Thyroid hormones and lipid metabolism

Some major pathways of lipid metabolism are under control of thyroid hormones. Thyroxine changes the lipid composition of different cell membranes. Modification of thyroid hormone metabolism during ontogenesis is one of the reasons of changes in lipid composition and function of cell nuclei and its other structures. Atherosclerosis and obesity may be a result of the thyroid dysfunction and modulation of the cellular lipid metabolism.     

In vitro Phytohormonal Regulation of Fern Gametophytes Growth and Development

Russian Journal of Developmental Biology - Interest in ferns as objects of biotechnological research is determined by the characteristics of their development and reproduction, which is important...     

European checkerspots (Melitaeini: Lepidoptera,Nymphalidae) are not aposematic – the point of view of great tits (Parus major)

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The dynamics of the composition of mtDNA haplotypes of the ancient population of the Altai Mountains from the early bronze age (3rd millennium BC) to the iron age (2nd–1st centuries BC)

The mtDNA polymorphism in representatives of various archaeological cultures of the Developed Bronze Age, Early Scythian, and Hunnish-Sarmatian periods was analyzed (N = 34). It detected the dominance of Western-Eurasian haplotypes (70.6%) in mtDNA samples from the representatives of the ancient population of the Early Bronze Age–Iron Age on the territory of Altai Mountains. Since the 8th to the 7th centuries BC, a sharp increase was revealed in the Eastern Eurasian haplogroups A, D, C, and Z (43.75%) as compared to previous cultures (16.7%). The presence of haplotype 223-242-290-319 of haplogroup A8 in Dolgans, Itelmens, Evens, Koryaks, and Yakuts indicates the possible long-term presence of its carriers in areas inhabited by these populations. The prevalence of western Eurasian haplotypes is observed not only in the Altai Mountains but also in Central Asia (Kazakhstan) and the south of the Krasnoyarsk Krai. All of the three studied samples from the Western Eurasian haplogroups were revealed to contain U, H, T, and HV. The ubiquitous presence of haplotypes of haplogroup H and some haplogroups of cluster U (U5a1, U4, U2e, and K) in the vast territory from the Yenisei River basin to the Atlantic Ocean may indicate the direction of human settlement, which most likely occurred in the Paleolithic Period from Central Asia.     

Polymorphism of <Emphasis Type="Italic">CD209</Emphasis> and <Emphasis Type="Italic">TLR3</Emphasis> genes in populations of North Eurasia

The DC-SIGN (dendritic cell-specific intercellular adhesion molecule (ICAM)-3-grabbing non-integrin) and TLR3 (toll-like receptor 3) proteins are key effectors of the innate immunity and particularly play an important role in the organism’s antiviral defense as pattern-recognition receptors. Previously, we demonstrated that certain genotypes and alleles of single nucleotide polymorphisms (SNPs) rs2287886 (G/A) in the promoter region of the CD209 gene (encoding DC-SIGN) and rs3775291 (G/A, Leu412Phe) in the exon 4 of the TLR3 gene are associated with human predisposition to tick-borne encephalitis in the Russian population. In the present work, the distribution of genotype and allele frequencies for these SNPs was studied in seven populations of North Eurasia, including Caucasians (Russians and Germans (from Altai region)), Central Asian Mongoloids (Altaians, Khakass, Tuvinians, and Shorians), and Arctic Mongoloids (Chukchi). It was found that the CD209 gene rs2287886 SNP A/A genotype and A allele, as well as the TLR3 gene rs3775291 SNP G/G genotype and G allele (the frequencies of which in our previous studies were increased in tick-borne encephalitis patients as compared with the population control (Russian citizens of Novosibirsk)), are preserved with a high frequency in Central Asian Mongoloids (who for a long time regularly came in contact with tick-borne encephalitis virus in places of their habitation). We suggested that predisposition to tick-borne encephalitis in Central Asian Mongoloid populations can be predetermined by a different set of genes and their polymorphisms than in the Russian population.     

Seasonal Variations in the Structure of an Anoxygenic Phototrophic Bacterial Community from the Meromictic Lake Trekhtsvetnoe (Kandalaksha Bay,White Sea)

Microbiology - The community of anoxygenic phototrophic bacteria (APB) from the water column of the meromictic Lake Trekhtsvetnoe (Kandalaksha Bay, White Sea, Russia) was studied in March 2012 and...     

