Sugar beet and barley yields in relation to inoculation with N2-fixing and phosphate solubilizing bacteria

Recently, there has been a resurgence of interest in bioorganic fertilizers as part of sustainable agricultural practices to alleviate drawbacks of intensive farming practices. N₂-fixing and P-solubilizing bacteria are important in plant nutrition increasing N and P uptake by the plants, and playing a significant role as plant growth-promoting rhizobacteria in the biofertilization of crops. A study was conducted in order to investigate the effects of two N₂-fixing (OSU-140 and OSU-142) and a strain of P-solubilizing bacteria (M-13) in single, dual and three strains combinations on sugar beet and barley yields under field conditions in 2001 and 2002. The treatments included: (1) Control (no inoculation and fertilizer), (2) Bacillus OSU-140, (3) Bacillus OSU-142, (4) Bacillus M-13, (5) OSU-140 + OSU-142, (6) OSU-140 + M-13, (7) OSU-142 + M-13, (8) OSU-140 + OSU-142 + M-13, (9) N, (10) NP. N and NP plots were fertilized with 120 kg N ha^–1 and 120 kg N ha^–1 + 90 kg P ha^- for sugar beet and 80 kg N ha^–1 and 80 kg N ha^–1 + 60 kg P ha^–1 for barley. The experiments were conducted in a randomized block design with five replicates. All inoculations and fertilizer applications significantly increased leaf, root and sugar yield of sugar beet and grain and biomass yields of barley over the control. Single inoculations with N₂-fixing bacteria increased sugar beet root and barley yields by 5.6–11.0% depending on the species while P-solubilizing bacteria alone gave yield increases by 5.5–7.5% compared to control. Dual inoculation and mixture of three bacteria gave increases by 7.7–12.7% over control as compared with 20.7–25.9% yield increases by NP application. Mixture of all three strains, dual inoculation of N₂-fixing OSU-142 and P-solubilizing M-13, and/or dual inoculation N₂-fixing bacteria significantly increased root and sugar yields of sugar beet, compared with single inoculations with OSU-140 or M-13. Dual inoculation of N₂-fixing Bacillus OSU-140 and OSU-142, and/or mixed inoculations with three bacteria significantly increased grain yield of barley compared with single inoculations of OSU-142 and M-13. In contrast with other combinations, dual inoculation of N₂-fixing OSU-140 and P-solubilizing M-13 did not always significantly increase leaf, root and sugar yield of sugar beet, grain and biomass yield of barley compared to single applications both with N₂-fixing bacteria. The beneficial effects of the bacteria on plant growth varied significantly depending on environmental conditions, bacterial strains, and plant and soil conditions.     

The role of microorganisms in mediating and facilitating the uptake of plant nutrients from soil

Summary No root systems in nature are without a microbial population. These may be freeliving or symbiotic.The incidence and nutrition of the freeliving microorganisms is discussed. Shortage of substrate makes it unlikely that the N-fixers in the population can fix useful amounts of N. There is a possibility that P supply is improved, but an analysis of possible processes shows them to be rather unlikely, and evidence for them to be poor. Manganese and iron uptake can be altered by microbial activity. Growth of plants can be affected by non-nutritional bacterial effects.The ecology of Rhizobium in the soil is briefly discussed, and the varying needs of different identified strains is stressed.Mycorrhizal infection of plants leads to large growth increases in appropriate conditions. This is almost always linked to increased P uptake, but zinc and copper nutrition can also be improved. The processes involved are briefly discussed. Rapid and extensive infection is important; it is very sensitive to temperature. New modelling methods are now becoming available to measure the behaviour of the fungal infections. The microorganisms require C compounds from the plant, and new measurements of this cost are discussed. The possibility of practical use of mycorrhizal fungi seem to be improving.Keynote address     

Utility of phyllosphere N2-fixing micro-organisms in the improvement of crop growth

Summary The beneficial effect of spraying some highly active phyllosphere N₂-fixing microorganisms on high and low yielding cultivars of rice plants as compared with that of urea applied at different doses are described. The dry weight, N-content, 1000 grain weight, and yield were remarkably increased in all cases with the application of phyllosphere microorganisms. The performance of two isolates KUP₄ and KUPBR₂ with IR-8 and IR-26 rice, was better than that of 52 kg urea-N per hectare. IR-579 rice leaves in association with some phyllosphere bacteria reduced acetylene at the rate of 664–816 nmoles/g leaf/h. In IR-26 rice the effect of application of bacterial suspension at three phases of plant growth corresponded very well with that of urea application in three split doses under identical conditions. Recommended fertilizer rates produced the same yield as the half dose plus bacterial spray in the cultivars Pankaj and Rupsail. Fertilizer application in Pankaj and Rupsail rice reduced nitrogenase activity and the beneficial effects of phyllosphere N₂-fixation was reduced by 40–55%.     

