of HA, and another set of 4 primers was designed for N1 and N2 discrimination. DNA Sequencing Two-step RT-PCR was performed by using universal primers and specific primers for influenza A viruses (21). The universal primers 5'-AGC AAA AAA: see American Automobile Association. (Triple A) A common single-cell battery used in a myriad of electronic devices of all variety. Like its double A (AA) cousin, it provides 1.5 volts of DC power. When used in series, the voltage is multiplied. AGC AGC Automatic Gain Control AGC Automotive Glass Cartridge (fuse) AGC Associated General Contractors AGC Associated General Contractors of America AGC Atypical Glandular Cells AGC Attorney-General's Chambers AGG-3' and 5'-ATG AGA AAC (Advanced Audio Coding) An audio compression technology that is part of the MPEG-2 and MPEG-4 standards. AAC, especially MPEG-4 AAC, provides greater compression and better sound quality than MP3, which also came out of the MPEG standard. AAG AAG Association of American Geographers (Washington, DC) AAG Assistant Attorney General AAG Asociación Argentina de Golf AAG Anti-Aircraft Gun AAG Assistant Adjutant General AAG Australian Association of Gerontology G-3" were used to amplify NS, M, NA, NP, and HA genes of the 2 isolates. The remaining genes, PA, PB1, and PB2, were amplified by using genespecific primers. The primer pairs are PA F, 5'--AGC AAA AGC AGG AGG Aggregate AGG Allgemeines Gleichbehandlungsgesetz AGG African Gold Group, Inc. AGG Arnall Golden Gregory LLP (Atlanta, GA) AGG Aggravated AGG Asociación de Gerentes de Guatemala TCA-3'; PA R, 5'-ATG AGA AAC AAG GTA GTA Grand Theft Auto (legal) GTA Grand Theft Auto (video game) GTA Greater Toronto Area (Canada) GTA Graduate Teaching Assistant CTT-3'; PB1 F, 5"-AGC AAA AGC AGG CA-3'; PB1 R, 5'-ATG AGA AAC AAG GCA GCA, ground-controlled approach: see instrument-landing system. TTT-3'; PB2 F, 5'-AGC AAA AGC AGG TC-3'; PB2 R, 5'-ATG AGA AAC AAG GTC GTC See: Good 'til cancelled order GTC See good-till-canceled order (GTC). GTT GTT, n See test, glucose tolerance. GTT Glucose tolerance test, see there T-3'. RNA was reverse transcribed by using Superscript Any letter, digit or symbol that appears above the line. For example, 10 to the 9th power is written with the 9 in superscript (109). Contrast with subscript. II (Invitrogen), and the cDNA was amplified by using the expand high fidelity PCR PCR polymerase chain reaction. PCR abbr. polymerase chain reaction Polymerase chain reaction (PCR) system (Roche, Indianapolis, IN, USA) according to manufacturer's instructions. The PCR products were cloned into pGEMT Easy (Promega, Madison, WI, USA). Purified plasmids containing the viral genes were sequenced by using an ABI Abi (ā`bī) [short for Abijah], in the Bible, King Hezekiah's mother. (Application Binary Interface) A specification for a specific hardware platform combined with the operating system. 3100 sequencer See MIDI sequencer. (music) sequencer - Any system for recording and/or playback of music via a programmable memory which stores music not as audio data, but as some representation of notes. (Applied Biosystems, Foster City, CA, USA) at the sequencing facility of the National Animal Disease Center, Agricultural Research Services, US Department of Agriculture (Ames, IA, USA). At least 4 cDNA clones of each gene were analyzed. Phylogenetic Analysis Individual gene sequences were combined and edited by using Lasergene (DNASTAR, Madison, WI, USA). Megablast (National Center for Biotechnology Information The National Center for Biotechnology Information (NCBI) is part of the United States National Library of Medicine (NLM), a branch of the National Institutes of Health. The NCBI is located in Bethesda, Maryland and was founded in 1988. , Bethesda, MD, USA) searches were performed to identify sequences with the best match to each individual gene of the 2 H3N1 viruses. Multiple alignments of DNA sequences were conducted on the complete NA gene and the HA1 region of the HA gene by using ClustalW (DNASTAR). Maximum parsimony phylogenetic trees were created by using MEGA3 (The Biodesign Institute, Tempe, AZ, USA) (22). The HA tree was rooted by an unrelated H4 duck influenza virus, A/duck/ Alberta/28/76. An avian N2, A/chicken/CA/6643/01, represented the outgroup of the NA tree. Each tree is a consensus of 1,000 bootstrap See boot. (operating system, compiler) bootstrap - To load and initialise the operating system on a computer. Normally abbreviated to "boot". From