新城疫病毒HN蛋白促细胞融合机制研究进展

新城疫病毒(Newcastle disease virus,NDV)可导致急性和高度致死性禽类传染病,严重危害世界养禽业。膜融合是NDV发挥毒力的第一步,血凝素-神经氨酸酶(Hemagglutinin-neuraminidase,HN)发挥促细胞融合作用,协助融合蛋白(Fusion protein,F)介导完成膜融合这一过程。本文从HN蛋白的结构和功能入手,对HN蛋白头部、头-颈连接区及颈部在促细胞融合机制中的作用进行综述与讨论,以期为深入研究NDV的致病机制,进一步研发新型药物和疫苗提供新的思路。     

非编码序列对仙台病毒HN基因表达的调控作用

仙台病毒的血凝素神经氨酸酶 (HN)蛋白在COS 7细胞中得到了表达 .结果表明 ,SRα启动子驱动HN基因表达的活性高于鸡 β肌动蛋白启动子 .而且 ,HN基因的 5′非编码序列能促进其表达 .Northern杂交证明 ,高表达是由HN mRNA转录引起 .为研究HN基因 5′编码序列对其转录的调控作用 ,用位点专一性突变分别以角蛋白基因和细胞色素P45 0基因的 5′非编码序列替代HN基因的 5′非编码序列 ,并分别缺失HN基因 3′非编码序列 ,构建了一系列表达载体 .以氯霉素乙酰转移酶(CAT)基因为报道基因 ,用S1酶对HN mRNA转录量进行定量分析 .实验证明 ,HN基因 5′非编码序列能非特异性提高HN mRNA的转录 ,3′非编码序列对其转录也有某种特殊的调控作用 .     

人副流感病毒3型HN糖蛋白N-糖链的功能研究

为了研究人副流感病毒3型(hPIV3)HN糖蛋白N-糖链的功能,采用基因定点突变技术构建糖基化位点突变体,然后检测各突变株的蛋白电泳速率、细胞表面表达量、受体结合活性、神经氨酸酶活性和促细胞融合活性。HN分子的G1、G2、G3和G4 4个糖基化位点分别和联合突变后发现G1、G2和G4及其联合突变株(G12、G14、G24和G124)电泳速率加快,而G3突变株电泳速率没有变化。各突变株的表达效率,神经氨酸酶活性与野毒株相比差别无统计学意义(P>0.05),但受体结合活性和促细胞融合活性均有不同程度的降低(P<0.05)。G1、G2和G4位点突变后受体结合活性分别为突变前的83.94%、76.45%和55.32%,而促细胞融合活性降为突变前的80.84%、77.83%和64.16%。联合突变株G12、G14、G24和G124血吸附活性进一步降低,为突变前的33.07%、20.67%、19.96%和15.11%,促细胞融合活性进一步降低为突变前的46.36%、12.04%、13.43%和4.05%。结果表明:hPIV3HN糖蛋白的糖链对HN糖蛋白的受体结合活性和促细胞融合活性有重要影响,推断糖链的丢失可能会引起HN糖蛋白头部结构(受体结合活性位点所在区域)或者方向的改变或者无法与宿主细胞膜表面的凝集素受体(一种与N-糖链结合的受体)结合,进而导致受体结合活性和促细胞融合活性的降低。     

新城疫病毒7793 HN蛋白在昆虫SF9细胞中的表达研究

本实验对新城疫病毒(newcastle disease virus,NDV) 7793 HN蛋白在杆状病毒表达系统中表达进行研究。提取病毒RNA并将其逆转录成cDNA,经PCR同义点突变在HN基因片段中加入NcoⅠ/XhoⅠ酶切位点,通过该酶切位点将HN基因克隆至穿梭载体p FastBac1质粒以构建重组质粒pFastBac1HTB-HN,然后用脂质体转染pFastBac1HTB-HN杆粒至昆虫SF9细胞。28℃无菌培养含pFastBac1HTB-HN杆粒的SF9细胞48 h,收集细胞培养上清液中的第一代病毒,感染SF9细胞,置28℃无菌培养60 h,收集细胞培养上清液,离心去除细胞碎片,取上清液中的第二代病毒,继续感染SF9细胞,置28℃无菌培养72 h,收集SF9细胞,用SDSPAGE和Western blotting验证HN蛋白的表达。SDS-PAGE和Western blotting均显示HN杆粒感染的SF9细胞成功表达了HN蛋白。本研究结果为进一步研究NDV7793-HN蛋白的抗肿瘤作用提供可靠试验依据。     

