Mode of Action of the Antiviral Activity of Amantadine in Tissue Culture.

Hoffmann, C. E. (E. I. du Pont de Nemours & Co., Inc., Wilmington, Del.), E. M. Neumayer, R. F. Haff, and R. A. Goldsby. Mode of action of the antiviral activity of amantadine in tissue culture. J. Bacteriol. 90:623-628. 1965.-Amantadine hydrochloride has shown antiviral activity in tissue culture, in ovo, and in vivo. Experiments with it during the course of virus proliferation indicate that its antiviral activity is due to inhibition of virus penetration into the host cell. These studies indicate that amantadine hydrochloride is not virucidal at concentrations active in tissue culture. It does not block virus adsorption to host cells, nor does it affect the virus enzyme neuraminidase. In the presence of amantadine hydrochloride, virus adsorbed to susceptible cells remains at the cell surface in an infective state. An attempt to demonstrate high development of resistance to the antiviral action of amantadine hydrochloride in tissue culture has been unsuccessful.     

Replication of Sendai Virus: II. Steps in Virus Assembly

Chick embryo fibroblast cultures infected with Sendai virus were incubated with (3)H-uridine in the presence of actinomycin D beginning at 18 hr after infection. The 35 and 18S virus-specific ribonucleic acid (RNA) components were found in a ribonuclease-sensitive form in the cell and appeared to be associated with polyribosomes. Newly synthesized 57S viral RNA was rapidly coated with protein to form intracellular viral nucleocapsid, and no 57S RNA was found "free" (ribonucleasesensitive) in the 2,000 x g supernatant fraction of disrupted cells. The nucleocapsid from detergent-disrupted Sendai virus and that from disrupted cells were indistinguishable in ultrastructure and buoyant density, and neither was found to be infectious or have hemagglutinating activity. Kinetic studies of nucleocapsid and virus formation indicated a relative block in conversion of viral nucleocapsid to complete enveloped virus in these cells, resulting in accumulation of large amounts of nucleocapsid in the cell cytoplasm.     

Effects of l-Glutamine Deprivation on Growth of HVJ (Sendai Virus) in BHK Cells

l-Glutamine requirement for viral maturation was found in BHK-HVJ cells, a cell line of baby hamster kidney cells persistently infected with HVJ (Sendai virus). Synthesis of envelope protein in BHK-HVJ cells was markedly suppressed by deprivation of l-glutamine, whereas development of nucleocapsid (S) antigen was less affected. More detailed examination of this phenomenon was carried out by using a cytolytic system. Growth of HVJ in BHK cells cultured in media deprived of various amino acids was investigated, and omission of l-glutamine from culture medium resulted in a marked inhibitory effect on the release of infectious virus and synthesis of envelope protein, although synthesis of virus-specific RNA and nucleocapsid antigen in the cells was readily detected. When l-glutamine was restored to the culture medium, infectious virus and envelope protein could be detected. l-Glutamic acid, l-aspartic acid, or l-alanine could be substituted for l-glutamine. Effects of l-glutamine deprivation on HVJ growth in several other cells were also investigated. The growth of HVJ in the cells other than BHK and FL cells was not suppressed by lack of l-glutamine. Growth of Sindbis virus in BHK cells was also markedly retarded in the absence of l-glutamine.     

Growth of Pathogenic Virus in a Large-Scale Tissue Culture System

A model system is described for the mass propagation of Rift Valley fever (RVF) virus, utilizing large-volume fermentor units for suspension culture of tissue cells and the subsequent production of virus. Comparisons between laboratory- and fermentor-scale operations of tissue cell growth gave equivalent results. Cell viability dropped 24 to 30 hr postinfection with a subsequent virus yield between 10(8.0) and 10(9.0) mouse intracerebral median lethal doses per milliliter. Infecting volumes of tissue cell culture (20- or 40-liter working volumes) had no apparent effect on virus yields. Tissue cells grown under either oxidation-reduction potential- and pH-controlled or uncontrolled conditions showed little or no difference in their ability to produce RVF virus. We believe this tissue cell virus process to have potential application for large-scale production of vaccines for human or veterinary use or for the mass propagation of certain carcinogenic viruses for cancer research, once use of established lines for this purpose is accepted.     