the curious expression "to pull oneself up by one's bootstraps", one of the legendary feats of Baron von Munchhausen. replicates. Hemagglutination hemagglutination /he·mag·glu·ti·na·tion/ (he?mah-gloo-ti-na´shun) agglutination of erythrocytes. he·mag·glu·ti·na·tion n. Inhibition (HI) Assay HI assays were performed to determine the antigenic relationship between the 2 H3N1 viruses, the H3N2 turkey isolates (23), and H3N2 SIVs. The H3N2 SIVs tested in the HI assay included viruses representing 3 H3N2 clusters: cluster I, TX98 (A/SW/TX/4199-2/98); cluster II, CO99 (A/SW/CO/23619/99); and cluster III, WI99 (A/SW/WI/ 14094/99) and IL99 (A/SW/IL/21587/99). Swine hyperimmune hyperimmune /hy·per·im·mune/ (hi?per-i-mun´) possessing very large quantities of specific antibodies in the serum. hyperimmune possessing very large quantities of specific antibodies in the serum. sera against various H3N2 SIVs (24) and a ferret serum raised against an H3N2 turkey isolate were adsorbed with kaolin kaolin (kā`əlĭn): see china clay. powder to eliminate nonspecific nonspecific /non·spe·cif·ic/ (non?spi-sif´ik) 1. not due to any single known cause. 2. not directed against a particular agent, but rather having a general effect. nonspecific 1. inhibitors. The 2 H3N1 and 4 H3N2 SIVs were tested with respective sera in a standard HI assay (25). Experimental Animal Infection The 2 H3NI viruses were inoculated into 10-week-old cross-bred swine in compliance with the Institutional Animal Care and Use Committee Institutional Animal Care and Use Committees are of central importance to the application of laws to animal research in the United States. Most research involving laboratory animals is funded by the United States National Institutes of Health or other federal agencies. of the National Animal Disease Center. The protocol for infection is described elsewhere (24). Briefly, 2 groups of swine (n = 4 or 5) were infected intratracheally with 2 x [10.sup.5] PFU/swine of either A/SW/MI/PU243/04 or A/SW/IN/PU542/04 inoculum inoculum /in·oc·u·lum/ (-ok´u-lum) pl. inoc´ula material used in inoculation. in·oc·u·lum n. pl. (total of 1 mL) prepared in embryonated eggs. Four swine were mock infected with medium only and served as controls. Five days after infection, swine were euthanized, lung lesions were scored (24), and bronchoalveolar lavage Bronchoalveolar lavage A way of obtaining a sample of fluid from the airways by inserting a flexible tube through the windpipe. Used to diagnose the type of lung disease. fluid (BALF) was collected. Sera and nasal swabs were collected the day of and 5 days after infection. Virus load in BALF, serum samples, and nasal swabs were determined in a 96-well format (24). Each sample was serially diluted 10-fold and injected into a monolayer mon·o·lay·er n. 1. A film or layer one molecule thick formed at the interface between water and either oil or air by a substance such as a partially esterified fatty acid that contains both hydrophobic and hydrophilic groups in the same of MDCK cells. The infected cells were fixed with methanol 48 hours after infection, and an indirect immunofluorescence assay was conducted by using anti-SIV swine serum (primary antibody) and a secondary fluorescein fluorescein /flu·o·res·ce·in/ (fldbobr-res´en) a fluorescing dye; its sodium salt is used as a tracer in retinal angiography and as a diagnostic aid for revealing corneal trauma and fitting contact lenses. isothiocyanate--conjugated anti-swine antiserum antiserum /an·ti·se·rum/ (an´ti-se?rum) a serum containing antibody(ies), obtained from an animal immunized either by injection of antigen or by infection with microorganisms containing antigen. (Sigma). Wells were determined as either positive or negative without counting individual foci. The virus titers were determined as 50% tissue culture infective dose ([TCID TCID tissue culture infective dose; that amount of a pathogenic agent that will produce pathological change when inoculated on tissue cultures. .sub.50]) per milliliter milliliter /mil·li·li·ter/ (mL) (-le?ter) one thousandth (10-3) of a liter. mil·li·li·ter n. Abbr. . Detecting Swine Respiratory Pathogens The presence of porcine reproductive and respiratory syndrome virus Porcine Reproductive and Respiratory Syndrome Virus (PRRSV), also known as Blue-Ear Pig Disease (in Chinese, zhū láněr bìng 豬藍耳病), is a virus that causes a disease of pigs, called (PRRSV PRRSV Porcine Reproductive and Respiratory Syndrome Virus ) and