表达新城疫病毒HN基因的重组火鸡疱疹病毒的构建

应用聚合酶链反应技术,用设计带有限制性酶切位点的引物,特异地扩增从起始密码子开始的１ ．８ ｋｂ 新城疫病毒（ Ｎ Ｄ Ｖ） 血凝素神经氨酸酶（ Ｈ Ｎ） 基因开放式阅读框,然后插入ｐ Ｔ Ｋ２ Ｂ 的 Ｎｈｅ Ⅰ位点,构建了含 Ｎ Ｄ Ｖ Ｈ Ｎ 基因的插入载体ｐ Ｔ Ｋ Ｈ Ｎ１ 和ｐ Ｔ Ｋ Ｈ Ｎ２ ,再与感染火鸡疱疹病毒（ Ｈ Ｖ Ｔ） 细胞的总 Ｄ Ｎ Ａ 共转染鸡胚成纤维细胞（ Ｃ Ｅ Ｆ） ,经有限稀释法和 Ｄｏｔｂｌｏｔ 筛选,得到含有 Ｈ Ｎ 基因的重组体ｒ Ｈ Ｖ Ｔ１ 和ｒ Ｈ Ｖ Ｔ２ 。经组织培养传代和 Ｗｅｓｔｅｒｎ ｂｌｏｔ 分析,表明重组体在感染细胞中表达了 Ｈ Ｎ 蛋白。重组体在 Ｃ Ｅ Ｆ 上的生长特性与亲本病毒相同,且在连续传代过程中保持稳定。为国内新城疫基因工程疫苗研制奠定了基础。     

副粘病毒HN蛋白颈部与F相互作用区功能的研究

副粘病毒(Paramyxovirus)包膜上镶嵌着两种糖蛋白血凝素-神经氨酸酶(Hemagglutinin-neuraminidase,HN)和融合蛋白(Fusion protein,F),两者的相互作用是决定病毒宿主范围、毒力和传播的关键。为探讨HN颈部与F相互作用区(Fusion interaction region,FIR)在膜融合机制中的作用,选取新城疫病毒(Newcastle disease virus,NDV)与人副流感病毒3型(human parainfluenza virus type 3,hPIV3)为研究对象,通过片段置换及同源重组技术构建嵌合体C1、C2,进一步将NDV及hPIV3 HN的FIR内第51位丝氨酸(Serine,S)、第55位天冬氨酸(Aspartic acid,D)定点突变为丙氨酸(Alanine,A),获得突变体NDVS51A、NDVD55A、hPIV3 S51A、hPIV3 D55A,对嵌合体及突变体蛋白的细胞表面表达效率、受体识别活性、神经氨酸酶活性、促细胞融合活性及半融合活性进行检测。结果:各嵌合体C1、C2及突变体NDV S51A、NDV D55A、hPIV3 S51A、hPIV3 D55A的细胞表达效率、神经氨酸酶活性(Neuraminidase,NA)与野生型相比差异不显著(P0.05),但促细胞融合活性均有不同程度的降低(P0.05),C1、C2、NDV S51A、NDV D55A、hPIV3 S51A、hPIV3 D55A分别为野生型的7%、9%、27%、19%、17%和21%;C1、C2、NDV S51A、NDV D55A、hPIV3 S51A、hPIV3 D55A的受体识别活性分别为14.7%、22.3%、35.5%、28.8%、33.9%和40.2%,与野生型相比差异显著(P0.05)。结果表明:副粘病毒HN蛋白颈部与F相互作用区的突变及置换使HN蛋白的促细胞融合活性、受体识别活性降低,其中第51位丝氨酸(S51)及第55位天冬氨酸(D55)发挥重要作用。     

不同基因型新城疫病毒HN基因保守区域的克隆表达及免疫活性的比较

对于NDV不同基因型毒株的HN基因的氨基酸序列比较后发现,基因Ⅶ型的毒株在第65~75位的氨基酸序列较为保守,而其他各基因型在该区域则不尽相同。因此本文克隆了NDV基因Ⅱ、Ⅶ、Ⅸ型的代表毒株La Sota、GX-2、F48E9的含有该区域的序列,并进行蛋白表达,通过特异性抗血清对表达肽段进行抗原性测定。应用表达的蛋白免疫SPF鸡,用ELISA检测各组的抗体水平。结果表明3个毒株在反应原性上存在差异。应用NDV F48E9强毒株攻毒,结果显示各多肽蛋白的保护率不同,表明在该区域这3个毒株之间存在着免疫原性差异。     

