Long-term nutrient and water utilization during micropropagation of Cattleya on a liquid/membrane system

Growth of two Cattleya clones (Sophrolaeliocattleya Jewel Box 'Scheherezade' and Brassolaeliocattleya Rugley's Mill 'Mendenhall') over 6 or 8 months on microporous polypropylene membrane rafts was compared for several inorganic nutrient formulations: Murashige and Skoog at full, half and quarter strength; Hoagland's hydroponic medium; and three media formulated specifically for orchid culture (Knudson, Lindemann, and Vacin and Went). Greatest fresh weight and number of plants per vessel were obtained on Murashige and Skoog medium and dilutions thereof. Shoot growth was greater than root growth only on full strength MS media. Media uptake by tissue and evaporation from the vessels required additional water to maintain contact between membrane and liquid. Most rapid growth occurred in periods following addition of water. In more dilute media formulations, shifting growth from shoots to roots was a possible outcome of low concentrations of ammonium.     

Acid phosphatase isozymes secreted under phosphate-deficient conditions inPholiota nameko

We previously reported the purification of an acid phosphatase (APase52) secreted from the mycelia ofPholiota nameko under phosphate-deficient conditions. In the present study, two other isozymes (APase47 and APase48) were found and their structures were compared with that of APase52. Thirteen amino acid residues at theN-terminus of APase47 were completely identical with those of APase48 and had partial homology with those of APase52. The deglycosylation of proteins indicated that three APase isozymes differ in theN-linked oligosaccharide content. The protease-generated peptide maps of the APases differed from one another in the band pattern. These results suggest that the APases are the products of different genes.     

Combined effects of enhanced UV-B radiation and nitrogen deficiency on the growth,composition and photosynthesis of rye (Secale cereale)

The interactive effects of N-deficiency and enhanced UV-B radiation on growth, photosynthesis and pigmentation of rye were studied. The plants were grown for 5 weeks in growth chambers with high (700 mol m^-2 s^-2) irradiance levels. A 30% difference in UV-B at plant level was achieved by using different thicknesses of UV-B transparent Plexiglass. One half of the plants received optimal N nutrition, while the other received half of this dose. Both enhanced UV-B and N deficiency strongly decreased production (from 24–33%). The combined effect was additive (no interaction) on most parameters, including total dry weight production which was 52% lower than in the control series. Significant interaction was found on the root/shoot ratio. While reduced N supply induced an increase in the ratio at normal UV-B irradiation, under the increased UV-B, N deficiency had no effect on the root/shoot ratio. The reduced biomass due to UV-B was clearly correlated to a reduction in photosynthesis. At optimal N supply the plants increased the production of protective pigments in response to UV-B, but at reduced N supply this response was lacking. The increased N content of the high UV-B/high N plants could be a result of increased flavonoid production as well as changes in light penetration in the canopy.     

Magnesium deficiency treatment causes reductions in photosynthesis of well-nourished Norway spruce

In order to investigate effects of magnesium deficiency on Norway spruce [Picea abies (L.) Karst.] photosynthesis, 100 well-nourished 5-year-old spruce trees were grown in sand culture, individually supplied with circulating nutrient solutions. Mineral nutrients were added to the nutrient solutions in optimal quantities and optimal relations to nitrogen. Magnesium was supplied at 0.203, 0.041 and 0.005 mM in order to simulate optimal nutrition, moderate deficiency and severe deficiency. Parameters of photosynthetic gas exchange, chlorophyll, magnesium and starch concentrations were determined in current-year and 1-year-old needles during one growing season. By mid May — 6 months after onset of the Mg deficiency treatments in late autumn — CO₂-assimilation rates of 1-year-old needles were significantly decreased independent of the severity of the deficiency treatment, whereas the chlorophyll concentrations did not differ from the controls. The occurrence of yellowing symptoms during July did not further influence the Mg deficiency effect on photosynthesis. In contrast to 1-year-old needles, significant reductions of photosynthesis and chlorophyll in current-year needles were only caused by severely deficient Mg supply. Mg deficiency affected carboxylation efficiency but not light use efficiency. From the accumulation of starch in the needles, up to 30-fold of the controls, the conclusion has been drawn that reactions of CO₂-fixation were affected by reduced carbohydrate export. The light-dependent pigment reduction, leading to the typical tipyellowing of needles, clearly reflects a secondary effect of Mg deficiency.     

Activity and subcellular distribution of protein kinase C (PKC) in muscle and brain of force-fed zinc-deficient rats

The purpose of the present study was to investigate, in force-fed rats, whether alimentary zinc (Zn) deficiency affects the activity of the Zn-metalloenzyme protein kinase C (PKC). The in vivo activity of PKC was determined by measuring the subcellular distribution of the enzyme between the cytosolic and the particulate fraction in brain and muscle. For this purpose, 24 male Sprague-Dawley rats with an average live mass of 126 g were divided into 2 groups of 12 animals each. The Zn-deficient and the control rats received a semisynthetic casein diet with a Zn content of 1.2 and 24.1 ppm, respectively. All animals were fed four times daily by gastric tube in order to ensure that the depleted animals also received adequate nutrients and to synchronize the feed intake exactly. After 12 d, the depleted rats were in a state of severe Zn deficiency, as demonstrated by a 70% lower serum Zn concentration and a 66% reduction in the serum activity of alkaline phosphatase. Neither the cytosolic nor the particulate fraction of the thigh muscle showed any difference between the depleted and the control animals as regards PKC activity/g of muscle. The specific activity of PKC/mg of protein in the cytosolic fraction of the muscle was not affected by alimentary zinc deficiency, whereas the specific activity of PKC in the particulate fraction of the muscle was reduced by a significant 10% in Zn deficiency (150±12 vs 135±14 pmol P/min/mg protein). In the brain, neither the cytosolic nor the particulate fraction revealed any difference in PKC activity/g of fresh weight or in the specific activity/mg of protein between the control and the Zn-deficient rats.     

