N2-Fixation in Alfalfa (Medicago sativa L.) Seedlings and Rhizobium meliloti L. Grown in Vitro Under Salt and Drought Stresses

Mohamad, Ramzi Muhiddin

01 May 1987

Alfalfa, Medicago sativa L., cultivars, breeding lines and germplasm releases (populations) and Rhizobium meliloti L. strains that exhibit nitrogen fixation efficiency and tolerance to salinity and drought stresses should enhance seedling establishment, increase yields, reduce nitrogen dependency on petroleum-based nitrogen fertilizers, and allow wider use of irrigated lands in semiarid and a rid regions. In vitro experiments were conducted to determine relative salt (sodium chloride -- NaCl) tolerance: l) during germination and early seedling growth of 229 alfalfa populations from North Africa, the Middle East and the United States, 2) survival and growth of 92 rhizobial strains obtained from different laboratories in the United States or isolated from host plants growing in saline and arid regions of the Intermountain west, 3) compatibility, nodulation and nitrogen fixation efficiency of the most salt-tolerant alfalfa populations and rhizobial strains, and 4) survival, nodulation and nitrogen fixation efficiency of the most salt-tolerant alfalfa populations and rhizobial strain tested under drought conditions. Results from screening of alfalfa at salinity levels of 0 to 3.2 S m-1 (0.1 S m-1 = 640 mg L-1 = 10 mM NaCl at 25° C) indicated 29 populations exhibited salt tolerance at 2.8 S m-1. At salinity levels of 0 to 7.2 S m-1, 14 rhizobial strains exhibited salt tolerance at 6.4 s m-1. Compatibility, nodulation and nitrogen fixation efficiency in the 29 alfalfa populations and the 14 rhizobial strains under controlled conditions showed that four of the rhizobial strains were highly compatible with all 29 populations. These 29 populations and four strains were then exposed to 0 to 1.6 S m-1 NaCl, with the result that nitrogen was fixed with highly compatible symbionts at 1.6 S m-1 NaCl. From these results, the six most highly compatible alfalfa populations and the best overall rhizobial strain were combined and tested under simulated drought stress. These populations were able to fix more nitrogen under drought stress (-0.76 MPa) (0.088 nmol seedling-1 s-1) than they did under salt stress (1.6 S m-1) (0.066 nmol seedling-1 s-1). The in vitro screening technique for acetylene reduction appears to be a useful tool for detecting physiological changes due to salinity and water stresses and for measuring seedling nitrogen fixation efficiency. Breeding for drought and salinity tolerance in conjunction with high nitrogen fix ing potential may be more realistic than breeding strictly for nitrogen fixation without regard for environmental adaptation.

N2-Fixations

Alfalfa

Medicago sativa L.

Rhizobium meliloti L.

In Vitro

Salt

Drought Stresses

Plant Sciences

Identification of “fhuA” Like Genes in Rhizobium leguminosarum ATCC 14479 and its Role in Vicibactin Transport and Investigation of Heme Bound Iron Uptake System

Khanal, Sushant

01 May 2018

Siderophores are low molecular weight, iron chelating compounds produced by many bacteria for uptake of iron in case of iron scarcity. Vicibactin is a trihydroxamate type siderophore produced by Rhizobium leguminosarum bv. trifolii ATCC 14479. This work focuses on identifying an outer membrane receptor involved in the transport of vicibactin. We have confirmed the presence of the putative fhuA gene in R. leguminosarum bv. trifolii ATCC 14479. This bacteria shows mutualistic symbiosis with the red clover plant Trifoliium prantense. Leghemoglobin, with its cofactor heme is present in the plant root nodules that surrounds the infecting organism present in the nodules. This work attempts to elucidate the ability of Rhizobium leguminosarum bv. trifolii ATCC 14479 to utilize heme-bound iron and genes involved in the transport. We have also elucidated the role of energy transducing proteins TonB- ExbB-ExbD on the heme-bound iron uptake system.

Rhizobium leguminosarum ATCC 14479

fhuA

vicibactin

heme

iron uptake

Biology

Life Sciences

Microbiology

Other Microbiology

Environmental factors and plant-to-bacteria signals effects on nodulation and nodule development of pea

Lira Junior, Mario de Andrade.

January 2001

No description available.

Plant cellular signal transduction.

Peas -- Roots -- Anatomy.

