The role of antibody in protection against African swine fever virus

Intraperitoneal immunization of pigs with anti-African swine fever virus (ASFV) antibody protected them against the effects of challenge with ASFV. This protection, which was exemplified by a reduction in pyrexia and viraemia plus an increased survival time, appeared to be mediated through the effects of complement-dependent antibody-mediated cytotoxicity (CDAC) or antibody dependent cell mediated cytotoxicity (ADCC). Experiments suggested that the reduction in viraemia was associated with complement lysis whereas protection was conferred by ADCC.     

Changes in macrophages in spleen and lymph nodes during acute African swine fever: expression of cytokines

To gain further insight into the pathogenesis of African swine fever (ASF), the cytokine expression by macrophages in spleen and lymph nodes were examined. Twenty-one piglets were inoculated with the highly virulent isolate Spain-70 of ASF virus and killed in groups at 1-7 post-inoculation days (pid). An increase in the immunohistochemical detection of proinflammatory monokines in spleen and renal and gastrohepatic lymph nodes is reported, along with an increase in the serum levels of TNF-alpha and IL-1 beta. The expression of these cytokines is detected simultaneously in time and space with the viral protein 73 (vp 73) of the ASF virus detection. Our results demonstrate that mononuclear phagocyte system cell activation results in the release of several cytokines that could induce apoptosis of lymphocytes and haemodynamic changes.     

Swine fever: classical swine fever and African swine fever.

Because of the clinical and pathologic similarity to common endemic diseases, introduction of CSFV or ASFV strains of moderate to low virulence represents the greatest risk to North American swine herds. Producers, veterinarians, and diagnosticians should increase their awareness of these devastating diseases and request specific diagnostic testing whenever they are suspected. Production practices that improve biosecurity will reduce the risk of introduction of CSF and ASF and limit the spread if an incursion occurs. Additional resources. The following Web sites contain excellent color photographs that will assist producers and practitioners in identifying clinical signs and gross lesions associated with CSFV and ASFV: http://www.vet.uga.edu/vpp/gray_book/FAD and http://www.pighealth.com. The latter Web site and the OIE Web site (http://www.oie.int) offer updated information on current worldwide epizootics of ASF and CSF and other swine diseases. Details of biosecurity procedures can be found at http://www.agebb.missouri.edu; see publication G2340.     

Extraction of viral DNA from erythrocytes of swine with acute African swine fever

The preparation of wild-type African swine fever (ASF) virus DNA from small amounts of viremic blood from acutely febrile pigs is outlined. The extracted DNA is viral and not host-cell DNA, because of specific homology with cell culture grown and purified ASF virus and because no DNA bands are obtained with an equal amount of nonviremic pig blood. Thus, in the absence of suitable serologic methods for strain identification, it is now possible to catalogue wild-type isolates by characteristic DNA restriction patterns. The wild-type virus genome contains terminal single-stranded DNA cross-links and has the largest genome size (180 kilobase pairs) reported for the ASF virus. Experimental passage of the virus in contact-infected pigs and buffy coat cultures appears to confirm the stable nature of the ASF genome in the field.     

饲料添加剂在非洲猪瘟防控中的作用

非洲猪瘟是一种烈性传染病,其暴发给全球养猪业带来了巨大的损失。至今尚未研发成功相应的疫苗。文章主要探讨了新型添加剂中草药饲料添加剂、微生态制剂对于猪只非特殊免疫力的调节以及对防控非洲猪瘟所起的作用。     

The epidemiology of African swine fever: the role of free-living hosts in Africa

The known distribution of African swine fever (ASF) virus in Africa is reviewed in relation to the distributions of its free-living hosts as are the infection rates of these species in different localities in southern Africa. Mechanisms by which ASF virus is maintained in its sylvatic state and ways in which the infection may enter domestic pig populations are discussed.     

吸血性节肢动物在非洲猪瘟病毒传播过程中可能扮演的角色

非洲猪瘟自2018年冬季从国外传入,给国内的生猪产业造成毁灭性打击,已造成大量生猪死亡和众多养殖户恐慌.尽管非洲猪瘟已被世界动物卫生组织列为法定上报疾病之一,但是市面上尚无有效的治疗药物和疫苗,故国际上针对该病的防制措施仍停留于消灭传染源、切断传播途等物理防御.据文献记载,非洲猪瘟病毒可由某些吸血性节肢动物所传播,故清...     