呼吸道合胞病毒包膜糖蛋白的抗体反应及临床意义

随着病毒免疫学研究的不断深入,呼吸道合胞病毒（ＲＳＶ）包膜糖蛋白的抗体反应在ＲＳＶ发病中的作用越来越引人们的重视。动物实验已证明体液免疫具有一定的保护作用,但在人类材料较少。本文综述了Ａ、Ｂ两亚型ＲＳＶ外膜Ｇ、Ｆ糖蛋白的特异抗原组分,抗体反应的相互联系和在抗ＲＳＶ感染的作用。     

单纯疱疹病毒包膜糖蛋白的结构与功能研究进展

单纯疱疹病毒共有11种包膜糖蛋白,它们以不同形式在病毒进入宿主后发挥不同功能,本文对已发现的11种包膜糖蛋白结构与功能的研究进展进行了概述。     

新城疫病毒F蛋白细胞融合活性位点中保守氨基酸基因突变分析

为了确定新城疫病毒融合蛋白(F)分子上活性位点中保守氨基酸在F蛋白的细胞融合作用,弄清F细胞融合的分子机理,采用基因定点突变法,创造一个酶切位点,用酶切反应初步筛选突变株,然后用DNA序列分析进一步确定,并于真核细胞内进行表达,Giemsa染色定性和指示基因法定量检测细胞融合功能,荧光强度分析(FACS)检测表达效率情况。结果表明,NDV F第117位苯丙氨酸(F)突变成亮氨酸(L)时对细胞融合作用没有显著影响。R112和K115同为保守序列,分别突变为G时,细胞融合活性只有原来的44%,下降了56%。细胞表面表达效率没有明显的改变。N147突变为K时,细胞融合活性明显下降,只有原来的15%,而细胞表面表达效率没有明显的改变。L154为保守序列,突变为K时,细胞融合活性消失,说明L154是一个非常关键的氨基酸,对维持F蛋白的细胞融合活性非常重要。细胞表面表达效率也有所下降(为原来的94%)。D462属于高度保守氨基酸,当突变为N时,细胞融合活性消失,但经细胞表面表达效率分析证明,此突变蛋白未表达于细胞表面,证明在细胞浆转运至细胞表面的过程中发生了问题。当突变为R和E时,细胞融合活性未发生改变,但细胞表面表达效率有所下降,分别为野毒株的63%和44%。说明NDV F分子上与HN相互作用的特异性区域中的某些保守氨基酸在细胞融合中发挥着重要作用,对F蛋白的折叠、加工、转运等,发挥着不同作用,从而影响F蛋白的细胞融合作用和/或在细胞表面的表达量。     

Activation of Natural Killer Cells by Newcastle Disease Virus Hemagglutinin-Neuraminidase