Flavonoids.

Rhizobium leguminosarum.

Root-tubercles.

Investigations into aspects of nod factor utilization for crop production

Supanjani

January 2005

No description available.

Plant cellular signal transduction.

Soybean -- Preharvest sprouting.

Mycorrhizas.

Rhizobium japonicum.

Oligosaccharides.

Bacterial Interactions of Inoculated Price's Potato Bean (<i>APIOS PRICEANA</i>): A Biological Study

Walker, Rhonda

01 December 2011

Apios priceana is a native endangered species plant found in the Southeast United States. It is characterized as a leguminous species that bears wisteria like clusters with pea like flowers, a large tuberous root and four to six inch long seed pods. It is believed the Native Americans and early European settlers relied on this species as a source of protein and utilized the seeds for cultivation of the tuberous “potato” which formed. Apios priceana contains an average of 13% fiber, 6.9% protein, 71% carbohydrate and 9 of the 11 essential amino acids needed in human diets (Walter et al.,1986). In addition, A. priceanatuberous roots contain anti-carcinogenic properties known to be used to treat prostate and breast cancer as well as lowering blood pressure and cholesterol with an added use for diabetes. If removed from the endangered species list it could prove to be a valuable agronomic crop. Its use spans human and animal consumption, bio fuel, medicinal and horticultural purposes. This research was initiated to investigate a biological symbiosis between A. priceana and known beneficial soil bacteria which may indicate growth potential of known colonies. Experimental treatments were 1) no inoculation 2) Azospirillum brasilense inoculate 3) Bradyrhizobium japonicum inoculate and 4) Rhizobium leguminosarum biovar viceae inoculate. Specimens were evaluated at 30, 60 and 90 day’s growth from emergence for taproot length, number of lateral roots and taproot girth. Due to non-germination of seeds, data presented is for treatments 2 and 3. The correlation coefficient for average taproot length, number of lateral roots developed and taproot girth per treatment was as follows: taproot length to number of lateral roots, positive correlation coefficient 0.996; taproot length to taproot girth, positive correlation coefficient 0.999; and number of lateral roots to taproot girth, positive correlation coefficient 0.991. All correlation coefficients are significant at the 0.01 level.

Bradyrhizobium japonicum

Rhizobium leguminosarum

Azospiriullum brasilense

Agricultural Science

Agriculture

Botany

Plant Pathology

Etude génétique et moléculaire de deux gènes de Medicago truncatula, DMI3 et RPG, contrôlant l'établissement de symbioses racinaires

Godfroy, Olivier Rosenberg, Charles Debelle, Frédéric

January 2008

Reproduction de : Thèse de doctorat : Biosciences végétales : Toulouse 3 : 2008. / Titre provenant de l'é215-232.

Farklı aşılama yöntemleri ile bakteri (bradyrhizobium japonicum) aşılamasının soyada azot fiksasyonuna ve tane verimine etkisi /

İşler, Erdinç. Coşkan, Ali.

January 2009

Tez (Yüksek Lisans) - Süleyman Demirel Üniversitesi, Fen Bilimleri Enstitüsü, Toprak Anabilim Dalı, 2009. / Kaynakça var.

Improving Snap Bean (Phaseolus vulgaris L.) Production under Reduced Input Systems

