Porcine reproductive and respiratory syndrome virus: origin hypothesis. (Perspectives).Porcine porcine /por·cine/ (por´sin) pertaining to swine. porcine pertaining to pig. See also hog (1), swine. porcine circovirus 1 a nonpathogenic virus. reproductive and respiratory syndrome 'respiratory syndrome' A relatively specific immune response to high-dose rifampin therapy, characterized by a flu-like complex, dyspnea and wheezing, leukopenia, thrombocytopenia; other hypersensitivity reactions caused by rifampin include flushing, fever, is a serious swine disease that appeared suddenly in the mid-western United States and central Europe approximately 14 years ago; the disease has now spread worldwide. In North America and Europe, the syndrome is caused by two genotypes 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 ), an arterivirus whose genomes diverge by approximately 40%. My hypothesis, which explains the origin and evolution of the two distinct PRRSV genotypes, is that a mutant of a closely related arterivirus of mice (lactate Lactate A salt or ester of lactic acid (CH3CHOHCOOH). In lactates, the acidic hydrogen of the carboxyl group has been replaced by a metal or an organic radical. Lactates are optically active, with a chiral center at carbon 2. dehydrogenase-elevating virus) infected wild boars in central Europe. These wild boars functioned as intermediate hosts and spread the virus to North Carolina North Carolina, state in the SE United States. It is bordered by the Atlantic Ocean (E), South Carolina and Georgia (S), Tennessee (W), and Virginia (N). Facts and Figures Area, 52,586 sq mi (136,198 sq km). Pop. in imported, infected European wild boars in 1912; the virus then evolved independently on the two continents in the prevalent wild hog populations for approximately 70 years until independently entering the domestic pig population. ********** Several human and animal virus diseases, generally caused by RNA viruses RNA viruses, n See viruses. , have emerged in the last 40 years (1,2). Some of these diseases are caused by preexisting pre·ex·ist or pre-ex·ist v. pre·ex·ist·ed, pre·ex·ist·ing, pre·ex·ists v.tr. To exist before (something); precede: Dinosaurs preexisted humans. v.intr. viruses that have the capacity to infect alternate hosts under certain conditions (e.g., Ebola virus, hantavirus hantavirus, any of a genus (Hantavirus) of single-stranded RNA viruses that are carried by rodents and transmitted to humans when they inhale vapors from contaminated rodent urine, saliva, or feces. There are many strains of hantavirus. , and Nipah virus). Other diseases are caused by viruses that seem to have adapted to new hosts after accidental transspecies transmission. In addition to AIDS, which is caused by HIV HIV (Human Immunodeficiency Virus), either of two closely related retroviruses that invade T-helper lymphocytes and are responsible for AIDS. There are two types of HIV: HIV-1 and HIV-2. HIV-1 is responsible for the vast majority of AIDS in the United States. , porcine reproductive and respiratory syndrome (PRRS PRRS porcine reproductive and respiratory syndrome. ) is a prime example of the latter class of diseases. PRRS, which affects domestic pigs, was first recognized approximately 14 years ago in North America (3) and in central Europe (4); this disease is now found worldwide and causes considerable economic losses in the swine industry (5). Initially, the disease was referred to as "mystery swine disease" until its cause was determined to be a positive-stranded RNA virus, designated porcine reproductive and respiratory syndrome virus (PRRSV), that together with murine murine /mu·rine/ (mur´en) pertaining to, derived from, or characteristic of mice or rats. mu·rine adj. lactate dehydrogenase-elevating virus (LDV LDV Laser Doppler Velocimetry LDV Light Duty Vehicle LDV Laser Doppler Velocimeter LDV Local Defence Volunteers (Afterwards Home Guard, UK) LDV Limited Dependent Variable LDV Laser Doppler Vibrometers LDV Leyland Daf Vehicles ), equine arteritis arteritis Inflammation of the arteries. It occurs in diseases including syphilis, tuberculosis, and lupus erythematosus. Varieties not closely associated with systemic disease or disease of an organ outside the cardiovascular system have been described as temporal arteritis, virus, and simian hemorrhagic fever virus, belongs to the family Arteriviridae (6). However, the origin of PRRSV is still a mystery, especially since the European and North American PRRSV isolates