Ontogenetic interactions between photosynthesis and symbiotic nitrogen fixation in pigeonpea

Total nodule nitrogenase activity (TNA, μmols ethylene plant^-1 h^-1) in pigeonpea (Cajanus cajari) increased with plant growth to reach maximum at flowering (75 days after sowing), decreasing thereafter until maturity (120 days after sowing). However, specific nodule nitrogenase activity (SNA, μmols ethylene g^-1 nodule fresh wt h^-1) reached its maximum earlier (45 days after sowing). The rate of photosynthesis and shoot and nodule respiration followed a similar pattern to TNA. However, higest rates of root respiration were observed at flowering and again immediately before final harvest. ¹⁴CO₂ feeding studies showed that assimilates produced in leaves before flowering were retained in the vegetative parts. Assimilates produced after flowering were exported to the reproductive structure at the expense of the nodules. It is suggested that the decreased availability of photosynthate to nodules decreased nitrogen fixation.     

Distribution of 14CO2 during ontogeny of chickpea (Cicer arietinum) grown at two moisture levels

The distribution of assimilates of ¹⁴CO₂ in ethanol soluble and insoluble fractions was measured at 20-day intervals from 45–135 days after sowing (DAS) in chickpea (Cicer arietinum) grown at two moisture levels. The contribution of pre-flowering assimilates to pods, although very low, was higher under the stress conditions. At the time of harvest, the recovery of ¹⁴C in pods was 0.4 and 0.9% of the total ¹⁴C fed 45 DAS in soluble and 2.5 and 5.1% in insoluble fractions in control and stressed plants, respectively. The %¹⁴C received by nodules continuously decreased with increasing age of plants. Stressed plants diverted more ¹⁴C to nodules, compared to control, during vegetative and flowering stages. During active seed filling, stressed plants diverted more ¹⁴C to reproductive parts and less to nodules, compared to control. Significant amounts of ¹⁴C were retgined by the stem and leaves during the seed-filling period and it appears that there is scope for the remobilisation of pre-flowering, as well as post-flowering assimilates for seed-filling of chickpea.     

Partitioning and Utilization of Carbon and Nitrogen in Nodulated Roots and Nodules of Chickpea (Cicer arietinum) Grown at Two Moisture Levels

The partitioning and utilization of carbon (C) and nitrogen(N) in nodulated roots and nodules of chickpea (Cicer arietinumL.) was studied at two moisture levels at 10-d intervals 40–140d after sowing (DAS). More C was used in respiration and lessin growth of nodulated roots and nodules under water stresscompared to controls during all growth stages except at theearly vegetative stage. Similarly, less nitrogen was investedin dry matter of both nodules and nodulated roots under stress,except during the vegetative stage where more nitrogen was used.Calculated over the entire growth period, as much as 14 and20% of the total nitrogen and 3 and 4% of the total carbon fixedby the plant was lost to the rooting medium under controlledand stressed conditions, respectively. The efficiency of nitrogen fixation with respect to net C utilizationwas maximal during seed filling under both control and stressconditions However, the efficiency of nitrogen fixation wasalways greater under drier conditions. Carbon, chickpea (Cicer arietinum L.), nitrogen, nitrogen fixation, partitioning     

Ontogenetic Changes in the Level of Ureides and Enzymes of their Metabolism in Various Plant Parts of Pigeonpea (Cajanus cajan)

Levels of allantoin and allantoic acid in shoots, roots, nodulesand leaves of pigeonpea plant, in general, followed the patternof acetylene reduction in nodules, increasing progressivelyfrom 15 days after sowing (DAS) and attaining peaks at 75 DASand 60 DAS, respectively, except in shoots where their contentsevinced maximum values at pod-setting (90 DAS). Activity ofGS in nodules and shoots reached a maximum at 60 DAS and 75DAS, respectively. However, in leaves and roots, the enzymeshowed a biphasic behaviour with peaks at days 60 and 105 inleaves and at days 75 and 105 in roots. GDH activity in nodulespeaked at 60 DAS, whereas, in leaves and roots, the maximumactivity was observed at flowering (75 DAS). Uricase was presentonly in nodules with peak activity at flowering. Allantoinaseactivity again peaked at flowering, where nodules had maximumactivity followed by leaves, roots and shoots. Urease couldbe detected in all the organs with maximum activity at 60 DASin leaves followed by roots and nodules. Except uricase, allthe enzymes reported above were also present in reproductivestructures. Compared to GS, GDH was more active both in flowerbuds and developing pods. Seeds, compared to podwalls, containedhigher activities of GDH, allantoinase and urease at day 105.Only allantoin could be detected in seeds and podwalls at day105. Key words: Cajanus cajan, Allantoin, Allantoic acid, Nitrogenase, Glutamine synthetase, Glutamate dehydrogenase, Uricase, Allantoinase, Urease, Development     

Quantitative and Qualitative Changes in Peroxidase during Germination of Mung Bean under Salt Stress

Seeds of mung bean (Phaseolus aureus Roxb.) cv. Pusa Baisakhi were surface sterilized with sodium hypochlorite solution and sown both in Petri dishes and in sand culture containing aqueous solutions of four different salts, viz. NaCI, KCI, Na₂SO₄ and K₂SO₄, each at 5 and 10 S/cm. Peroxidase activity and its isoenzymes were studied in different plant parts at suitable time intervals during germination. Activity of peroxidase increased in embryo axis and leaves but decreased in cotyledons and roots with different salt treatments to varying degrees. A highly significant inverse correlation (r= -0.931 was found between the peroxidase level and the growth of embryo axis under saline conditions. The number of isoenzymes of peroxidase increased with increase in the time of germination. Salinity treatments resulted in the appearance of new isoenzymes in all the plant organs except roots where the isoenzymic pattern remained unchanged. Different types of salinity resulted in the appearance or/and disappearance of different isoenzymes.     

