Thromboxane and Prostacyclin Levels in Fetal Rabbit Brain and Placenta After Intrauterine Partial Ischemic Episodes

The appearance of arachidonic acid (AA) oxidation products in fetal rabbit brain and placenta under normal or partial short-term ischemic episodes induced by placental blood vessel restriction was examined. Intracerebral administration of [3H]AA into close-to-term rabbit fetuses gave rise to radioactively labeled prostaglandin (PG) E2, thromboxane B2, and 6-keto-PGF1 alpha metabolites as detected by HPLC analysis. A significant increase of 20-30% of [3H]AA precursor into eicosanoids was detected in brain of fetuses after 2-h restriction. The thromboxane B2 and 6-keto-PGF1 alpha levels were determined by radioimmunoassay technique over a period of 48 h following ischemic episodes. Thromboxane B2 content in affected animals was higher by five- and twofold at 3 h over control fetal brain and placental tissue values, respectively, and remained significantly higher for 24 h. 6-Keto-PGF1 alpha levels reached a peak value that was greater by 2.5- and 1.5-fold at 6 h for the ischemic brain and placental tissue, respectively, compared with control fetuses. PGE2 levels were less affected, attaining a maximum of 1.9- and 1.1-fold in brain and placenta correspondingly. The thromboxane/prostacyclin ratio reached a maximum in the brain after approximately 3 h, while that in the placenta continued to rise even after 20 h. Persisting high levels of thromboxane are indicative of cerebral vasoconstriction and may suggest possible damaging effects.     

Tomato Rab1A homologs as molecular tools for studying Rab geranylgeranyl transferase in plant cells.

Rab proteins attach to membranes along the secretory pathway where they contribute to distinct steps in vesicle-mediated transport. To bind membranes, Rab proteins in fungal and animal cells must be isoprenylated by the enzyme Rab geranylgeranyl transferase (Rab GGTase). We have isolated three tomato (Lycopersicon esculentum, M.) cDNAs (LeRab 1A, B, and C) encoding Rab-like proteins and show here that all three are substrates for a Rab GGTase-like activity in plant cells. The plant enzyme is similar to mammalian Rab GGTase in that the plant activity (a) is enhanced by detergent and (b) is inhibited by mutant Rab lacking a prenylation consensus sequence. LeRab1B contains a rare prenylation target motif and was the best substrate for the plant, but not the yeast, Rab GGTase. LeRab1A, B, and C are functional homologs of the Saccharomyces cerevisiae Rab protein encoded by YPT1 and are differentially expressed in tomato. LeRab1A mRNA, but not that of LeRab1B or C, is induced by ethylene in tomato seedlings and is also upregulated in ripening fruit. The increase in LeRab1A mRNA expression in ripe fruit may be linked to increased synthesis and export of enzymes like polygalacturonase, pectin esterase, and other enzymes important in fruit softening.     

Zero-crossing detectors in primary visual cortex?

David Marr and others have hypothesized that the visual system processes complex scene information in stages, the first of which involves the detection of light intensity edges or zero-crossings (Marr, 1982). Ideal zero-crossing detector mechanisms have been described and modeled in terms of their possible physiological implementation (Marr and Hildreth, 1980; Poggio, 1983). We now present evidence of visual cortical receptive fields which resemble in spatial organizational terms the requirements of zero-crossing analysis. The linear and nonlinear summation within and between the receptive field subunits are described and compared with predicted processes. The relative subunit sizes and separations are analyzed in these terms. Our findings support the notion that receptive fields may correspond with zero-crossing filters rather than zero-crossing detector gates.     

