Evaluation of thymidine kinase and neomycin phosphotransferase II positive selection systems for recovery of genetically atypical and recombinant DNA vaccine viruses

Dominant phenotypic marker cell culture selection systems were evaluated for the recovery of thymidine kinase positive (TK+), thymidine kinase negative (TK-), and neomycin phosphotransferase II positive (NPT II+) viruses. From 1 to 100 pfu of each marker-positive virus was diluted into 10(6) pfu of marker-negative background virus prior to selection. All three selection systems recovered 100 or fewer pfu of marked virus from the background population (10(-4) fractional level). In some instances, 1 to 10 pfu of marked virus were recovered (10(-5)-10(-6) fractional levels). TK+ and NPT II+ selections yielded nearly pure marker positive virus (98.8% and 99.5% respectively). Populations surviving TK- selection were significantly less pure (58.7%, P less than 0.05). Purity of recovered viruses was independent of the initial fractional level of marker-positive virus. The use of TK+, TK-, and NPT II+ selection systems is discussed in the context of purity testing and environmental surveillance of recombinant DNA viral vaccines.     

Enrichment of a precore-minus mutant of duck hepatitis B virus in experimental mixed infections

A precore-deficient mutant of duck hepatitis B virus (DHBV) produced by site-directed mutagenesis was tested for its ability to compete with wild-type virus in a mixed infection of 3-day-old ducklings. The mutation was shown to produce a cis-acting defect, resulting in a replication rate that was about one-half that of wild-type virus. Accordingly, wild-type virus was rapidly selected during the spread of infection. During the chronic phase of the infection, however, two selection patterns were seen. In 4 of 10 ducks, the wild-type virus slowly replaced the precore mutant. In another four ducks, the precore mutant virus slowly replaced the wild-type virus. In the remaining two ducklings, ratios of wild-type and precore mutant virus fluctuated, with wild-type virus slowly predominating. The replacement of wild-type virus was not due to the emergence of a rapidly replicating variant of the precore mutant, since genomes cloned from the infected ducks retained their original replication defect. Replacement of wild-type virus, however, correlated with elevated anti-core antibody titers, which continued to increase with time. The selection of a precore-negative strain of DHBV may be analogous to the selection for precore mutants of HBV during chronic hepatitis in humans.     

Immuno-epidemiological Modeling of HIV-1 Predicts High Heritability of the Set-Point Virus Load,while Selection for CTL Escape Dominates Virulence Evolution

It has been suggested that HIV-1 has evolved its set-point virus load to be optimized for transmission. Previous epidemiological models and studies into the heritability of set-point virus load confirm that this mode of adaptation within the human population is feasible. However, during the many cycles of replication between infection of a host and transmission to the next host, HIV-1 is under selection for escape from immune responses, and not transmission. Here we investigate with computational and mathematical models how these two levels of selection, within-host and between-host, are intertwined. We find that when the rate of immune escape is comparable to what has been observed in patients, immune selection within hosts is dominant over selection for transmission. Surprisingly, we do find high values for set-point virus load heritability, and argue that high heritability estimates can be caused by the ‘footprints’ left by differing hosts'' immune systems on the virus.     

Chimeric retroviral helper virus and picornavirus IRES sequence to eliminate DNA methylation for improved retroviral packaging cells

Most retroviral packaging cell lines were established by a helper virus plasmid cotransfected with a separate plasmid encoding a selection marker. Since this selection marker coexisted in trans with the helper virus sequence, helper virus gene expression could be inactivated by host DNA methylation despite selection for the cotransfected selection marker. We have reported that DNA methylation could occur in the long terminal repeat (LTR) region of helper virus in vector producer cells (VPC) in up to 2% of the population per day (W. B. Young, G. L. Lindberg, and C. J. Link, Jr., J. Virol. 74:3177-3187, 2000). To overcome host cell DNA methylation that suppresses viral gene expression, we constructed a chimeric retroviral helper virus, pAM3-IRES-Zeo, that contains Moloney murine leukemia virus as a helper virus and a picornavirus internal ribosome entry site (IRES) sequence followed by a Zeocin selection marker at the 3' end of the env sequence. This pAM3-IRES-Zeo permitted selection for intact and functional helper virus in transfected cells without subcloning. By selection with Zeocin, a mixed population of pAM3-IRES-Zeo-transfected NIH3T3 cells (AMIZ cells) was maintained with little or no DNA methylation of the helper virus 5' LTR. The high level of pAM3-IRES-Zeo gene expression resulted in no detectable vector superinfection and in high vector titers (2 x 10(6) to 1.5 x 10(7) CFU/ml) after introduction of a retroviral vector. When Zeocin selection was withdrawn from AMIZ cells, methylation of the 5' LTR increased from 17 to 36% of the population during 67 days of continuous culture and the cells became susceptible to superinfection. During this period, gene expression of pAM3-IRES-Zeo decreased and vector titer production was reduced to 2 x 10(4) CFU/ml. These data demonstrate an important role of DNA methylation in the genetic instability of VPC. The chimeric helper virus allows the establishment of a mixed population of packaging cells capable of high-level and sustained vector production without cloning procedures.     