Effect of water stress on the enzymes of nitrogen metabolism in mung bean (Vigna radiata Wilczeck) nodules

Abstract. Water stress created by withholding irrigation in mung bean resulted in decreased leaf water potential and nodule moisture content. Decreased leaf water potential was associated with decreased activity of nitrogenase, glutamine synthetase (GS), asparagine synthetase (AS), aspartate amino transferase (AAT), xanthine dehydrogenase (XDH) and uricase. However, the activity of glutamate dehydrogenase increased three-fold under severe stress. The activity of allantoinase and allantoicase was not affected by moderate stress but decreased under severe stress. The in vitro production of allantoic acid from allantoin and uric acid in the cytosol fraction decreased more than its production from xanthine and hypoxanthine. The production of NADH also decreased under stress.
During recovery from severe stress, the activity of XDH and uricase further decreased, whilst that of allantoinase and allantoicase increased compared to the control. This corresponded with the higher content of ureides during recovery. The recovery in other enzymes was not complete although leaf water potential and nodule moisture content recovered fully within 24 h.     

Partitioning of Carbon and Nitrogen During Growth and Development of Pigeonpea (Cajanus cajan L.)

Budgets for C and N were computed for pigeonpea (Cajanus cajanL.) at 15 d intervals, for the entire life cycle. Maximum Cand N in dry matter was observed at 90 d after sowing. Of theplants total respiratory loss during the vegetative phase, shoots,roots and nodules accounted for 65%, 23% and 12%, respectively.During the reproductive phases, the respiratory burden of theroots increased, while that of shoots and nodules decreased.Total respiratory loss as a proportion of net photosynthateremained more or less constant until ‘flowering and pod-setting’but increased heavily during seed filling, losing nearly 75%of the photosynthate in respiration. The efficiency of nitrogenfixation, in relation to respiratory output of the whole plantand nodulated roots, decreased during the period 60–90d after sowing, while that of nodules decreased from day 45onwards. Photosynthate supply to nodules and nodulated rootsincreased up to 75 d and 90 d after sowing, respectively. During45–90 d, nodules were fixing a constant proportion ofN per unit of C translocated (0.2 mg N mg^–1 C). Nodulatedroots, on an average, fixed 0.07 mg N mg^–1 C translocatedin the vegetative phase and this value decreased considerablyduring the subsequent phases. The crop produced during its lifecycle 50.4 g of glucose equivalents and yielded 3.8 g seed drymatter and 0.8 g seed protein giving an average of 13.2 g g^–1seed dry matter and 62.8 g g^–1 seed protein. Selectioncriteria for the improvement of C, N economy in pigeonpea havebeen suggested. Key words: Cajanus cajan, Carbon, Nitrogen, Dry weight, Plant parts, Growth, Development, Models     

In Vivo Fixation of CO2 by Attached Pods of Brassica campestris L.

In vivo net CO₂ exchange characteristics of attached Brassicapods were studied during the entire period of their growth anddevelopment after anthesis. ¹⁴CO₂ was fed both from the externalatmosphere and internally through the pod cavity, and the anatomyof the pod-wall was examined microscopically. Stomata were observedin the outer epidermal layer of the pod wall. Net in vivo CO₂fixation by the pods was observed throughout the period of theirdevelopment and was maximum on day 42 after anthesis (DAA).Compared to the internal feeding experiments, ¹⁴CO₂ fixationfrom the external environment was very high. Apparent translocationof fixed carbon from the pod wall to seeds was rapid. Pod photosynthesiscontributed substantially to seed growth. pods, Brassica campestris L, CO₂ fixation, stomata     

In Vivo Fixation of CO2 by Attached Pods of Brassica campestris L.

In vivo net CO₂ exchange characteristics of attached Brassicapods were studied during the entire period of their growth anddevelopment after anthesis. ¹⁴CO₂ was fed both from the externalatmosphere and internally through the pod cavity, and the anatomyof the pod-wall was examined microscopically. Stomata were observedin the outer epidermal layer of the pod wall. Net in vivo CO₂fixation by the pods was observed throughout the period of theirdevelopment and was maximum on day 42 after anthesis (DAA).Compared to the internal feeding experiments, ¹⁴CO₂ fixationfrom the external environment was very high. Apparent translocationof fixed carbon from the pod wall to seeds was rapid. Pod photosynthesiscontributed substantially to seed growth. pods, Brassica campestris L., CO₂ fixation, stomata     

Partitioning and Utilization of Carbon and Nitrogen for Dry Matter and Protein Production in Chickpea (Cicer arietinum L.)

The partitioning of N and utilization of C in various processesin chickpea (Cicer arielinum L.) was studied at 10 d intervalsfrom 35 to 135 d after sowing (DAS). Dry matter, C and N contentof the plant increased throughout the study period. The maximumamounts of C and N were fixed during the flowering and earlyfruiting phase (75–115 DAS) and the minimum during theseed filling phase (115–135 DAS). Efficiency of nitrogenfixation in relation to net C utilization and respiratory outputof the whole plant, nodules and nodulated root, varied widely,but was maximum during 75–115 DAS. The crop experiencedsevere respiratory losses, particularly during the vegetativephase, when 83% of the total fixed C was lost in respiration.The crop produced 54·6 g of glucose units, 2·36g of seed dry matter and 495 mg of seed protein. Possible reasonsfor the poor efficiency of chickpea, in terms of photosynthateutilization for dry matter and protein production are discussed. Key words: Cicer arietinum, C, N, economy