Synergism between Phyllobacterium sp. (N(2)-fixer) and Bacillus licheniformis (P-solubilizer), both from a semiarid mangrove rhizosphere

Mangrove seedlings were treated with a mixture of two bacterial species, the slow-growing, N(2)-fixing bacterium Phyllobacterium sp. and the fast-growing, phosphate-solubilizing bacterium Bacillus licheniformis, both isolated from the rhizosphere from black, white, and red mangroves of a semiarid zone. Nitrogen fixation and phosphate solubilization increased when the mixture was used compared to the effects observed when adding individual cultures, notwithstanding that there was no increase in bacterial multiplication under these conditions. Inoculation of black mangrove seedlings in artificial seawater showed the mixture performed somewhat better than inoculation of the individual bacterium; more leaves were developed and higher levels of (15)N were incorporated into the leaves, although the total nitrogen level decreased. This study demonstrates that interactions between individual components of the rhizosphere of mangroves should be considered when evaluating these bacteria as plant growth promoters.     

Ecogenomic sensor reveals controls on N2-fixing microorganisms in the North Pacific Ocean

Nitrogen-fixing microorganisms (diazotrophs) are keystone species that reduce atmospheric dinitrogen (N₂) gas to fixed nitrogen (N), thereby accounting for much of N-based new production annually in the oligotrophic North Pacific. However, current approaches to study N₂ fixation provide relatively limited spatiotemporal sampling resolution; hence, little is known about the ecological controls on these microorganisms or the scales over which they change. In the present study, we used a drifting robotic gene sensor to obtain high-resolution data on the distributions and abundances of N₂-fixing populations over small spatiotemporal scales. The resulting measurements demonstrate that concentrations of N₂ fixers can be highly variable, changing in abundance by nearly three orders of magnitude in less than 2 days and 30 km. Concurrent shipboard measurements and long-term time-series sampling uncovered a striking and previously unrecognized correlation between phosphate, which is undergoing long-term change in the region, and N₂-fixing cyanobacterial abundances. These results underscore the value of high-resolution sampling and its applications for modeling the effects of global change.     

Alanine dehydrogenase of the N2-fixing blue-green alga,Anabaena cylindrica

The l-alanine dehydrogenase (ADH) of Anabaena cylindrica has been purified 700-fold. It has a molecular weight of approximately 270000, has 6 sub-units, each of molecular weight approximately 43000, and shows activity both in the aminating and deaminating directions. The enzyme is NADH/NAD⁺ specific and oxaloacetate can partially substitute for pyruvate. The K _m ^app for NAD⁺ is 14 M and 60 M at low and high NAD⁺ concentrations, respectively. The K _m ^app for l-alanine is 0.4 mM, that for pyruvate is 0.11 mM, and that for oxaloacetate is 3.0 mM. The K _m ^app for NH ₄ ⁺ varies from 8–133 mM depending on the pH, being lowest at high pH levels (pH 8.7 or above). Alanine, serine and glycine inhibit ADH activity in the aminating direction. The enzyme is active both in heterocysts and vegetative cells and activity is higher in nitrogen-starved cultures than in N₂-fixing cultures. The data suggest that although alanine is formed by the aminating activity of ADH, entry of newly fixed ammonia into organic combination does not occur primarily via ADH in N₂-fixing cultures of A. cylindrica. Ammonia assimilation via ADH may be important in cultures with an excess of available nitrogen. The deaminating activity of the enzyme may be important under conditions of nitrogen-deficiency.Abbreviations ADH alanine dehydrogenase - DEAE diethylamino ethyl cellulose - EDTA ethylenediamine tetraacetic acid - GDH glutamic dehydrogenase - GS glutamine synthetase - GOT aspartate-glutamate aminotransferase - NAD⁺ nicotinamide adenine dinucleotide - NADH reduced nicotinamide adenine dinucleotide - NADP⁺ nicotinamide adenine dinucleotide phosphate - NADPH reduced nicotinamide adenine dinucleotide phosphate - SDS sodium dodecyl sulphate - Tris tris(hydroxymethyl) aminomethane     