Isolation of vaccinia MVA recombinants using the viral F13L gene as the selective marker

Modified vaccinia Ankara (MVA) is a highly attenuated vaccine vector that has an excellent vaccine safety record. Also, as a eukaryotic gene expression vector, MVA can be used in a biosafety level 1 setup, in contrast to more virulent vaccinia virus strains. Isolation of recombinant MVA involves repeated plaquing of the virus and is burdensome because virus plaques are slow to develop and difficult to recognize. To facilitate the generation of MVA recombinants, we have developed a cloning system for MVA based on the selection of the viral F13L gene. Deletion of F13L in MVA produced a small plaque phenotype and a reduction in extracellular virus formation, indicating a severe block in cell-to-cell spread. When using the F13L knockout virus as the parental virus, reintroduction of the F13L gene in the original locus was used as an efficient selection for the isolation of virus recombinants. The selection procedure can be done entirely in the permissive baby hamster kidney (BHK)-21 cell line, does not require plaque isolation, and rendered close to 100% recombinant virus.     

Citrus tristeza virus (CTV) resistance in transgenic citrus based on virus challenge of protoplasts

Summary A strategy for the sereening of candidate virus-derived sequences to provide RNA-mediated citrus tristeza virus (CTV) resistance and early selection of virus-resistant citrus is presented. The system is based on the polyethylene glycol-(PEG) mediated cotransformation of protoplasts using virus-derived sequences and green fluorescent protein as a single selectable marker, followed by an in vitro assay of virus inoculation into transgenic protoplasts to determine the level of citrus tristeza virus replication. A cotransformation rate higher than 20% allowed selection of several clones carrying the desired transgenes. Efficient in vitro inoculation of virus in transgenic protoplasts was performed. Tobacco mosaic virus virions were used as a control in order to check eitrus protoplast viability. Different CTV replication levels were detected in transgenic clones. Only one clone showed no replication of CTV. Considerations regarding selection of candidate virusderived sequences and virus challenge of transgenic cells are presented.     

Phylogenetic and evolutionary analyses of St. Louis encephalitis virus genomes

St. Louis encephalitis virus belongs to the Japanese encephalitis virus serocomplex of the genus Flavivirus, family Flaviviridae. Since the first known epidemic in 1933, the virus has been isolated from a variety of geographical, temporal, and host origins. We have sequenced 10,236 nucleotides of the open reading frame (93.6% of the full-length genome) of 23 of these strains, and have used the sequences to conduct phylogenetic analyses, in order to investigate the forces shaping the evolution of St. Louis encephalitis virus. Contrary to previous reports, we found little evidence for recombination in these isolates. Most of the amino acid sites in the SLEV polyprotein appeared to be under negative selection, with some sites evolving neutrally, and a small number under positive selection. The strongest signal for positive selection was evident in the N-linked glycosylation site of the envelope protein. Intra-strain sequence variability within strains was observed at this site, and analyses suggested that it is under selection in vitro. Furthermore, using heterochronous sequence data, we estimated the most recent expansion of St. Louis encephalitis virus in North America to have happened towards the end of the 19th century.     

Genetic selection in presence of pathogens such as the lymphoid leukosis virus: computer simulation

Summary A computer model was developed to simulate the population dynamics involved when selection is for a trait influenced by the presence of a pathogen in addition to quantitative genetic factors. The lymphoid leukosis virus is such a pathogen, when selection is for egg production in chickens. It is transmitted congenitally from dam to offspring and horizontally from one individual to another. For these simulations, individual selection for high performance in the trait influenced by the pathogen was more effective than family selection for removing infected individuals from populations. The resulting reduction in the incidence of infected individuals in following generations made the overall response to individual selection greater than for family selection. However, the virus would remain in most populations due to horizontal transmission to individuals which later transmit the virus to their offspring. These horizontally infected individuals would not be eliminated in the selection process because their egg production was assumed to be less reduced than that of congenitally infected birds. These simulation results seem to mimic certain experimental results which heretofore have been difficult to explain since they were not consistent with quantitative genetic theoretical expectations from selection.Journal Paper No. 9028 of the Purdue Agricultural Experiment StationAnimal Research Centre Contribution No. 1145     

Influence of mutagenesis and viral load on the sustained low-level replication of an RNA virus

