Cat-2 gene expression

Summary Poly(A)⁴ RNA was isolated from maize scutella of different stages of post-germinative development and translated in vitro in a rabbit reticulocyte translation system. Immunoprecipitation of the translation products with CAT-2-specific antibody was used to quantitate the relative levels of translatable CAT-2 mRNA at each stage. The results show a close correlation between the developmental profile of Cat2 gene expression and the profile of CAT-2 mRNA levels. Evidence that the levels of CAT-2 mRNA are regulated by a temporal regulatory gene (Car1) is presented and the possible mechanism(s) of this regulation discussed.This work was supported by Research Grants No. GM22733 and No. GM33817 from the U.S. National Institutes of Health, Public Health Service to J.G.S. This is paper No. 9933 of the Journal Series of the North Carolina Agricultural Research Service, Raleigh, NC 27695, USA     

Species-specific effects of elevated CO2 on resource allocation in Plantago maritima and Armeria maritima

We investigated the effects of increased atmospheric CO₂ on the biomass, photosynthesis, protein and phenolic concentrations and content of Plantago maritima and Armeria maritima. This enabled us to test the protein competition model (PCM) for predicting C allocation to phenolics. Three contrasting responses to elevated CO₂ (600 μmol CO₂ mol⁻¹) between the two study species were observed. (1) In P. maritima, plant biomass increased and the maximum carboxylation rate of Rubisco (V_c,max) was decreased. However, in A. maritima, shoot biomass decreased and the V_c,max of Rubisco was unchanged. (2) The total phenolic content increased in P. maritima but decreased in A. maritima. (3) Protein concentrations and content decreased in P. maritima and root protein concentrations and content increased in A. maritima. We conclude that C and N allocation to phenolics and proteins is species- and organ-specific and the PCM predictions were correct when phenolics and proteins were expressed on a per plant content basis.     

Effects of acute hypoxia and CO2 inhalation on systemic and peripheral oxygen uptake and circulatory responses during moderate exercise

The effect of acute hypoxia and CO2 inhalation on leg blood flow (LBF), on leg vascular resistance (LVR) and on oxygen supply to and oxygen consumption in the exercising leg was studied in nine healthy male subjects during moderate one-leg exercise. Each subject exercised for 20 min on a cycle ergometer in four different conditions: normoxia, normoxia + 2% CO2, hypoxia corresponding to an altitude of 4000 m above sea level, and hypoxia + 1.2% CO2. Gas exchange, heart rate (HR), arterial blood pressure, and LBF were measured, and arterial and venous blood samples were analysed for PCO2, PO2, oxygen saturation, haematocrit and haemoglobin concentration. Systemic oxygen consumption was 1.83 l.min-1 (1.48-2.59) and was not affected by hypoxia or CO2 inhalation in hypoxia. HR was unaffected by CO2, but increased from 136 beat.min-1 (111-141) in normoxia to 155 (139-169) in hypoxia. LBF was 6.5 l.min-1 (5.4-7.6) in normoxia and increased significantly in hypoxia to 8.4 (5.9-10.1). LVR decreased significantly from 2.23 kPa.l-1.min (1.89-2.99) in normoxia to 1.89 (1.53-2.52) in hypoxia. The increase in LBF from normoxia to hypoxia correlated significantly with the decrease in LVR. When CO2 was added in hypoxia a significant correlation was also found between the decrease in LBF and the increase in LVR. In normoxia, the addition of CO2 caused a significant increase in mean blood pressure. Oxygen consumption in the exercising leg (leg VO2) in normoxia was 0.97 l.min-1 (0.72-1.10), and was unaffected by hypoxia and CO2.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effects of CO2 and chronic cold exposure on fecundity of female Drosophila melanogaster

Carbon dioxide and chilling are sometimes used to immobilise insects for laboratory research. Both of these methods are known to have short-term effects on behaviour and physiology in Drosophila, but their long-term impacts are unknown. We exposed female D. melanogaster adults to high CO₂ concentrations (4 h at 18,000 ppm) and chronic cold (72 h at 4 °C). The carbon dioxide exposure increased chill coma recovery time, but did not result in changes in offspring number, sex ratio, or size. By contrast, the cold exposure resulted in fewer, smaller offspring, and resulted in a male-biased sex ratio compared to controls. There was no significant interaction between CO₂ and cold. We conclude that although caution must be used in choosing an immobilisation method, CO₂ appears to have less long-term impact than cold.     

