Monoclonal antibodies specific for African swine fever virus proteins.

We have obtained 60 stable hybridomas which produced immunoglobulins that recognized 12 proteins from African swine fever virus particles and African swine fever virus-infected cells. Most of the monoclonal antibodies were specific for the three major structural proteins p150, p72, and p12. The specificity of some monoclonal antibodies for the structural proteins p150 and p37 and the nonstructural proteins p220 and p60 indicated that proteins p150 and p220 are antigenically related to proteins p37 and p60. The association of some viral antigens to specific subcellular components was determined by immunofluorescence and analysis of the binding of monoclonal antibodies to infected cells. A host protein (p24) seemed to be associated with the virus particles.     

Polypeptides of African swine fever virus

The published data on the characteristics and properties of structural and nonstructural polypeptides of the African porcine virus are reviewed. Localization of the viral proteins in virions and infected cells, kinetics of biosynthesis, glycosylation, phosphorylation and the antigenicity of the proteins are discussed.     

Nanopore sequencing of African swine fever virus

正Dear Editor,African swine fever (ASF) is one of the most pathogenic viral diseases in pigs caused by African swine fever virus(ASFV). The fatality rate is almost 100%, which brings huge economic losses to the hog industry in countries with epi-     

非洲猪瘟病毒的免疫逃逸策略

非洲猪瘟(African swine fever,ASF)是由非洲猪瘟病毒(African swine fever virus,ASFV)引起的一种猪烈性传染病。目前无商品化的ASF疫苗,一旦发病,仅能依靠快速扑杀进行防控,严重威胁我国养猪及相关行业的健康发展。ASF疫苗研发面临的主要困难是对ASFV的毒力相关基因、致病及其免疫逃逸机制知之甚少。本文对ASFV的免疫逃逸研究进行了总结,探讨了ASFV免疫逃逸基因及其编码蛋白的功能,以便加深对ASFV及其免疫逃逸策略的认知,为致病机制研究和疫苗研发提供借鉴。     

Purification and properties of African swine fever virus

We describe a method for African swine fever (ASF) virus purification based on equilibrium centrifugation in Percoll density gradients of extracellular virions produced in infected VERO cells that yielded about 15 +/- 9% recovery of the starting infectious virus particles. The purified virus preparations were essentially free of a host membrane fraction (vesicles) that could not be separated from the virus by previously described purification methods. The purified virus sedimented as a single component in sucrose velocity gradients with a sedimentation coefficient of 3,500 +/- 300S, showed a DNA-protein ratio of 0.18 +/- 0.02 and a specific infectivity of 2.7 X 10(7) PFU/micrograms of protein, and remained fully infectious after storage at -70 degrees C for at least 7 months. The relative molecular weights of the 34 polypeptides detected in purified virus particles ranged from 10,000 to 150,000. Some of these proteins were probably cellular components that might account for the reactivity of purified virus with antiserum against VERO cells.     

African swine fever virus interaction with microtubules

The role of microtubules in intracellular transport of African swine fever virus (ASFV) and virus-induced inclusions was studied by immunofluorescence using anti-ASFV and anti-tubulin antibodies, by electron microscopy of infected Vero cells and by in vitro binding of virions to purified microtubules. MTC, a reversible colchicine analogue, was used to depolymerize microtubules. In cells treated with MTC multiple large inclusions containing ASFV antigens and particles were observed in the cytoplasm. Removal of the drug lead to migration and fusion of the inclusions at a perinuclear location. To study the effect of microtubule repolymerization on virus particle distribution, the particles were counted in thin sections of MTC treated cells and at different times after removal of the drug. In cells treated with MTC 6.8% and 3.6% of the virus particles were found respectively in the cytoplasm and at the cell membrane while 38% of the particles were located around the virosome. With reversal of the drug effect the number of virus particles around the virosomes progressively decreased to 10% at 2 h while the number of particles in the cytoplasm and at the cell membrane increased. At 2 h after removal of the drug 33.5% of the particles were found budding from the cell membrane. Virus particles were found closely associated with microtubules in cytoskeletons obtained by Triton X-100 extraction of taxol treated cells. The association of virus particles with microtubules was also observed in vitro using purified microtubules and virus particles. The results show that microtubules are involved in the transport of African swine fever virus particles from the assembly site to the cell surface and in the movement and fusion of the virus inclusions.     

African swine fever virus attachment protein.

Treatment of African swine fever virus particles with nonionic detergents released proteins p35, p17, p14, and p12 from the virion. Of these proteins, only p12 bound to virus-sensitive Vero cells but not to virus-resistant L or IBRS2 cells. The binding of p12 was abolished by whole African swine fever virus and not by similar concentrations of subviral particles that lacked the external proteins. A monoclonal antibody (24BB7) specific for p12 precipitated a protein that, when analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis in the absence of 2-mercaptoethanol, showed a molecular mass of 17 kDa (p17*) instead of 12 kDa as found in the presence of 2-mercaptoethanol. The relationship between these two proteins was confirmed by the conversion of p17* to p12 when the former was isolated from polyacrylamide gels in the absence of 2-mercaptoethanol and subsequently treated with the reducing agent. The supernatant obtained after immunoprecipitation with the p12-specific antibody lacked the virus-binding protein.     