The avian paramyxovirus Newcastle disease virus (NDV) selectively replicates in tumor cells and is known to stimulate T-cell-, macrophage-, and NK cell-mediated responses. The mechanisms of NK cell activation by NDV are poorly understood so far. We studied the expression of ligand structures for activating NK cell receptors on NDV-infected tumor cells. Upon infection with the nonlytic NDV strain Ulster and the lytic strain MTH-68/H, human carcinoma and melanoma cells showed enhanced expression of ligands for the natural cytotoxicity receptors NKp44 and NKp46, but not NKp30. Ligands for the activating receptor NKG2D were partially downregulated. Soluble NKp44-Fc and NKp46-Fc, but not NKp30-Fc, chimeric proteins bound specifically to NDV-infected tumor cells and to NDV particle-coated plates. Hemagglutinin-neuraminidase (HN) of the virus serves as a ligand structure for NKp44 and NKp46, as indicated by the blockade of binding to NDV-infected cells and viral particles in the presence of anti-HN antibodies and by binding to cells transfected with HN cDNA. Consistent with the recognition of sialic acid moieties by the viral lectin HN, the binding of NKp44-Fc and NKp46-Fc was lost after desialylation. NKp44- and NKp46-CD3ζ lacZ-inducible reporter cells were activated by NDV-infected cells. NDV-infected tumor cells stimulated NK cells to produce increased amounts of the effector lymphokines gamma interferon and tumor necrosis factor alpha. Primary NK cells and the NK line NK-92 lysed NDV-infected tumor cells with enhanced efficiency, an effect that was eliminated by the treatment of target cells with the neuraminidase inhibitor Neu5Ac2en. These results suggest that direct activation of NK cells contributes to the antitumor effects of NDV.Virulent strains of Newcastle disease virus (NDV) infect domestic poultry and other birds, causing a rapidly spreading viral disease that affects the alimentary and respiratory tracts as well as the central nervous system (55). In humans, however, NDV is well tolerated (17, 18). Other than mild fever for a day, only a few adverse effects have been reported. NDV, also known as avian paramyxovirus 1, is an enveloped virus containing a negative-sense, single-stranded RNA genome which codes for six proteins in the order (from 3′ to 5′) of nucleoprotein, phosphoprotein, matrix protein, fusion (F) protein, hemagglutinin-neuraminidase (HN), and large polymerase protein (19). There are many different strains of NDV, classified as either lytic or nonlytic for different types of cells. Lytic and nonlytic NDV strains both replicate much more efficiently in human cancer cells than they do in most normal human cells (43). Viruses of both strain types have been investigated as potential anticancer agents (30, 49, 52). The NDV strains that have been evaluated most widely for the treatment of cancer are 73-T, MTH-68, and Ulster (1, 7, 11, 17, 18, 53, 54, 56, 71).Initial binding of NDV to a host cell takes place through the interaction of HN molecules in the virus coat with sialic acid-containing molecules on the cell surface (31). NDV neuraminidase has strict specificity for the hydrolysis of the NeuAc-α2,3-Gal linkage, with no hydrolysis of the NeuAc-α2,6-Gal linkage (41).NDV infection of tumor cells not only improves T-cell responses (53, 58, 68), but has also been reported to vigorously stimulate innate immune responses. In the course of NDV infection, large amounts of alpha interferon (IFN-α) are released (68) and in turn activate dendritic cells and NK cells and polarize, in concert with interleukin-12 (IL-12), toward a Th1 T-cell response (33, 44, 47). In addition, NDV induces antitumor cytotoxicity in murine macrophages which produce increased amounts of tumor necrosis factor alpha (TNF-α) and nitric oxide (51, 60) and in human monocytes through the induction of TRAIL (64). Little is known about the NDV-mediated activation of NK cells. The coincubation of peripheral blood mononuclear cells with NDV was shown previously to stimulate NK-mediated cytotoxicity (70). Enhanced cytotoxicity correlates with the induction of IFN-α (70). It is not known, however, whether NDV-infected cells can directly activate NK cells and, if so, which molecular interactions are involved.The cytolytic activity of NK cells against virus-infected or tumor cells is regulated by the engagement of activating or inhibitory NK cell surface receptors, the actions of cytokines, and cross talk with other immune cells (32, 39). Most inhibitory receptors recognize particular major histocompatibility complex (MHC) class I alleles and thereby ensure the tolerance of NK cells against self antigens (38). Activating receptors on human NK cells include CD16; NKG2D; the natural cytotoxicity receptors (NCR) NKp30, NKp44, and NKp46; as well as NKp80; DNAM-1; and various stimulatory coreceptors (32).NCR are important activating receptors for the antitumor and antiviral activities of NK cells (5, 32, 37). Heparan sulfate has been discussed previously as a cellular ligand for NKp46, NKp44, and NKp30 (9, 26, 27), and nuclear factor BAT3, which can be released from tumor cells under stress conditions, has been described as a cellular ligand for NKp30 (42). Ligands for NKp30 and NKp44 can be detected on the surfaces and in the intracellular compartments of several kinds of tumor cells (10). Moreover, a number of pathogen-derived NCR ligands have been reported. The hemagglutinin protein of influenza virus and the HN of Sendai virus can bind to NKp46 and NKp44 and activate NK cells (3, 24, 34). The pp65 protein of human cytomegalovirus has been shown to bind NKp30 and inhibit its function (4). Human immunodeficiency virus, vaccinia virus, and herpes simplex virus have also been shown to upregulate the expression of cellular NCR ligands in infected cells (13, 14, 62). The Plasmodium falciparum erythrocyte membrane protein 1 is involved in the NCR-mediated NK cell attack against infected erythrocytes (36). Furthermore, NKp46 recognizes cells infected with mycobacteria (22, 61), and NKp44 was recently reported to directly bind to the surfaces of mycobacteria and other bacteria (21).In this study, we investigated the expression of ligand structures for NCR and NKG2D on NDV-infected cells. We demonstrate that NDV HN proteins which are strongly expressed on NDV-infected tumor cells function as activating ligand structures for NKp44 and NKp46 but that cellular ligands for NKG2D are partially downregulated during NDV infection.     