Mycoplasma hyopneumoniae in BALF was determined by using either RT-PCR or PCR assays, respectively. For PRRSV, total RNA was isolated from BALF from each swine by using the QIAamp Viral RNA mini kit (Qiagen, Valencia, CA, USA). One microgram microgram /mi·cro·gram/ (µg) (mi´kro-gram) one millionth (10-6) of a gram. mi·cro·gram n. Abbr. of the extracted RNA and a primer pair specific for open reading frame 5 of PRRSV were included in a single-tube RT-PCR as described previously (26). To find M. hyopneumoniae, DNA DNA: see nucleic acid. DNA or deoxyribonucleic acid One of two types of nucleic acid (the other is RNA); a complex organic compound found in all living cells and many viruses. It is the chemical substance of genes. was extracted from BALF by using the QIAamp DNA mini kit according to the manufacturer's recommendations (Qiagen). A forward primer specific for M. hyopneumoniae and a common reverse primer for the 16S rRNA gene were used in the PCR as previously described (27). A laboratory-grown M. hyopneumoniae DNA sample was used as a positive control. Amplified products were detected by electrophoresis on ethidium bromide-stained agarose agarose more highly purified form of agar with similar uses to agar and widely used in the separation of nucleic acid fragments. gel. Results Virus Isolation and Subtype Determination MDCK cells injected with a lung homogenate from swine PU243 or with the nasal swab of swine PU542 produced cytopathic effect approximately 2-3 days after infection. The supernatant agglutinated turkey erythrocytes in HA tests. Total RNA of each isolate was prepared from the supernatant of PU243- or PU542-infected MDCK cells and used as templates for the multiplex RT-PCR. Results of the multiplex RT-PCR assay specific for HA showed that both isolates were of the H3 subtype, since no H 1-specific band was present. The multiplex RT-PCR specific for NA showed that both isolates were of N1 and not N2 subtype. The 2 H3N1 SIV isolates were designated A/SW/MI/ PU243/04 or A/SW/IN/PU542/04. Subsequently, the RNA from the culture supernatants was used for amplification and cloning. Experimental Animal Infection Four or five 10-week-old swine, negative for SIV-specific antibodies, were infected with the PU243 and PU542 H3N1 isolates. No respiratory difficulties were reported during 5 days of observation before the animals were euthanized. At necropsy necropsy /nec·rop·sy/ (nek´rop-se) examination of a body after death; autopsy. nec·rop·sy n. See autopsy. necropsy examination of a body after death. See also autopsy. , macroscopic macroscopic /mac·ro·scop·ic/ (mak?ro-skop´ik) gross (2). mac·ro·scop·ic or mac·ro·scop·i·cal adj. 1. Large enough to be perceived or examined by the unaided eye. 2. lesions characterized by marked plum-colored, consolidated areas on lung lobes were observed. The PU243-infected swine had an average lung lesion score of [approximately equal to] 8%. The PU542 infected group had a milder lung lesion score of [approximately equal to] 3%. Control swine had no obvious lung lesions. To determine lung replication and nasal shedding of the H3N1 viruses in swine, virus titers in the sera, nasal swabs, and BALF were evaluated. All samples from all swine in the control group as well as all samples obtained before infection were virus negative. Titers of viruses from nasal swabs and BALF 5 days after infection are shown in Table 1. Viral loads in BALF at 5 days after infection ranged from [10.sup.6.3] to [10.sup.7.6] [TCID.sub.50]/mL (mean [10.sup.7]) and were substantially greater (p<0.05) than those in nasal swabs 5 days after infection (titer range [10.sup.3] - [10.sup.5.8] [TCID.sup.50]/mL, mean [10.sup.4.7] [TCID.sup.50]/mL). Sera from infected swine collected 5 days after infection were virus negative. Other respiratory pathogens of swine that might produce lung lesions similar to SIV were not found in BALF of infected swine. The result of a PCR specific for the 16S RNA of M. hyopneumoniae showed that BALF from all swine were negative. Similarly, BALF did not contain PRRSV nucleic acids Nucleic acids The cellular molecules DNA and RNA that act as coded instructions for the production of proteins and are copied for transmission of inherited traits. . These results eliminated the possibility that swine might have been infected with M. hyopneumoniae or PRRSV. Sequence Analysis Comparison of individual gene sequences of the 2 H3N1 SIVs showed that the identities ranged from 92.3% to 99.3% at