Effects of Pod Removal on Metabolism and Senescence of Nodulating and Nonnodulating Soybean Isolines: II. Enzymes and Chlorophyll

The objectives of this work were to determine the effect of sink strength (presence or absence of pods) and nitrogen source (nodulating versus nonnodulating plants) on enzymic activities, chlorophyll concentration, and senescence of soybean (Glycine max [L.] Merr. cv Harosoy) isolines. A 2-year (1981-1982) field study was conducted.

For both nodulated and nonnodulated plants, ribulose bisphosphate carboxylase (RuBPCase) activity of upper-canopy leaves was decreased by pod removal in both years, while chlorophyll concentration was decreased in 1981 only. Nonnodulated plants had lower RuBPCase activity in 1981 and lower chlorophyll concentration in both years compared with nodulated plants. In both years, and for all treatments, RuBPCase activity and chlorophyll began to decline at about the same time, but the rate of decline was less for depodded than for podded plants. Leaves in the middle and lower parts of the canopy had similar RuBPCase activity and chlorophyll concentration trends as upper-canopy leaves for all treatments.

Profiles of nitrate reductase activity (NRA) were similar for all treatments in both 1981 and 1982. Acetylene reduction profiles were similar for nodulated-podded and nodulated-depodded plants. The peak and decline in NRA profiles preceded the peak and decline in acetylene reduction profiles. The rate of decline in acetylene reduction activity was less for depodded plants, especially in 1982, but activities reached zero by the final sampling time. Thus, nodule senescence was not prevented by pod removal.

Based on seasonal profiles of RuBPCase activity, chlorophyll, NRA, and acetylene reduction activity, the initiation of senescence appeared to occur at the same approximate time for all treatments and, thus, did not depend on the presence or absence of pods or nodules. The hypothesis that nodules act as a nitrogen source and carbohydrate sink to delay senescence in the absence of pods was not correct.

     

Pla2g12b and Hpn Are Genes Identified by Mouse ENU Mutagenesis That Affect HDL Cholesterol

Despite considerable progress understanding genes that affect the HDL particle, its function, and cholesterol content, genes identified to date explain only a small percentage of the genetic variation. We used N-ethyl-N-nitrosourea mutagenesis in mice to discover novel genes that affect HDL cholesterol levels. Two mutant lines (Hlb218 and Hlb320) with low HDL cholesterol levels were established. Causal mutations in these lines were mapped using linkage analysis: for line Hlb218 within a 12 Mbp region on Chr 10; and for line Hlb320 within a 21 Mbp region on Chr 7. High-throughput sequencing of Hlb218 liver RNA identified a mutation in Pla2g12b. The transition of G to A leads to a cysteine to tyrosine change and most likely causes a loss of a disulfide bridge. Microarray analysis of Hlb320 liver RNA showed a 7-fold downregulation of Hpn; sequencing identified a mutation in the 3' splice site of exon 8. Northern blot confirmed lower mRNA expression level in Hlb320 and did not show a difference in splicing, suggesting that the mutation only affects the splicing rate. In addition to affecting HDL cholesterol, the mutated genes also lead to reduction in serum non-HDL cholesterol and triglyceride levels. Despite low HDL cholesterol levels, the mice from both mutant lines show similar atherosclerotic lesion sizes compared to control mice. These new mutant mouse models are valuable tools to further study the role of these genes, their affect on HDL cholesterol levels, and metabolism.     

Different subsets of axonal guidance cues are essential for sensory neurite outgrowth to cutaneous and muscle targets in the dorsal ramus of the embryonic chick

The dorsal ramus nerve diverges dorsally from each spinal nerve to innervate the epaxial muscle and dermis that are derived in situ from each dermamyotome. The outgrowth of both the sensory and motor components of this nerve are sensitive to the proximity of the dermamyotome. Motoneurons display a direct target response that is not dependent upon the concurrent outgrowth of sensory neurites (Tosney: Dev. Biol. 122:540-588, 1987). Likewise, the outgrowth of sensory neurites could be directly dependent on the dermamyotome. Alternatively, sensory neurites could be dependent on motor axons that in turn require the dermamyotome for outgrowth. To distinguish between these possibilities, motor outgrowth was abolished by unilateral ventral neural tube deletion and the patterns of subsequent sensory neurite outgrowth were assessed. The cutaneous nerve branch formed in all cases. In contrast, neither of the epaxial muscle nerves formed in the absence of epaxial motoneuron outgrowth. Furthermore, sensory neurites could not be detected diverging into muscle from the cutaneous nerve or entering muscle via other novel routes. We conclude that motoneurons are essential for sensory outgrowth to epaxial muscle but not to cutaneous targets. It is clear that different subsets of navigational cues guide sensory afferents to muscle and to cutaneous destinations.     

