Role of methyl groups in dynamics and evolution of biomolecules

Recent studies have discovered strong differences between the dynamics of nucleic acids (RNA and DNA) and proteins, especially at low hydration and low temperatures. This difference is caused primarily by dynamics of methyl groups that are abundant in proteins, but are absent or very rare in RNA and DNA. In this paper, we present a hypothesis regarding the role of methyl groups as intrinsic plasticizers in proteins and their evolutionary selection to facilitate protein dynamics and activity. We demonstrate the profound effect methyl groups have on protein dynamics relative to nucleic acid dynamics, and note the apparent correlation of methyl group content in protein classes and their need for molecular flexibility. Moreover, we note the fastest methyl groups of some enzymes appear around dynamical centers such as hinges or active sites. Methyl groups are also of tremendous importance from a hydrophobicity/folding/entropy perspective. These significant roles, however, complement our hypothesis rather than preclude the recognition of methyl groups in the dynamics and evolution of biomolecules.     

Effect of a low-frequency magnetic field on systemic arterial pressure in spontaneously hypertensive rats

The effect of low-frequency magnetic field (MF) on systemic blood pressure has been studied in chronic experiments on 21 spontaneously hypertensive rats. The animals' kidney area was exposed to MF (induction value 30T). Direct blood pressure measurements have revealed an antihypertensive effect.     

Lymphocyte-mediated modulation of the functional activity of macrophages by individual antigenic complexes of Trichophyton cells

The capacity of antigenic complexes of the causative agent of zoo- and anthroponotic trichophytosis for inducing the factors, that modify the functional activity of macrophages, in mice and in spleen cell cultures has been studied. These complexes are capable of inducing the T-lymphocyte-mediated suppression and of stimulating the fungicidal activity (and oxygen-dependent metabolism) of phagocytes. The production of fungicidal activity suppressing lymphokines is linked with the presence of alkali-insoluble components of fungal cell walls and cytoplasmic antigens (the latter appear only in interactions of antigens with the lymphocytes of immunized animals) in the above-mentioned complexes.     

Ultrastructural characteristics of the neocortex during rehabilitation from the sequelae of long-term protein-energy deficiency

Electron microscopy of mouse neocortex was carried out during rehabilitation following long-term protein-caloric deficiency. Food rehabilitation led to partial recovery of brain ultrastructure, however, a high neuronal level of secondary lysosoms and lipofuscin bodies was preserved, with the changes in the spine apparatus and synaptic contacts persisting in neuropile. Carnitine addition to food during rehabilitation increased the number of free ribosomes in cortical neurons. A substantial development of granular endoplasmic reticulum was observed. A greater number of spine apparatus cisterns was detected, however, like in conventional rehabilitation, the width of synaptic clefts and postsynaptic densities remained narrower than in control mice.     

Kallikrein as a modulator of serotoninergic and bradykininergic myotropic reactions in the small intestine

The effect of 0.01 U/ml of kallikrein on serotonin and bradykinin contractile action in the isolated intestinal segment has been described. The character of myotropic reactions was shown to change in accordance with the anatomical localization of the intestinal segment. Sensitivity to serotonin and bradykinin increases in duodenum segments and decreases in jejunum and ileum segments. Kallikrein is supposed to serve as a modulator of intestinal serotonin- and bradykininergic myotropic reactions.     

Combinatorial Cysteine Mutagenesis Reveals a Critical Intramonomer Role for Cysteines in Prestin Voltage Sensing

Prestin is a member of the SLC26 family of anion transporters and is responsible for electromotility in outer hair cells, the basis of cochlear amplification in mammals. It is an anion transporting transmembrane protein, possessing nine cysteine residues, which generates voltage-dependent charge movement. We determine the role these cysteine residues play in the voltage sensing capabilities of prestin. Mutations of any single cysteine residue had little or no effect on charge movement. However, using combinatorial substitution mutants, we identified a cysteine residue pair (C415 and either C192 or C196) whose mutation reduced or eliminated charge movement. Furthermore, we show biochemically that surface expression of mutants with markedly reduced functionality can be near normal; however, we identify two monomers of the protein on the surface of the cell, the larger of which correlates with surface charge movement. Because we showed previously by Förster resonance energy transfer that monomer interactions are required for charge movement, we tested whether disulfide interactions were required for dimerization. Using Western blots to detect oligomerization of the protein in which variable numbers of cysteines up to and including all nine cysteine residues were mutated, we show that disulfide bond formation is not essential for dimer formation. Taken together, we believe these data indicate that intramembranous cysteines are constrained, possibly via disulfide bond formation, to ensure structural features of prestin required for normal voltage sensing and mechanical activity.     

Two-Dimensional Nanoscale Structural and Functional Imaging in Individual Collagen Type I Fibrils

The piezoelectric properties of single collagen type I fibrils in fascia were imaged with sub-20 nm spatial resolution using piezoresponse force microscopy. A detailed analysis of the piezoresponse force microscopy signal in controlled tip-fibril geometry revealed shear piezoelectricity parallel to the fibril axis. The direction of the displacement is preserved along the whole fiber length and is independent of the fiber conformation. It is shown that individual fibrils within bundles in skeletal muscle fascia can have opposite polar orientations and are organized into domains, i.e., groups of several fibers having the same polar orientation. We were also able to detect piezoelectric activity of collagen fibrils in the high-frequency range up to 200 kHz, suggesting that the mechanical response time of biomolecules to electrical stimuli can be ∼5 μs.