Langerhans' cells and subtypes of human papillomavirus in cervical intraepithelial neoplasia.

There is strong circumstantial evidence that human papillomavirus is a cofactor in the development of cervical neoplasia. Systemic immunosuppression has also been implicated. A study was therefore carried out examining the relation between subtypes of human papillomavirus and local immunocompetent cells in the cervix. Colposcopically directed punch biopsy specimens were taken from normal cervix and from histologically proved cervical intraepithelial neoplasia for immunohistochemical studies. Human papillomavirus genome probing was performed on the abnormal specimens. A relation was apparent between decreased Langerhans'' cells and moderate to high copy numbers of human papillomavirus type 16. The reduction in Langerhans'' cells was significant for human papillomavirus type 18 even at low copy numbers. Conversely, the absence of human papillomavirus was associated with increased numbers of Langerhans'' cells in cervical intraepithelial neoplasia. These findings suggest that the proposed oncogenic potential of human papillomavirus type 16 and human papillomavirus type 18 in particular may be mediated by a specific effect on the afferent limb of the immune response.     

Mice immunized with measles virus develop antibodies to a cell surface receptor for binding virus.

Mice were immunized with measles virus to determine whether an auto-anti-idiotypic antireceptor response could be generated as a probe for measles virus receptors. Mice initially responded to viral antigens (days 11 to 18) and subsequently developed antibodies to a putative measles virus receptor (peak at day 30 to 35) by three criteria: the sera (1) agglutinated erythrocytes which virus agglutinates, (2) reacted with Vero cells, and (3) inhibited virus attachment to Vero cells. Additionally, select sera inhibited virus infection of Vero cells. The cell-reactive activity was identified as immunoglobulin G antibody and was neutralized by sera reacting with virus (idiotype). The application of this anti-idiotypic antibody to identify measles virus-binding sites on Vero cells was revealed by the ability of sera to immunoprecipitate 20- and 30.5-kilodalton proteins from metabolically labeled ([35S]methionine) Vero cells.     

Replication and persistence of measles virus in defined subpopulations of human leukocytes.

Replication of Edmonston strain measles virus was studied in several human lymphoblast lines, as well as in defined subpopulations of circulating human leukocytes. It was found that measles virus can productively infect T cells, B cells, and monocytes from human blood. These conclusions were derived from infectious center studies on segregated cell populations, as well as from ultrastructural analyses on cells labeled with specific markers. In contrast, mature polymorphonuclear cells failed to synthesize measles virus nucleocapsids even after infection at a relatively high multiplicity of infection. Measles virus replicated more efficiently in lymphocytes stimulated with mitogens than in unstimulated cells. However, both phytohemagglutinin and pokeweed mitogen had a negligible stimulatory effect on viral synthesis in purified populations of monocytes. In all instances the efficiency of measles virus replication by monocytes was appreciably less than that of mitogenically stimulated lymphocytes or of continuously culture lymphoblasts. Under standard conditions of infection, all of the surveyed lymphoblast lines produced equivalent amounts of measles virus regardless of the major histocompatibility (HL-A) haplotype. Hence, no evidence was found that the HL-A3,7 haplotype conferred either an advantage or disadvantage with respect to measles virus synthesis in an immunologically neutral environment. A persistent infection with measles virus could be established in both T and B lymphoblasts. The release of infectious virus from such persistently infected cells was stable over a period of several weeks and was approximately 100-fold less than peak viral titers obtained in each respective line after acute infection.     

Assembly of nucleocapsidlike structures in animal cells infected with a vaccinia virus recombinant encoding the measles virus nucleoprotein.

A vaccinia virus recombinant containing the measles virus nucleoprotein gene was shown to induce the synthesis of a 60 kDa phosphorylated nucleoprotein similar to authentic measles virus nucleoprotein. Mammalian or avian cells infected with the recombinant virus displayed tubular structures reminiscent of viral nucleocapsids both in the cytoplasm and in the nucleus. Such structures could be labelled in situ by using an immunogold detection method specific for measles virus proteins. Electron microscopic examination of tubular structures purified from cells infected with the vaccinia virus recombinant indicated that they displayed most of the features of measles virus nucleocapsids, although their length was on the average shorter. These results demonstrate the spontaneous assembly of measles virus nucleocapsids in the absence of viral leader RNA and provide a means for a detailed molecular analysis of the requirements for nucleocapsid assembly. Furthermore, these findings raise the possibility of achieving complete assembly of measles virus particles, devoid of infectious RNA, by using a vaccinia virus vector.     