cause similar clinical symptoms but represent two distinct viral genotypes whose genomes diverge by approximately 40% (7). The European and North American PRRSV prototypes are Lelystad virus (4) and VR-2332 (3), respectively. Retrospective serologic tests did not detect antibodies (Abs) to PRRSV in domestic pigs in Iowa and in Germany before the mid-1980s (8,9). The first seropositive seropositive /se·ro·pos·i·tive/ (-poz´i-tiv) showing positive results on serological examination; showing a high level of antibody. se·ro·pos·i·tive adj. pigs were discovered in herds in Iowa in 1985, Minnesota in 1986, and the former East Germany in 1988-1989. Researchers have postulated that LDV and PRRSV, which are closely related, are derived from a common ancestor (10,11). I suggest that PRRSV is derived from LDV and that wild boars have functioned as intermediate hosts, based on the following observations. The primary structural proteins of arteriviruses are 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. (N) protein, the integral membrane/matrix (M) protein, and the primary envelope glycoprotein glycoprotein (glī'kōprō`tēn), organic compound composed of both a protein and a carbohydrate joined together in covalent chemical linkage. , GP5 (10-12). Both the M protein and GP5 of LDV and PRRSV seem to be triple membrane-spanning proteins whose short ectodomains of approximately 11 and 30 amino acids, respectively, are disulfide di·sul·fide n. A chemical compound containing two sulfur atoms combined with other elements or radicals. Also called bisulfide. linked (11,13,14). The ectodomain heterodimer seems critical for the infection of macrophages Macrophages White blood cells whose job is to destroy invading microorganisms. Listeria monocytogenes avoids being killed and can multiply within the macrophage. , the primary host cell of all arteriviruses, perhaps playing a role in receptor interaction (14), but neither the GP5 ectodomain nor the M protein ectodomain appears to determine host cell tropism tropism (trōp`ĭzəm), involuntary response of an organism, or part of an organism, involving orientation toward (positive tropism) or away from (negative tropism) one or more external stimuli. (15,16). LDV was first isolated from tumor-bearing laboratory mice but later found to be endogenous in wild house mouse populations (Mus rnusculus dornesticus; 10,17). LDV invariably in·var·i·a·ble adj. Not changing or subject to change; constant. in·var  i·a·bil causes a lifelong asymptomatic infection in mice that is recognized only by an elevation of plasma lactate dehydrogenase activity. The virus replicates cytocidally in a subpopulation sub·pop·u·la·tion n. A part or subdivision of a population, especially one originating from some other population: microbial subpopulations. Noun 1. of permissive tissue macrophages that clears excess lactate dehydrogenase from circulation. Persistent infection is maintained by replication in newly regenerated permissive macrophages and the escape from all host defenses. The single neutralization neutralization, chemical reaction, according to the Arrhenius theory of acids and bases, in which a water solution of acid is mixed with a water solution of base to form a salt and water; this reaction is complete only if the resulting solution has neither acidic nor epitope epitope: see immunity. located in the middle of GP5 ectodomain (Figure 1) is flanked in the common LDV isolates, represented by LDV-P (10), by two N-glycans that impair the immunogenicity immunogenicity /im·mu·no·ge·nic·i·ty/ (-je-nis´it-e) the property enabling a substance to provoke an immune response, or the degree to which a substance possesses this property. of the epitope and render the viruses completely resistant to in vivo Ab neutralization (18,19). LDV, which is poorly transmitted between mice, is transmitted by biting and perhaps sexually but not via the respiratory route; oral transmission requires high amounts of virus (10,20). All LDVs isolated from tumor-bearing laboratory mice and wild house mice are genetically closely related to LDV-P. Nucleotide differences are largely found in the segments encoding the signal peptides of the glycoproteins or represent mostly translational silent substitutions (21,22), which indicates that LDV-P has attained close to evolutionary stasis (23). [FIGURE 1 OMITTED] In contrast to LDV, individual field isolates of both the European and North American PRRSVs exhibit great genome variability (e.g., 