The response of field grownPhaseolus vulgaris to Rhizobium inoculation and the quantification of N2 fixation using15N

Summary A field experiment was performed to assess the effects of Rhizobium inoculation and nitrogen fertilizer (100 kg N ha^–1) on four cultivars of Phaseolus beans; Carioca, Negro Argel, Venezuela 350 and Rio Tibagi. In the inoculated treatment 2.5 kg N ha^–1 of¹⁵N labelled fertilizer was added in order to apply the isotope dilution technique to quantify the contribution of N₂ fixation to the nutrition of these cultivars.Nodulation of all cultivars in the uninoculated treatments was poor, but the cultivars Carioca and Negro Argel were well nodulated when inoculated. Even when inoculated, nodulation of the cultivars Venezuela 350 and Rio Tibagi was poor and these cultivars showed little response to inoculation in terms of nitrogen accumulation or grain yield. The estimates of the contribution of N₂ fixation estimated using the isotope dilution technique, for the Carioca and Negro Argel cultivars, amounted to 31.7 and 18.4 kg N ha^–1 respectively. These two cultivars produced 991 and 883 kg ha^–1 of grain, respectively, when inoculated and 663 and 620 kg ha^–1 with the addition of 100 kg N ha^–1 of N fertilizer. The response to nitrogen was particularly poor due to high leaching losses in the very sandy soil at the experimental site.The Venezuela 350 and Rio Tibagi cultivars only responded to N fertilizer and not to inoculation with Rhizobium which stresses the great importance of selecting plant cultivars for nitrogen fixation in the field.     

Effects of inoculation ofPoa pratensis andTriticum aestivum with root-associated,N2-fixing Klebsiella,Enterobacter and Azospirillum

Strains ofKlebsiella pneumoniae, Klebsiella terrigena, Enterobacter agglomerans andAzospirillum lipoferum were compared as diazotrophic inoculants in association withPoa pratensis andTriticum aestivum. Each strain colonized both plants in numbers ranging from 10⁴ to 10⁷ bacteria per root, and electron microscopy and immunofluorescence staining of inoculated roots revealed bacteria mainly on root hairs. Indirect immunofluorescence with specific antifimbriae antibodies showed that the enteric bacteria expressed their fimbria in both associations. All associations were positive in an acetylene reduction test but only in half of them was atmospheric nitrogen transferred to the plant. In the inoculated plants, variable effects in the dry matter and N yields in both hosts were observed and no correlation was found between dry matter, nitrogen content or the amount of fixed nitrogen. In infected plants, the number of root hairs and lateral roots increased and the length of the zone of elongation decreased. The changes in root morphology were more evident in associations with enteric bacteria than with Azospirillum. The results give further evidence on the importance of bacterial adhesion in associative N₂ fixation and suggest that bacteria-induced physiological changes in plant roots may be more important than the amount of nitrogen transferred to the plant.     

Isolation and identification of N2-fixing microorganisms from the rhizosphere of Capparis spinosa (L.)

Four bacterial strains, Pseudomonas stutzeri var. mendocina, Comamonas sp., Agrobacterium tumefaciens biovar. 2 and Sphingobacterium sp., isolated from the rhizosphere of wild-grown caper (Capparis spinosa L.) plants were able to fix N₂ as shown by their growth in nitrogen-free medium and by the acetylene reduction test. P. stutzeri var. mendocina and Comamonas sp. contained DNA homologous to the Klebsiella pneumoniae M5a1 nifHDK genes. No hybridization was found with total DNA from either A. tumefaciens biovar. 2 or Sphingobacterium sp. using nifHDK probes from either K. pneumoniae or Rhizobium meliloti.     

Inoculation of forage grasses with N2-fixing Enterobacteriaceae

Summary Previous investigations indicated some forage grass roots in Texas are heavily colonized with N₂-fixing bacteria. The most numerous N₂-fixing bacteria were in the genera Klebsiella and Enterobacter. In the present investigation inoculation experiments were conducted using 18 isolates of these bacteria to determine if a N₂-fixing association could be established between the bacteria and the grassesCynodon dactylon andPanicum coloratum. Plants were grown in soil for approximately 5 months in a greenhouse and were measured periodically for dry matter, nitrogen accumulation, and acetylene reduction activity. Results of the investigation indicated that 25% of the plant-soil systems were active in acetylene reduction and the activity was high enough to indicate agronomically significant quantities of N₂ were being fixed (>8kg N ha⁻¹). However, plant systems extrapolated to fix>8 kg N ha⁻¹ contained less nitrogen and accumulated less dry matter than plants less active in acetylene reduction. Inocula could not be re-isolated from healthy grass roots indicating that the N₂-fixing activity may have not have been closely assiciated with plant roots. Future research is needed to determine factors limiting colonization of grass roots.     

