Autoregulation of the biosynthesis of the CcpA-like protein, PepR1, in Lactobacillus delbrueckii subsp bulgaricus

PepR1 from Lactobacillus delbrueckii subsp bulgaricus (Lb. bulgaricus) is involved in biosynthesis regulation of the prolidase PepQ. In this paper, we demonstrated that Lb. bulgaricus PepR1 biosynthesis is not constitutive like those of several bacteria but is auto-regulated and depends on the glucose concentration of the culture medium. We propose a model for PepQ regulation by PepR1.     

Insights into protein biosynthesis from structures of bacterial ribosomes

Understanding the structural basis of protein biosynthesis on the ribosome remains a challenging problem for cryo-electron microscopy and X-ray crystallography. Recent high-resolution structures of the Escherichia coli 70S ribosome without ligands, and of the Thermus thermophilus and E. coli 70S ribosomes with bound mRNA and tRNAs, reveal many new features of ribosome dynamics and ribosome-ligand interactions. In addition, the first high-resolution structures of the L7/L12 stalk of the ribosome, responsible for translation factor binding and GTPase activation, reveal the structural basis of the high degree of flexibility in this region of the ribosome. These structures provide groundbreaking insights into the mechanism of protein synthesis at the level of ribosome architecture, ligand binding and ribosome dynamics.     

Generation of chemically engineered ribosomes for atomic mutagenesis studies on protein biosynthesis

The protocol describes the site-specific chemical modification of 23S rRNA of Thermus aquaticus ribosomes. The centerpiece of this 'atomic mutagenesis' approach is the site-specific incorporation of non-natural nucleoside analogs into 23S rRNA in the context of the entire 70S ribosome. This technique exhaustively makes use of the available crystallographic structures of the ribosome for designing detailed biochemical experiments aiming at unraveling molecular insights of ribosomal functions. The generation of chemically engineered ribosomes carrying a particular non-natural 23S rRNA residue at the site of interest, a procedure that typically takes less than 2 d, allows the study of translation at the molecular level and goes far beyond the limits of standard mutagenesis approaches. This methodology, in combination with the presented tests for ribosomal functions adapted to chemically engineered ribosomes, allows unprecedented molecular insight into the mechanisms of protein biosynthesis.     

Autoregulation of stress response in microorganisms

Examples are considered of the involvement of low-molecular-weight autoregulators in the development of resistance of proliferating microbial cultures to unfavorable environmental impacts of various intensity, including impacts programmed to occur in the developmental cycle ("new medium stress," starvation stress) and nonprogrammed impacts. It was shown that extracellular adaptation factors control the reversible adhesion of cells in submerged cultures and the processes of cell reactivation in the poststress period and are involved in the stabilization of cellular biopolymers (proteins and DNA) and subcellular structures (membranes); the adaptogens of the phenolic type also act as efficient scavengers of reactive oxygen species. The protective effect of the adaptogenic autoregulators is manifested in the increase of resistance of microbial cells to stressors of various nature and in the preservation of the cell proliferative capacity.     

Autoregulation of stress response in microorganisms

Examples are considered of the involvement of low-molecular-weight autoregulators in the development of resistance of proliferating microbial cultures to unfavorable environmental impacts of various intensity, including impacts programmed to occur in the developmental cycle (“new medium stress,” starvation stress) and nonprogrammed impacts. It was shown that extracellular adaptation factors control the reversible adhesion of cells in submerged cultures and the processes of cell reactivation in the poststress period and are involved in the stabilization of cellular biopolymers (proteins and DNA) and subcellular structures (membranes); the adaptogens of the phenolic type also act as efficient scavengers of reactive oxygen species. The protective effect of the adaptogenic autoregulators is manifested in the increase of resistance of microbial cells to stressors of various nature and in the preservation of the cell proliferative ability.