Fate of Sendai Virus Ribonucleoprotein in Virus-infected Cells

The cytoplasmic extracts of Ehrlich ascites tumor cells infected with (32)PO(4) and (3)H-leucine-labeled Sendai virus have been examined during the course of infection with respect to sedimentation behavior and buoyant densities of input virus radioactivity. It was found that (32)P and (3)H radioactivities were coincident, and, at 30 min after infection, the bulk of radioactivity was recovered in the polysome region of a sucrose gradient in the position of Sendai virus ribonucleoprotein (210S). The heterogeneity of radioactivity profiles appeared at 1 hr after infection and increased during 6 hr of incubation. The buoyant densities of input virus components were determined by banding in CsCl gradient. Here again the bulk of coincident (32)P and (3)H radioactivity at 30 min after infection banded at the same density as Sendai virus ribonucleoprotein (1.31 g/cm(3).) This component disappeared at 3 hr after infection, and (32)P and (3)H radioactivities were now found in components banded at densities 1.38, 1.41, 1.45, 1.49, and 1.55 g/cm(3). The results presented are consistent with the idea that virus ribonucleoprotein is retained in the cytoplasm of infected cells during at least 6 hr of incubation, being partly deproteinized in the course of infection. The nature of components which banded at rho = 1.41, 1.45, 1.49, and 1.55 as complexes of partly deproteinized ribonucleoprotein with ribosomes will be described in a separate paper.     

Factors Influencing the Establishment of Persistent Infection of HVJ (Sendai Virus) in L Cells

Infection of a subline of L cells adapted to grow in suspension (Ls) with Fushimi strain of HVJ (HVJ-F) resulted in a virus carrier state. Ls cells, when cultured in monolayer, showed morphological changes following infection of HVJ-F and were detached from the glass wall. However, when the detached cells were transferred to a new environment of suspension culture within 5 days after infection, the carrier state was again established. HVJ-F caused only lethal infection in L cells maintained exclusively in monolayer (Lm). On the other hand, both Ls and Lm, irrespective of their culture conditions, were lethally infected by Nagoya 1–60 strain of HVJ. The overall results showed that culture condition as well as the kind of host cells or virus strains is an important factor regulating the establishment and maintenance of the virus carrier state.     

Changes in the Activity of Certain Enzymes of Acer pseudoplatanus L. Cells at four Stages of Growth in Suspension Culture

The activities of twelve enzymes were studied in Acer psendoplatanum L. cells grown in suspension cultures for 6, 12, 19 and 22 days. The enzyme activities of cells (6 and 12 days) in the phase of rapid cell division were rather different from that of cells in the stationary phase (19, 22 days). The activity of aldolasc was highest at the first two stages of growth, when the amount of RNA and protein per cell was highest, and after this decreased steeply. The curves of specific activities of several phosphatases (glucosc-6-phosphatasc, α-glycerophosphatase, acid phosphatase and ATPase) and ribonuclease were almost the reverse of the curve of aldolase, showing a minimum in 12-day-old cells and a maximum in cells 19 and 22 days old. The activity of peroxidase was also high in ageing cells. Glutamate: oxaloacetate transaminase and aminopeptidases (leucine and alanine) had synchronous maxima (6 and 19 days) of specific activity but the activity of aminopeptidases decreased gradually during ageing of the suspension, if the enzyme activities are calculated per 10⁷ cells. Glutamate: pyruvate transaminasc activity was very low and no dcoxyribonuclease activity could be detected.     

Transient Inhibition of Polyoma Virus Synthesis by Sendai Virus (Parainfluenza I) II. Mechanism of the Interference by Inactivated Virus

The mechanism of the transient inhibition of polyoma virus synthesis by betapropiolactone-inactivated Sendai virus was studied. Polyoma virus early functions did not appear to be affected, although deoxyribonucleic acid (DNA) and structural protein synthesis were inhibited 60 and 35% respectively. The inhibition of macromolecular synthesis was not sufficient to account for the 90% inhibition of infectious progeny formation. Encapsidation of polyoma DNA into mature virions appears to be completely inhibited after superinfection by beta-propiolactone-inactivated Sendai virus. Ultraviolet irradiation of live or beta-propiolactone-inactivated Sendai virus preparations abolishes the interfering capacity, indicating that a functional Sendai virus ribonucleic acid molecule is the interfering component.     

Growth and Antithraquinone Biosynthesis by Galium mollugo L. Cells in Batch and Chemostat Culture

The kinetics of growth, nutrient uptake, and anthraquinone biosynthesisby suspension cultures of Galium mollugo L. cells were examinedin batch and continuous (chemostat) culture. In batch culture,although the initial growth rate was constant (minimum doublingtime = 35 h) characteristic changes in cell composition wereobserved during the growth cycle particularly cell dry weight(between 3.9 and 9.2 g/10⁹ cells), cell anthraquinone (22–80mg/10⁹ cells), and cell protein (0.7–1.6 g/10⁹ cells).Using a chemostat steady state growth was established at twodifferent specific growth rates with mean doubling times of40 h and 25 h. Phosphate was established as the growth-limitingnutrient in chemostat culture at a concentration of 11 µgP ml^–1. In steady state growth at a doubling time of 40h the cell composition remained constant although this was differentfrom any cells grown in batch culture. The cell anthraquinonelevel in steady state growth was between 7 and 30 times lowerthan in batch culture. This result raises the question of therelative importance of growth rate and the growth-limiting nutrientin determining accumulation of secondary products by culturedplant cells.     