Establishment of a persistent measles virus infection in HEp-2 cells.

A productive measles virus persistent infection has been established in HEp-2 cells. Greater than 90% of the persistently infected HEp-2 cells (H2MV) exhibited measles specific immunofluorescence and haemadsorption. Although most of the H2MV cells contained measles specific antigens, only a small percentage (less than 1%) actually produced infectious measles virus as determined by infectious centre assays. The measles virus produced by H2MV cells exhibited properties different from the initiating parent Edmonston strain virus, being reduced in virulence and also temperature sensitive for replication at 39 degrees C. The role of these altered virus properties in the establishment of persistence is considered.     

Marmoset lymphoblastoid cells as a sensitive host for isolation of measles virus.

B95-8, an Epstein-Barr virus-transformed marmoset B-lymphoblastoid cell line, and its derivative B95a, capable of attachment to a substrate surface, were 10,000-fold more sensitive to measles virus present in clinical specimens than were Vero cells. B95-8 and B95a cells were thus thought to be useful host cells for the isolation of measles virus. Quantitation of measles virus present in clinical specimens showed that a large quantity of virus, exceeding 10(6) 50% tissue culture infective doses per ml of a nasal-swab eluate, is shed into secretions by patients with acute measles, consistent with the contagiousness of the disease. Measles viruses isolated in B95a cells differed in some biological properties from those adapted to Vero cells. First, the viruses isolated in B95a cells did replicate in Vero cells, but release into the fluid phase was less efficient than that of Vero cell-adapted viruses. Second, minor antigenic differences were found between virus strains isolated in B95a cells and those isolated in Vero cells from the same clinical specimens. Third, the viruses isolated and propagated in B95a cells caused clinical signs in experimentally infected monkeys resembling those of human measles. It was suspected that measles virus is subject to host cell-mediated selection and that the viruses grown in B95a cells are more representative of measles virus circulating among humans than are the viruses selected in Vero cells.     

Gamma interferon is a major mediator of antiviral defense in experimental measles virus-induced encephalitis.

Measles virus infection of the central nervous system in the murine model of experimental measles virus-induced encephalitis is successfully controlled by virus-specific T-helper lymphocytes. T cells from BALB/c mice that are resistant to measles virus encephalitis proliferate well against measles virus in vitro, and bulk cultures recognize viral nucleocapsid and hemagglutinin as well as fusion proteins. The measles virus-specific T cells secrete large amounts of interleukin 2 (IL-2), gamma interferon (IFN-gamma), and tumor necrosis factor alpha (TNF-alpha) but no IL-4, IL-6, or IL-10, and hence the cytokine pattern is consistent with that of subtype 1 T-helper lymphocytes. In contrast, cells obtained from measles virus-infected susceptible C3H mice recognize measles virus proteins only weakly and secrete little IFN-gamma and TNF-alpha. Treatment of infected mice with anti-TNF-alpha antibodies has no effect on survival or virus clearance from the brain. Upon neutralization of IFN-gamma in vivo, the phenotype of measles virus-specific T-helper cells isolatable from BALB/c mice is reversed from subtype 1 to subtype 2-like. Anti-IFN-gamma antibody-treated BALB/c mice are susceptible to measles virus encephalitis, and viral clearance from the central nervous system is impaired. These results indicate that IFN-gamma plays a significant role in the control of measles virus infection of the central nervous system.     

Fate of microfilaments in vero cells infected with measles virus and herpes simplex virus type 1.

In herpes simplex virus type 1-infected Vero cells, reorganization of microfilaments was observed approximately 4 h postinfection. Conversion of F (filamentous) actin to G (globular) actin, as assessed by a DNase I inhibition assay, was continuous over the next 12 to 16 h, at which time a level of G actin of about twice that observed in uninfected cells was measured. Fluorescent localization of F actin, using 7-nitrobenz-2-oxa-1,3-diazole (NBD)-phallacidin, demonstrated that microfilament fibers began to diminish at about 16 to 18 h postinfection, roughly corresponding to the time that G actin levels peaked and virus-induced cytopathology was first observable. In measles virus-infected cells, no such disassembly of microfilaments occurred. Rather, there was a modest decrease in G actin levels. Fluorescent localization of F actin showed that measles virus-infected Vero cells maintained a complex microfilament network characterized by fibers which spanned the entire length of the newly formed giant cells. Disruption of microfilaments with cytochalasin B, which inhibits measles virus-specific cytopathology, was not inhibitory to measles virus production at high multiplicities of infection (MOI) but was progressively inhibitory as the MOI was lowered. The carbobenzoxy tripeptide SV-4814, which inhibits the ability of Vero cells to fuse after measles virus infection, like cytochalasin B, inhibited measles virus production at low MOI but not at high MOI. Thus, it appears that agents which affect the ability of Vero cells to fuse after measles virus infection may be inhibitory to virus production and that the actin network is essential to this process.     