Threonine Overproduction in Transgenic Tobacco Plants Expressing a Mutant Desensitized Aspartate Kinase of Escherichia coli

In higher plants, the synthesis of the essential amino acid threonine is regulated primarily by the sensitivity of the first enzyme in its biosynthetic pathway, aspartate kinase, to feedback inhibition by threonine and lysine. We aimed to study the potential of increasing threonine accumulation in plants by means of genetic engineering. This was addressed by the expression of a mutant, desensitized aspartate kinase derived from Escherichia coli either in the cytoplasm or in the chloroplasts of transgenic tobacco (Nicotiana Tabacum cv Samsun NN) plants. Both types of transgenic plants exhibited a significant overproduction of free threonine. However, threonine accumulation was higher in plants expressing the bacterial enzyme in the chloroplast, indicating that compartmentalization of aspartate kinase within this organelle was important, although not essential. Threonine overproduction in leaves was positively correlated with the level of the desensitized enzyme. Transgenic plants expressing the highest leaf aspartate kinase activity also exhibited a slight increase in the levels of free lysine and isoleucine, both of which share a common biosynthetic pathway with threonine, but showed no significant change in the level of other free amino acids. The present study proposes a new molecular biological approach to increase the limiting content of threonine in higher plants.     

An allied reprogramming,selection, expansion and differentiation platform for creating hiPSC on microcarriers

ObjectivesInduced pluripotent stem cells (iPSCs) generated by monolayer cultures is plagued by low efficiencies, high levels of manipulation and operator unpredictability. We have developed a platform, reprogramming, expansion, and differentiation on Microcarriers, to solve these challenges.Materials and MethodsFive sources of human somatic cells were reprogrammed, selected, expanded and differentiated in microcarriers suspension cultures.ResultsImprovement of transduction efficiencies up to 2 times was observed. Accelerated reprogramming in microcarrier cultures was 7 days faster than monolayer, providing between 30 and 50‐fold more clones to choose from fibroblasts, peripheral blood mononuclear cells, T cells and CD34+ stem cells. This was observed to be due to an earlier induction of genes (β‐catenin, E‐cadherin and EpCAM) on day 4 versus monolayer cultures which occurred on days 14 or later. Following that, faster induction and earlier stabilization of pluripotency genes occurred during the maturation phase of reprogramming. Integrated expansion without trypsinization and efficient differentiation, without embryoid bodies formation, to the three germ‐layers, cardiomyocytes and haematopoietic stem cells were further demonstrated.ConclusionsOur method can solve the inherent problems of conventional monolayer cultures. It is highly efficient, cell dissociation free, can be operated with lower labor, and allows testing of differentiation efficiency without trypsinization and generation of embryoid bodies. It is also amenable to automation for processing more samples in a small footprint, alleviating many challenges of manual monolayer selection.

We have developed an allied protocol for reprogramming, selecting, expanding and differentiating human pluripotent stem cells on Microcarriers (designated as RepMC). This method allows faster reprogramming, selecting 30‐50‐fold more candidates for characterization and also allows us to find high quality candidates that differentiate to cardiomyocytes and blood lineages. Mechanistically, this method appears to accelerate the induction, maturation and stabilization phases of reprogramming. Our findings help simplify the process of deriving and expanding iPSCs for therapeutic applications, offering a robust and scalable suspension platform for large‐scale generation of clinical grade iPSCs.     

Nuclear import and DNA-binding activity of RFX1. Evidence for an autoinhibitory mechanism.

RFX1 binds and regulates the enhancers of a number of viruses and cellular genes. RFX1 belongs to the evolutionarily conserved RFX protein family that shares a DNA-binding domain and a conserved C-terminal region. In RFX1 this conserved region mediates dimerization, and is followed by a unique C-terminal tail, containing a highly acidic stretch. In HL-60 cells nuclear translocation of RFX1 is regulated by protein kinase C with unknown mechanisms. By confocal fluorescence microscopy, we have identified a nonclassical nuclear localization signal (NLS) at the extreme C-terminus. The adjacent 'acidic region', which showed no independent NLS activity, potentiated the function of the NLS. Subcellular fractionation showed that the tight association of RFX1 with the nucleus is mediated by its DNA-binding domain and enhanced by the dimerization domain. In contrast, the acidic region inhibited nuclear association, by down-regulating the DNA-binding activity of RFX1. These data suggest an autoinhibitory interaction, which may regulate the function of RFX1 at the level of DNA binding. The C-terminal tail thus constitutes a composite localization domain, which on the one hand mediates nuclear import of RFX1, and on the other hand inhibits its association with the nucleus and binding to DNA. The participation of the acidic region in both activities suggests a mechanism by which the nuclear import and DNA-binding activity of RFX1 may be coordinately regulated by phosphorylation by kinases such as PKC.