Newcastle Disease Virus Infection of L Cells

Newcastle disease virus (NDV) California strain reportedly grows poorly in L cells but replicates very well in chicken embryo cells. NDV-infected L cell cultures show a characteristic virus growth curve with respect to uridine incorporation, but plaque assays of the virus produced 24 h postinfection (PI) show no infectious particles when assayed on L cell monolayers and only a very low titer on chick cell monolayers. Plasma membranes isolated and purified from infected L cells 8 h PI contain all of the major virion proteins. In addition, NDV-infected L cells show a 50% loss of H-2 antigenic activity, a phenomenon previously observed in cells productively infected with vesicular stomatitis virus. These results suggest that at least part of the normal process of NDV maturation occurs in NDV-infected L cells. Sodium dodecyl sulfate-polyacrylamide gel patterns of supernatant virus purified from cells radiolabeled with amino acids from 3 to 24 h PI in the presence of actinomycin D show that all the major NDV structural proteins are present. Electron micrographs of NDV-infected L cells show extensive virus maturation at cell membranes. It can be concluded that infection of L cells with NDV results in a normal production of virus-specific RNA, synthesis of all the major structural proteins, association of the viral envelope proteins with the L cell plasma membrane, and the loss of cell surface H-2 antigenic activity. However, most of the virus particles produced are noninfectious.     

Selective Inhibition of Newcastle Disease Virus-Induced Glycoprotein Synthesis by d-Glucosamine Hydrochloride

d-Glucosamine selectively affected the synthesis of virus-induced glycoproteins in Newcastle disease virus-infected chick fibroblasts, but had no effect upon post-translational cleavage of the glycoprotein precursor for one of the two major glycoproteins of the mature virion. In response to glucosamine, at least one of the two virus-induced glycoproteins is formed in reduced quantity and the second is either not formed or has an electrophoretic mobility identical to that of another virus-induced protein.     

Temperature-Sensitive Mutants Isolated from L Cells Persistently Infected with Newcastle Disease Virus

Virus mutants (NDV(pi)) isolated from L cells persistently infected with the Herts strain of Newcastle disease virus have been previously reported by this laboratory to differ from the wild-type virus (NDV(o)) in several physical and biological properties. It has now been determined that, in addition to these differences, the NDV(pi) mutants are also spontaneously selected temperature-sensitive mutants. The temperature sensitivity of 10 NDV(pi) clones was confirmed by temperature inhibition, plaquing efficiency, and single-cycle yield experiments. The cut-off temperature, at which more than 90% of virus replication is inhibited was between 41 and 42 C. All 10 NDV(pi) clones were also found to be defective in virus-specific ribonucleic acid (RNA) synthesis in infected chick embryo cells at 42 C and are tentatively classified as RNA(-). The possible relationships of the temperature sensitivity, the other NDV(pi) properties, and the maintenance of the persistently infected state are discussed.     

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.     

Cell Fusion by Newcastle Disease Virus in the Absence of RNA Synthesis

OUR studies on the cytopathic effects of Newcastle disease virus (NDV) grown in chick embryo fibroblast cell cultures have shown that the principal cytopathic effect involves the formation of polykaryocytes by cell fusion (our unpublished work). This ability is related directly to the virulence of the infecting strain; those pathogenic for chick embryos readily induce cell fusion whereas avirulent strains induce little or no fusion¹. We now report that, although protein synthesis is required for NDV-induced cell fusion, RNA synthesis is not. Furthermore, blocking of RNA synthesis significantly increases cell fusion by avirulent strains.     

Cell Fusion by Various Strains of Newcastle Disease Virus and Their Virulence

Some properties of eight strains of Newcastle disease virus (cell-fusing ability, hemolysin, heat stability of hemagglutinin or of hemolysin) do not correlate with virulence of these strains.     

Temperature-Sensitive Defect of Mutants Isolated from L Cells Persistently Infected with Newcastle Disease Virus

The temperature-sensitive defects of virus mutants isolated from L cells persistently infected with Newcastle disease virus (NDV) were analyzed. Genetic grouping of the mutants by complementation tests was attempted by using several different methods, including yield analysis, RNA synthesis, and heterozygote formation at 42 to 43 C, the nonpermissive temperature. In each case, specific interference prevented detection of complementation. This interference was shown to occur prior to or at the level of virus RNA synthesis. Temperature-shift experiments with five different NDV(pi) clones showed that virus replication begun at 37 C could not be completed at the nonpermissive temperature. The activity of the NDV-specific RNA-dependent RNA polymerase in the cytoplasm of infected chicken embryo cells was not stable and could not be demonstrated directly. However, indirect measurement of RNA polymerase activity at the nonpermissive temperature was accomplished by studying the kinetics of virus-specific RNA synthesis in infected cells after temperature shift. Two types of response were obtained: with three NDV(pi) clones, virus-specific RNA synthesis ceased immediately upon transfer of infected cells to 42 to 43 C, whereas in cells infected with two other NDV(pi) clones, RNA synthesis continued for several hours at this temperature. These results suggested that there may be two types of ts defects in NDV(pi), both associated with virus-specific RNA polymerase activity.     