Influence of Temperature on Nitrate Metabolism and Leaf Expansion in Soybean (Glycine max L. Merr.) Seedlings

The effect of various day temperatures on NADH-nitrate reductase, NADH- and NADPH-glutamate dehydrogenases, nitrate, protein and leaf area, measured at intervals during the ontogeny of the first trifoliolate soybean leaf, was determined. At 32.5 C and 25 C, nitrate concentration, nitrate reductase, and NADPH-glutamate dehydrogenase activities increased concurrently with leaf development and then decreased as leaf maturation progressed. At 40 C, these three components showed no initial increase and the concentration or activities decreased throughout the development of the leaf. The effects of temperature on NADH-glutamate dehydrogenase were the reverse. Rates of protein accumulation were higher at 40 C during the first 2 days of leaf development while higher rates were measured the first 5 days of leaf growth at 32.5 C. At 25 C, protein accumulation was low during the first 3 days of leaf growth, increased in the period of 3 to 5 days, and then declined up to 8 days of leaf development. Leaf expansion progressed at faster rates at 32.5 C and 25 C and at a much slower rate at 40 C. Leaf growth was essentially complete after the fifth day regardless of temperature.     

Variation in Nitrate Accumulation, Nitrate Reductase Activity and Nitrite Reductase Activity along Primary and Nodal Roots of Corn (Zea mays L.) Seedlings

Significant differences in NO₃ accumulation and nitrate reductaseactivity (NRA) were noted in the successive segments of developingyoung primary and nodal roots. This variation was also foundto be a function of root age. Nitrite reductase activity (NiRA)on the other hand had little variation among various segmentsof primary and nodal roots and also as a function of root age.These data suggest root NO₃ accumulation and root NRA are twoprocesses which are not directly linked. ¹ Present address: Division of Plant Physiology, Indian AgriculturalResearch Institute, New Delhi-110012, India. (Received December 3, 1983; Accepted June 18, 1983)     

Improvements of the nitrite color development in assays of nitrate reductase by phenazine methosulfate and zinc acetate

Nitrate reductase activity is most commonly assayed by measurement of product formation. Excess NADH and factor(s) present in the enzyme extract that interfere with the diazotization and azo color complex of nitrite cause a depression of apparent nitrate reductase activity. Two postassay treatments were found that markedly enhanced the extent of nitrite color formation and apparent nitrate reductase activity. The procedure involves stopping the reaction with zinc acetate (50 μmoles per ml of reaction mix), followed by removal of the precipitate by centrifugation. Presumably the zinc acetate removes extract factor(s) that interfere with color development, because it does not remove the NADH. Phenazine methosulfate (15 nmoles per ml of reaction mix) is added to aliquots of the supernatant and allowed to stand for 20 min at 30 C to oxidize the residual NADH before color development.     

Generation of reduced nicotinamide adenine dinucleotide for nitrate reduction in green leaves

An in vivo assay of nitrate reductase activity was developed by vacuum infiltration of leaf discs or sections with a solution of 0.2 m KNO₃ (with or without phosphate buffer, pH 7.5) and incubation of the infiltrated tissue and medium under essentially anaerobic conditions in the dark. Nitrite production, for computing enzyme activity, was determined on aliquots of the incubation media, removed at intervals.     

Heterogeneity in Waardenburg syndrome.

Heterogeneity of Waardenburg syndrome is demonstrated in a review of 1,285 patients from the literature and 34 previously unreported patients in five families in the Netherlands. The syndrome seems to consist of two genetically distinct entities that can be differentiated clinically: type I, Waardenburg syndrome with dystopia canthorum; and type II, Waardenburg syndrome without dystopia canthorum. Both types have an autosomal dominant mode of inheritance. The incidence of bilateral deafness in the two types of the syndrome was found in one-fourth with type I and about half of the patients with type II. This difference has important consequences for genetic counseling.     

5-Chloroindoloyl glycine amide inhibitors of glycogen phosphorylase: synthesis, in vitro, in vivo, and X-ray crystallographic characterization

The synthesis, in vitro, and in vivo biological characterization of a series of achiral 5-chloroindoloyl glycine amide inhibitors of human liver glycogen phosphorylase A are described. Improved potency over previously reported compounds in cellular and in vivo assays was observed. The allosteric binding site of these compounds was shown by X-ray crystallography to be the same as that reported previously for 5-chloroindoloyl norstatine amides.     

Intracellular localization of nitrate reductase, nitrite reductase, and glutamic Acid dehydrogenase in green leaf tissue

Greenhouse grown seedlings of corn (Zea mays L.) and foxtail (Setaria faberii Herrm.) were used as source material in determining the intracellular localization of nitrate reductase, nitrite reductase, and glutamic acid dehydrogenase, Nonaqueous and aqueous isolation techniques were used to establish that nitrite reductase is localized within the chloroplasts, but that nitrate reductase and glutamic acid dehydrogenase are not. Nonaqueous isolation gives distribution patterns of nitrite reductase which are the same as those observed for NADP-dependent 3-phosphoglyceraldehyde dehydrogenase but which differ drastically from the patterns observed for pyruvic acid kinase. The distribution patterns for nitrate reductase are the same as those of pyruvic acid kinase. The techniques used do not eliminate the possibility that nitrate reductase and pyruvic acid kinase are localized on the external chloroplast membrane.

The data obtained establish that glutamic acid dehydrogenase of green leaves is localized within the mitochondria.