the nucleotide level. The M gene is the most conserved, while the HA and NA genes are more variable with identities of 96.5% and 92.3% at the nucleotide level and 95.6% and 92.3% at the amino acid amino acid (əmē`nō), any one of a class of simple organic compounds containing carbon, hydrogen, oxygen, nitrogen, and in certain cases sulfur. These compounds are the building blocks of proteins. level, respectively. The similarity among the remaining 5 genes of the 2 isolates is >98%. Table 2 shows results obtained from Megablast analyses, which searched for sequences in the GenBank with the best match to each individual gene of both H3N1 SIVs. The HA of both H3N1s has the highest similarity with the HA of an H3N2 virus isolated from a turkey (A/TK/NC/12344/03). The NA sequence of both H3N1s is closely related to the NA of a human H1N1 isolate (A/WI/10/98) (28). The remaining 5 genes of both isolates are closely related to respective genes found in currently circulating H3N2 and H1N2 SIVs (Table 2). The M gene of PU243 isolate is most similar to a turkey isolate (A/TK/NC/12344/03) while the M gene of PU542 is similar to an H1N2 SIV (A/SW/IN/14810-S/01). Phylogenetic Analyses Maximum parsimony analysis of the HA1 region of the H3 subtype of recent North American SIVs separates these subtypes into 3 clusters as previously reported (Figure 1A) (16). Both H3N1 SIVs are closely related to 2 H3N2 turkey isolates, A/TK/NC/16108/03 and A/TK/MN/764/ 03, within cluster III. Branch length between the H3N1 viruses and the turkey H3N2 viruses is shorter than between the H3N1 SIVs and the swine H3N2 isolates. [FIGURE 1 OMITTED] Phylogenetic analysis of the N1 subtype of NA separates the sequences into 3 groups: swine, human, and avian. Both human and swine N1 s share a common ancestor; however, they are placed in different clusters (Figure 1B). The N1s of the 1930 and 1973 SIVs were placed near the root of the human cluster. The human influenza isolates within the swine group were obtained from humans infected with swine viruses. The NAs of both H3N1 SIVs are placed into the swine cluster and are most closely related to an H1N1 human virus, A/WI/10/98. The A/SW/IN/ PU243/04 and the 1998 H1N1 human isolate were placed in similar root at a 99% level. Antigenic Relationship of Swine and Turkey H3 Subtype Viruses Cross-reactivity between the H3N1 SIVs, H3N2 turkey isolates, and H3N2 SIVs representing 3 genetic clusters (16) were tested in HI assays. The results showed that neither H3N1 isolate reacted with antibodies raised against H3N2 swine viruses representing cluster II and III at a 1:10 dilution, the lowest dilution tested. They reacted poorly with a serum raised against the cluster I TX98 SIV, with an HI titer of 20. PU243 reacted with a ferret serum raised against the H3N2 turkey isolate with a low HI titer of 40. PU542 reacted weakly with the same ferret serum with an HI titer of 20. Antisera from swine infected with each H3N1 virus showed weak reactivity to a H3N2 cluster I SIV (TX98) with an HI titer of 10 and cluster III SIVs (WI99 and IL99) with HI titers of 20 and moderate reactivity to a cluster II SIV (CO99) with HI titers of 80 for PU243 and 40 for PU542. Receptor-binding Site Critical amino acid positions within the receptor-binding site of the H3 subtype of swine and turkey viruses are shown in Figure 2. Most of the residues are highly conserved, especially those associated with the sialoside receptor-binding region, Tyr98, Trp153, His 183, Glu190, and Leu194 (29,30), and the residues (amino acids 226 and 228) responsible for host range specificity (3,10). All isolates have Tyr98, Trp153 (with the exception of H3N1 PU542), His183, Asp190 or Glu190, Leu194 (with the exception of H3N2 TX98), and Ser228. Residue 226 of the H3 subtype of SIVs and the H3N2 turkey viruses is either Ile or Val instead of Leu (Figure 2). [FIGURE 1 OMITTED] Discussion Although influenza viruses show host-range-specific characteristics, interspecies transmission of influenza viruses has been well documented (1). Infection of turkeys with swine influenza viruses seems to be common, and influenza viruses isolated from turkeys indicated that 73% of turkey influenza viruses contained genes of swine origin (31). Influenza viruses antigenically similar to the classic H1N1 swine virus were found to infect and produce diseases in different turkey herds (32-34). Recently, an influenza virus containing 8 genes closely related to those of A/SW/IN/9K035/99 