Cross-links in African swine fever virus DNA.

African swine fever virus DNA sediments in neutral sucrose density gradients as a single component with a sedimentation coefficient of 60S. In alkaline sucrose density gradients, this material shows two components with sedimentation coefficients of 85S and 95S, respectively. The sedimentation rate value of alkali-denatured virus DNA in neutral sucrose density gradients and the renaturation velocity of denatured DNA show that is reassociated much faster than expected from its genetic complexity. This behavior is compatible with the existence of interstrand cross-links in the molecule. We also present results which suggest that there are only a few such cross-links per molecule, that they are sensitive to S1 nuclease digestion, and that they are probably located next to the ends of the DNA.     

Porcine leukocyte cellular subsets sensitive to African swine fever virus in vitro.

African swine fever virus infected most, if not all, of the macrophages (monocytes) and ca. 4% of the polymorphonuclear leukocytes from porcine peripheral blood. B and T lymphocytes, either resting or stimulated with phytohemagglutinin, lipopolysaccharide, or pokeweed mitogen, were not susceptible to the virus. All of the mitogens used inhibited African swine fever multiplication in susceptible cells. The number of virus passages in vitro and the virulence degree of the virus did not affect the susceptibility of porcine B or T lymphocytes to African swine fever virus.     

Localization of structural proteins in African swine fever virus particles by immunoelectron microscopy.

Seven African swine fever virus structural proteins were localized in the virion by immunoelectron microscopy. African swine fever virus-infected cells were incubated, before or after embedding and thin sectioning, with monoclonal antibodies specific for different structural proteins, and after labeling with protein A-gold complexes, the samples were examined in the electron microscope. Proteins p14 and p24 were found in the external region of the virion, proteins p12, p72, p17, and p37 were found in the intermediate layers, and protein p150 was found in the nucleoid and in one vertex. A monoclonal antibody that recognized protein p150 as well as p220, a virus-induced, nonstructural protein, could also bind to a component present in the nucleus of both uninfected and virus-infected cells.     

Laboratory-scale inactivation of African swine fever virus and swine vesicular disease virus in pig slurry

Two methods were evaluated for the inactivation of African swine fever (ASV) and swine vesicular disease (SVD) viruses in pig slurry: chemical treatment and heat treatment. The addition of NaOH or Ca(OH)2 at different concentration/time combinations at 4 degrees C and 22 degrees C was examined, as was virus stability at different temperature/time combinations. ASF virus (ASFV) was less resistant to both methods than SVD virus (SVDV). In slurry from one source, ASFV was inactivated at 65 degrees C within 1 min, whereas SVDV required at least 2 min at 65 degrees C. However, it was found that thermal inactivation depended on the characteristics of the slurry used. Addition of 1% (w/v) of NaOH or Ca(OH)2 caused the inactivation of ASFV within 150 s at 4 degrees C; 0.5% (w/v) NaOH or Ca(OH)2 required 30 min for inactivation. NaOH or Ca(OH)2 (1% (w/v)) was not effective against SVDV at 22 degrees C after 30 min, and 1.5% (w/v) NaOH or Ca(OH)2 caused inactivation of SVDV at both 4 degrees C and 22 degrees C. At higher chemical concentrations or temperatures, ASFV and SVDV inactivation was faster in slurry than in buffered medium.     

New insights into the role of endosomal proteins for African swine fever virus infection

African swine fever virus (ASFV) infectious cycle starts with the viral adsorption and entry into the host cell. Then, the virus is internalized via clathrin/dynamin mediated endocytosis and macropinocytosis. Similar to other viruses, ASF virion is then internalized and incorporated into the endocytic pathway. While the endosomal maturation entails luminal acidification, the decrease in pH acts on the multilayer structure of the virion dissolving the outer capsid. Upon decapsidation, the inner viral membrane is exposed to interact with the limiting membrane of the late endosome for fusion. Viral fusion is then necessary for the egress of incoming virions from endosomes into the cytoplasm, however this remains an intriguing and yet essential process for infection, specifically for the egress of viral nucleic acid into the cytoplasm for replication. ASFV proteins E248R and E199L, located at the exposed inner viral membrane, might be implicated in the fusion step. An interaction between these viral proteins and cellular endosomal proteins such as the Niemann-Pick C type 1 (NPC1) and lysosomal membrane proteins (Lamp-1 and -2) was shown. Furthermore, the silencing of these proteins impaired ASFV infection. It was also observed that NPC1 knock-out cells using CRISPR jeopardized ASFV infection and that the progression and endosomal exit of viral cores was arrested within endosomes at viral entry. These results suggest that the interactions of ASFV proteins with some endosomal proteins might be important for the membrane fusion step. In addition to this, reductions on ASFV infectivity and replication in NPC1 KO cells were accompanied by fewer and smaller viral factories. Our findings pave the way to understanding the role of proteins of the endosomal membrane in ASFV infection.     