Comparison of RNA Polymerase Associated With Newcastle Disease Virus and a Temperature-Sensitive Mutant of Newcastle Disease Virus Isolated from Persistently Infected L Cells

An in vitro comparison was made of the RNA polymerase activity associated with Newcastle disease virus (NDVo) and three clones of the temperature-sensitive mutant (NDVpi) isolated from persistently infected L cells. Less polymerase activity was associated with the NDVpi clones. Also, compared to NDVo, an increase in incubation temperature from 32 to 37 or 42 C resulted in a marked decrease in polymerase activity for the temperature-sensitive mutants which coincided with their inability to replicate at 42 C.     

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。     

Viral Ribonucleic Acid Synthesis by Newcastle Disease Virus Mutants Isolated from Persistently Infected L Cells: Effect of Interferon

The synthesis of different viral ribonucleic acid (RNA) species was studied in chick embryo (CE) and mouse L-cell cultures infected with the Herts strain of Newcastle disease virus (NDV(o)) and a mutant isolated from persistently infected L cells (NDV(pi)). In CE cell cultures, both viruses synthesized significant amounts of 54, 36, and 18S RNA. However, in L cells, synthesis of 54S virion RNA was markedly reduced. From these results, it seems likely that the low yield of infective virus in L cells is due to a deficient synthesis of 54S RNA in this host. On this basis, however, it is apparent that the "covert" replication of NDV(o) in L cells is due to factors other than viral RNA synthesis. When low concentrations of interferon were used to pretreat CE cells, a differential effect on the synthesis of various RNA species was observed. The 18S RNA of NDV(o) was more sensitive to interferon action than the 36 and the 54S RNA species. In contrast, the 18S RNA of NDV(pi) was less sensitive than the 36S and the 54S RNA. The inhibition of 54S RNA synthesis correlated with the reduction of viral yield and explained the greater sensitivity of NDV(pi) to interferon.     

Different Regions of the Newcastle Disease Virus Fusion Protein Modulate Pathogenicity

Newcastle disease virus (NDV), also designated as Avian paramyxovirus type 1 (APMV-1), is the causative agent of a notifiable disease of poultry but it exhibits different pathogenicity dependent on the virus strain. The molecular basis for this variability is not fully understood. The efficiency of activation of the fusion protein (F) is determined by presence or absence of a polybasic amino acid sequence at an internal proteolytic cleavage site which is a major determinant of NDV virulence. However, other determinants of pathogenicity must exist since APMV-1 of high (velogenic), intermediate (mesogenic) and low (lentogenic) virulence specify a polybasic F cleavage site. We aimed at elucidation of additional virulence determinants by constructing a recombinant virus that consists of a lentogenic NDV Clone 30 backbone and the F protein gene from a mesogenic pigeon paramyxovirus-1 (PPMV-1) isolate with an intracerebral pathogenicity index (ICPI) of 1.1 specifying the polybasic sequence R-R-K-K-R*F motif at the cleavage site. The resulting virus was characterized by an ICPI of 0.6, indicating a lentogenic pathotype. In contrast, alteration of the cleavage site G-R-Q-G-R*L of the lentogenic Clone 30 to R-R-K-K-R*F resulted in a recombinant virus with an ICPI of 1.36 which was higher than that of parental PPMV-1. Substitution of different regions of the F protein of Clone 30 by those of PPMV-1, while maintaining the polybasic amino acid sequence at the F cleavage site, resulted in recombinant viruses with ICPIs ranging from 0.59 to 1.36 suggesting that virulence is modulated by regions of the F protein other than the polybasic cleavage site.     

新城疫病毒F蛋白在昆虫细胞中的表达及其融细胞作用

用RT-PCR方法扩增出新城疫病毒标准强毒株F48E8的F基因,并将其克隆到pGEM-T载体,命名为pGEM-NDF.鉴定正确后,以BamHI和XbaI双酶切将F基因从pGEM-NDF中释放出来,并插入到pFast Bac I载体中,得到重组转移载体pFast-NDF.然后将该重组质粒转入含有穿梭质粒的感受态DH10Bac中,通过转座作用获得重组穿梭质粒reBacmid-NDF.再用reBacmid-NDF转染Sf9昆虫细胞,获得含有新城疫病毒F48E8株F基因的重组杆状病毒.间接免疫荧光和Western-blot分析结果表明F蛋白在昆虫细胞中获得表达,而且主要表达于细胞膜上,并使感染重组杆状病毒的昆虫细胞在96h发生融合作用.动物试验表明,表达的F蛋白能够产生中和抗体.本文的研究结果为F蛋白的进一步开发奠定了基础.     