Persistent infection of cells in culture by measles virus. II. Effect of measles antibody on persistently infected HeLa sublines and recovery of a HeLa clonal line persistently infected with incomplete virus

Rustigian, Robert (Tufts University School of Medicine, Boston, Mass.). Persistent infection of cells in culture by measles virus. II. Effect of measles antibody on persistently infected HeLa clonal line persistently infected with incomplete virus. J. Bacteriol. 92:1805-1811. 1966.-The effect of viral antibody on persistent infection of HeLa cells by the Edmonston strain of measles virus was investigated by culturing cells from three persistently infected clones in medium supplemented with human immune globulin. The three infected HeLa clones were isolated from a persistently infected parent line. Two sublines which were grown in the presence of measles antibody developed a nonyielder state, wherein there is no detectable virus infectious for normal HeLa cultures. There is, however, continued synthesis of intracellular viral antigen and formation of viral intracytoplasmic inclusion bodies. The development of a nonyielder state was associated with a marked decrease in the degree of hemadsorption in cultures of both sublines. Further studies of the viral properties of non-yielder HeLa cell populations were made with a clone obtained from one of these sublines by plating under antibody. Persistent infection in this line was characterized by synthesis of incomplete virus even when the cells were cultured thereafter in anti-body-free medium. This was evidenced by (i) failure to recover infectious virus from the clonal population despite continued formation of intracellular viral antigen and viral intracytoplasmic inclusion bodies in a majority of the cells, (ii) the presence of only a few cells with surface viral antigen(s) including hemagglutinin, and (iii) the relatively weak antibody response to viral envelope antigen(s) after injection of cells into guinea pigs.     

Acute and chronic infection of human lymphoblastoid cell lines with measles virus.

Several human continuous lymphoblastoid cell lines (LCL) having T or B characteristics were infected with low and high passage strains of measles virus. All of the cell lines were susceptible to one or the other or to both strains of measles virus with the production of typical syncytial giant cells and released cell-free infectious virus into the supernatant medium. There was no consistent pattern of susceptibility of LCL with either T or B characteristics to infection by measles virus. Viral induced cytolysis of the lymphoblastoid cells in many of the lines was marked, but in the LCL that could be maintained over longer periods of time, a state of chronic, less cytolytic and persistent infection could be established. The infection was characterized by the production of moderate amounts of cell-free infectious virus for up to 4 1/2 months after initial infection with little change in the number of viable cells in culture. Long-term low multiplicity of infection (MOI) experiments demonstrated that the cell-free infectious virus was being produced only by a small number of cells, but the majority of cells in culture contained measles antigen that was in a cell-restricted, noninfectious, or defective form. Electron microscopic examination of the chronically infected cells demonstrated that many of them contained aggregates of hollow tubular intranuclear nucleocapsids whose "stripped" appearance was in marked contrast to the larger granular intracytoplasmic nucleocapsids found during earlier stages of infection. It is theorized that the persistent infection of LCL may serve as a model in understanding the immune mechanisms which permit latent and chronic measles infection in man.     

Immune responses during measles infection in immunosuppressed Rhesus monkeys.

Rhesus monkeys immunosuppressed with horse anti-human thymocyte gamma-globulin (ATG) were infected with measles and simultaneously inoculated with sheep erythrocytes (SRBC), a thymus-dependent antigen, and with pneumococcal polysaccaride type III (SSS-III), a thymus-independent antigen. ATG treatment alone suppressed SRBC antibody production, had no effect on SSS-III antibody production, and effectively eliminated circulating T cells compared to nonsuppressed monkeys. ATG treatment of measles-infected monkeys resulted in delayed virus clearance and delayed antibody production compared to nonsuppressed infected monkeys. After cessation of ATG treatment, measles antibodies and T cells reached normal levels, and measles virus was eliminated. Thus, immune clearance of measles virus is T cell-dependent, but the relative roles of cellular- and humoral-mediated immunity in vivo could not be clearly separated. Also, measles infection was associated with a decreased T cell mitogen responsiveness of circulating lymphocytes but not of lymph node lymphocytes, suggesting an altered circulating pattern of the cells responsible for delayed hypersensitivity. Also, measles infection had no effect on T-dependent antibody production to SRBC.     