Mechanism of thrombocytopenia in African swine fever

Pigs were inoculated with an African swine fever (ASF) isolate of moderate virulence, and the changes in the number of circulating blood platelets during infection were correlated with the appearance of antiviral antibody and fluctuations in total plasma hemolytic complement concentrations. Thrombocytopenia was detected by postinoculation days (PID) 7 and 8, and antiviral antibody was detected by PID 7, using an indirect immunofluorescence technique. The total hemolytic complement concentration was moderately and transiently decreased from PID 5 to 9, but was consistently low from PID 18 to 26. Pigs inoculated with an ASF virus isolate of greater virulence had a decrease in platelet counts on PID 6 and 7, and the total plasma hemolytic complement levels decreased in all pigs by PID 6 to 7. Antibody to ASF virus was not detected in pigs inoculated with the more virulent isolate. Pigs sensitized to ASF viral antigen with an inactivated-virus vaccine or by previous infection with ASF were challenge exposed. Sensitized pigs became clinically ill and thrombocytopenic by 24 to 72 hours earlier than did inoculated, nonsensitized pigs. Vaccinated pigs inoculated with homologous virus had lower blood virus concentrations than did nonvaccinated pigs. African swine fever virus-sensitized pigs inoculated with heterologous virus had a higher fatality rate than did nonsensitized pigs, and the pigs died peracutely, with only a few gross lesions in evidence. In vitro experiments demonstrated that ASF virus antigen induced platelet aggregation in platelet-rich plasma from recovered, nonviremic pigs. Viral antigen, antibody, or complement was not demonstrable on the surface of platelets from pigs inoculated with ASF virus isolate, by direct immunofluorescence testing.     

Diversity of African swine fever virus

An African swine fever virus is an heterogeneous population, consisting of clones having different biological characteristics in respect to hemadsorption, virulence, infectivity, plaque size, and antigenic determinants. The following observations were made: Nonhemadsorbing virus (NHV) have been segregated from field isolates from Haiti (HT-1) and a bone marrow- and buffy coat-passaged Portuguese isolate (L'60BM89BC1) and appear as a major, minor, or equal mixture with hemadsorbing viruses in the virus population. Biological characteristics of the virus inoculated into pigs often differed from viruses isolated later from the same pigs. Virulence and nonhemadsorbing characteristics of isolated clones were genetically stable. The lethal effect of 2 NHV clones of L'60BM89BC1 virus was dose-dependent; small doses of virus induced immunologic deaths or recoveries from the clinical disease in pigs, and large doses induced acute deaths. The NHV of Lisbon isolate of 1960 (L'60) and HT-1 isolate share the same antigenic determinants for inducing protection. Tengani isolate contained clones of distinctly different antigenic determinants, not shared by L'60 or HT-1 isolate that enabled it to overcome the protection induced by the other clones. Passaging of an African swine fever virus isolate in pigs or cell cultures may readily alter the proportions of the different clones in the population and thereby change its overall characteristics. A new virus population with atypical hemadsorption was found in HT-1 field isolate and L'60BM89BC1 virus.     

非洲猪瘟病毒研究进展

非洲猪瘟（African swine fever，ASF）是由非洲猪瘟病毒（African swine fever virus,ASFV）引起的猪的一种烈性传染病，曾在非洲和欧洲国家广泛流行，并造成巨大的经济损失。虽然本病目前仅在部分非洲国家呈地方性流行，但由于对养猪业的危害巨大，且无有效的疫苗用于防疫，仍被国际兽疫局列为A类重点防范的传染病。对于ASFV而言，虽是严格的动物病毒，所致疾病的危害也限于非洲部分地区，但由于具有一些独特的特点，尤其是具有复杂的免疫逃逸机制，一直是动物分子病毒学研究的热点，而且取得了突破性研究进展。     

Cellular processes essential for African swine fever virus to infect and replicate in primary macrophages

The macrophage (Mø) is an essential immune cell for innate immunity. Such cells are targeted by African swine fever virus (ASFV). The early phases of infection with ASFV have been previously characterized in non-leukocyte cells such as Vero cells. Here, we report on several additional key parameters that ASFV utilizes during the infection of primary Mø. Related to virus infection, we established that receptor-mediated endocytosis of the virus by Mø is not the exclusive means of entry to infect the host cells. Analysis of the ensuing processes identified divalent cation-dependent activities to be particularly important, relating to the virus requirement for microtubule assembly needed for endocytic and endosomal processing. Actin-dependent endocytosis and endocytic flux involving microtubule activity are also implicated, pointing to entry via phagocytosis. Subsequently, the virus avoids terminal degradation by circumventing mature lysosome activities, including autophagosome–lysosome delivery. Nevertheless, the replicative cycle is apparently dependent on certain lysosomal functions, i.e. activities sensitive to propylamine are essential for the virus, whereas vinblastine- and leupeptin-sensitive functions only partially influence viral replication. The present work has identified cellular processes essential for ASFV to infect and replicate in the macrophage. These findings will improve our understanding of the cellular pathways employed by viruses infecting immune scavenger cells.     

African swine fever and classical swine fever: a review of the pathogenesis

This paper describes major pathogenetic mechanisms of African and Classical Swine Fever virus infections. The interactions between both viruses and the monocyte-macrophage-system result in the release of mediator molecules, which are important for the further progression of the diseases. The causes of the thrombocytopenia and the mechanisms of the haemorrhages, which are characteristic in both infections, are described. Apoptotic cell death is regarded as the predominant cause of lymphopenia in both virus infections.