Lethal mutagenesis is an antiviral strategy that aims to extinguish viruses as a consequence of enhanced mutation rates during virus replication. The molecular mechanisms that underlie virus extinction by mutagenic nucleoside analogues are not well understood. When mutagenic agents and antiviral inhibitors are administered sequentially or in combination, interconnected and often conflicting selective constraints can influence the fate of the virus either towards survival through selection of mutagen-escape or inhibitor-escape mutants or towards extinction. Here we report a study involving the mutagenesis of foot-and-mouth disease virus (FMDV) by the nucleoside analogue ribavirin (R) and the effect of R-mediated mutagenesis on the selection of FMDV mutants resistant to the inhibitor of RNA replication, guanidine hydrochloride (GU). The results show that under comparable (and low) viral load, an inhibitory activity by GU could not substitute for an equivalent inhibitory activity by R in driving FMDV to extinction. Both the prior history of R mutagenesis and the viral population size influenced the selection of GU-escape mutants. A sufficiently low viral load allowed continued viral replication without selection of inhibitor-escape mutants, irrespective of the history of mutagenesis. These observations imply that reductions of viral load as a result of a mutagenic treatment may provide an opportunity either for immune-mediated clearing of a virus or for an alternative antiviral intervention, even if extinction is not initially achieved.     

Role of the host immune response in selection of equine infectious anemia virus variants.

Equine infectious anemia virus was isolated from peripheral blood leukocytes collected during two early febrile cycles of an experimentally infected horse. RNase T1-resistant oligonucleotide fingerprint analyses indicated that the nucleotide sequences of the isolates differed by approximately 0.25% and that the differences appeared randomly distributed throughout the genome. Serum collected in the interval between virus isolations was able to distinguish the isolates by membrane immunofluorescence on live cells. However, no neutralizing antibody was detected in the interval between virus isolations. In fact, multiple clinical cycles occurred before the development of a neutralizing antibody response, indicating that viral neutralization might not be the mechanism for selection of antigenic variants. The ability of early immune sera to recognize variant specific antigens on the surface of infected cells suggested that immune selection occurs through recognition and elimination of certain virus-infected cells. Alternately, the random distribution of the genomic differences observed between the two isolates may indicate that equine infectious anemia virus variants emerge as a result of nonimmunological selection processes.     

Identifying Selection in the Within-Host Evolution of Influenza Using Viral Sequence Data

The within-host evolution of influenza is a vital component of its epidemiology. A question of particular interest is the role that selection plays in shaping the viral population over the course of a single infection. We here describe a method to measure selection acting upon the influenza virus within an individual host, based upon time-resolved genome sequence data from an infection. Analysing sequence data from a transmission study conducted in pigs, describing part of the haemagglutinin gene (HA1) of an influenza virus, we find signatures of non-neutrality in six of a total of sixteen infections. We find evidence for both positive and negative selection acting upon specific alleles, while in three cases, the data suggest the presence of time-dependent selection. In one infection we observe what is potentially a specific immune response against the virus; a non-synonymous mutation in an epitope region of the virus is found to be under initially positive, then strongly negative selection. Crucially, given the lack of homologous recombination in influenza, our method accounts for linkage disequilibrium between nucleotides at different positions in the haemagglutinin gene, allowing for the analysis of populations in which multiple mutations are present at any given time. Our approach offers a new insight into the dynamics of influenza infection, providing a detailed characterisation of the forces that underlie viral evolution.     

The molecular population genetics of the Tomato spotted wilt virus (TSWV) genome

RNA viruses are characterized by high genetic variability resulting in rapid adaptation to new or resistant hosts. Research for plant RNA virus genetic structure and its variability has been relatively scarce compared to abundant research done for human and animal RNA viruses. Here, we utilized a molecular population genetic framework to characterize the evolution of a highly pathogenic plant RNA virus [Tomato spotted wilt virus (TSWV), Tospovirus, Bunyaviridae]. Data from genes encoding five viral proteins were used for phylogenetic analysis, and for estimation of population parameters, subpopulation differentiation, recombination, divergence between Tospovirus species, and selective constraints on the TSWV genome. Our analysis has defined the geographical structure of TSWV, attributed possibly to founder effects. Also, we identify positive selection favouring divergence between Tospovirus species. At the species level, purifying selection has acted to preserve protein function, although certain amino acids appear to be under positive selection. This analysis provides demonstration of population structuring and species-wide population expansions in a multisegmented plant RNA virus, using sequence-based molecular population genetic analyses. It also identifies specific amino acid sites subject to selection within Bunyaviridae and estimates the level of genetic heterogeneity of a highly pathogenic plant RNA virus. The study of the variability of TSWV populations lays the foundation in the development of strategies for the control of other viral diseases in floral crops.     

