Molecular genetic basis of tapetoretinal degeneration

The review considers tapetoretinal degeneration (TD), a severe incurable disease occurring at a frequency of 1 per 3500–5000 people. TD is most commonly caused by mutations of the genes for rhodopsin (RHO), peripherin (RDS), and retinol acetyltransferase (RPE65). Since pigmentary degeneration strongly correlates with mutations of these genes, it is possible to develop approaches to DNA diagnosis of hereditary retinal dystrophies, which are common in practical ophthalmology, and to exactly, rather than probabilistically, evaluate its risk. Molecular analysis of the TD-associated changes in the genes that ensure the proper function of photoreceptors and the retinal pigment epithelium will provide for a better understanding of the physiological and pathological processes occurring in the retina, as well as for the development of pathogenetic therapy in TD.     

Stem Cells: Properties and Prospective Medical Applications

The properties of some stem cells (SCs) that are most interesting in terms of their implications for medicine (embryonic, hematopoietic, and mesenchymal SCs) are considered. SCs are undifferentiated cells capable of both self-maintenance and differentiation into specialized cells. According to their origin, SCs are divided into embryonic and somatic ones. The former can be maintained in vitro for an infinitely long time and can differentiate into all cells of adult organisms. The latter have a limited capacity for differentiation and, probably, a limited proliferative potential. The plasticity of somatic SCs, i.e., their capacity for context-dependent differentiation into unrelated cell types, is of considerable therapeutic importance, although some researchers doubt this capacity. It is assumed that most types of SCs differentiate by the stepwise hierarchical maturation mechanism, one of the steps being rapidly proliferating progenitor cells. The use of SCs in medicine is currently at the stage of preclinical trials. Although embryonic SCs are promising for medicine, there are serious limitations of their use in therapy in the near future. However, the first clinical trials have demonstrated that the approaches involving autotransplantation of hematopoietic and mesenchymal SCs are effective for treating ischemia of extremities and the consequences of myocardial infarction. Obviously, the use of SCs in medicine promises dramatic progress in treating many severe diseases.     

Molecular pilot study on peripheral populations of Kenyan greenbul in an afromontane fragmented forest

We provide a molecular study on peripheral populations of three closely related species of African forest‐dependent greenbuls: the generalist Eurillas latirostris and the specialists Phyllastrephus cabanisi and Arizelocichla nigriceps. These species co‐occur within their range limits in the Kenyan Afromontane forest, Cherangani Hills. This forest has experienced drastic deforestation, which began about 50 years ago, that is causing habitat fragmentation. The aims of this study, using the analyses of molecular tools, are twofold: (i) to provide evidence that functional traits (i.e., ecological attributes) may shape different genetic structure in peripheral populations and (ii) to identify the possible effects of forest fragmentation. Blood and plucked feathers were sampled from a total of 124 birds analysed using two molecular approaches: (i) sequencing of cytochrome b mtDNA and (ii) genotyping nuclear DNA at eight microsatellite loci. Molecular diversity indices, minimum spanning network and mismatch distribution analysis of mtDNA results indicated that the peripheral populations showed different demographic trends: a highly variable and bimodal pattern in forest specialist P. cabanisi, a less variable and unimodal pattern in forest generalist E. latirostris and in the montane specialist A. nigriceps. Although this is a pilot study on the Cherangani forest fragmentation, the nuclear results may not exclude the hypothesis of reduced connectivity in all forest‐dependent greenbuls.     

The treatment of isolated genera

Problems presented by genera, or small groups of genera, which have been given family rank are reviewed, and the genera are divided into a number of categories according to the closeness of their affinity to other genera or families. Satellite genera that stand in close relation to families should be united with them. Binary families, that have been divided into two (or more) related families, should be re–united. Families connected by linking genera, should, logically, be united but practical considerations usually prevent this. Clusters of diverse but more or less distantly related genera present unusual problems, being treated either as several, often monogeneric families or as a loosely structured family. Truly isolated genera must be given family and often ordinal rank.     