Growth of Mouse L Cells in Shaken Culture and Mengovirus Plaque Formation on L Cells Suspended in Agar

Procedures are described that require a minimum of equipment and maintenance for growing mouse L cells suspended in liquid medium and for plaquing mengovirus on L cells suspended in agar. Viability of L cells during storage for 1 to 2 hr at relatively high concentrations was better in media at 30 C than at 0 C, as measured by viable counts after growth for 24 hr at 35 C. The number and size of plaques increased with increasing concentration of NaHCO(3) in the agar layers, but the relative difference in plaque size was maintained. Large- and small-plaque-size variants had similar virulence as determined by the rates of viability loss of L cells in liquid suspension cultures.     

Heterokaryon Formation of Simian Virus 40-transformed Cells in the Presence of Ultraviolet-irradiated Sendai Virus

Most simian virus 40-transformed mouse kidney lines form heterokaryons with CV-1 cells in the presence of ultraviolet-irradiated Sendai. However, two nonyielder lines, mKS-U2 and mKS-U20, fuse poorly.     

Cytopathogenesis of Sendai Virus in Well-Differentiated Primary Pediatric Bronchial Epithelial Cells

Sendai virus (SeV) is a murine respiratory virus of considerable interest as a gene therapy or vaccine vector, as it is considered nonpathogenic in humans. However, little is known about its interaction with the human respiratory tract. To address this, we developed a model of respiratory virus infection based on well-differentiated primary pediatric bronchial epithelial cells (WD-PBECs). These physiologically authentic cultures are comprised of polarized pseudostratified multilayered epithelium containing ciliated, goblet, and basal cells and intact tight junctions. To facilitate our studies, we rescued a replication-competent recombinant SeV expressing enhanced green fluorescent protein (rSeV/eGFP). rSeV/eGFP infected WD-PBECs efficiently and progressively and was restricted to ciliated and nonciliated cells, not goblet cells, on the apical surface. Considerable cytopathology was evident in the rSeV/eGFP-infected cultures postinfection. This manifested itself by ciliostasis, cell sloughing, apoptosis, and extensive degeneration of WD-PBEC cultures. Syncytia were also evident, along with significant basolateral secretion of proinflammatory chemokines, including IP-10, RANTES, tumor necrosis factor (TNF)-related apoptosis-inducing ligand (TRAIL), interleukin 6 (IL-6), and IL-8. Such deleterious responses are difficult to reconcile with a lack of pathogenesis in humans and suggest that caution may be required in exploiting replication-competent SeV as a vaccine vector. Alternatively, such robust responses might constitute appropriate normal host responses to viral infection and be a prerequisite for the induction of efficient immune responses.Sendai virus (SeV) is a nonsegmented negative-strand RNA virus of the Paramyxoviridae family. Recombinant SeV (rSeV) has been extensively studied as a vector for vaccines, cancer immunotherapy, and gene therapy (14, 22, 34, 41, 43). SeV is virulent in rodents, but despite extensive antigenic and genetic similarity to human parainfluenza virus type 1 (hPIV1), it is not known to cause disease in humans (33). Interest in rSeV as a vector is exemplified by the fact that (i) its genome can easily be manipulated to stably express heterologous genes (9), (ii) it does not undergo homologous recombination, (iii) cell transduction is independent of the cell cycle, (iv) there is no DNA phase during replication and hence no possibility of cell transformation, and (v) its cell or tissue tropisms and replication competency may be modulated by reverse genetics and appropriate rescue systems (5, 8).Much of the research on rSeV as a vector involves monolayer cells and animal models and employs both replication-competent and transmission-incompetent viruses. In view of its respiratory tract tropism, particular attention was paid to its use as a gene therapy vector for lung diseases such as cystic fibrosis (CF) (2, 13, 14, 43). Indeed, early studies demonstrated its capacity to efficiently overcome a series of extra- and intracellular barriers in the respiratory tract, such as the glycocalyx, mucus layer, mucociliary clearance, and cell membranes (13, 14, 43). However, in vivo studies demonstrated that rSeV-mediated gene transduction was transient (lasting ∼7 days) and that repeated administration was inefficient (16). The reasons for this transient transduction remain unclear.In contrast, the capacity to efficiently and transiently transduce host cells is of considerable interest from a vaccine vector viewpoint. Indeed, promising rSeV-vectored vaccine candidates have been described for other respiratory viruses, such as respiratory syncytial virus (RSV), hPIV1, hPIV2, hPIV3, and systemic viruses, such as HIV-1 (22, 40, 44). Despite its considerable promise as a viral vector, little is known about how rSeV interacts with human airway epithelial cells (HAE).To address this, we established an ex vivo/in vitro model of respiratory virus infection based on well-differentiated primary pediatric bronchial epithelial cells (WD-PBECs) in air-liquid interface (ALI) cultures. The pediatric origin of the primary bronchial cells allowed us to investigate SeV-host interactions in a pediatric context. The need for CF gene therapy or respiratory virus vaccines for infants or children emphasizes the relevance of this ex vivo/in vitro pediatric model. Using rSeV expressing enhanced GFP (rSeV/eGFP), we comprehensively investigated the consequences of SeV infection in these cultures, including the types of cells infected, virus growth kinetics, cytopathic effects (CPE), and inflammatory responses. Our data provided novel insights into the interaction of SeV with pediatric airway epithelium and the limitations and/or advantages of its use as a vector.     