RNA干扰抑制麻疹病毒体外复制的实验研究

为了研究短发夹RNA(shRNA)介导的RNA干扰对麻疹病毒体外复制的抑制作用,构建靶向与麻疹病毒复制密切相关的宿主细胞基因Rab9 GTPase基因特异性shRNA表达载体,分别转染Vero-E6和B95a细胞后感染麻疹病毒Edmonston株和野生株。逆转录聚合酶链反应(RT-PCR)和免疫印迹技术(Western-blot)检测转染细胞内Rab9 GTPase基因表达水平;标准蚀斑试验测定麻疹病毒滴度。结果显示转染细胞内Rab9 GTPase mRNA和蛋白质的表达水平同对照组相比明显降低,标准蚀斑试验显示麻疹病毒的复制受到显著抑制,抑制率达到90%以上。结果表明载体介导的shRNAs能通过特异性下调Rab9 GTPase基因表达抑制麻疹病毒体外复制,Rab9 GTPase可能成为治疗麻疹病毒感染的RNA干扰靶。     

Lymphocyte-mediated cytotoxicity to cells infected with measles virus: I. Use of in vitro infected leukocytes as autologous target cells; absence of virus-specific cytotoxic lymphocytes

We investigated lymphocyte-mediated cytotoxicity in humans to autologous cells infected with measles virus. Mononuclear leukocytes, isolated from peripheral blood, were stimulated by phytohemagglutinin (PHA) and infected with measles virus. At 72 hr after infection, about 80% of the cells could be lysed by antibodies against measles virus and human complement, which meant that at that time the expression of virus-specific antigens on the cell surface was maximal. Such PHA-stimulated, infected leukocytes were used as target cells in an assay for lymphocyte-mediated cytotoxicity. Effector lymphocytes were obtained from the same donor who had provided the target cells, and were tested for their cytotoxicity directly after isolation.Lymphocytes obtained from adult humans, with a history of natural measles infection contracted during childhood, were not found to be cytotoxic to autologous infected cells, unless antibodies against measles virus were present during the assay. The same response, though to a lesser extent, was observed with cord blood lymphocytes obtained from healthy neonates. This indicates that the observed cytotoxicity does not reflect acquired cellular immunity but rather antibody-dependent cellular cytotoxicity (ADCC).     

Lymphocyte-mediated cytotoxicity to autologous cells infected with measles virus. II. Specificity of the cytotoxic reaction and characterization of the effector cells involved.

The mechanism of lymphocyte-mediated cytotoxicity to cells infected with measles virus was investigated. Cytotoxicity was measured in a direct assay, immediately after the isolation of lymphocytes from human peripheral blood; mononuclear leukocytes, infected with measles virus in vitro, served as autologous target cells. Virus-specific cytotoxicity required the presence of both IgG antibodies against measles virus and of effector lymphocytes. The effector lymphocytes had Fc receptors and were mainly present in a fraction of non-T lymphocytes. Monocytes were not cytotoxic but rather inhibitory. These results indicate that lysis of virus-infected cells in this direct assay is due to antibody-dependent cellular cytotoxicity (ADCC), caused by K cells. Control experiments showed that the virus-infected target cells were sensitive to incubation with human serum or IgG, resulting in a nonspecific increase of ⁵¹Cr release; however, this did not affect the results of K-cell cytotoxicity. Maximal virus-specific lysis by ADCC did not reach the level obtained by complement-dependent cytotoxicity. Possible explanations for this difference are discussed.     

Host cell factors involved in the production of slowly sedimenting nucleocapsids in measles virus-infected cells.

A decrease in the sedimentation rates of the measles virus nucleocapsid, and the RNA contained within, were observed during acute measles virus infection when the growth conditions of Vero cells were altered. The change in sedimentation rates of virus nucleocapsids in these experiments was apparently due to the physiological state of the cell and was independent of the history of the measles virus used for infection since: (i) the same virus stock was used to infect cells from which nucleocapsids were prepared, (ii) nucleocapsid sedimentation rates were rapid when Vero cells freshly revived from liquid nitrogen were infected, but nucleocapsid profiles showed no decrease in the amount of slowly sedimenting material using the same cells and changing the virus preparation used for infection. Frequent cell splittings and numerous medium changes were among the growth factors which appeared to correlate to slowly sedimenting particle production. Changes in the amount of self-complementarity of the measles virus RNA were also observed under these conditions.     