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 of open reading frame [ORF] 5, Figure 2). However, all PRSSV isolates are closely related to LDV, which is clearly indicated by amino acid comparisons of individual viral proteins. For example, the GP5 ectodomains of LDV, PRRSV VR-2332, and PRRSV Lelystad virus are collinear col·lin·e·ar adj. 1. Passing through or lying on the same straight line. 2. Containing a common line; coaxial. col·lin and contain a segment with approximately 70% amino acid identity (Figure 1). This segment contains the primary neutralization epitopes of LDV and of PRRSV (24,25), two highly conserved N-glycosylation sites and the Cys residue between them that is postulated to disulfide link the GP5 ectodomain to that of the M protein. The branching of the LDV sequence in the phylogenetic tree (Figure 2) in the line connecting the European and North American PRRSVs indicates that LDV is approximately equally related to both. This relationship is also indicated by the finding that some amino acids in all viral proteins are identical for LDV and VR-2332 but not Lelystad virus; vice versa, some amino acids are identical for LDV and Lelystad virus proteins only. For example, in the highly conserved segment of the GP5 ectodomain, two amino acids are identical in LDV and VR-2332 and one is identical in LDV and Lelystad virus (Figure 3; see also the discussion of the N-protein, and ORF1b protein). [FIGURES 2-3 OMITTED] The genetic stability of LDV (which contrasts with the high variability of the PRRSV genomes typical for a new virus) and the relationship between the genome of LDV and those of the two PRRSV genotypes (Figure 2) both suggest that PRRSV has been derived from LDV. My hypothesis is that LDV was transmitted from an infected wild house mouse to a Eurasian wild boar (Sus scrofa) in central Europe sometime during the 19th century. At that time, wild boars were common throughout Europe, North Africa, and Asia (26). Such transmission would be rare because of species differences and the low transmissibility trans·mis·si·ble adj. That can be transmitted: transmissible signals. trans·mis of LDV. The transmission may have occurred through oral means or wounds and involved a mutant form of LDV able to infect wild boars. The initial replication of this LDV mutant in and transmission between wild boars was likely slow until better host-adapted mutants were selected. The replication of the initially infecting virus might have been limited to tissue macrophages, as in mice. Where the initial virus transmission from wild house mice to wild boars occurred cannot be deduced from genome sequence comparisons. The ORF5 phylogenetic tree (Figure 2) suggests that the transmission could have occurred in Lithuania because the ORF5s of the Lithuanian isolates are more closely related to LDV than those of other European PRRSV isolates, but this relationship is not apparent in a phylogenetic analysis of ORF7 that encodes the N-protein. The initial infection of wild boars likely occurred in the eastern part of Germany (Sachsen-Anhalt), where the first PRRSV-seropositive pigs were discovered in Europe in 1988 and 1989 (9) and infected boars detected in this region in 1991 and 1992. From there the virus may have spread to the United States. Eurasian wild boars were introduced into the United States several times, but the primary introduction that became established occurred in 1912 when 14 wild boars (11 females and 3 boars) were released in a game preserve in the southwestern part of North Carolina in Hooper Bald (26). The origin of these wild boars is not entirely certain, but they probably came from the Harz Mountains in Sachsen-Anhalt. I postulate that one or more of these wild boars was infected with a PRRSV precursor virus and thus spread the virus to the United States. In 1912, feral pigs were widely prevalent throughout the United States (26). They were derived from domestic pigs that had escaped from farms, were intentionally released, or were free ranging. Soon after their importation, some wild boars escaped from the enclosed park; hybridization hybridization /hy·brid·iza·tion/ (hi?brid-i-za´shun) 1. crossbreeding; the act or process of producing hybrids. 