H1N2 caused an outbreak in a turkey flock from Missouri (35). Thus far, transmission of turkey viruses to swine populations has not been reported. SIV subtype H3N1 viruses were previously isolated in Taiwanese swine; these viruses most likely acquired the HA from a human H3N2 isolate and the NA from an H1N1 SIV circulating in Taiwan (36). The novel H3N1 SIVs reported here contain HA genes highly similar to those of recently reported H3N2 turkey isolates. These H3N2 turkey isolates, A/TK/NC/16108/03 and A/TK/MN/ 764/03, were most likely swine viruses, which infected and caused disease in turkeys (23). Phylogenetic analysis of the HA1 region of the HA gene placed the H3N1 SIVs at a similar root to the turkey isolates. Additionally, branch lengths of the H3N1 SIVs and the turkey isolates are shorter than those between the H3N1 viruses and the swine H3N2 viruses. This finding suggests that the H3N1 SIVs may have acquired their HA from a virus similar to the H3N2 turkey isolate; this finding could indicate interspecies transmission from turkeys to swine. Subsequently, the swine H3N1 s have diverged separately from the turkey H3N2s. Maximum parsimony analysis of the NA gene separates human, avian, and swine clusters as previously reported (37). The NA of the H3N1 SIVs is placed into the swine cluster. A/SW/MI/PU243/04 shares a similar root with the human H1N1 isolate, WI/10/98, at the 99% level. This finding strongly suggests that both viruses have a common ancestor; however, the H3N1 swine virus may have evolved from the WI/10/98 H1N1 or similar human isolates. Although the 2 H3N1 SIVs were isolated from 2 separate herds, they may have evolved from a similar ancestor. Both HA and NA phylogenetic analyses placed the 2 isolates into different branches at 61% and 52% bootstraps, respectively. Both may have originated from a similar reassortant event and continued diverging from each other. Analysis of the deduced amino acid sequence (Figure 2) also supports this assumption. Residues mainly responsible for sialyl [alpha] 2,6-galactose specificity are Leu226 and Ser228 (3,10). Leu226 is not in contact with the sialoside but changes in this position alter the conformation con·for·ma·tion n. One of the spatial arrangements of atoms in a molecule that can come about through free rotation of the atoms about a single chemical bond. of the binding pocket (30). The space-filling model of the H3 HA complex with a receptor analog showed that Leu226 is in close proximity to the Vander Waal space of C6 of the galactose (29). The H3N1 and H3N2 SIV sequences, including the H3N2 turkey viruses, contain all Ser228 but Ile226 or Va1226 instead of Leu226 in their HA1 molecules. H3 subtypes of human influenza viruses isolated from Japan and China during 1994 and 1995 also contain Ile226 instead of Leu226 (38). Leu, Ile, and Val are similar neutral nonpolar nonpolar not having poles; not exhibiting dipole characteristics. amino acids; substitution between them most likely maintains hydrophobic interactions and proper conformation of the binding pocket. In contrast, Gln226 and Gly228 are normally found in the HA1 molecule of avian viruses (10). Gln is classified as a hydrophilic hydrophilic /hy·dro·phil·ic/ (-fil´ik) readily absorbing moisture; hygroscopic; having strongly polar groups that readily interact with water. hy·dro·phil·ic adj. amino acid, and its amino acid structure is different from Leu, Ile, or Val. Ser and Gly are classified into different groups of amino acids; they possess different charges and structure. The H3 turkey HA still maintains Ile226 and Ser228 similar to that of swine viruses, indicating that they maintained their ability to infect swine and possibly humans, despite replicating in an avian host. Whether influenza virus receptors in turkeys are different from those in other avian species is not known. Why it took [approximately equal to] 6 years for H3N1 SIVs to emerge in US swine where H3N2 and H1N1 viruses have been cocirculating since 1998 is not known. Reassortant H1N2 and H1N1 SIVs were isolated shortly after the 1998 introduction of the H3N2 viruses into US swine. A certain constellation of the HA and NA surface molecules was necessary to create a successful H3N1 reassortant, since optimal balance between NA activity and HA affinity to the sialoside receptor is crucial for effective influenza virus infections (39-41). Our study showed that the H3N1 SIVs can replicate in the respiratory tract respiratory tract