Functional cDNA library for efficient expression of measles virus-specific gene products in primate cells.

A cDNA library designed for high-level expression of measles virus-specific gene products in mammalian cells was generated. From this library, functional clones which contained the entire protein-coding sequences of the nucleocapsid (N) and the phosphoprotein (P) genes were isolated. By DNA-mediated gene transfer into a line of simian virus 40-transformed monkey kidney cells, the N-specific cDNA was expressed into a single polypeptide of about 60,000 Mr, which was immunoprecipitated by monoclonal antibodies against the measles virus N protein. In contrast, the P-specific cDNA could be expressed into either one or two species of polypeptides of 75,000 or 70,000 Mr, both of which were immunoprecipitated by monoclonal antibodies against the measles virus P protein.     

A Single Amino Acid Change in the Hemagglutinin Protein of Measles Virus Determines Its Ability To Bind CD46 and Reveals Another Receptor on Marmoset B Cells

This paper provides evidence for a measles virus receptor other than CD46 on transformed marmoset and human B cells. We first showed that most tissues of marmosets are missing the SCR1 domain of CD46, which is essential for the binding of Edmonston measles virus, a laboratory strain that has been propagated in Vero monkey kidney cells. In spite of this deletion, the common marmoset was shown to be susceptible to infections by wild-type isolates of measles virus, although they did not support Edmonston measles virus production. As one would expect from these results, measles virus could not be propagated in owl monkey or marmoset kidney cell lines, but surprisingly, both a wild-type isolate (Montefiore 89) and the Edmonston laboratory strain of measles virus grew efficiently in B95-8 marmoset B cells. In addition, antibodies directed against CD46 had no effect on wild-type infections of marmoset B cells and only partially inhibited the replication of the Edmonston laboratory strain in the same cells. A direct binding assay with insect cells expressing the hemagglutinin (H) proteins of either the Edmonston or Montefiore 89 measles virus strains was used to probe the receptors on these B cells. Insect cells expressing Edmonston H but not the wild-type H bound to rodent cells with CD46 on their surface. On the other hand, both the Montefiore 89 H and Edmonston H proteins adhered to marmoset and human B cells. Most wild-type H proteins have asparagine residues at position 481 and can be converted to a CD46-binding phenotype by replacement of the residue with tyrosine. Similarly, the Edmonston H protein did not bind CD46 when its Tyr481 was converted to asparagine. However, this mutation did not affect the ability of Edmonston H to bind marmoset and human B cells. The preceding results provide evidence, through the use of a direct binding assay, that a second receptor for measles virus is present on primate B cells.     

Subacute sclerosing panencephalitis: detection of measles virus RNA in appendix lymphoid tissue before clinical signs.

An appendix removed 15 days before onset of symptoms of subacute sclerosing panencephalitis was examined retrospectively for measles virus ribonucleic acid (RNA). Tissue sections hybridised in situ to a cloned measles virus probe of deoxyribonucleic acid specific for nucleocapsid protein showed that many cells of the lymphoid tissue contained measles virus RNA. In contrast, only a few infected lymphoid cells were detected in three out of six seropositive controls and none in three seronegative infants. A widespread chronic viral infection of the immune system, established after measles, may promote or even initiate nerve cell infection in subacute sclerosing panencephalitis.     

Measles virus-induced immune suppression in the cotton rat (Sigmodon hispidus) model depends on viral glycoproteins.

Immune suppression during measles accounts for most of the morbidity and mortality associated with the virus infection. Experimental study of this phenomenon has been hampered by the lack of a suitable animal model. We have used the cotton rat to demonstrate that mitogen-induced proliferation of spleen cells from measles virus-infected animals is impaired. Proliferation inhibition is seen in all lymphocyte subsets and is not dependent on viral replication. Cells which express the viral glycoproteins (hemagglutinin and fusion protein) transiently by transfection induce proliferation inhibition after intraperitoneal inoculation, whereas application of a recombinant measles virus in which measles virus glycoproteins are replaced with the vesicular stomatitis virus G protein does not have an antiproliferative effect. Therefore, in vivo expression of measles virus glycoproteins is sufficient and necessary to induce inhibition of lymphocyte proliferation.