2. molecular hybridization 3. occurred between them and the feral pigs indigenous to the area (26). Most wild hogs now found in many U.S. states appear to be descendants of these hybrids. Wild boars from the North Carolina game farm were introduced into California in 1924, where they became well established. Wild boars were also released in Texas from 1930 to 1933 and became established there; these boars came from the San Antonio Zoo The San Antonio Zoological Gardens and Aquarium is an Association of Zoos and Aquariums-accredited zoo in San Antonio, Texas, United States. The 56-acre zoo has a collection of over 3,500 animals representing 750 species. The zoo's annual attendance exceeds 850,000. , but their original source is unknown (26). After the introduction of PRRSV-infected wild boars in the United States in 1912, the virus would be expected to have evolved independently for 70 years in Europe and North America with the selection of mutants with better growth potential in the different wild hog populations on the two continents. Such independent evolution would explain the two distinct genotypes which, however, remain equally, but differently, related to LDV (Figure 2). Such selection of host environment--adapted mutants in this group of viruses is indicated by the rapid development of geographic clades of both the European and North American genotypes of PRRSV (27,28) (Figure 2). Such evolution must also have eventually involved the selection of mutants that efficiently replicate in alveolar macrophages, which is a property of PRRSV. This selection not only increased virulence of the viruses but also improved their replication potential in their hosts and transmission between the latter via the respiratory route. Eventually, PRRSV variants infected pigs being raised domestically. Direct contact between wild hogs and domestic pigs in outdoor farms is not uncommon, and wild hogs have been intentionally introduced into existing swine herds. However, transmission could also have been mediated by products from hunted or slaughtered infected wild hogs. When and where this transmission might have occurred are unclear. Retrospective analyses found that approximately 1,400 serum samples collected in Iowa in 1980 lacked anti-PRRSV Abs. The first seropositive samples were detected in Iowa in 1985, and the earliest clinical symptoms were observed in herds in North Carolina, Iowa, and Minnesota (29). Thus, the first transmission from wild hogs to domestic pigs in the United States likely occurred in North Carolina, where wild hogs are numerous; the virus further evolved in the domestic pig population there and then spread to various midwestern states. By 1990, PRRSV had spread to 19 western, midwestern, and eastern states (29). In Europe, the first pigs with antiPRRSV Abs were detected in East German herds in 1988 and 1989 (9) shortly before clinical symptoms of the disease were reported in herds in the central part of western Germany (30). A molecular clock of ORF3 suggests that the common ancestor of the European type of PRRSV infected domestic pigs around 1979 (31). This conclusion is not inconsistent with the relationship between the PRRSV strains in Europe and North America (Figure 2). The infection of the domestic pig populations on both continents may have occurred when the density of the wild hog and domestic swine populations increased considerably, which may have facilitated contact between them. Once virulent variants developed in the domestic pig populations, the spread of PRRSV has been extremely rapid on both continents as well as to other continents. Thus, pinpointing the location of the initial infection of domestic pigs is difficult. Wild hogs with anti-PRRSV Abs have now been detected in both Europe and the United States. Two serum samples from 482 wild boars shot in 1991 and 1992 in Sachsen-Anhalt were found to have anti-PRRSV Abs by using the indirect immunoperoxidase 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 assay. The PRRSV-positive boars were shot close to the former border to West Germany (32). Similarly, in northern France, 25 of 303 farmed wild boars tested in 1993 and 1994 and 8 of 603 shot in the same period were found to be seropositive by using the same serologic test or an indirect enzyme-linked immunosorbent assay enzyme-linked immunosorbent assay n. ELISA. Enzyme-linked immunosorbent assay (ELISA) A diagnostic blood test used to screen patients for AIDS or other viruses. (ELISA ELISA (e-li´sah) Enzyme-Linked Immuno-Sorbent Assay; any enzyme immunoassay using an enzyme-labeled immunoreactant and an immunosorbent. ELISA n. ) (33), and 2 of 117 feral hogs tested in Oklahoma were seropositive in a commercial ELISA and a fluorescent Ab-staining test (34). However, no Abs were detected in 24 feral