n. The air passages from the nose to the pulmonary alveoli, including the pharynx, larynx, trachea, and bronchi. Respiratory tract of swine and are shed in nasal secretions. In this study, investigations on virus transmissibility trans·mis·si·ble adj. That can be transmitted: transmissible signals. trans·mis in which contact animals are housed together with infected animals were not performed. Therefore, whether these 2 H3N1 SIVs will be transmitted efficiently in the field situation requires further experimental and epidemiologic studies. However, our results underline the scenario in which swine can be a mixing vessel for human, swine, and avian influenza viruses to create new reassortants that may be dangerous to human health. Turkeys are more susceptible to influenza viruses from waterfowl than are other domestic poultry (42), and a high degree of genetic reassortment most likely occurs in domestic turkeys (31). This finding may indicate that influenza A viruses could sequentially acquire new genes during transmission from waterfowl via turkey to swine and humans. Acknowledgments We thank David Alt for DNA sequencing, Brooke Peterson-Bruch for assistance with phylogenetic analysis, R. J. Webby for providing influenza A virus primers and ferret serum raised against a H3N2 turkey isolate, Eileen Thacker for providing a laboratory-grown Mycoplasma hyopneumoniae DNA sample, Deborah F. Clouser for technical assistance, and Andrew Gibson for animal care. Dr Lekcharoensuk is pursuing postdoctoral research at the National Animal Disease Center in molecular biology of swine influenza viruses. She is a member of the Department of Microbiology and Immunology, Faculty of Veterinary Medicine, Kasetsart University, Bangkok, Thailand. Her research interests include epidemiology and molecular virology of emerging infectious diseases of animals. References (1.) Webster RG, Bean W J, Gorman OT, Chambers TM, Kawaoka Y. Evolution and ecology of influenza A viruses. Microbiol Rev. 1992;56:152-79. (2.) Roger GN, Pritchette TJ, Lane JL, Paulson JC. Differential sensitivity of human, avian, and equine influenza A viruses to a glycoprotein glycoprotein (glī'kōprō`tēn), organic compound composed of both a protein and a carbohydrate joined together in covalent chemical linkage. inhibitor infection: selection of receptor specific variants. Virology virology, study of viruses and their role in disease. Many viruses, such as animal RNA viruses and viruses that infect bacteria, or bacteriophages, have become useful laboratory tools in genetic studies and in work on the cellular metabolic control of gene expression . 1983; 131:394-408. (3.) Rogers GN, Paulson JC, Daniels RS, Skehel JJ, Wilson IA, Wiley DC. Single amino acid substitutions in influenza haemagglutinin change receptor binding specificity. Nature. 1983;304:76-8. (4.) Guan guan: see curassow. Y, Shortridge KF, Krauss S, Li PH, Kawaoka Y, Webster RG. Emergence of avian H1N1 influenza viruses in pigs in China. J Virol. 1996;70:8041-6. (5.) Karasin AI, Anderson GA, Olsen CW. Isolation and characterization of H4N6 avian influenza viruses from pigs with pneumonia in Canada. J Virol. 2000;74:9322-7. (6.) Kida H, Ito T, Yasuda J, Shimizu Y, Itakura C, Shortridge KF, et al. Potential for transmission of avian influenza viruses to pigs. J Gen Virol. 1994;75:2183-8. (7.) Ito T, Couceiro JN, Kelm S, Baum LG, Krauss S, Castrucci MR, et al. Molecular basis for the generation in pigs of influenza A viruses with pandemic potential. J Virol. 1998;72:7367-73. (8.) Wilson IA, Skehel JJ, Wiley DC. Structure of the haemagglutinin membrane glycoprotein of influenza virus at 3 A resolution. Nature. 1981;289:366-73. (9.) Matrosovich M, Tuzikov A, Bovin N, Gambaryan A, Klimov A, Castrucci MR, et al. Early alterations of the receptor-binding properties of H1, H2, and H3 avian influenza virus hemagglutinins after their introduction into mammals. J Virol. 2000;74:8502-12. (10.) Vines A, Wells K, Matrosovich M, Castrucci MR, Ito T, Kawaoka Y. The role of influenza A virus hemagglutinin residues 226 and 228 in receptor specificity and host range restriction. J Virol. 1998;72:7626-31. (11.) Choi YK, Goyal SM, Joo HS. Prevalence of swine influenza virus subtypes on swine farms in the United States. Arch Virol. 