Rate of oxygen consumption during embryonic development of great ramshorn <Emphasis Type="Italic">Planorbarius corneus</Emphasis> (Gastropoda)

Energy metabolism is studied in great ramshorn Planorbarius corneus during embryonic development. It is shown that the rate of oxygen consumption is constantly increasing in the process of embryogenesis. The respiration intensity (rate of the oxygen consumption per unit of the embryo volume) initially increases and then slowly decreases until eclosion. At the early stages of development until the early trochophore stage, the embryo is not growing, and, thus, the change in the rate of oxygen consumption during this period is not associated with the change of the embryo volume. Reduction in the intensity of respiration begins simultaneously with the beginning of the growth of the embryo at the stage of the middle trochophore. Starting from the middle trochophore and until eclosion, an association between oxygen consumption rate and volume of the embryo can be described with an allometric equation with exponential coefficient equal to approximately 0.23.     

<Emphasis Type="Italic">Constitutive Expressor of Pathogenesis-Related Genes5</Emphasis>affects cell wall biogenesis and trichome development

Background  

The Arabidopsis thaliana CONSTITUTIVE EXPRESSOR OF PATHOGENESIS-RELATED GENES5 (CPR5) gene has been previously implicated in disease resistance, cell proliferation, cell death, and sugar sensing, and encodes a putative membrane protein of unknown biochemical function. Trichome development is also affected in cpr5 plants, which have leaf trichomes that are reduced in size and branch number.     

Morphometry of hepatocyte mitochondrial apparatus in normal and cirrhotic rat liver

Morphometric electron microscopy study of the hepatocyte mitochondrial apparatus and morphofunctional analysis of the degree of pathological alterations were carried out on the liver of rats with CCL4-cirrhosis (experimental group). Chronic poisoning of rats with CCL4 for 6 months led to a 4.2-fold increase in proportion of connective tissue and to a decrease in the number of hepatocytes in the liver by 21.8 %. Dry mass and ploidy of hepatocytes in the cirrhotis liver rose as compared with norm by 20.6 and 9.3%, respectively. Activities of alanine and aspartate aminotransferases in blood of rats of experimental group exceeded normal ones 2.0 and 1.4 times, respectively. Concentration of total bilirubin in blood of the cirrhotic animals increased 1.7 times, while concentration of total protein decreased by 22%. Concentration of diene conjugates in the liver of rats of experimental group increased 2.1 times as compared with normal one, while the level of malonic dialdehyde - by 34%. Activities of superoxide dismutase and catalase in the cirrhotic liver were lower than in the normal liver were lower than in the normal liver by 16 and 23 %, respectively. Morphometry of the hepatocyte mitochondrial apparatus has shown that in spite of an increase in the voluminous density of mitochondria in hepatocytes of the cirrhotic liver (by 28 %), concentration of internal mitochondrial membranes in the cells was reduced almost 1.5 times, while the total length of internal membrane in a single mitochondrion was reduced about twice as compared with norm. Thus, despite compensation of the partial loss of hepatocytes because of their polyploidization and hypertrophy, the specific synthetic activity of cells in the case of cirrhosis is decreased due to deterioration of the antioxidant system and electron transport chain of the mitochondrial apparatus.     

Neuronal replacement from endogenous precursors in the adult brain after stroke

In the adult brain, new neurons are continuously generated in the subventricular zone and dentate gyrus, but it is unknown whether these neurons can replace those lost following damage or disease. Here we show that stroke, caused by transient middle cerebral artery occlusion in adult rats, leads to a marked increase of cell proliferation in the subventricular zone. Stroke-generated new neurons, as well as neuroblasts probably already formed before the insult, migrate into the severely damaged area of the striatum, where they express markers of developing and mature, striatal medium-sized spiny neurons. Thus, stroke induces differentiation of new neurons into the phenotype of most of the neurons destroyed by the ischemic lesion. Here we show that the adult brain has the capacity for self-repair after insults causing extensive neuronal death. If the new neurons are functional and their formation can be stimulated, a novel therapeutic strategy might be developed for stroke in humans.     

The Arabidopsis TUBULIN-FOLDING COFACTOR A gene is involved in the control of the alpha/beta-tubulin monomer balance

The control of the stoichiometric balance of alpha- and beta-tubulin is important during microtubule biogenesis. This process involves several tubulin-folding cofactors (TFCs), of which only TFC A is not essential in mammalian in vitro systems or in vivo in yeast. Here, we show that the TFC A gene is important in vivo in plants. The Arabidopsis gene KIESEL (KIS) shows sequence similarity to the TFC A gene. Expression of the mouse TFC A gene under the control of the 35S promoter rescues the kis mutation, indicating that KIS is the Arabidopsis ortholog of TFC A. kis plants exhibit a range of defects similar to the phenotypes associated with impaired microtubule function: plants are reduced in size and show meiotic defects, cell division is impaired, and trichomes are bulged and less branched. Microtubule density was indistinguishable from that of the wild type, but microtubule organization was affected in trichomes and hypocotyl cells of dark-grown kis plants. The kis phenotype was rescued by overexpression of an alpha-tubulin, indicating that KIS is involved in the control of the correct balance of alpha- and beta-tubulin monomers.     

Functional analysis of the tubulin-folding cofactor C in Arabidopsis thaliana

The biogenesis of microtubules comprises several steps, including the correct folding of alpha- and beta-tubulin and heterodimer formation. In vitro studies and the genetic analysis in yeast revealed that, after translation, alpha- and beta-tubulin are processed by several chaperonins and microtubule-folding cofactors (TFCs) to produce assembly-competent alpha-/beta-tubulin heterodimers. One of the TFCs, TFC-C, does not exist in yeast, and a potential function of TFC-C is thus based only on the biochemical analysis. In this study and in a very recently published study by Steinborn and coworkers, the analysis of the Arabidopsis porcino (por) mutant has shown that TFC-C is important for microtubule function in vivo. The predicted POR protein shares weak amino acid similarity with the human TFC-C (hTFC-C). Our finding that hTFC-C under the control of the ubiquitously expressed 35S promoter can rescue the por mutant phenotype shows that the POR gene encodes the Arabidopsis ortholog of hTFC-C. The analysis of plants carrying a GFP:POR fusion construct showed that POR protein is localized in the cytoplasm and is not associated with microtubules. While, in por mutants, microtubule density was indistinguishable from wild-type, their organization was affected.     

Cell polarity in Arabidopsis trichomes

Arabidopsis leaf trichomes are unicellular hairs that display a highly characteristic cell form that has a fixed orientation with respect to the basal-distal leaf axis. The genetic, molecular and cell biological analysis of trichome morphogenesis reveal that various cellular processes need to be coordinated including regulation of the cell cycle, the cell size and the actin and tubulin cytoskeleton. Here we will focus on what is known about the establishment and maintenance of positional information during trichome formation.