胶水树兰的组织培养

1植物名称胶水树兰（Epidendrum ciliare L．）。 2材料类别幼芽。 3培养条件以1／2MS为基本培养基。（1）愈伤组织诱导与原球茎增殖培养基：1／2MS＋6-BA1．5mg．L^-1（单位下同）＋NAA0．5;（2）原球茎诱导丛生芽培养基：112MS＋6-BA7．0＋NAA1．0;     

耧斗菜的组织培养

1 植物名称 耧斗菜（Aquilegia vulgaris L．）。 2材料类别 幼叶叶片、叶柄。 3培养条件 愈伤组织诱导和增殖培养基：（1）MS＋2,4-D0．5-2．0mg·L^-1（单位下同）＋6-BA0．5;（2）MS＋NAA 0．2-1．5＋6-BA0．2;     

鹿角苔的组织培养

1植物名称鹿角苔（Riccia Fluitans L.）。 2材料类别 叶状体。 3培养条件（1）启动培养基：1/2MS＋10g·L-1蔗糖＋2g·L-1活性炭＋3g·L-1琼脂粉;（2）生长培养基：1/2MS＋BA0.1mg·L-1（单位下同）＋NAA0.1＋40g·L-1土豆泥＋30g·L-1蔗糖＋1g·L-1活性炭＋3g·L-1琼脂粉;     

野生树莓组织培养技术研究

以未萌发的腋芽和单芽茎段为外植体,对野生种刺萼粉枝莓进行了组织培养技术研究。.结果表明,未萌发的腋芽是最佳的外植体;MS 6-BA 1.0 mg/L NAA 0.01 mg/L为较佳的启动培养基;MS 6-BA 1.0 mg/L NAA 0.2 mg/L为最佳的增殖培养基;生根培养基为1/2MS NAA 0.05 mg/L,试管苗生根率高,炼苗移栽成活率达90%以上。     

Mode of Subacute Sclerosing Panencephalitis (SSPE) Virus Infection in Tissue Culture Cells

Cell-free infectious viruses were successfully recovered by the aid of freezing and thawing from cultures infected with the Kitaken-1 and Biken strains of subacute sclerosing panencephalitis (SSPE) virus. Our results including those in a previous report which dealt with the Niigata-1 strain of SSPE virus show that cell-free viruses can be detected from all of the SSPE virus-carrying cultures established in Japan. It was also found that cell-free infectious viruses can be recovered efficiently by dispersing the virus-carrying cultures with EDTA. The inclusion of trypsin in the EDTA solution, however, caused a poor recovery of the infectious viruses. Infection of cells with the cell-free viruses readily established the virus-carrying cultures that have characteristics comparable to those of their original cultures. The culture infected with the Kitaken-1 strain produced infectious viruses in about ten times the amount of the other two infected cultures. The buoyant densities of the cell-free infectious viruses were almost the same among the three strains, the values being 1.120 to 1.132, but significantly less than that of 1.164 of measles virus. The low density can be ascribed to one of the characteristics of these SSPE viruses.     

冬寒菜的组织培养

1植物名称 冬寒菜（Malva verticillata L．）,又名冬苋菜、马蹄菜、冬葵、滑菜、滑肠菜等。2材料类别 茎段、叶片和上胚轴。     

毛酸浆的组织培养

1植物名称 毛酸浆（PhysalispubescensL．）。 2材料类别种子长成的无菌苗的子叶。