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Host cell

The viruses responsible for AIDS are human immunodeficiency virus 1 and 2 (HIV 1 and HIV 2) Both are retroviruses, meaning that their genetic material is RNA rather than DNA HI Vs require a host cell to reproduce and the hosts m humans are the T4 lymphocytes which are the cells primarily responsible for inducing the immune system to respond when provoked The HIV penetrates the cell wall of a T4 lymphocyte and deposits both its RNA and an enzyme called reverse transcriptase inside There the reverse transcriptase catalyzes the formation of a DNA strand that is complementary to the viral RNA The transcribed DNA then serves as the template from which the host lymphocyte produces copies of the virus which then leave the host to infect other T4 cells In the course of HIV reproduction the ability of the T4 lymphocyte to reproduce Itself IS compromised As the number of T4 cells decrease so does the body s ability to combat infections... [Pg.1179]

Section 28 13 HIV which causes AIDS is a retrovirus Its genetic matenal is RNA instead of DNA HIV contains an enzyme called reverse transcriptase that allows Its RNA to serve as a template for DNA synthesis m the host cell... [Pg.1189]

Trace contaminants such as host cell proteins (HCPs) and DNA are deterrnined by more specialized techniques. Host cell proteins are generally deterrnined using an immunochemical assay, in which an antibody preparation, raised against a mixture of the HCPs, is used to selectively detect the total level of HCPs in the product. DNA can be deterrnined using a labeled mixture, or probe, of complimentary DNA from the host cell. [Pg.198]

The antiviral mechanism of action of acyclovir has been reviewed (72). Acyclovir is converted to the monophosphate in herpes vims-infected cells (but only to a limited extent in uninfected cells) by viral-induced thymidine kinase. It is then further phosphorylated by host cell guanosine monophosphate (GMP) kinase to acyclovir diphosphate [66341 -17-1], which in turn is phosphorylated to the triphosphate by unidentified cellular en2ymes. Acyclovir triphosphate [66341 -18-2] inhibits HSV-1 viral DNA polymerase but not cellular DNA polymerase. As a result, acyclovir is 300 to 3000 times more toxic to herpes vimses in an HSV-infected cell than to the cell itself. Studies have shown that a once-daily dose of acyclovir is effective in prevention of recurrent HSV-2 genital herpes (1). HCMV, on the other hand, is relatively uninhibited by acyclovir. [Pg.308]

A.ntibiotic is an organic chemical substance produced by microorganisms that has the capacity in low concentration to selectively destroy or inhibit the growth of other microorganisms without injuring the host cells. It may be adrninistered systemicaHy and be an antimicrobial chemotherapeutic agent. [Pg.121]

The major stmctural feature of the HAz chain (blue in Figure 5.20) is a hairpin loop of two a helices packed together. The second a helix is 50 amino acids long and reaches back 76 A toward the membrane. At the bottom of the stem there is a i sheet of five antiparallel strands. The central i strand is from HAi, and this is flanked on both sides by hairpin loops from HAz. About 20 residues at the amino terminal end of HAz are associated with the activity by which the vims penetrates the host cell membrane to initiate infection. This region, which is quite hydrophobic, is called the fusion peptide. [Pg.79]

In addition to binding to sialic acid residues of the carbohydrate side chains of cellular proteins that the virus exploits as receptors, hemagglutinin has a second function in the infection of host cells. Viruses, bound to the plasma membrane via their membrane receptors, are taken into the cells by endocytosis. Proton pumps in the membrane of endocytic vesicles that now contain the bound viruses cause an accumulation of protons and a consequent lowering of the pH inside the vesicles. The acidic pH (below pH 6) allows hemagglutinin to fulfill its second role, namely, to act as a membrane fusogen by inducing the fusion of the viral envelope membrane with the membrane of the endosome. This expels the viral RNA into the cytoplasm, where it can begin to replicate. [Pg.80]

In this chapter we will examine the construction principles of spherical viruses, the structures of individual subunits and the host cell binding properties of the surface of one of the picornaviruses, the common cold virus. [Pg.327]

Rossmann suggested that the canyons form the binding site for the rhi-novirus receptor on the surface of the host cells. The receptor for the major group of rhinoviruses is an adhesion protein known as lCAM-1. Cryoelectron microscopic studies have since shown that ICAM-1 indeed binds at the canyon site. Such electron micrographs of single virus particles have a low resolution and details are not visible. However, it is possible to model components, whose structure is known to high resolution, into the electron microscope pictures and in this way obtain rather detailed information, an approach pioneered in studies of muscle proteins as described in Chapter 14. [Pg.338]