2002; 147:1209-20. (12.) Shope RE. Swine Influenza. III. Filtration experiments and etiology. J Exp Med. 1931;54:373-80. (13.) Karasin AI, Schutten MM, Cooper LA, Smith CB, Subbarao K, Anderson GA, et al. Genetic characterization of H3N2 influenza viruses isolated from pigs in North America, 1977-1999: evidence for wholly human and reassortant virus genotypes. Virus Res. 2000;68:71-85. (14.) Zhou NN, Senne DA, Landgraf JS, Swenson SL, Erickson G, Rossow K, et al. Genetic reassortment of avian, swine, and human influenza A viruses in American pigs. J Virol. 1999;73:8851-6. (15.) Richt JA, Lager KM, Clouser DF, Spackman E, Suarez DL, Yoon KJ. Real-time reverse transcription polymerase chain reaction “RT-PCR” redirects here. For real-time polymerase chain reaction, also called quantitative real time polymerase chain reaction or kinetic polymerase chain reaction, see real-time polymerase chain reaction. assays for the detection and differentiation of North American swine influenza viruses. J Vet Diagn Invest. 2004; 16:367-73. (16.) Webby RJ, Swenson SL, Krauss SL, Gerrish PJ, Goyal SM, Webster RG. Evolution of swine H3N2 influenza viruses in the United States. J Virol. 2000;74:8243-51. (17.) Karasin AI, Olsen CW, Anderson GA. Genetic characterization of an H1N2 influenza virus isolated from a pig in Indiana. J Clin Microbiol. 2000;38:2453-6. (18.) Karasin AI, Landgraf J, Swenson S, Erickson G, Goyal S, Woodruff M, et al. Genetic characterization of H1N2 influenza A viruses isolated from pigs throughout the United States. J Clin Microbiol. 2002;40:1073-9. (19.) Karasin AI, West K, Carman S, Olsen CW. Characterization of avian H3N3 and H1N1 influenza A viruses isolated from pigs in Canada. J Clin Microbiol. 2004;42:4349-54. (20.) Choi YK, Goyal SM, Kang SW, Faruham MW, Joo HS. Detection and subtyping of swine influenza H1N1, H1N2 and H3N2 viruses in clinical samples using two-multiplex RT-PCR assays. J Virol Methods. 2002;102:53-9. (21.) Hoffmann E, Stech J, Guan Y, Webster RG, Perez DR. Universal primer set for the full-length amplification of all influenza A viruses. Arch Virol. 2001 ; 146:2275-89. (22.) Kumar S, Tamura K, Nei M. MEGA3: integrated software for molecular evolutionary genetics analysis and sequence alignment. Briefings in Bioinformatics. 2004;5:150-63. (23.) Choi YK, Lee JH, Erickson G, Goyal SM, Joo HS, Webster RG, et al. H3N2 influenza virus transmission from swine to turkeys, United States. Emerg Infect Dis. 2004; 10:2156-60. (24.) Richt JA, Lager KM, Janke BH, Woods RD, Webster RG, Webby RJ. Pathogenic and antigenic properties of phylogenetically phy·lo·ge·net·ic adj. 1. Of or relating to phylogeny or phylogenetics. 2. Relating to or based on evolutionary development or history: a phylogenetic classification of species. distinct reassortant H3N2 swine influenza viruses cocirculating in the United States. J Clin Microbiol. 2003;41:3198-205. (25.) Palmer DF, Coleman MT, Dowdle WR, Schild GC. Advanced laboratory techniques for influenza diagnosis. Immunology series no. 6. Washington: US Department of Health, Education, and Welfare. 1975. p. 51-2. (26.) Andreyev VG, Wesley RD, Mengeling WL, Vorwald AC, Lager KM. Genetic variation and phylogenetic relationships of 22 porcine reproductive and respiratory syndrome virus (PRRSV) field strains based on sequence analysis of open reading frame 5. Arch Virol. 1997;142:993-1001. (27.) Stemke GW, Phan R, Young TF, Ross RF. Differentiation of Mycoplasma hyopneumoniae, M flocculare, and M hyorhinis on the basis of amplification of a 16S rRNA gene sequence. Am J Vet Res. 1994;55:81-4. (28.) Cooper L, Olsen C, Xu X. Molecular characterization of human influenza A viruses bearing swine-like hemagglutinin genes. Virus Evolution Workshop; 1999 Oct 21-24; Ardmore, Oklahoma. (29.) Kaverin NV, Rudneva IA, Ilyushina NA, Lipatov AS, Krauss S, Webster RG. Structural differences among hemagglutinins of influenza A virus subtypes are reflected in their antigenic architecture: analysis of H9 escape mutants. J Virol. 2004;78:240-9. (30.) Skehel JJ, Wiley DC. Receptor binding and membrane fusion in virus entry: the influenza hemagglutinin. Annu Rev Biochem. 2000;69:531-69. (31.) Wright SM, Kawaoka Y, Sharp GB, Senne DA, Webster RG. Interspecies transmission and reassortment of influenza A viruses in pigs and turkeys in the United States. Am J Epidemiol. 1992; 136:488-97. (32.) Andral B, Toquin D, Madec F, Aymard M, Gourreau JM, Kaiser C, et al. Disease in turkeys associated with H1N1 influenza virus following an outbreak of the disease in pigs. Vet Rec. 1985;116:617-8. (33.) Ficken MD, Guy JS, Gonder E. An outbreak of influenza (H1N1) in turkey breeder hens. Avian Dis. 1989;33:370-4. (34.) Hinshaw VS, Webster RG, Bean W J, Downie J, Senne DA. Swine influenza-like viruses in turkeys potential source of virus for humans? Science. 