尼帕病毒F糖蛋白在重组牛痘病毒中的表达及鉴定

尼帕病毒(NiV)F蛋白在病毒侵入细胞和诱导中和抗体等方面具有重要作用。通过over-lapping PCR合成密码子优化的F蛋白基因构建了表达NiV F蛋白的重组牛痘病毒(WR株)rWR-NiV-F。利用兔抗NiV血清为检测抗体,通过间接免疫荧光(IFA)检测到了F蛋白在重组病毒感染细胞中的表达。SDS-PAGE和Western blot检测证明重组蛋白F0被裂解为F1和F2。以rWR-NiV-F感染瞬时转染共表达NiV受体结合囊膜糖蛋白G的BHK细胞,可诱导细胞膜融合及合包体形成,证明该重组病毒表达F蛋白保持良好的抗原性及生物学活性,为NiV诊断及重组活载体疫苗研究奠定了重要基础。     

猪瘟病毒石门强毒株和兔化弱毒疫苗株E2蛋白糖基化位点差异分析

猪瘟病毒强毒株和兔化弱毒疫苗株E2糖蛋白分别含有5个和6个潜在的糖基化位点,其中986N是兔化弱毒疫苗株所特有的。为了分析二者糖基化位点差异及其影响,将去掉信号肽和跨膜区的猪瘟病毒石门强毒株(Shi-men)和兔化弱毒疫苗株(HCLV)E2基因置于蜂素信号肽序列下游,使其在Sf9细胞内表达重组Shimen-E2和HCLV-E2蛋白。结果显示,重组E2蛋白以二聚体的形式分泌表达于细胞培养液中,但二者分子量存在差异。用endo H和PNGase F对纯化后的重组E2蛋白进行去糖基化处理后,二者分子量大小变成一致,证实石门强毒株和兔化弱毒株E2蛋白分子量大小的差异可能是由于糖基化程度的差异所致。对986N糖基化位点进行定点突变后发现,突变后的Shimen-E2与野生型HCLV-E2分子量大小一致,而突变后的HCLV-E2与野生型Shimen-E2分子量大小一致,表明Shimen-E2和HCLV-E2分子量大小的差异的确是由于986N糖基化位点的差异引起的。     

减毒沙门氏菌为载体在Vero细胞中表达新城疫病毒融合蛋白

RT PCR扩增了新城疫病毒 (NDV)F4 8E9株的融合蛋白 (F)基因并插入到 pcDNA3的CMV启动子下游 ,构建成真核表达质粒pcDNA3 F ,高压电转化dam和 phoP基因双突变株减毒鼠伤寒沙门氏菌 (ZJ111株 ) ,并直接感染Vero细胞 ,分别提取细胞总DNA和总RNA ,DIG标记探针均可检测到阳性杂交信号。FITC标记的羊抗鸡IgG进行间接免疫荧光试验 ,可检测到特异性的黄绿色荧光。ELISA检测F蛋白结果表明 ,转染后 4 8h开始表达 ,随后逐渐增多。SDS PAGE和Western印迹可检测到 5 5kD的蛋白质条带。上述试验结果证实减毒沙门氏菌不仅可将目的基因呈递给Vero细胞 ,而且还得到了转录和表达 ,表达的F蛋白具有免疫反应性 ,为研制减毒沙门氏菌为载体的口服NDVDNA疫苗创造了条件。     

Structure of the Ulster Strain Newcastle Disease Virus Hemagglutinin-Neuraminidase Reveals Auto-Inhibitory Interactions Associated with Low Virulence

