Similarities and differences in the growth of the heart in situ and in transplants

Growth and ploidy of rat ventricular myocytes were studied during development in situ and in grafts (1 day old rat ventricle transplanted under kidney capsule of syngenic adult animals). Both in situ and in the transplants polyploidization occurred on days 4-14 of postnatal life, and the modal group of myocytes was represented by binucleate diploid (2c x 2) cells. Minor quantities of 4c, 4c x 2, 8c and 2c x 4 myocytes were detected as well. In ventricles of 14 and 28 days old rats and in the transplants of the corresponding age the portion of polyploid myocytes was 90-96% and 32-63% respectively. The intensity of postmitotic myocyte transplants was decreased as compared with in situ development, and cells that exit proliferation cycle did not grow until day 14. The data on thymidine label dilution suggest that diploid myocytes of the transplant can divide two or three times but the majority of labeled diploids divided only once. Labeled 2c x 2 myocytes originated from the first, and less frequently, the second cell generation or resulted from initial acytokinetic mitosis. Mononucleate tetraploids 4c originated from 2c x 2 and mostly from 2c cells. Octaploids were formed after 3d or 4th labeled mitosis. The conclusion about cardiac myocyte polyploidization as an intrinsic developmental program is supported, implying the programming of onset, mode, duration and termination of polyploidization and its prolongation during early postnatal life.(ABSTRACT TRUNCATED AT 250 WORDS)     

Differences in the concentration of erythrocytes and the hematocrit value in the blood in relation to the location of the vessels and the intensity of the blood flow

The experiments in adult rabbits revealed that in the blood flowing in cerebral veins the red cell concentration and hematocrit are much greater than in the veins of hind legs of the same animals. In blood samples taken from the heart these values are higher than in those taken from the hind leg, but usually lower than in blood samples taken from the brain. Under conditions of reduced cerebral blood flow (ischemia) the red cell concentration and hematocrit in the brain vessels decrease significantly as compared to the control conditions. Thus, the red cell distribution in arterial branching sequence is irregular, depending both on the localization of the vascular bed and the blood flow rate in it.     

国际植物基因组组织与计划概况及我国的应对策略

本文简要介绍了植物基因组领域主要的组织和计划,简单分析了国际植物基因组计划的特点和我国存在的问题,并初步提出我国的应对策略。     

Corticotrophic cells in the rostral zone of the pars intermedia and in the adjacent neurohypophysis of the rat and mouse

Summary In the mouse, the rostral zone of the pars intermedia is almost exclusively composed of typical corticotrophic cells. They are located around and even within the neural stalk, at the level of transition between stalk and neural lobe. In the rat, the corticotrophic cells of the rostral zone are found in scattered islets among the MSH producing cells, and also in the neural lobe. In both the rat and mouse, these cells are in direct contact with various types of nerve terminals. Synaptoid contacts with aminergic and neurosecretory nerve fibers are observed. Furthermore they are also closely related to the hypophysial portal vessels. Following adrenalectomy, the cells located in the neurohypophysis always react more intensely than tose in the rostral zone. The functional significance of these corticotrophic cells which are subject to both humoral and neural regulation remains as yet hypothetical. Their participation in neurogenic stress response seems probable.     

Tremor characteristics in the norm and in the diagnosis and treatment of parkinsonism

With the aid of tensotremorography, a voluntary effort was recorded and characteristics of involuntary and voluntary components of the hands' isometrically recorded efforts were studied. The revealed frequency ranges of the oscillations spectral density's changes corroborate existence of two suprasegmental systems of movements control, the systems being related to voluntary control and a current control of the efforts maintaining or preserving a posture. Results of cross-correlation analysis of the hands' efforts maintained under conditions of a visual feedback are demonstrated in norm and in central disorders of the movement control system.     

Structure and function of the genes involved in the biosynthesis of carotenoids in the mucorales

Carotenoids are widely distributed natural pigments which are in an increasing demand by the market, due to their applications in the human food, animal feed, cosmetics, and pharmaceutical industries. Although more than 600 carotenoids have been identified in nature, only a few are industrially important (β-carotene, astaxanthin, lutein or lycopene). To date chemical processes manufacture most of the carotenoid production, but the interest for carotenoids of biological origin is growing since there is an increased public concern over the safety of artificial food colorants. Although much interest and effort has been devoted to the use of biological sources for industrially important carotenoids, only the production of biological β-carotene and astaxanthin has been reported. Among fungi, several Mucorales strains, particularlyBlakeslea trispora, have been used to develop fermentation process for the production of β-carotene on almost competitive cost-price levels. Similarly, the basidiomycetous yeastXanthophyllomyces dendrorhous (the perfect state ofPhaffia rhodozyma), has been proposed as a promising source of astaxanthin. This paper focuses on recent findings on the fungal pathways for carotenoid production, especially the structure and function of the genes involved in the biosynthesis of carotenoids in the Mucorales. An outlook of the possibilities of an increased industrial production of carotenoids, based on metabolic engineering of fungi for carotenoid content and composition, is also discussed.     

Interactions in the Metabolism of Glutamate and the Branched-Chain Amino Acids and Ketoacids in the CNS

Glutamatergic neurotransmission entails a tonic loss of glutamate from nerve endings into the synapse. Replacement of neuronal glutamate is essential in order to avoid depletion of the internal pool. In brain this occurs primarily via the glutamate-glutamine cycle, which invokes astrocytic synthesis of glutamine and hydrolysis of this amino acid via neuronal phosphate-dependent glutaminase. This cycle maintains constancy of internal pools, but it does not provide a mechanism for inevitable losses of glutamate N from brain. Import of glutamine or glutamate from blood does not occur to any appreciable extent. However, the branched-chain amino acids (BCAA) cross the blood–brain barrier swiftly. The brain possesses abundant branched-chain amino acid transaminase activity which replenishes brain glutamate and also generates branched-chain ketoacids. It seems probable that the branched-chain amino acids and ketoacids participate in a “glutamate-BCAA cycle” which involves shuttling of branched-chain amino acids and ketoacids between astrocytes and neurons. This mechanism not only supports the synthesis of glutamate, it also may constitute a mechanism by which high (and potentially toxic) concentrations of glutamate can be avoided by the re-amination of branched-chain ketoacids.