hogs killed in 1993-1994 in the Fort Riley Army Base in Kansas (35), in 44 wild boars shot in 1999 in Croatia (36), in 78 wild boars shot in 1999-2000 in Spain (37), or in >1,000 serum samples collected from wild boars in Eastern Europe (Stadejek, pers. comm.). The assumption is that seropositive wild hogs became infected by contact with infected domestic pigs (33), but no evidence exists to rule out that this infection may be an endogenous infection of wild boars that served as recent reservoir for the infection of domestic pigs. Regardless, the finding of PRRSV-seropositive wild hogs in both Europe and the United States indicates that wild hogs are susceptible to PRRSV infection. Wild hogs can also carry other viruses, such as those causing classical swine fever Classical swine fever (CSF) or hog cholera (also sometimes called pig plague based on the German word Schweinepest) is a highly contagious disease of pigs and wild boar. , Aujeszky's disease, and pseudorabies pseudorabies see aujeszky's disease. ; these viruses are considered an important potential source of infection of domestic pigs, especially in the case of classical swine fever. In any case, the serologic tests available for the assay of anti-PRRSV Abs are likely inefficient or unsuitable for the detection of Abs to LDV-PRRSV intermediates that may be prevalent in wild hog populations. The tests are designed to detect anti-N-protein Abs, which are the primary Abs generated in PRRSV infected domestic pigs (11). Although the N-protein is a relatively conserved arterivirus protein, considerable amino acid differences exist between European and North American PRRSVs. For example, the N-proteins of Lelystad virus and VR-2332 exhibit only 60% amino acid identity (Figure 3). Several linear epitopes have been identified in the N-proteins of Lelystad virus and North American PRRSV, but they differ for the two PRRSVs and little serologic se·rol·o·gy n. pl. se·rol·o·gies 1. The science that deals with the properties and reactions of serums, especially blood serum. 2. cross reaction occurs between them (11). Furthermore, these epitopes were identified by reaction with N-protein specific mouse monoclonal Abs (mAbs); only limited information is available on the immunogenicity of these epitopes in pigs. In addition, a common conformational epitope has been identified in the center of the N-protein (AA51-69), which exhibits 84% amino acid identity between Lelystad virus and VR-2332 (Figure 3). The corresponding segment of the LDV N-protein, however, exhibits much lower amino acid identity (42%) (Figure 3). Overall amino acid identity of the N-proteins of LDV, Lelystad virus, and VR-2332 is 36% (Figure 3); 15 additional amino acids are identical in LDV and VR-2332 and 10 amino acids in LDV and Lelystad virus, again indicating the close, but distinct, relationship of LDV with both PRRSV genotypes. The LDV/VR-2332 and LDV/Lelystad virus identical amino acids are primarily located in the C-terminal and N-terminal halves of the N-proteins, respectively. These amino acid differences between the LDV and PRRSV proteins may explain a lack of serologic cross-reaction between them; the same may be true for LDV-PRRSV intermediates. In addition, mice infected with LDV or immunized with inactivated inactivated rendered inactive; the activity is destroyed. inactivated viruses treated so that they are no longer able to produce evidence of growth or damaging effect on tissue. virions do not generate Abs to the N-protein (38,39), apparently because the viral envelope or its proteins interfere with the immunogenicity of the N-protein since a mAb to the N-protein was generated by immunizing mice with isolated nucleocapsids (40). The primary Ab response of mice to LDV is to nonneutralization epitopes of GP5, which contrasts with the primary anti-N-protein Ab response of pigs or mice to PRRSV. These differences in Ab responses of pigs and mice may also apply to LDV-PRRSV intermediates and make it unlikely that their infection can be recognized by the available serologic tests for either LDV or PRRSV Abs. Furthermore, nothing is known about the prevalence of potential LDV-PRRSV intermediates in the wild hog population, the pathogenesis and course of infection of such viruses (or of PRRSV) in wild hogs, or the antiviral immune response of wild hogs. An approach that is more suitable to detect LDV-PRRSV intermediates is reverse transcription--polymerase chain reaction (RT-PCR RT-PCR reverse transcriptase-polymerase