Neutralizing antibodies to different proteins of African swine fever virus inhibit both virus attachment and internalization.

African swine fever virus induces in convalescent pigs antibodies that neutralized the virus before and after binding to susceptible cells, inhibiting both virus attachment and internalization. A further analysis of the neutralization mechanisms mediated by the different viral proteins showed that antibodies to proteins p72 and p54 are involved in the inhibition of a first step of the replication cycle related to virus attachment, while antibodies to protein p30 are implicated in the inhibition of virus internalization.     

非洲猪瘟病毒编码蛋白功能研究进展

非洲猪瘟(African swine fever,ASF)是非洲猪瘟病毒(African swine fever virus,ASFV)感染家猪或野猪引起的一种急性、出血性、高度接触性传染病,其特征是病程短、高热和出血性病变,急性感染死亡率高达100%,严重威胁全球养猪业但目前尚未开发出有效的疫苗和治疗方法。ASFV是非洲猪瘟病毒科非洲猪瘟病毒属的唯一成员,为大型双链DNA病毒,主要在巨噬细胞胞质中复制,其基因组约170?193 kb,含有150?167个开放阅读框,编码150?200种蛋白质。目前已知功能的病毒编码蛋白约有50个,大部分为病毒的结构蛋白,仍有一半以上的ASFV编码蛋白功能尚不清楚。除结构蛋白以外,病毒含有完整的酶和与病毒转录有关的因子,编码调节宿主细胞功能及与病毒免疫逃逸相关的蛋白等。本文综述了ASFV的结构蛋白、非结构蛋白以及参与免疫逃逸等相关蛋白功能的研究进展,以期为ASFV病毒蛋白研究及疫苗研发提供相关借鉴。     

非洲猪瘟病毒的生物学特性与疫苗研制的难点

非洲猪瘟(African swine fever,ASF)是由非洲猪瘟病毒(African swine fever virus,ASFV)引起的一种猪烈性传染病,是全球养猪业的"头号杀手",强毒株引发的超急性和急性感染死率高达100%。2018年8月ASF首次传入我国,截止2019年6月6日,已有32个省份累计暴发137起疫情,给我国社会、经济构成巨大威胁。ASF疫苗的研制始于20世纪60年代,但均以失败而告终,其主要原因是对ASFV生物学特性缺乏深入的研究。有效控制当前ASF疫情扩散、研制安全有效的疫苗将是我国面临的巨大挑战。本文对ASFV形态与基本结构、传播途径、致病机制、基因组及编码蛋白、入侵机制、免疫逃逸等生物学特性进行了概述,并分析了当前疫苗研制面临的难点,以期为我国有效控制ASF疫情及病原研究提供参考。     

Biosynthesis of classical swine fever virus nonstructural proteins

Proteolytic processing of polyproteins is considered a crucial step in the life cycle of most positive-strand RNA viruses. An enhancement of NS2-3 processing has been described as a major difference between the noncytopathogenic (non-CP) and the cytopathogenic (CP) biotypes of pestiviruses. The effects of accelerated versus delayed NS2-3 processing on the maturation of the other nonstructural proteins (NSP) have never been compared. In this study, we analyzed the proteolytic processing of NSP in Classical swine fever virus (CSFV). Key to the investigation was a panel of newly developed monoclonal antibodies (MAbs) that facilitated monitoring of all nonstructural proteins involved in virus replication (NS2, NS3, NS4A, NS5A, and NS5B). Applying these MAbs in Western blotting and radioimmunoprecipitation allowed an unambiguous identification of the mature proteins and precursors in non-CP CSFV-infected cells. Furthermore, the kinetics of processing were determined by pulse-chase analyses for non-CP CSFV, CP CSFV, and a CP CSFV replicon. A slow but constant processing of NS4A/B-5A/B occurred in non-CP CSFV-infected cells, leading to balanced low-level concentrations of mature NSP. In contrast, the turnover of the polyprotein precursors was three times faster in CP CSFV-infected cells and in cells transfected with a CP CSFV replicon, causing a substantial increase of mature NSP concentrations. We conclude that a delayed processing not only of NS3 but further of all NSP represents a hallmark of regulation in non-CP pestiviruses.     

非洲猪瘟病毒内囊膜蛋白p17与宿主互作蛋白的初步鉴定

非洲猪瘟病毒(African swine fever virus,ASFV)的感染导致猪的死亡率高达100%,给养猪业造成毁灭性灾难。因此,开展针对ASFV感染复制的研究有着重大的意义。目前发现ASFV有超过150个开放阅读框,其中D117L基因编码的内囊膜蛋白p17参与病毒二十面体结构的形成,但是对p17调控宿主细胞功能的机制知之甚少。研究通过免疫沉淀技术联合蛋白质谱分析,初步筛选出与ASFV p17潜在的宿主互作蛋白。通过进一步免疫共沉淀技术和激光共聚焦实验确认了p17与线粒体外膜蛋白TOMM70(translocase of outer mitochondrial membrane 70)、热休克蛋白HSPA8(heat shock 70 kDa protein 8)的互作。该研究为进一步探索p17在ASFV感染过程中的功能提供了重要信息。