Glycogen in Leukocytes from Bovine Blood and Milk

Glycogen content was determined quantitatively by the Anthrone reagent method in leukocytes obtained from blood and milk of five cows. Distribution of glycogen in leukocytes was studied by microscopic examination of slides stained by Periodic acid-Schiff (PAS) reaction. Blood glucose concentrations were investigated in these animals by standard procedures. In two of five cows both blood glucose levels and blood leukocyte glycogen levels on the same day were determined for six consecutive days. One hundred and two blood leukocyte samples from five cows had a mean glycogen content of 1.32 ± 0.04 (S.E.) mg/10⁹ WBC, and 6.11 ± 0.17 (S.E.) mg/10⁹ PMNs. Leukocyte preparations from 80 samples of milk comprising 97 to 98% PMNs contained 3.81 ± 0.18 (S.E.) mg glycogen/10⁹ milk leukocytes. In PAS preparations of blood and milk leukocytes glycogen was found almost exclusively in PMNs. Glycogen granules, present frequently in PMNs and occasionally in monocytes and large lymphocytes from blood, were not observed in those from milk. The glycogen level in milk leukocytes was significantly lower (P = <0.01) than that of the blood PMNs in every cow, and the overall mean difference between levels for milk leukocytes and blood PMNs was highly significant (P = <0.001). Mean blood glucose concentration in the five cows was 44.46 ± 0.66 (S.E.) mg%. There was no significant relationship between blood glucose and blood leukocyte glycogen levels in the five corresponding cows; nor between blood glucose and blood PMN glycogen levels on the same day in either of two cows investigated. Leukocyte preparations from milk samples obtained on the second day following intramammary infusion of endotoxin consistently contained markedly less glycogen than the leukocyte preparations from first day post-infusion samples.

These tended to level off and became intermediate between first and second day levels. It is postulated that the poor phagocytic competence of leukocytes from bovine mammary glands compared to their counterparts in blood observed by various workers may be due partially to low energy reserves in these cells.

     

The effects of ultraviolet-B radiation on photosynthesis of different aged needles in field-grown loblolly pine

We examined the effect of supplemental UV-B radiation (290-320 nm) on photosynthetic characteristics of different aged needles of 3-year-old, field-grown loblolly pine (Pinus taeda L.). Needles in four age classes were examined: I, most recently fully expanded, year 3; II, first flush, year 3; III, final flush, year 2; and IV, oldest needles still present, year 2. Enhanced UV-B radiation caused a statistically significant decrease (6%) in the ratio of variable to maximum fluorescence (F(v)/F(m)) following dark adaptation only in needles from the youngest age class, suggesting transient damage to photosynthesis. However, no effects of enhanced UV-B radiation on other instantaneous measures of photosynthesis, including maximum photosynthesis, apparent quantum yield and dark respiration, were seen for needles of any age. Foliar nitrogen concentration was unaffected by UV-B treatment. However, the (13)C/(12)C carbon isotope ratios (delta(13)C-a time integrated measure of photosynthetic function) of needles in age classes II and IV were 3% (P < 0.01) and 2% (P < 0.05) more negative, respectively, in treated plants than in control plants. Exposure to enhanced UV-B radiation caused a 20% decrease in total biomass and a 4% (P < 0.05), 25% (P < 0.01), and 9% (P < 0.01) decrease in needle length of needles in age classes I, II, and IV, respectively. The observed decreases in delta(13)C, and F(v)/F(m) of the needles in the youngest needle age class suggest subtle damage to photosynthesis, although overall growth reductions were probably a result of decreased total leaf surface rather than decreased photosynthetic capacity. Needles of age class IV had lower light- and CO(2)-saturated maximum photosynthetic rates (39%), lower dark respiration (34%), lower light saturation points (37%), lower foliar nitrogen concentration (28%), and lower delta(13)C (14%) values than needles of age class I. Apparent quantum yield and F(v)/F(m) did not change with needle age. The observed changes in photosynthesis and foliage chemical composition with needle age are consistent with previous studies of coniferous trees and may represent adaptations of older needles to shaded conditions within the canopy.     

Inheritance of iron deficiency chlorosis resistance in groundnut (Arachis hypogaea L.)

Iron-deficiency chlorosis (IDC) is an important abiotic constraint affecting the growth and yield of groundnut in calcareous and alkaline soils worldwide. The present study investigated the inheritance of IDC resistance among four straight crosses of groundnut involving four IDC susceptible cultivars as females and a common IDC resistant male parent. The F₁'s of all the four crosses were resistant to IDC indicating the dominant nature of IDC resistance. The F₂'s of all the four crosses showed a good fit to the ratio of 15 (IDC resistant): 1 (IDC susceptible) and their behavior among the F₃'s was as per the expected ratio of 7:4:4:1. The IDC resistance in groundnut is under the control of duplicate dominant genes wherein, the presence of a dominant allele at either of the loci results in IDC resistance, while duplicate recessive results in IDC susceptibility. This information would facilitate development of IDC resistant cultivars of groundnut.