The purification of hydrogenase II (uptake hydrogenase) from the anaerobic N2-fixing bacterium Clostridium pasteurianum

The H₂ uptake activity (units/mg protein) of Clostridium pasteurianum cells with methylene blue as the electron acceptor increases with cell density independent of the growth conditions. The H₂ evolution activity (units/mg protein) of the same cells with reduced methyl viologen as the electron donor remains fairly constant under all growth conditions tested. Cells grown under N₂-fixing conditions have the highest H₂ uptake activity and were used for the purification of hydrogenase II (uptake hydrogenase). Attempts to separate hydrogenase II from hydrogenase I (bidirectional hydrogenase) by a previously published method were unreliable. We report here a new large-scale purification procedure which employs a rapid membrane filtration system to fractionate cell-free extracts. Hydrogenases I and II were easily filtered into the low-molecular-weight fraction (M_r less than 100 000), and from this, hydrogenase II was further purified to a homogeneous state. Hydrogenase II is a monomeric iron-sulfur protein of molecular weight 53 000 containing eight iron atoms and eight acid-labile sulfur atoms per molecule. Hydrogenase II catalyzes both H₂ oxidation and H₂ evolution at rates of 3000 and 5.9 μmol H₂ consumed or evolved/min per mg protein, respectively. The purification procedure for hydrogenase II using the filtration system described greatly facilitates the large-scale purification of hydrogenase I and other enzymes from cell-free extracts of C. pasteurianum.     

Physiological studies on N2-fixing root nodules ofDatisca cannabina L. andAlnus nitida Endl. from Himalaya region in Pakistan

Summary The nodulation and the morphology and physiology of the nodules were studied onDatisca cannabina, a perennial herb from northern Pakistan andAlnus nitida, a nodulated tree in the same locality. Both species bear coralloid clusters of actinorhizal nodules. The main free amino acid inD. cannabina nodules was arginine while the predominant free amino acid inA. nitida nodules was citrulline. The infectivity of crushed nodules of both types of plants on their respective host was about 10⁶ infective particles per gram of nodule fresh wt. In cross-inoculation experiments crushed nodule inoculum fromA. nitida failed to induce nodulation onD. cannabina seedlings but the crushed nodule inoculum fromD. cannabina caused low nodulation on seedlings ofA. nitida (10³ infective particles. g. nodule fresh wt.).The activity of nitrogenase, hydrogenase and respiration (O₂ uptake) were measured in detached nodules, nodule homogenates and the 20 m residue and 20 m filtrate preparations from the nodules of both species. Both species showed similar patterns of activities except that only the nodule homogenate and 20 m residue preparations fromD. cannabina showed pronounced enhancement of the O₂ uptake by succinate which was further stimulated by ADP. This has in part been explained by the presence of mitochondria in close connection with the endophyte.     

Rice carbohydrate dynamics regulate endophytic colonization of Diaporthe liquidambaris in response to external nitrogen

The fungal endophyte Diaporthe liquidambaris can establish mutualistic relationships with rice (Oryza sativa) and promote plant growth, specifically under low nitrogen (N) conditions, but the underlying mechanisms are largely unknown. The fungal nutritional status, which is based on host carbohydrate dynamics, determines symbiotic outcomes. In this study, an experiment with (E+) and without (E-) D. liquidambaris under low, moderate and high N conditions demonstrated that D. liquidambaris promoted chlorophyll biosynthesis and water-soluble carbohydrate (WSCs) accumulation in rice roots and root exudates under a lower N supply. In addition, D. liquidambaris grew better on substrates containing E+ root extracts in vitro due to the carbon (C) resource compared to that on E-treatments. Further experiments with manipulated environmental conditions (light and temperature) in vivo indicated that increased root WSCs were closely related to improved fungal colonization. We concluded that the presence of the fungal endophyte induced an enhanced mutualistic system by mediating host carbohydrate dynamics under N-poor conditions.     