chain reaction. See PCR1. ) with primers to highly conserved genomic sequences, for example, in a segment of the RNA polymerase domain upstream of the nidovirus characteristic SDD (Software Design Description) The architecture of an information system. See IDD. protein sequence (Figure 4). This nucleotide segment exhibits 53% identity between LDV, Lelystad virus, and VR-2332 (118/224 nucleotides; amino acid identity of the encoded protein segment is even higher, 75%). This segment contains short segments with complete nucleotide identity (Figure 4, stars); in addition, 25, 30, and 31 nucleotides are identical for LDV and VR-2332, LDV and Lelystad virus, and Lelystad virus and VR-2332, respectively, indicating again the close, but distinct, relationship between LDV and both Lelystad virus and VR-2332. My laboratory has previously used degenerate primer sets of this region designed on the bases of LDV, equine arteritis virus, and Lelystad virus sequence information (Figure 4) that detected not only the genomes of these three viruses but also those of VR-2332 and simian hemorrhagic fever virus, for which no sequence information was available at the time (41). The additional advantages of the RT-PCR approach are that this method can be readily applied to both serum and tissue samples and that the sequence of the PCR-amplified segment allows conclusions about the relatedness of the detected virus to existing viruses and the synthesis of specific gene probes for this virus. Also, degenerate primer sets can be designed to detect specific LDV-PRRSV intermediates. The same approach can be used to examine other species for the presence of arteriviruses. [FIGURE 4 OMITTED] My hypothesis on the origin of PRRSV encompasses all known facts but will be difficult, if not impossible, to prove, largely because of a lack of suitable materials for experimental investigation. My explanation of the theory serves to elicit interest in this subject and to encourage collaboration between investigators, especially in the search for stored or new materials that can be used to test the hypothesis. Acknowledgments I thank T. Stadejek and V. Kaden for personal communications and T. Stadejek for providing the phylogenetic tree of lactate dehydrogenase-elevating virus and porcine reproductive and respiratory syndrome virus isolates. References (1.) Morse S. Crossing over: the interspecies traffic of emerging infections. J NIH "Not invented here." See digispeak. NIH - The United States National Institutes of Health. Res 1994;6:52-6. (2.) Nathanson N. The emergence of infectious diseases: societal causes and consequences. ASM (1) (Association for Systems Management) An international membership organization based in Cleveland, Ohio. Founded in 1947 and disbanded in 1996, it sponsored conferences in all phases of administrative systems and management. News 1996;63:83-8. (3.) Collins J, Benfield D, Christianson W, Harris L, Hennings J, Shaw D, et al. Isolation of swine infertility and respiratory syndrome swine infertility and respiratory syndrome see porcine reproductive and respiratory syndrome. virus (isolate ATCC ATCC American Type Culture Collection, see there VR-2332) in North America and experimental reproduction of the disease in gnotobiotic gno·to·bi·ot·ic adj. 1. Of or relating to gnotobiology. 2. Free of germs or associated only with known or specified germs. gnotobiotic pertaining to a gnotobiote or to gnotobiotics. pigs. J Vet Diagn Invest 1992;4:117-26. (4.) Wensvoort G. Lelystad virus and the porcine epidemic abortion and respiratory syndrome. Vet Res 1993;24:117-24. (5.) Benfield D, Collins J, Dee S, Halbur P, Joo H, Lager K, et al. Porcine reproductive and respiratory syndrome. In: Straw BE, D'Allaire S, Mengeling WL, Taylor DJ, editors. Diseases of the swine. 8th ed. Ames, Iowa: Iowa State University Academics ISU is best known for its degree programs in science, engineering, and agriculture. ISU is also home of the world's first electronic digital computing device, the Atanasoff–Berry Computer. Press; 1999. p. 201-32. (6.) Cavenagh D. Nidovirales: a new order comprising Coronaviridae and Arteriviridae. Arch Virol 1997; 142:629-33. (7.) Nelsen C, Murtaugh M, Faaberg K. Porcine reproductive and respiratory syndrome virus comparison: divergent evolution on two continents. J Virol 1999;73:270-80. (8.) Hill H, Owen W, Eernisse K, Zimmerman J, Uhlenhopp E, Frey M. 1992. Prevalence of SIRS in Iowa swine herds. American Association Swine Practitioners News 1992:47. (9.) Ohlinger V. PRRS/Blue ear disease. In: Meredith M, editor. SIRS monthly newsletter. Cambridge: Pig Disease Information Center; December 1992. (10.) Plagemann P. Lactate dehydrogenase-elevating virus and related viruses. In: Fields BN, Knipe DM, Howley PM, editors. 