Sequence-specific resonance assignment and secondary structure of (1–71) bacterioopsin

Summary The conformation of chymotryptic fragment C2 of bacteriorhodopsin (residues 1–71) was studied by 2D¹H NMR. The fragment was solubilized in a mixture of chloroform/methanol (11), 0.1 M LiClO₄. Most of the resonances in¹H NMR spectra of fragment C2 were assigned using phase-sensitive DQF-COSY, TOCSY, and NOESY techniques. To simplify the assignment procedure for overlapping regions of NMR spectra, an analog of fragment C2 with leucines deuterated in -positions was used. Deuterium exchange rates for amide protons were measured in a series of TOCSY spectra. Two right-handed -helical regions Pro⁸-Lys³⁰ and Lys⁴¹-Leu⁶² were identified on the basis of NOE connectivities and deuterium exchange rates. The N-terminal part of the fragment (Ala.²-Gly⁶) adopts the helical conformation stabilized by 3 hydrogen bonds.     

Modified low density lipoproteins decrease the activity and expression of lysosomal acid lipase in human endothelial and smooth muscle cells

Lysosomal acid lipase (LAL), the only lysosomal enzyme involved in the hydrolysis of LDL-cholesteryl esters, is a key regulator of cellular cholesterol and fatty acid homeostasis and its deficiency contributes to the pathophysiology of various diseases. In this study, we questioned whether oxidized or glycated LDL, a common occurrence in atherosclerosis and diabetes, affect the activity and expression of LAL in vascular endothelial cells (EC) and smooth muscle cells (SMC). LAL activity and expression were assayed in cultured human EC and SMC exposed to oxidized LDL (oxLDL), (±)9-hydroxyoctadecadienoic acid-cholesteryl ester (HODE), glycated LDL (gLDL), or native LDL (nLDL) as control, in the presence or absence of LXR or PPAR-gamma agonists. We found that LAL activity and expression were significantly down regulated by oxLDL and HODE in EC, and by gLDL in SMC. The LXR agonist T0901317 reversed the decreased LAL expression in modified LDL- or HODE-exposed EC (P < 0.001) and in gLDL-exposed SMC, whereas PPAR-gamma agonist rosiglitazone induced a low effect only in EC. In conclusion, modified LDL down regulates LAL expression in human EC and SMC by a process involving the LXR signaling pathway. This is the first demonstration that modified LDL modulate LAL expression, in a cell specific manner.     

Molecular-genetic basis of tapetoretinal degeneration

The review on problem tapetoretinal degeneration (TD) which represents serious enough and incurable disease revealed with frequency 1 : 3500-5000 in general population is presented. The most often reason of occurrence TD are mutations in RHO, RDS and RPE65 genes. The precise interrelation of pigmentary degenerations of a retina and mutations in genes RHO, RDS and RPE65 will allow to develop approaches of DNA--diagnostics of hereditary dystrophies of a retina so frequently meeting in clinical practice of the ordinary ophthalmologist, and also to pass at medical genetics consultation from probability estimations of risk of disease to unequivocal. Also the molecular analysis of genes changes in the providing correct functioning of photoreceptors and pigmentary epithelium of a retina and determining pathological changes at TD, will allow to approach to understanding of the physiological and pathological processes proceeding in a retina and by that will serve becoming and development pathogenic to caused therapy TD closer.     

The role of macrophages in the tissues regeneration stimulated by the biomaterials

Allogenic grafted tissues are subjected to biodegradation and replaced by the regenerate. To minimize the immune response and improve the rebuilding of tissues there was developed a technology to treat tissues with a cells elimination and dosed out extraction of proteoglycanes (Alloplant^®). With aim to clarify the role of macrophages in the tissues regeneration resulting implantation the biomaterials 112 rats were injected the allogenic and xenogenic (rabbits) pulverized biomaterials in the form of suspension. Injections were performed subcutaneously into the animals back by the base of the tail. The control group (14 rats) were injected a physiologic saline. Animals were killed by ether inhalation on day 2, 4, 7, 14, 30, 90 and 180 and tissue sections were studied by light and electron microscopy. The study showed the key role of the macrophages in resorption of the allogenic biomaterial and formation of the newly-formed tissue. Implantation of the biomaterial induced activity a great number of the mature macrophages, which completely lysed and resorbed the biomaterial particles. Expression TNF was significantly higher whereas expression TGF-1 was significantly lower. With xenogenic biomaterial implantation there were less macrophages, their activity was restricted. Macrophages containing large vacuoles with an active endo- and exocytosis were revealed in the allogenic biomaterial implantation and were named matrix-forming macrophages. We may suppose that these macrophages synthesize (or re-synthesize) proteoglycan component of the newly-formed collagen fibers. There was put forward a hypothesis about the two component mechanism of the collagen fibers formation.