A conserved inhibitory and differential stimulatory action of nucleotides on K(IR)6.0/SUR complexes is essential for excitation-metabolism coupling by K(ATP) channels.

The mechanism by which ubiquitous adenine nucleotide-gated K(IR)6.0(4)/SUR(4) channels link membrane excitability with cellular metabolism is controversial. Is a decreased sensitivity to inhibitory ATP required, or is the Mg-ADP/ATP-dependent stimulatory action of the ATPase, sulfonylurea receptor (SUR), on K(IR) sufficient to elicit a physiologically significant open channel probability? To evaluate the roles of nucleotide inhibition versus stimulation, we compared K(IR)6.1-based K(NDP) channels with K(IR)6.2-based K(ATP) channels and all possible K(IR)6.1/6.2 hybrids. Although K(NDP) channels are thought to be poorly sensitive to inhibitory ATP and to require Mg-nucleotide diphosphates for activity, we demonstrate that, like K(ATP), and hybrid channels, they are inhibited with an IC(50(ATP)) 100-fold lower than [ATP](i). K(IR)6.1 is, however, more efficiently stimulated by SUR than K(IR)6.2, thus providing a mechanism for differential nucleotide regulation, in addition to the known differential interactions of Mg-nucleotides with SUR isoforms. The on-cell and spontaneous activities of K(NDP), K(ATP), and hybrid channels identified in native cells, are different; thus, their similar IC(50(ATP)) values argue the regulatory "beta" SUR subunits play a preeminent role in coupling excitation to metabolism and pose questions about the physiologic significance of models, which assume the ATP insensitivity of open K(IR)s.     

Two regions of sulfonylurea receptor specify the spontaneous bursting and ATP inhibition of KATP channel isoforms

KATP channels are heteromultimers of KIR6.2 and a sulfonylurea receptor, SUR, an ATP binding cassette (ABC) protein with several isoforms. KIR6.2 forms a channel pore whose spontaneous activity and ATP sensitivity are modulated by the receptor via an unknown interaction(s). Side by side comparison of single-channel kinetics and steady-state ATP inhibition of human beta-cell, SUR1/KIR6.2, versus cardiac, SUR2A/KIR6.2 channels demonstrate that the latter have a greater mean burst duration and open probability in the absence of nucleotides and approximately 4-fold higher IC50(ATP). We have used matched chimeras of SUR1 and SUR2A to show that the kinetics, which determine the maximal open probability (Pomax), and the ATP sensitivity are functionally separable and to identify the two segments of SUR responsible for these isoform differences. A region within the first five transmembrane domains specifies the interburst kinetics, whereas a C-terminal segment determines the sensitivity to inhibitory ATP. The separable effects of SUR on ATP inhibition and channel kinetics implies that the cytoplasmic C terminus of SUR either directly modulates the affinity of a weak ATP binding site on the inward rectifier or affects linkage between the binding site and the gate. This is the first identification of parts of an ABC protein that interact with an ion channel subunit to modulate the spontaneous activity and ATP sensitivity of the heteromeric channel.     

The N-terminus of KIR6.2 limits spontaneous bursting and modulates the ATP-inhibition of KATP channels

KATP channels are heteromultimers of a sulfonylurea receptor SUR and KIR6.2 with the inward rectifier forming the pore which is regulated by SUR. We have examined the contributions of the cytoplasmic domains of KIR6.2 to control of spontaneous bursting and ATP-inhibition in human SUR1/KIR6.2 KATP channels. Truncations of the N-terminus of KIR6.2 nearly eliminate transitions to interburst closed states without affecting the open or intraburst closed states, thus producing SUR1/DeltaNKIR6.2 channels with an extremely high open probability in the absence of nucleotides. These channels have a decrease apparent ATP-sensitivity which is consistent with the involvement of the N-terminus in a transition to an interburst closed state that preferentially binds inhibitory ATP. Mutations in both the N- and proximal C-termini of KIR6.2 can synergistically attenuate the ATP-inhibition. The results identify the N-terminus of KIR6.2 as a determinant of the interburst kinetics of KATP channels and suggest that the two cytoplasmic domains of KIR6.2 participate in ATP-inhibitory gating through distinct mechanisms.