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 . 3rd edition. New York: Raven Press; 1996. p. 1105-20. (11.) Dea S, Ganon C, Mardassi H, Pirzadeh B, Rogan D. Current knowledge on the structural proteins for porcine reproductive and respiratory syndrome (PRRS) virus: comparison of the North American and European isolates. Arch Virol 2000; 145:659-68. (12.) Meulenberg J. PRRSV, the virus. Vet Res 2000;31:11-21. (13.) Faaberg K, Plagemann P. The envelope proteins of lactate dehydrogenase-elevating virus and their membrane topography. Virology 1995;212:512-25. (14.) Faaberg K, Even C, Palmer G, Plagemann P. Disulfide bonds between two envelope proteins of lactate dehydrogenase-elevating virus are essential for viral infectivity. J Virol 1995;69:613-7. (15.) Dobbe J, van der Meer Van der Meer is a Dutch surname that simply means the phrase 'from the lake' in English. Many years ago, descendants would have lived from a lake in the Netherlands which is how the name first originated. Y, Spaan W, Snijder E. Construction of chimeric chi·mer·ic adj. 1. Relating to a chimera. 2. Composed of parts of different origin. arteriviruses reveals that the ectodomain of the major glycoprotein is not the main determinant of equine arteritis tropism in cell culture. Virology 2001 ;288:283-94. (16.) Verheide M, Welting T, Jansen H, Rottier P, Meulenberg J. Chimeric arteriviruses generated by swapping of the M protein ectodomain rule out a role of this domain in viral targeting. Virology 2002;303:364-73. (17.) Rowson K, Mahy B. Lactic lactic /lac·tic/ (lak´tik) pertaining to milk. lac·tic adj. Of, relating to, or derived from milk. lactic pertaining to milk. dehydrogenase dehydrogenase /de·hy·dro·gen·ase/ (de-hi´dro-jen-as?) an enzyme that catalyzes the transfer of hydrogen or electrons from a donor, oxidizing it, to an acceptor, reducing it. de·hy·dro·gen·ase n. virus. Virol Monogr 1975;13. (18.) Plagemann P, Chen Z, Li K. Polylactosaminoglycan chains on the ectodomain of the primary envelope glycoprotein of an arterivirus determine its neuropathogenicity, sensitivity to antibody neutralization and immunogenicity of the neutralization epitope. Curr Top Virol 1999;1:27-43. (19.) Plagemann P. Complexity of the single linear neutralization epitope of the mouse arterivirus lactate dehydrogenase-elevating virus. Virology 2001;290:11-20. (20.) Cafruny W, Hovinen D. The relationship between route of infection and minimum infectious dose: studies with lactate dehydrogenase-elevating virus. J Virol Methods 1988;20:265-70. (21.) Li K, Schuler T, Chen Z, Glass G, Childs J, Plagemann P. Isolation of lactate dehydrognease-elevating viruses from wild house mice and their biological and molecular characterization. Virus Res 2000;67:153-62. (22.) Plagemann P, Chen Z, Li K.Replication competition between lactate dehydrogenase-elevating virus quasispecies in mice: implications for quasispecies selection and evolution. Arch Virol 2001 ;146:1283-96. (23.) Holland J, Domingo E. Origin and evolution of viruses. Virus Genes 1998;16:13-21. (24.) Ostrowski M, Galeota J, Jar A, Platt K, Osorio F, Lopez O. Identification of neutralizing and nonneutralizing epitopes in the porcine reproductive and respiratory syndrome virus GP5 ectodomain. J Virol 2002;76:4241-50. (25.) Plagemann P, Rowland R, Faaberg K. The primary neutralization epitope of porcine reproductive and respiratory syndrome virus is located in the middle of the GP5 ectodomain. Arch Virol 2002; 147:2327-47. (26.) Mayer J, Brisbin I. Wild pigs of the United States: their biology, history, morphology and current status. Athens (GA): The University of Georgia Press The University of Georgia Press or UGA Press is a publishing house and is a member of the Association of American University Presses. Founded in 1938, the UGA Press is a division of the University of Georgia and is located on the campus in Athens, Georgia, USA. ; 1991. (27.) Stadejek T, Stankevicius A, Storgaard T, Oleksiewicz M, Drew T, Pesak Z. Identification of radically different variants of porcine reproductive and respiratory syndrome virus in Eastern Europe: towards a common ancestor for European and American viruses. J Gen Virol 2002;83:1861-73. (28.) Forsberg R, Storgard T, Nielsen