Protein synthesis during oxygen conformance and severe hypoxia in the mouse muscle cell line C2C12

Oxygen conformance can be described as the ability to reduce energy demand, and hence oxygen consumption, in response to a decline in oxygen availability without a decrease in the concentration of ATP. It has been proposed that oxygen conformance may enhance cellular survival at low oxygen concentrations. We demonstrate that non-contracting C₂C₁₂ cells, a mouse skeletal muscle cell line, are capable of oxygen conformance. Typically, we found oxygen consumption to decline by 30–40% as the concentration of oxygen was reduced from 100 μM to 10 μM. Unexpectedly, the rate of protein synthesis, a major energy consumer in the cell, did not decrease significantly during oxygen conformance. Unlike oxygen conformance, severe hypoxia (<0.5 μM) caused a 36% decline in the concentration of PCr, and under these conditions of energy stress, the rate of protein synthesis declined by 43%. We conclude that there are two distinct metabolic responses to declines in oxygen concentration in non-contracting C₂C₁₂ cells.     

Salinity effects on CO2 assimilation and diffusive conductance of cowpea leaves

The effect of NaCl salinity at concentrations of 43–173 mM in nutrient solution on net gas exchange of attached cowpea [Vigna unguiculata (L.) Walp cv. California Black-eye No. 5 (CB5)] leaves was investigated under both greenhouse and growth chamber conditions.
There was a marked decrease in leaf conductance to water vapor after exposure to low salinity levels and a slighter decrease when salinity levels were higher. The decrease in net assimilation was much more gradual throughout the entire salinity range. The altered responses of net assimilation and leaf conductance to salinity were more evident at a high light intensity. A decrease in intercellular partial CO₂ pressure [p(CO₂)] was found at the low and intermediate salinity levels but not at the high level. These findings suggest that CO, assimilation was mainly controlled by stomatal conductance and the fixation of CO, might have been increased due to stimulated biochemical activity or to higher chlorophyll concentration per unit leaf area. A decrease in assimilation was already found one day after salinization and pro-ceeded up to 4 days when it was inhibited by 50% at 43 mM NaCl and up to 85% at 173 mM. The decrease in transpiration was larger than the decrease in net assimila-tion, and both were attributed to osmotic stress. Partial recovery was found thereaf-ter and new steady-state rates, in the range of 55 to 100% of the control, were then obtained for salinity levels between 43 and 130 mM. Inhibition of net CO, assimila-tion at this stage was attributed partly to a specific sodium effect and partly to plant water status. A linear relationship between leaf sodium content and net photosynthe-sis was also evident at this stage. Net CO, assimilation recovered more completely than transpiration when salt stress was removed, but at 173 mM NaCl recovery was neglible.     

The effect of temperature change on gene expression in Paramecium primaurelia

When paramecia grown at 24°C are transferred rapidly to 32°C, DNA and protein synthesis continue uninterrupted but at higher rates. Electron microscopic observations indicate that more of the macronuclear chromatin is transcribed at the elevated temperature. This interpretation is supported by hybridization experiments which show that the percentage of the macronuclear genome transcribed into poly(A)⁺ RNA is 24°C and 35% at 32°C. Kinetic analysis of cDNA-poly(A)⁺ RNA hybridizations reveals three abundance classes of poly(A)⁺ RNA and indicates that the number of genes expressing low abundance sequences is about 9000 at 24°C and 13000 at 32°C. The intermediately abundant and highly abundant classes are represented by 100–200 and 1–3 different kinds of RNA sequence, respectively. Cross hybridization shows that changes occur throughout the distribution of abundance classes of poly(A)⁺ RNA with increase in temperature.