Different tissue responses for iodine and iodide in rat thyroid and mammary glands

This research describes the effects of short-term elemental iodine (I₂) and iodide (I⁻) replacement on thyroid glands and mammary glands of iodine-deficient (ID) Sprague-Dawley female rats. Iodine deficiency causes atypical tissue and physiologic changes in both glands. Tissue histopathology and the endocrine metabolic parameters, such as serum TT₄, tissue and body weights, and vaginal smears, are compared. A moderate reduction in thyroid size from the ID control (IDC) was noted with both I⁻ and I₂, whereas serum total thyroxine approached the normal control with both I⁻ and I₂, but was lower in IDC. Thyroid gland IDC hyperplasia was reduced modestly with I₂, but eliminated with I⁻. Lobular hyperplasia of the mammary glands decreased with I₂ and increased with I⁻ when compared with the IDC; extraductal secretions remained the same as IDC with I₂, but increased with I⁻; and periductal fibrosis was markedly reduced with I₂, but remained severe with I⁻. Thus, orally administered I₂ or I⁻ in trace doses with similar iodine availability caused different histopathological and endocrine patterns in thyroid and mammary glands of ID rats. The significance of this is that replacement therapy with various forms of iodine are tissue-specific.     

Activated oxygen and antioxidant defences in iron-deficient pea plants

Iron (Fe) deficiency in pea leaves caused a large decrease (44–62&) in chlorophyll a, chlorophyll b and carotenoids, and smaller decreases in soluble protein (18&) and net photosynthesis (28&). Catalase, non-specific peroxidase and ascorbate peroxidase activities declined by 51& in young Fe-deficient leaves, whereas monodehydroascorbate reductase, dehydroascorbate reductase and glutathione reductase activities remained unaffected. Ascorbate peroxidase activity was highly correlated (r²= 0. 99, P < 0. 001) with the Fe content of leaves, which allows its use as an indicator of the Fe nutritional status of the plant. Fe deficiency resulted in an increase of CuZn-superoxide dismutase but not of Mn-superoxide dismutase. The content of ascorbate decreased by only 24& and those of reduced and oxidized glutathione and vitamin E did not vary. The low-molecular-mass fraction of Fe-sufficient leaves contained 30–65 μg (g dry weight)^?1 Mn. This concentration was 15–60 times greater than that of Fe and Cu in the same fraction, and was further enhanced (1. 5- to 2. 5-fold) by Fe deficiency without causing Mn toxicity. The concentration of catalytic Fe, that is, of Fe active for free radical generation, was virtually zero and that of catalytic Cu did not change with severe Fe deficiency. Because catalytic metals mediate lipid and protein oxidation in vivo, the above findings would explain why oxidatively damaged lipids and proteins do not accumulate in Fe-deficient leaves.     

Effects of root hypoxia and a low P supply on relative growth, carbon dioxide exchange rates and carbon partitioning in Pinus serotina seedlings

The present study was conducted to determine how 10 weeks of root hypoxia and a low P supply altered relative growth, and carbon acquisition and partitioning in a moderately flood tolerant pine. Pond pine (Pinus serotina Michx.) seedlings were grown in continuously flowing solution culture at 5 or 100 μM P, under aerobic or hypoxic solution conditions. Staggered harvests were used to ascertain changes in biomass allocation and relative growth over time. Carbon dioxide exchange rates (CER) were determined by infrared gas analysis, and needles were analyzed for inorganic P (Pi), sucrose, reducing sugars and starch. Although aeration treatment had no significant effect on shoot dry weight or shoot ontogeny, root dry weight of hypoxic seedlings was significantly lower than that of aerobic seedliings after 8 weeks, regardless of the P treatment. Mean relative growth rates (RGR) of roots in the high P treatment initially decreased under hypoxia, but recovered by the sixth week with the production of adventitious roots. Two weeks of hypoxic growth conditions decreased CER and stomatal conductances of seedlings in the high P treatment by more than 30% relative to their aerobic counterparts. Stomatal closure was not accompanied by a decrease in intracellular CO₂, but was accompanied by an increase in starch accumulation. Recoveries of CER, stomatal conductance and carbohydrate metabolism coincided with the recovery of root growth. Low P growth conditions did not significantly affect shoot or root dry weight until the sixth week of treatment. However, differences in seedling RGR, particularly needle RGR, were discernable during the first 2 weeks. Low P treatment effects on CER paralleled changes in needle RGR, with needle RGR more affected than CER. After 6 weeks, CER of aerobically grown seedlings in the low P treatment were only 15% lower than CER of seedlings in the high P treatment, despite a 31% and 75% reduction in needle RGR and Pi concentrations, respectively. Increased starch concentrations of recently expanded needles at this time were probably a result of diminished growth. The inhibitory effect of a low P supply on shoot growth, more specifically on needle expansion and emergence of new fascicular needles, probably limited net carbon fixed per plant more than any direct effect of low P on CER per se.