1983;220:206-8. (35.) Suarez DL, Woolcock PR, Bermudez AJ, Senne DA. Isolation from turkey breeder hens of a reassortant H 1 N2 influenza virus with swine, human, and avian lineage genes. Avian Dis. 2002;46:111-21. (36.) Tsai CP, Pan MJ. New H1N2 and H3N1 influenza viruses in Taiwanese pig herds. Vet Rec. 2003; 153:408. (37.) Reid AH, Fanning TG, Janczewski TA, Taubenberger JK. Characterization of the 1918 "Spanish" influenza virus neuraminidase gene. Proc Natl Acad Sci USA. 2000;97:6785-90. (38.) Lindstrom S, Sugita S, Endo A, Ishida M, Huang P, Xi SH, et al. Evolutionary characterization of recent human H3N2 influenza A isolates from Japan and China: novel ehanges in the reeeptor binding domain. Arch Virol. 1996;141:1349-55. (39.) Baigent SJ, McCauley JW. Glycosylation of haemagglutinin and stalk-length of neuraminidase combine to regulate the growth of avian influenza viruses in tissue culture. Virus Res. 2001 ;79:177 85. (40.) Kaverin NV, Gambaryan AS, Bovin NV, Rudneva IA, Shilov AA, Khodova OM, et al. Postreassortment changes in influenza A virus hemagglutinin restoring HA-NA functional match. Virology. 1998;244:315-21. (41.) Kobasa D, Wells K, Kawaoka Y. Amino acids responsible for the absolute sialidase si·al·i·dase n. See neuraminidase. activity of the influenza A virus neuraminidase: relationship to growth in the duck intestine. J Virol. 2001;75:11773-80. (42.) Alexandra DJ. A review of avian influenza in different bird species. Vet Microbiol. 2000;74:3-13. Address for correspondence: Jurgen A. Richt, Virus and Prion Diseases of Livestock Research Unit, National Animal Disease Center, US Department of Agriculture, Agricultural Research Service, 2300 Dayton Ave, B-15, Ames, IA 50010, USA; email: jricht@nadc.ars.usda.gov Porntippa Lekcharoensuk,* (1) Kelly M. Lager,* Ramesh Vemulapalli, [dagger] Mary Woodruff, [dagger] Amy L. Vincent,* and Jurgen A. Richt* * US Department of Agriculture, Ames, Iowa, USA; and [dagger] Purdue University, West Lafayette, Indiana West Lafayette (IPA: [wɛst ˈlɑ.fəˌjɛt]) is a city in Tippecanoe County, Indiana, United States, 65 miles (105km) northwest of Indianapolis. The population was 28,778 at the 2000 census. , USA (1) Current affiliation: Kasetsart University, Bangkok, Thailand
Table 1. Virus titers in nasal swabs and BALF from experimentally
infected pigs 5 days after infection *
A/SW/MI/PU243/04 ([TCID.sub.50]/ml)
Inoculum/
pig no. 108 109 111
Nasal swab [10.sup.4.3] [10.sup.4.7] [10.sup.5]
BALF [10.sup.6.6] [greater than [10.sup.7]
or equal to]
[10.sup.4.7]
A/SW/MI/PU243/04 A/SW/MI/PU542/04
([TCID.sub.50]/ml) ([TCID.sub.50]/ml)
Inoculum/
pig no. 114 127 3
Nasal swab [10.sup.3] [10.sup.5.8] [10.sup.5.8]
BALF [greater than [10.sup.6.3] [10.sup.7.5]
or equal to]
[10.sup.7.6]
A/SW/MI/PU542/04
([TCID.sub.50]/ml)
Inoculum/
pig no. 110 112 113
Nasal swab [10.sup.5.6] [10.sup.4.5] [10.sup.4.1]
BALF [10.sup.6.5] [10.sup.7.6] [10.sup.6.9]
* BALF, bronchoalveolar lavage fluid; 50%
[TCID.sub.50], 50% tissue culture
infective dose.
Table 2. Results of Megablast nucleotide analyses of influenza
A viruses with the best match of each gene with the H3N1
swine influenza viruses *
A/SW/MI/PU243/04
%
Gene Virus Subtype identity
PB2 A/SW/IU10084/01 H1N2 98.20
PB1 A/SW/IA/930/01 H1N2 98.37
PA A/SW/IA/569/99 H3N2 97.21
HA A/TK/NC/12344/03 H3N2 96.91
NP A/SW/OH/891/01 H1N2 98.96
NA A/WI/10/98 H1N1 95.54
M A/TK/NC/12344/03 H3N2 98.78
NS A/SW/IN/14810-S/01 H1N2 99.24
A/SW/IN/PU542/04
%
Gene Virus Subtype identity
PB2 A/SW/IL/10084/01 H1N2 98.20
PB1 A/SW/IA/930/01 H1N2 97.93
PA A/SW/IA/569/99 H3N2 97.02
HA A/TK/NC/12344/03 H3N2 97.42
NP A/SW/OH/891/01 H1N2 98.46
NA A/WI/10/98 H1N1 93.78
M A/SW/IN/14810-S/01 H1N2 99.48
NS A/SW/IN/14810-S/01 H1N2 99.05
* Accession numbers: A/SW/MI/PU243/04 PB2 (DQ150422), PB1 (DQ150423),
PA (DQ150424), HA (DQ150425), NP (DQ150426), NA (DQ150427), M
(DQ150428), and NS (DQ150429); A/SW/IN/PU542/04 PB2 (DQ150430),
PB1 (DQ150431), PA (DQ150432), HA (DQ150433), NP (DQ150434), NA
(DQ150435), M (DQ150436), and NS (DQ150437); A/SW/IU10084/01
PB2 (AF455738); A/SW/IA/930/01 PB1(AF455727); A/SW/IA/569/99 PA
(AF251425); A/TK/NC/12344/03 HA (AY779253) and M (AY779257);
A/SW/OH/891/01 NP (AF455699); A/WI/10/98 NA (AF342820);
A/SW/IN/14810-S/01 M (AY060071) and NS (AY060136).
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