Aluminum tolerance in nodulated N2-fixing legumes species native to two contrasting savanna sites

Eight native legume species were analyzed for their tolerance to high soil aluminium (Al) levels in terms of the Al, iron (Fe) and calcium (Ca) contents in different plant organs and spatial distribution in two contrasting savanna sites in Venezuela. The less fertile soils in site 1 (S-1) are characterized by a pH of 4 and contents of Al 8.4, Fe 0.9 and Ca 0.2 cmol kg^–1. The relatively more fertile soils in site 2 (S-2) have a pH of 5.4, with Al 1.3, Fe 0.4 and Ca 2.2 cmol kg^–1. Examples of nodulated Chamaecrista flexiuosa, Clitoria guianensis, Galactia jussieuana, Stylosanthes elegans and Zornia curvata were harvested at S-1. Nodulated examples of the same species plus examples of Centrosema pubescens, Chamaecrista tetraphilla and Phaseolus gracillis were harvested at S-2. All S-1 species were categorized as Al-tolerant. In turn, C. pubescens, C. tetraphilla and P. gracillis were classified as non-tolerant to soil Al contents above 1.3 cmol kg^–1. With the exception of S. elegans, all S-1 species accumulate Al in underground organs, mainly in secondary roots, and were considered root-Al accumulators. The accumulation of Al in aboveground organs of S. elegans allowed the classification of this species as leaf-Al accumulator. Over all the species, the Al contents in underground and aboveground organs were 11 and 8-fold higher in S-1 than in S-2 species, respectively. However, the accumulation of Al in roots of S-1 species did not inhibit their symbiotic performance as indicated by the absence of significant differences in the relative abundance of ureides between S-1 and S-2 species. This situation could be partially explained by the exclusion of Al from nodule tissues. In S-1 and S2 species, Al contents in nodules were below detectable values. Significant differences in Ca content were also encountered between S-1 and S-2 species, with the highest values in S-2 species. Except for S. elegans, there was a significant positive correlation between Al and Fe contents in the different organs of S-1 and S-2 species, as well as a significant negative correlation between Al and Ca contents in S-1 species.     

一株珊瑚礁-海草床复合生态系统固氮菌的分离与鉴定

三亚珊瑚礁自然保护区部分珊瑚礁退化后逐渐演替为以泰来藻(Thalassia hemprichii)为优势种的海草床群落,采用选择性无氮培养基从泰来藻植株的根际,分离得到一株固氮菌,编号为G33-1,经形态学、生理生化鉴定和16SrDNA及固氮基因nifH的序列分析,初步鉴定为成团泛菌(Pantoea agglomerans)。该菌为革兰氏阴性菌,以周生鞭毛运动,呈直杆状,菌落圆形,半透明乳白色,比较湿润,有光泽,直径约1mm,低凸,光滑,边缘比较整齐。最适培养条件为:氯化钠浓度25‰,生长温度为37°C,起始pH值为8。与成团泛菌标准菌株(ATCC27155TM)相比较,在碳源利用、精氨酸双水解、苯丙氨酸脱胺酶、鸟氨酸脱胺酶、以及生长温度和盐度等方面都具有较高的相似性,以16SrDNA为基础构建的系统进化树分析结果,表明其与成团泛菌属Pantoeaag-glomeransWAB1870进化距离最近,相似性大于99%。此外,利用乙炔还原法对固氮活性进行测定,其具有较高的固氮活性,达299.16nmolC2H2/(mL.h)。     

Nitrogen limitations to field bean productivity: A comparison of combined nitrogen applications with Rhizobium inoculation

Summary Nitrogen limitations to the yield of a field crop ofVicia faba have been examined. Application of nitrogen totalling 560 kg/ha increased dry matter yield at flowering by 674 kg/ha (32%) and grain yield at final harvest by 1.6 tonnes/ha (24%). Attempts to reduce nitrogen limitations by replacing the native rhizobia with strains ofRhizobium leguminosarum selected for high rates of nitrogen fixation were unsuccessful but the introduction of poor rhizobia reduced grain yield. The reasons for this and the implications of the results for crop improvement are discussed.     