新城疫病毒F蛋白在昆虫细胞中的表达及其融细胞作用

用RT-PCR方法扩增出新城疫病毒标准强毒株F48E8的F基因,并将其克隆到pGEM-T载体,命名为pGEM-NDF。鉴定正确后,以BamHI和XbaI双酶切将F基因从pGEM-NDF中释放出来,并插入到pFastBacI载体中,得到重组转移载体pFast-NDF。然后将该重组质粒转入含有穿梭质粒的感受态DH10Bac中,通过转座作用获得重组穿梭质粒reBacmid-NDF。再用reBacmid-NDF转染Sf9昆虫细胞,获得含有新城疫病毒F48E8株F基因的重组杆状病毒。间接免疫荧光和Western-blot分析结果表明F蛋白在昆虫细胞中获得表达,而且主要表达于细胞膜上,并使感染重组杆状病毒的昆虫细胞在96h发生融合作用。动物试验表明,表达的F蛋白能够产生中和抗体。本文的研究结果为F蛋白的进一步开发奠定了基础。     

Conditional Dependence of Fusion from Within and Other Cell Membrane Alterations by Newcastle Disease Virus

Fusion from within (FFWI) by Newcastle disease virus occurs optimally in medium maintained at pH 8.2, whereas fusion from without is relatively insensitive to the pH of the medium in the range of 7.0 to 8.3. The pH-sensitive events in FFWI take place in the synthesis of the hypothetical fusion factor rather than in the response to it. pH pulse and pH shift experiments have localized the pH-sensitive events between 4 and 6.5 h postinfection (a period of synthesis of proteins required for FFWI), but before the fusion process. The pH sensitivity is not due to a pH-sensitive interference phenomenon. Virus production and the appearance of hemadsorbing cell surfaces are also pH sensitive, but for these functions the pH optima depend upon the virus strains tested. The independence of FFWI, hemadsorption, and virus production is discussed. Also discussed are the possible roles of virus-specific proteins in the fusion process.     

Protein Synthesis in Newcastle Disease Virus-Infected Chicken Embryo Cells

A double-isotopic label difference analysis of polyacrylamide gels has been used to distinguish between cellular and viral protein accumulation in infected cells and to quantify the kinetics of accumulation of viral polypeptides. This technique, coupled with the determination of total radioactive amino acid incorporation in infected cultures, has revealed the following kinetic patterns. Viral polypeptides are first detected in infected cultures 2.0 to 2.5 h postinfection. The rate of accumulation of radioactive amino acids in viral polypeptides increases to a maximum (30 to 35% of the rate of accumulation in uninfected control cultures), whereas the rate of accumulation of radioactive amino acids in host-cell protein decreases to a minimum (20% of the rate of accumulation in uninfected control cultures) by 5 to 6 h postinfection. All of the viral polypeptides detected late in infection are also present at the earlier times, and the major virion structural polypeptides are present in approximately the same (N/G-2, 53K) or slightly increasing (L, G-1, M) relative amounts. One peak area containing a nonstructural glycopeptide with an apparent molecular weight of 66,000 shows significant alterations in rates of accumulation during infection. Inhibition in the rate of radioactive amino acid incorporation into both trichloroacetic acid-soluble and acid-precipitable material during infection has been demonstrated. However, these two inhibition phenomena can be uncoupled temporally by incubating infected cultures at 36 C instead of the usual 40 C, suggesting that they may not be directly related.     

Titration of Adenovirus by Counting Cells Containing Virus-Induced Inclusion Bodies

A new method for the titration of adenovirus types 2 and 12 based on the enumeration of viral inclusions in infected cells was devised and evaluated. The technique gave virus titers comparable to those obtained by the plaque assay procedure.     