Picornaviruses construct their shells from 60 copies each of three different polypeptide chains. These 180 subunits are arranged within the shell in a manner very similar to the 180 identical subunits of bushy stunt virus. In some picornaviruses there are protrusions around the fivefold axes, which are surrounded by deep "canyons." In rhinoviruses, the canyons form the virus s attachment site for protein receptors on the surface of the host cells, and they are adjacent to cavities that bind antiviral drugs. [Pg.344]

Bacteriophage- Virus that infects bacteria, often with destruction or lysis of the host cell. [Pg.606]

FIGURE 1.25 The virus life cycle. Viruses are mobile bits of genetic iuformatiou encapsulated in a protein coat. The genetic material can be either DNA or RNA. Once this genetic material gains entry to its host cell, it takes over the host machinery for macromolecular synthesis and subverts it to the synthesis of viral-specific nucleic acids and proteins. These virus components are then assembled into mature virus particles that are released from the cell. Often, this parasitic cycle of virus infection leads to cell death and disease. [Pg.31]

Colicins are pore-forming proteins, produced by certain strains of E. coli, that kill or inhibit the growth of other, competing bacteria and even other strains of E. coli (a process known as allelopathy). Channel-forming colicins are released as soluble monomers. Upon encountering a host cell, the colicin molecule traverses the bacterial outer membrane and periplasm, then inserts itself... [Pg.315]

Expression vectors are engineered so that any cloned insert can be transcribed into RNA, and, in many instances, even translated into protein. cDNA expression libraries can be constructed in specially designed vectors derived from either plasmids or bacteriophage A. Proteins encoded by the various cDNA clones within such expression libraries can be synthesized in the host cells, and if suitable assays are available to identify a particular protein, its corresponding cDNA clone can be identified and isolated. Expression vectors designed for RNA expression or protein expression, or both, are available. [Pg.413]

Viral infections continue to be significant causes of morbidity and mortality and at the same time continue to be resistant to treatment by small molecules. Avridine (6) is an antiviral compound which has shown some activity in a variety of animal tests apparently based upon its ability to stimulate a number of cells to produce the high molecular weight endogenous antiviral substance interferon. Thus, the compound is believed to operate indirectly by stimulating the body s own natural defenses against viral penetration into host cells. Avridine is synthesized by... [Pg.1]


See other pages where Host cell is mentioned: [Pg.15]    [Pg.1050]    [Pg.192]    [Pg.206]    [Pg.360]    [Pg.122]    [Pg.302]    [Pg.302]    [Pg.303]    [Pg.309]    [Pg.310]    [Pg.229]    [Pg.285]    [Pg.2132]    [Pg.70]    [Pg.325]    [Pg.326]    [Pg.333]    [Pg.282]    [Pg.1050]    [Pg.30]    [Pg.30]    [Pg.31]    [Pg.315]    [Pg.316]    [Pg.396]    [Pg.396]    [Pg.403]    [Pg.403]    [Pg.420]    [Pg.421]    [Pg.421]    [Pg.229]    [Pg.116]   
See also in sourсe #XX -- [ Pg.197 ]

See also in sourсe #XX -- [ Pg.90 ]




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Bacterial agent host cells

Envelope, viral fusion with host cell membrane

Graft-versus-host disease after hematopoietic cell transplantation

Guest-host cells

Hematopoietic stem cell transplantation graft-versus-host disease

Host Cell Engineering

Host Cell Genomes Become Intimate

Host Cell Proteins downstream processing

Host Cell RNA Synthesis

Host Cell Susceptibility

Host Cell and Environmental Factors

Host Cell-Specific Interactions

Host Organisms Mammalian Cells

Host cell delayed

Host cell early

Host cell genomic mRNAs

Host cell inhibition

Host cell lines

Host cell mechanism

Host cell penetration inhibitors

Host cell protein, HCP

Host cell proteins

Host cell replication

Host cell togavirus

Host cells identifying

Host cells large-scale cultivation

Host cells viral interactions

Host cells virus multiplication

Host-cell protein impurity

Host-cell protein synthesis

Host-cell proteins biopharmaceutical

Host-cell proteins process-related impurities

Mammalian cells, cloning host

Polioviral Mediator of Host Cell Shut-off

Reovirus Effects on Host Cell DNA Synthesis

Residual host cell proteins

Stem cells graft-versus-host disease

Virions release from host cell

Virus-host cell interactions

Viruses, host cell protein synthesis affected

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