Paramyxovirus hemagglutinin-neuraminidase (HN) plays roles in viral entry and maturation, including binding to sialic acid receptors, activation of the F protein to drive membrane fusion, and enabling virion release during virus budding. HN can thereby directly influence virulence and in a subset of avirulent Newcastle disease virus (NDV) strains, such as NDV Ulster, HN must be proteolytically activated to remove a C-terminal extension not found in other NDV HN proteins. Ulster HN is 616 amino acids long and the 45 amino acid C-terminal extension present in its precursor (HN₀) form has to be cleaved to render HN biologically active. Here we show that Ulster HN contains an inter-subunit disulfide bond within the C-terminal extension at residue 596, which regulates HN activities and neuraminidase (NA) domain dimerization. We determined the crystal structure of the dimerized NA domain containing the C-terminal extension, which extends along the outside of the sialidase β-propeller domain and inserts C-terminal residues into the NA domain active site. The C-terminal extension also engages a secondary sialic acid binding site present in NDV HN proteins, which is located at the NA domain dimer interface, that most likely blocks its attachment function. These results clarify how the Ulster HN C-terminal residues lead to an auto-inhibited state of HN, the requirement for proteolytic activation of HN₀ and associated reduced virulence.     

传染性喉气管炎病毒gB基因和新城疫病毒F基因在重组禽痘病毒中共表达

在重组禽痘病毒中表达多个禽类病原的主要免疫原基因是构建多价基因工程疫苗的前提,但相关研究很少。在表达传染性喉气管炎病毒(ILTV)gB基因重组禽痘病毒的转移载体的基础上,构建了含有ILTV gB基因和新城疫病毒(NDV)F基因的重组禽痘病毒转移载体pSY-gB-F,采用脂质体转染禽痘病毒感染的鸡胚成纤维(CEF)细胞后,通过蓝斑试验筛选出重组禽痘病毒(rFPv-gB-F),并进行了6轮蚀斑纯化。Western-blot试验和间接免疫荧光试验证明ILTV gB基因和NBVF基因在rFPV-gB-F感染的CEF细胞中获得表达。为传染性喉气管炎、新城疫与鸡痘活载体多价疫苗的研制奠定基础。     

我国部分地区不同动物来源新城疫病毒的分子流行病学研究

对从我国部分地区1985～2001年间分离的26株新城疫病毒毒株进行研究,克隆其融合蛋白(F)基因,分析相应的核苷酸(nt)序列.根据绘制的系统进化发生树和F基因上三种限制性内切酶(RE)位点分布,确定了这些毒株的基因型分类地位.除2个毒株属于已知的VIb亚型外,其余24个毒株分别属于新发现的基因Ⅸ型、Ⅵf亚型、Ⅵg亚型和VⅡc亚型.基因Ⅸ型毒株的F基因540nt存在RsaⅠ位点,同时缺乏1198nt HinfⅠ位点、1478nt BstOⅠ位点和1625nt RsaⅠ位点;Ⅵf和Ⅵg亚型毒株不具有国外其它Ⅵ型毒株的872nt RsaⅠ位点;Ⅶc亚型的RE位点分布和Ⅶa亚型、Ⅶb亚型、Ⅷ型毒株不同,鹅源毒株均出现973nt RsaⅠ位点,7个鹅源毒株还出现了特有的1249nt RsaⅠ位点.在F基因编码的氨基酸中,基因Ⅸ型毒株出现Ile9→Val9和Val106→Ala106的替换,Ⅵf和Ⅵg亚型却没有出现其它Ⅵ亚型的Ser5→Pro5变异.     

几株益生菌的体外抗新城疫病毒作用

【目的】探讨益生菌的抗新城疫病毒(NDV)作用并分析其可能的机制。【方法】采用NDV血凝试验和MTT比色法,分别在体外和鸡胚成纤维细胞(CEF)上评价益生菌对NDV血凝价和抑制率的影响。【结果】所选择的5株益生菌及其代谢产物都极显著地降低了NDV的血凝价,而2株致病菌及其代谢产物对NDV的血凝价均没有影响,这一结果说明益生菌可能对NDV具有直接破坏的作用,并且具有菌株特异性。益生菌可以显著地提高CEF对NDV的抑制率,并且这种作用具有量效关系(P0.01)。益生菌与细胞作用后再感染病毒,对NDV抑制率升高的结果反映了益生菌对NDV吸附细胞的阻断作用;从益生菌与病毒同时接入细胞后降低病毒对细胞侵害的现象,可以看出益生菌可能对病毒具有直接破坏作用;在细胞感染病毒后再接入益生菌对NDV抑制率极低的现象说明,病毒感染后益生菌再很难起作用。【结论】益生菌对NDV既具有直接破坏的作用,又可以阻断NDV对细胞的感染、抑制其在细胞内的增殖。