新城疫病毒分离株的生物学特性鉴定及F蛋白基因序列分析

通过部分生物学特性鉴定、RT-PCR及F基因的序列测定与遗传进化分析,对2005~2006年从我国江苏省和广西省部分地区的发病鸡群和鹅群中分离到的20株新城疫病毒(NDV)进行了研究。各分离株经典毒力测定结果显示:MDT在45.3h~58.2h之间,ICPI在1.61~2.00之间,均为新城疫病毒强毒株特征。血凝解脱及血凝素热稳定性试验显示:各分离株的血凝解脱时间短,血凝素热稳定性较差,符合NDV强毒株的特征。F基因的序列测定表明,分离株之间的核苷酸序列具有79.7%~100%的同源性,与疫苗株LaSota的同源性为78.1%~83.4%;与国内标准强毒株F48E8同源性为80.2%~90.1%。推导其氨基酸序列分析表明,各分离株的F蛋白的裂解位点氨基酸组成为112R-R-Q-R/K-R-F117,具有NDV强毒株特征,与毒力测定结果相符。根据序列所绘制系统进化发生树,表明20株NDV分离株中有18株为基因Ⅶd型,2株为基因Ⅲ型。     

转新城疫病毒融合蛋白基因水稻植株的获得

以编码新城疫病毒融合蛋白(NDV—F)基因为外源基因,与玉米泛素蛋白(Ubi)启动子和农杆菌胭脂碱合成酶基因(NOS)终止子构建成嵌合基因,构建了适宜于农杆菌介导转化水稻的表达质粒pUNDV;并以潮霉素磷酸转移酶(HPT)基因作选择标记基因、β-半乳糖苷酸酶(GUS)基因作报告基因,借助于农杆菌介导转化水稻,获得了多株转基因植株。PCR分析和GUS活性检测结果证实含有NDV—F基冈的T—DNA已整合到水稻基因组中,为研制廉价的转基因水稻新城疫基因工程疫苗奠定了基础。     

Effect of Cleavage Mutants on Syncytium Formation Directed by the Wild-Type Fusion Protein of Newcastle Disease Virus

The effects of Newcastle disease virus (NDV) fusion (F) glycoprotein cleavage mutants on the cleavage and syncytium-forming activity of the wild-type F protein were examined. F protein cleavage mutants were made by altering amino acids in the furin recognition region (amino acids 112 to 116) in the F protein of a virulent strain of NDV. Four mutants were made: Q114P replaced the glutamine residue with proline; K115G replaced lysine with glycine; double mutant K115G, R113G replaced both a lysine and an arginine with glycine residues; and a triple mutant, R112G, K115G, F117L, replaced three amino acids to mimic the sequence found in avirulent strains of NDV. All mutants except Q114P were cleavage negative and fusion negative. However, addition of exogenous trypsin cleaved all mutant F proteins and activated fusion. As expected for an oligomeric protein, the fusion-negative mutants had a dominant negative phenotype: cotransfection of wild-type and mutant F protein cDNAs resulted in an inhibition of syncytium formation. The presence of the mutant F protein did not inhibit cleavage of the wild-type protein. Furthermore, evidence is presented that suggests that the mutant protein and the wild-type protein formed heterooligomers. By measuring the syncytium-forming activity of the wild-type protein at various ratios of expression of mutant and wild-type protein, results were obtained that are most consistent with the notion that the size of the functionally active NDV F protein in these assays is a single oligomer, likely a trimer. That a larger oligomer, containing a mix of both wild-type and mutant F proteins, has partial activity cannot, however, be ruled out.     

Methotrexate Treatment Causes Early Onset of Disease in a Mouse Model of Ross River Virus-Induced Inflammatory Disease through Increased Monocyte Production

Part of the Togaviridae family, alphaviruses, including chikungunya virus (CHIKV), Sindbis virus (SINV) and Ross River virus (RRV), are able to cause significant inflammatory pathologies ranging from arthritis to encephalitis. Following symptomatic infection with arthritis-associated alphaviruses, patients often experience severe joint pain, affecting distal and small joints, which can last six months or longer. Recently, methotrexate (MTX), a disease modifying anti-rheumatic drug (DMARD), was used to treat patients experiencing chronic rheumatic symptoms following infection with CHIKV. Here, the effect of MTX on Ross River virus disease (RRVD) in mice was examined to better understand its therapeutic potential for alphaviral-induced musculoskeletal disease and to further our knowledge of the development of alphaviral pathologies. Using a mouse model, we analyzed the effect of MTX on RRVD. RRV disease pathogenesis in response to MTX treatment was determined by measuring levels of proinflammatory factors, cellular infiltrates, viral titer and histological analysis of infected tissues. RRV-infected mice receiving MTX treatment rapidly developed musculoskeletal disease, which correlated with a significant influx of inflammatory cell infiltrates into the skeletal muscle tissue. Although no difference was observed in the level of proinflammatory cytokines and chemokines, the viral load increased at early time points post infection in the serum and quadriceps of MTX treated mice, possibly contributing to disease pathogenesis. Results suggest that MTX treatment of acute RRVD in mice provides no therapeutic benefit and underline the importance of inflammatory monocytes in alphaviral induced arthritides.