H, Oleksiewicz M, Cardioli P, Sala G, et al. The genetic diversity of European type PRRSV is similar to that of the North American type but is geographically skewed skewed curve of a usually unimodal distribution with one tail drawn out more than the other and the median will lie above or below the mean. skewed Epidemiology adjective Referring to an asymmetrical distribution of a population or of data within Europe. Virology 2002;299:38-47. (29.) Christianson W, Joo H-S. Porcine reproductive and respiratory syndrome: a review. Swine Health Prod 1994;2:10-28. (30.) Lindhaus W, Lindhaus B. Raetselhafte Schweinekrankheit. Prakt Tierarzt 1991 ;5:423-5. (31.) Forsberg R, Oleksiewiez M, Peterson A, Hein J, Botner A, Storgaard T. A molecular clock dates the common ancestor of European-type porcine reproductive and respiratory syndrome virus at more than 10 years before emergence of disease. Virology 2001 ;289:174-9. (32.) Oslage U, Dahle J, Mueller T, Kramer M, Liess B. Praevalenz von Antikoerpem gegen die Viren der Europaeischen Schweinepest,der Aujeszky'schen Krankheit and des" porcine reproductive and respiratory syndrome"(PRRS) bei Wildschweinen in den Bundeslaendem Sachsen-Anhalt und Brandenburg. Dtsch Tieraerztl Wochenschr 1994;101:33-8. (33.) Albina Albina is:
pertaining to or emanating from serology. serological test one involving examination of blood serum usually for antibody. survey on classical swine fever (CSF Cerebrospinal Fluid (CSF) Analysis Definition Cerebrospinal fluid (CSF) analysis is a laboratory test to examine a sample of the fluid surrounding the brain and spinal cord. ), Aujeszky's disease (AD) and porcine reproductive and respiratory syndrome (PRRS) virus infections in French wild boars from 1991 to 1998. Vet Microbiol 2000;77:43-57. (34.) Saliki J, Rodgers S, Eskew G. Serosurvey of selected viral and bacterial diseases in wild swine from Oklahoma. J Wildl Dis 1998;34:834-8. (35.) Gibson P, Veatc J, Matlack R, Jones D. Health status of a recently discovered population of feral swine in Kansas. J Wildl Dis 1999;35:624-7. (36.) Zupancic Z, Jukic B, Lojkic M, Cac Z, Staresina V. Prevalence of antibodies to classical swine fever, Aujeszky's disease, porcine reproductive and respiratory syndrome, and bovine viral diarrhea viruses in wild boars in Croatia. J Vet Med B Infect Dis Vet Public Health 2002;49:253-6. (37.) Vincent J, Leon-Vizcaino L, Gortazar C, Cubero M, Gonzales M, Martin-Atance P. Antibodies to selected viral and bacterial pathogens in European boars from southwestern Spain. J Wildl Dis 2002;38:649-52. (38.) Cafruny W, Chan S, Harty J, Yousefi S, Kowalchyk K, McDonald D, et al. Antibody response of mice to lactate dehydrogenase-elevating virus during infection and immunization immunization: see immunity; vaccination. with inactivated virus. Virus Res 1986;5:357-75. (39.) Harty J, Chan S, Plagemann P. Characteristics of monoclonal antibodies to the lactate dehydrogenase-elevating virus. Intervirology 1987;27:53-60. (40.) Coutelier J, van Roost F, Lambotte P, van Snick J. The murine antibody response to lactate dehydrogenase-elevating virus. J Gen Virol 1986;67:1099-108. (41.) Chen Z, Plagemann P. Detection of related positive strand RNA virus genomes by reverse transcription/polymerase chain reaction using degenerate primers for common replicase replicase /rep·li·case/ (rep´li-kas) 1. a polymerase synthesizing RNA from an RNA template. 2. more generically, any enzyme that replicates nucleic acids, i.e., a DNA or RNA polymerase. sequences. Virus Res 1995;39:365-75. Dr. Plagemann is professor of microbiology at the University of Minnesota (body, education) University of Minnesota - The home of Gopher. http://umn.edu/. Address: Minneapolis, Minnesota, USA. . He has studied arteriviruses for over 40 years, especially the molecular biology, pathogenesis, and immunology of lactate dehydrogenase-elevating virus. He has written several reviews on the subject. Now partially retired, he is continuing research on the immune response of pigs to porcine reproductive and respiratory syndrome virus. Peter G.W. Plagemann, University of Minnesota, Minneapolis, Minnesota, USA Address for correspondence: Peter G.W. Plagemann, Department of Microbiology, Medical School, University of Minnesota, 420 Delaware St. S.E., MMC See MultiMediaCard and Microsoft Management Console. 196, Minneapolis, MN, 55455, USA; fax: 612-626-0623; email: plage plage (pläzh): see chromosphere. 001@umn.edu |
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