Bacteriophage P1: a new paradigm for control of phage lysis

Xu, Min

01 November 2005

The N-terminal hydrophobic domain of the phage P1 endolysin Lyz was found to facilitate the export of Lyz in a sec-dependent fashion, explaining the ability of Lyz to cause lysis of E.coli in the absence of the P1 holin. The N-terminal domain of Lyz is demonstrated to be both necessary and sufficient not only for export to the membrane but also for release into the periplasm of this endolysin. We propose that this unusual N-terminal domain functions as a "signal arrest- release" (SAR) sequence, which first directs the endolysin to the periplasm in membrane-tethered form and then allows it to be released as a soluble active enzyme in the periplasm. To understand why release from the membrane is required for the physiological expression of the lytic activity of Lyz, we examined the role of its seven cysteine residues in the biogenesis of the active endolysin. The inactive, membrane-tethered and the active, soluble forms of Lyz differ in their pattern of intramolecular disulfide bonding. We conclude that the release of Lyz from the membrane leads to an intramolecular thiol-disulfide bond isomerization causing a dramatic conformational change in the Lyz protein. As a result, an active site cleft that is missing in nascent Lyz is generated in the mature form of the endolysin. Examination of the protein sequences of related bacteriophage endolysins suggests that the presence of an SAR sequence is not unique to Lyz. Studies on holin and antiholin indicated that P1 encodes two holins, LydA and LydC. The antiholin LydB inhibits LydA by binding to it directly on the membrane. All above results demonstrate a new paradigm for control of phage lysis, which is, upon depolarization of the membrane by holin function at a programmed time, endolysin is released from the bilayer leading to the immediate lysis of the host.

Bacteriophage P1

endolysin

holin

antiholin

SAR domain

lysis

Odrůstání kultur na kalamitních holinách horských poloh

Albrechtová, Petra

January 2014

The work deals with the issue of regenerating clearings due to salvage felling at mountain altitudes. Development was monitored on research plots Sokol in the Hrubý Jeseník Mts. (15 plots) and Jizerka in the Jizerské Mts. (15 plots). The aim was to assess the developing young plantations of Norway spruce, European beech, European larch and Carpathian pubescent birch in particular, as well as of sycamore maple, European mountain ash and Silesian willow aged 9 -- 14 years after planting. The assessment was focused primarily on the mensurational variables of the tree species (height, root collar diameter, crown diameter, and their increments). Part of the work was to evaluate the condition of soil environment, nutrition, root system architecture and health of Norway spruce. The best growth was shown by European larch. By contrast, the use of sycamore maple, European mountain ash and Silesian willow did not prove well. The mixing of Norway spruce and European beech was demonstrated to have a significantly favourable influence on the growth of the two species. The root system was confined to humus horizons only and all individuals exhibited deformation into a tangle. Analyses of soil conditions revealed that the effect of liming had persisted even after 20 years and the nutritional condition of the trees pointed to the luxurious supply namely of calcium and magnesium.

Characterization of <em>Lactobacillus</em> bacteriophage LL-H genes and proteins having biotechnological interest

Vasala, A. (Antti)

11 November 1998

Abstract Two regions of the genome of the Lactobacillus delbrueckii subsp. lactis bacteriophage LL-H were characterized, representing 14 % of the phage genome. The first region of 2497 bp contained genes encoding phage structural proteins and the second region of 2498 bp genes involved in lytic functions. The nucleotide sequences of the major capsid protein gene g34, a putative capsid morphogenesis gene (ORF178A), the gene mur encoding phage cell wall hydrolase (lysin), the gene hol (ORF107) encoding the cell membrane permeabilizing phage holin, and six other genes with unknown function were found. Identification of these genes was performed by amino acid sequencing of their encoded proteins (genes g34 and mur), by their physiological effect on E. coli (genes hol and mur), by sequence comparison (genes mur, hol, ORF178A), and by biochemical analysis of their encoded purified protein (gene mur). A promoter for the capsid protein encoding gene cluster was determined by primer extension method. A purification method suitable for large scale processing (cation exchange chromatography by expanded bed adsorption method) was developed for the phage LL-H lysin protein Mur. Purified Mur was biochemically determined as a N-acetylmuramidase, which was effective on cell walls of Lb. delbrueckii, Lb. helveticus, Lb. acidophilus and Pediococcus damnosus. Some biotechnological applications for the lysis genes hol and mur or the purified protein Mur are suggested. Mur digests E. coli cell walls inefficiently, but could still be used for lysis of E. coli. Coexpression of the phage LL-H lysin and holin genes yielded to lysis of the E. coli host only at low culture densities. Therefore, some chemicals were tested for their ability to trigger lysis of E. coli cells overexpressing the phage LL-H gene mur. Thymol was found to mimic the physiological effects of the phage holin in a bacterial growth state independent manner. An efficient lysis method utilizing intracellular production of Mur and triggering the lysis with thymol was developed.

cell wall hydrolase

holin

lactic acid bacteria

lysin

Probing the structural dynamics, conformational change, and topology of pinholin S21, a bacteriophage lytic protein, using electron paramagnetic resonance spectroscopy

Ahammad, Tanbir

24 July 2020

No description available.

Biophysics

Chemistry

Biochemistry

Holin

Pinholin

EPR

DEER

Bacteriophage

Determining the Structural Dynamics and Topology of Canonical HOLIN-S05 Using EPR Spectroscopy

Perera, Rehani Shinuka

11 June 2020

No description available.

Biochemistry

Chemistry

Physical Chemistry

EPR

S105

Canonical Holin

Membrane protein

Protein topology

Protein dynamics