表达HIV-1多价合成基因的重组痘苗病毒疫苗株的构建

为研制适合我国使用的HIV疫苗,选择具有代表意义的中国流行株HIV CN54(B′/C)病毒gag、pol、nef等基因的合成基因syngpnef,插入到自行构建的能在病毒筛选过程中将标记基因去除掉的双标记基因痘苗病毒载体pVI75的KpnI酶切位点,构建成转移质粒pVI75-syngpnef,与我国的天坛株痘苗病毒共转染鸡胚成纤维细胞,通过蓝白斑筛选得到的重组病毒疫苗株DNA。经PCR鉴定标记基因已被删除并有目的基因的整合,Western blot可检测到目的基因的融合表达。此重组病毒疫苗株有望成为HIV/AIDS候选疫苗。     

乙型流行性感冒病毒两大谱系的起源及其演变特征

测定1972－2000年间在中国分离并保存的乙型流行性感冒（流感）病毒一些毒株的HA1区核苷酸序列,结合GenBank中其它毒株的相关序列以及流行病学资料进行分析。结果提示,当前在世界上流行的乙型流感病毒两大谱系起源于20世纪70年代中期,而不是以前推测的60年代末,并且其中一个谱系起源于中国。结果还提示,乙型流感病毒的演变同时受到很强的正选择与负选择的作用,而以前人们认为选择对乙型流感病毒的演变作用甚微。还修正了乙型流感病毒变异速率的计算方法。     

Group Selection and Contribution of Minority Variants during Virus Adaptation Determines Virus Fitness and Phenotype

Understanding how a pathogen colonizes and adapts to a new host environment is a primary aim in studying emerging infectious diseases. Adaptive mutations arise among the thousands of variants generated during RNA virus infection, and identifying these variants will shed light onto how changes in tropism and species jumps can occur. Here, we adapted Coxsackie virus B3 to a highly permissive and less permissive environment. Using deep sequencing and bioinformatics, we identified a multi-step adaptive process to adaptation involving residues in the receptor footprints that correlated with receptor availability and with increase in virus fitness in an environment-specific manner. We show that adaptation occurs by selection of a dominant mutation followed by group selection of minority variants that together, confer the fitness increase observed in the population, rather than selection of a single dominant genotype.     

Complementation and Epistasis in Viral Coinfection Dynamics

Coinfection in RNA virus populations results in two important phenomena, complementation and recombination. Of the two, complementation has a strong effect on selection against deleterious mutations, as has been confirmed in earlier studies. As complementation delays the purging of less-fit mutations, coinfection may be detrimental to the evolution of a virus population. Here we employ both deterministic modeling and stochastic simulation to explore the mechanisms underlying the interactions between complementation and other evolutionary factors, namely, mutation, selection, and epistasis. We find that strong complementation reduces slightly the overall fitness of a virus population but substantially enhances its diversity and robustness, especially when interacting with selection and epistasis.     

Positive selection operates continuously on hemagglutinin during evolution of H3N2 human influenza A virus

It has been proposed that antigenic evolution of hemagglutinin 1 (HA1) for H3N2 human influenza A virus was punctuated. In the population genetic analysis, however, it was controversial whether positive selection operated on HA1 in a punctuated manner for the branches of the phylogenetic tree where transitions to new antigenic clusters occurred (C branches), or continuously. In the molecular evolutionary analysis, positive selection was detected for the trunk (T) branches but the relationship between antigenic evolution and positive selection was unclear. Here molecular evolutionary analysis was conducted to examine natural selection operating on HA1 of H3N2 human influenza A virus by dividing HA1 into epitopes A-E and other sites, as well as dividing the phylogenetic tree into the C branches overlapping with the T branches (C-T branches), those not overlapping with the T branches (C-NT branches), the T branches not overlapping with the C branches (NC-T branches), and other branches (NC-NT branches). Positive selection was detected for C, T, and NC-T branches, whereas evolution for the NC-NT branches appeared to be mainly neutral. Positive selection appeared to have operated throughout the trunk, which covered the entire time period of the phylogenetic tree, suggesting that positive selection operated continuously on HA1 during evolution of H3N2 human influenza A virus.     

Influenza A virus—a model for viral antigen presentation to cytotoxic T lymphocytes

Human influenza A virus is characterized by its high degree of variability and by its ability to cause frequent epidemics of disease. Most of the variation occurs in the two surface glycoproteins of the virus, against which protective antibodies are directed. In contrast, the strong MHC class I-restricted CTL response to infection with virus is predominantly specific for internal viral proteins which are relatively well conserved, and is cross-reactive between different strains of influenza A virus. However, the natural evolution of influenza viruses is largely driven by selection with antibody, with no firm evidence of selection by CTL. In normal individuals influenza virus produces an acute, localized infection, and this in part may reflect an inability to escape the CTL response.