Comparative analysis of the active sites of orthologous endolysins of the Escherichia lytic bacteriophages T5, RB43, and RB49.

The methods of solution NMR, circular dichroism (CD), and differential scanning calorimetry (DSC) were used to study two zinc-containing L-alanyl-D-glutamate peptidases - endolysins of the pseudo T-even myoviruses RB43 and RB49 (EndoRB43 and EndoRB49, respectively), which are orthologous to the EndoT5, which is a zinc-containing L-alanyl-D-glutamate peptidase of the T5 siphovirus. The spatial conservation of the Zn2+-binding sites for the enzymes EndoT5, EndoRB43, and EndoRB49 was established, and the key role of Zn2+ ions in the stabilization of the spatial structures of these three peptidases was confirmed. We are showing here that the binding of the Zn2+ ion in the active center of EndoRB49 peptidase causes conformational rearrangements similar to those observed in the EndoT5 peptidase upon binding of Zn2+ and Ca2+ ions and lead to the formation of a catalytically active form of the enzyme. Therefore, the binding of the Zn2+ ion to the active site of EndoRB49 peptidase is a necessary and sufficient condition for functioning of this protein.

Chronic inhibition of brain glycolysis initiates epileptogenesis.

Metabolic abnormalities found in epileptogenic tissue provide considerable evidence of brain hypometabolism, while major risk factors for acquired epilepsy all share brain hypometabolism as one common outcome, suggesting that a breakdown of brain energy homeostasis may actually precede epileptogenesis. However, a causal link between deficient brain energy metabolism and epilepsy initiation has not been yet established. To address this issue we developed an in vivo model of chronic energy hypometabolism by daily intracerebroventricular (i.c.v.) injection of the nonmetabolizable glucose analog 2-deoxy-D-glucose (2-DG) and also investigated acute effects of 2-DG on the cellular level. In hippocampal slices, acute glycolysis inhibition by 2-DG (by about 35%) led to contrasting effects on the network: a downregulation of excitatory synaptic transmission together with a depolarization of neuronal resting potential and a decreased drive of inhibitory transmission. Therefore, the potential acute effect of 2-DG on network excitability depends on the balance between these opposing pre- and postsynaptic changes. In vivo, we found that chronic 2-DG i.c.v. application (estimated transient inhibition of brain glycolysis under 14%) for a period of 4 weeks induced epileptiform activity in initially healthy male rats. Our results suggest that chronic inhibition of brain energy metabolism, characteristics of the well-established risk factors of acquired epilepsy, and specifically a reduction in glucose utilization (typically observed in epileptic patients) can initiate epileptogenesis. © 2017 Wiley Periodicals, Inc.

Evidence for the residual tertiary structure in the urea-unfolded form of bacteriophage T5 endolysin.

Using high-resolution NMR spectroscopy, we studied peculiarities of the unfolding process of the bacteriophage T5 endolysin (EndoT5) by strong denaturants. It was shown that in the absence of zinc ions this protein is mostly unfolded in the solution of 8 M urea or 6 M guanidine hydrochloride. However, in the presence of zinc ions EndoT5 unfolding can be achieved only in acidic solutions (at pH < 4.0), whereas at pH > 4.0 NMR spectra of the metal-bound protein (Zn2+-Ca2+-EndoT5 or Zn2+-EndoT5 complexes) exhibit a few chemical shifts characteristic of the native or native-like proteins. Our data, including the pH-titration curve with the pK of ~5, suggested involvement of the zinc-binding histidines in the stabilization of this protein. Up-field signals that appear in the NMR spectra of apo-EndoT5 in the presence of high concentrations of strong denaturants are probably derived from the amino acid residues included in the formation of structured hydrophobic cluster, which likely corresponds to the 81-93 region of EndoT5 and contains some residual tertiary structure. It is possible also that this hydrophobic fragment serves as a foundation for the formation of structured cluster in the unfolded state.

Looking at microbial metabolism by high-resolution (2)H-NMR spectroscopy.

We analyzed the applicability of high-resolution (2)H-HMR spectroscopy for the analysis of microbe metabolism in samples of mitochondrion isolated from rat liver and from aqueous extracts of homogenates of rat liver and other organs and tissues in the presence of high D2O contents. Such analysis is possible due to the fast microbe adaptation to life in the heavy water. It is also shown that some enzymatic processes typical for the intact cells are preserved in the homogenized tissue preparations. The microbial and cellular metabolic processes can be differentiated via the strategic use of cell poisons and antibiotics.