Nitrogenase activity and N2 fixation are stimulated by elevated CO2 in a tropical N2-fixing tree

 Seeds of Gliricidia sepium, a fast-growing woody legume native to seasonal tropical forests of Central America, were inoculated with N₂-fixing Rhizobium bacteria and grown in environmentally controlled glasshouses for 67–71 days under ambient CO₂ (35 Pa) and elevated CO₂ (70 Pa) conditions. Seedlings were watered with an N-free, but otherwise complete, nutrient solution such that bacterial N₂ fixation was the only source of N available to the plant. The primary objective of our study was to quantify the effect of CO₂ enrichment on the kinetics of photosynthate transport to nodules and determine its subsequent effect on N₂ fixation. Photosynthetic rates and carbon storage in leaves were higher in elevated CO₂ plants indicating that more carbon was available for transport to nodules. A ¹⁴CO₂ pulse-chase experiment demonstrated that photosynthetically fixed carbon was supplied by leaves to nodules at a faster rate when plants were grown in elevated CO₂. Greater rates of carbon supply to nodules did not affect nodule mass per plant, but did increase specific nitrogenase activity (SNA) and total nitrogenase activity (TNA) resulting in greater N₂ fixation. In fact, a 23% increase in the rate of carbon supplied to nodules coincided with a 23% increase in SNA for plants grown in elevated CO₂, suggesting a direct correlation between carbon supply and nitrogenase activity. The improvement in plant N status produced much larger plants when grown in elevated CO₂. These results suggest that Gliricidia, and possibly other N₂-fixing trees, may show an early and positive growth response to elevated CO₂, even in severely N-deficient soils, due to increased nitrogenase activity. Received: 27 February 1996 / Accepted: 19 June 1996     

Delivery of N2 to bacteroids in simulated soybean nodule cells: consideration of gradients of concentration of dissolved N2 in cell walls,cytoplasm, and symbiosomes

Summary The previously published simulation of physiological functions occurring in infected cells of soybean nodules has been extended to include consideration of the diffusion of N₂ from the outside of a nodule to the nitrogen-fixing bacteroids, in relation to published values for the apparentK _m(N₂) for nitrogen fixation in the soybean nodule system. Nitrogen fixation is driven by bacteroid respiration, so increases in the average relative oxygenation (Y) of cytoplasmic leghaemoglobin lead to increased bacteroid respiration, increased nitrogen fixation, and greater differences in concentration of dissolved N₂ between the cell surface and the innermost bacteroids (d[N₂]). Over the range ofY considered, values for d[N₂] were from 5.2- to 6.2-fold greater than the corresponding values for d[O₂], because of facilitation of O₂ flux by cytoplasmic leghaemoglobin. Gradients of [N₂] within symbiosomes are small relative to cytoplasmic values and at the symbiosome surface [N₂] was greater than 0.4 mol/m³ at the greatest rates of nitrogen fixation calculated. Therefore, it is unlikely that values for [N₂] anywhere in the infected cell are low enough to affect rates of nitrogen fixation significantly, unless low external atmospheric N₂ pressures are used experimentally.Abbreviations Lb leghaemoglobin - LbO₂ oxyleghaemoglobin - [O₂], [N₂ concentrations of free, dissolved oxygen and nitrogen - Y fractional oxygenation of leghaemoglobin     

Effect of varying periods of inoculation ofAzolla pinnata R. Brown on its growth,nitrogen fixation and response to rice crop

Summary Inoculation of water fernAzolla pinnata R. Brown (Bangkok isolate) at the rate of 500kg fresh weight ha⁻¹ in rice fields at weekly intervals after planting in addition to 30 kg N ha⁻¹ as urea showed a decrease in its growth and N₂-fixation with delay in application. Use of Azolla up to 3 weeks after planting (WAP) during wet and 4 WAP during dry season produced significantly more grain yield than 30 kg N ha⁻¹, whereas its application upto one WAP produced more grain yield than 60 kg N ha⁻¹. Grain yield with Azolla applied at the time of planting was similar to that of 60 kg N treatment during the wet season. Higher grain yields in zero and one WAP Azolla treatments resulted due to increase in both number of panicles m⁻² and number of grains/panicle while the subsequent Azolla inoculations increased grain yield mainly by producing more number of grains/panicle. Dry matter and total N yields at maturity of rice crop were more with Azolla application upto 3 WAP during wet and 2 WAP during dry season while the reduction in sterility (%) was observed upto one WAP over 30 kg N ha⁻¹ during both seasons. Number of tillers m⁻² and dry matter production at maximum tillering and flowering were more than 30 kg N ha⁻¹ with the use of Azolla upto one WAP. Increased grain N yield was observed with the use of Azolla upto 4 WAP during two seasons whereas straw N yield increased upto one WAP during wet and 2 WAP during dry season.