Browsing by Subject "Bakteriophage M13"
Now showing 1 - 2 of 2
- Results Per Page
- Sort Options
Publication Biogenese und Virusassembly des filamentösen Coliphagen M13(2012) Ploß, Martin; Kuhn, AndreasTaxonomically, the bacteriophage M13 is assigned to the single-stranded DNA phage and belongs to the family of Inoviridae. For propagation the Gram-negative bacteria Escherichia coli with F-pili is required. The host cell is not lysed by the phage. New findings about the M13 phage biogenesis are presented here within four essential areas of the M13 phage cycle concerning the sections infection, assembly, and phage secretion. Phage adsorption experiments in which the host bacterium E. coli K38 was infected by M13 phage showed that the phage adsorption to the cells takes place within the first 5 minutes and because of a limitation of F-pili per cell a maximum of 7 phages per cell were found to be adsorbed. The insertion of the phage coat protein gp9 into the cytoplasmic membrane of the host cell was verified by the periplasmic location of antigenic epitopes introduced into the N-terminal domain of gp9. The membrane insertion of gp9 was found to depend on the host protein YidC. Plasmid-encoded gp9 exhibiting antigenic epitopes at the N-terminal domain did not interfere with the assembly of new progeny phage. Therefore, the development of a phage display system with gp9 by introducing short peptide sequences (17 ? 36 amino acids) is feasible. After overexpression of gp1/11 assembly complexes in E. coli and size exclusion chromatography, respectively, the complex was characterized and a molecular weight of ~ 300 kDa was assigned. Examinations of the purified gp1/11 assembly complexes by transmission electron microscopy (TEM) revealed ring-like structures with ~ 7 ? 8 nm in inner diameter and ~ 11 ? 12 nm in outer diameter. The investigation of M13 wild-type infection showed that the secretion of new progeny phage starts after a short lag period (eclipse). An infected E. coli cell secreted upto 925 progeny in a time period of 115 minutes which corresponds to an average of 7 secreted phages per minute. The generation time of the infected E. coli K38 cells rose from 24 minutes to 48 minutes. Experiments were carried out with genetically manipulated phages which were hindered to synthesize the major coat protein gp8 in the host cell by a nonsense mutation in the phage genome. Therefore, phage replication was only observed in host cells bearing plasmid encoding gene 8. Since the quantity of the protein was limited the lag period (eclipse) was extended to 12 minutes and the efficiency of phage secretion was decreased to about 2 phages per minute. The M13 phage secretion from infected E. coli cells was visualized by atomic force microscopy (AFM). The identity of the phage was verified by labeling with protein-A conjugated gold and transmission electron microscopy (TEM). The secretion of M13 progeny was first observed at the cell poles of E. coli and then spreaded within 4 minutes along the cell surface. After 16 minutes the secretion was observed over the entire cell surface.Publication Die Insertion des „minor coat“ Proteins G3P des Bakteriophagen M13 in die innere E. coli Membran benötigt die Insertase YidC und die Translokase SecYEG.(2021) Kleinbeck, Farina; Kuhn, AndreasThe membrane of every cell forms a spacial limitation for this smallest unit of a life form. Such a very simple unicellular life form is also the Gram-negative bacterium Escherichia coli (E. coli) and is therefore a valid model organism for a living cell. Due to the inner membrane the cellular components are held together in close proximity and are separated from the extracellular environment. Most substrates cannot pass the lipid bilayer, which forms the membrane, so an import and export system had to be developed to accomplish this. For these import and export systems, very complex, polytopic transmembrane protein complexes are needed. Examples are ion channels, ion pumps or large complexes through which energy production, secretion of toxins and the transfer of nutrients are catalysed. Moreover, proteins with functions in the periplasm or outer membrane must also travel from their site of synthesis in the cytoplasm to their destination. For these different processes proteins must be inserted into or translocated across the inner membrane. Of the total proteome in prokaryotes approximately 25 to 30% is either inserted into or secreted across the inner membrane. This work identified several components required for the insertion of the "minor coat" protein G3P of M13 bacteriophage. This protein is important for the assembly of the phage particle that occurs in the inner membrane. The outermost C-terminus of G3P is anchored in the inner membrane via a single transmembrane domain, while the bulk of the approximately 42 kDa protein is located in the periplasm. Using an N-terminal cleavable signal peptide, the major portion of G3P is translocated into the periplasm via SecYEG with the help of SecA and the membrane potential. Targeting, on the other hand, could not be clearly assigned to one of the known post- or co-translational pathways. Although contact via disulfide crosslink studies to Ffh, the protein component of the ribonucleoprotein SRP, was observed via stalled ribosome nascent chains (RNCs), insertion into the membrane in vivo was independent of Ffh. Even when the interaction between SecY and FtsY, the receptor for SRP at the membrane, was impaired, G3P was inserted via SecYEG. Although the chaperone SecB was able to bind to G3P in vitro, G3P inserted independently of SecB in vivo. For membrane incorporation of G3P, it was shown that YidC is required in vivo in addition to SecYEG. Disulphide crosslink studies demonstrated that G3P first contacts the plug domain TM2b and lateral gate (TM2a and TM7) via the signal peptide of G3P, and finally the C-terminal transmembrane domain of G3P contacts YidC via TM3 and TM5 of the hydrophilic slide. Based on these contact sites, a possible insertion model was confirmed, with SecY and YidC mediating defined steps in the insertion process, providing new insights into this largely unknown process.