2015 October 1900

Snap bean (Phaseolus vulgaris L.) production by large scale commercial producers in Ethiopia is under intensive production and relies on high rates of nitrogen (N) fertilizer and irrigation during the dry season. Despite increasing interest to produce this crop, small scale farmers cannot afford the high cost of N fertilizer. Field and greenhouse experiments were conducted to test snap bean production under a low input production system better suited to small scale resource limited farmers. Field experiments were conducted in 2011 and 2012 under rain fed conditions, and in 2012 under irrigation, at three locations (Debre Zeit, Hawassa, Ziway) representing different climate zones in Ethiopia. This experiment used three N treatments: 0 and 100 kg N ha-1, and inoculation with Rhizobium etli [HB 429], and eight cultivars: Andante, Boston Contender Blue, Lomami, Melkassa 1, Melkassa 3, Paulista and Volta. The general objective of the field experiment was to determine the potential of snap bean production under a low input production system using rhizobium inoculation as the nitrogen source, and use rain fed conditions. Results obtained indicated that rhizobial inoculation and applied inorganic N increased on average the marketable pod yield of snap bean under rain fed conditions by 18 % and 43%, respectively. Nodulation and subsequent N2 fixation was not effective in improving yield or other traits of snap bean pod under irrigation, although applied N increased marketable yield by 33%. Melkassa 1 was the most suitable cultivar for a reduced input production system due to its successful nodulation characteristics, greatest N2 fixation levels and consistently good performance across locations under rain fed conditions. Commercial cultivars possessed the best pod quality characteristics and they yielded better under irrigation. Cultivars interacted with locations to affect pod traits including total soluble solids and concentrations of protein, calcium, and potassium under rain fed conditions. Snap bean cultivrs produced at Debre Zeit and Hawassa were similar in marketable yield and several other traits particularly under rain fed conditions. Zinc (Zn) concentration in pods was greatest at Hawassa both under rain fed and irrigated conditions. Conditions at Debre Zeit were the most conducive for supporting biological N2 fixation for snap bean production. The eight cultivars were also used for a greenhouse study that was evaluated treatments of drought stress of 50% field capacity (50% FC) during the vegetative (V4.4), flowering (R6) and pod formation (R7) developmental stages. Our result showed that drought stresses during reproductive stages (R6 and R7) were the most sensitive stages in deteriorating the quality of snap bean pods. Drought stress increased protein, phosphorus and Zn concentrations but it reduced iron concentration in snap bean pods. All cultivars had a similar response to drought stress. A second greenhouse experiment was conducted to test foliar application of growth regulators: the control, 10-5 M and 10-4 M concentrations of each of abscisic acid (ABA), kinetin and salicylic acid (SA); and two concentrations of yeast extract (4 g l-1 and 8 g l-1), under drought (50% FC) stressed and unstressed conditions. Foliar application of SA on snap bean under greenhouse conditions reduced the impact of drought stress, particularly the pod quality parameters: marketable yield, pod curving, texture and appearance of snap bean pods. However, application of ABA, kinetin and SA reduced pod quality of snap bean under unstressed conditions. In conclusion, pod yield improvement could be achieved by a N2 fixation system under rain fed conditions, which is more sustainable than N fertilizer inputs. Pod quality was also adequate for commercial export production. Rhizobium inoculant can therefore be used as an alternative N source, particularly under low input production system for resource-limited small-scale snap bean producers.

Snap bean

Pod quality

Drought stress

Rhizobium

Growth regulator

Nutrient concentration

Bradyrhizobium japonicum strains and mutants allow improved soybean nodulation, nitrogen fixation and yield in a short season (cool spring) area

Zhang, Hao, 1963-

January 2001

In the soybean nitrogen fixing symbiosis, suboptimal root zone temperatures (RZTs) inhibit the inception and development of nodules, leading to reduced nitrogen fixation and soybean yield. The purpose of this thesis was to evaluate the effects of selected with potential low temperature tolerant strains, originating from the northern areas of the USA, and mutants made from Bradyrhizobium japonicum USDA 110, on soybean nodulation, nitrogen fixation and yield in a short season area with cool spring conditions. Among the 40 B. japonicum strains evaluated, only USDA 30, USDA 31, 532 C and USDA 110 grew well at 15°C. USDA 30 and USDA 31 grew better than 532 C and USDA 110 at 15°C. Mutants Bj 30050--Bj 30059 could not produce lipo-chito-oligosaccharide (LCO) at measurable levels in the absence of genistein. All mutants produced more LCOs than 532 C and USDA 110 at the same temperature and genistein concentration. Temperature and genistein concentration did not affect LCO production dynamics for the following: mutant Bj 30055, 532 C and USDA 110. Both mutant production and identification of low temperature tolerant strains achieved the general objective of improved soybean nitrogen fixation in a cool climate. Inoculation with low temperature tolerant strains (USDA 30, USDA31), or mutants (Bj 30055 and Bj 30058) improved soybean development (increases in leaf area and shoot nitrogen content), nodulation (increases in nodule number and nodule weight), nitrogen fixation and yield relative to inoculation with B. japonicum strain 532 C, the strain currently included in most Canadian soybean inocula.

Rhizobium japonicum.

Soybean -- Roots.

Root-tubercles.

Nitrogen -- Fixation.

Soybean -- Yields -- Québec (Province).

Integrated pest management of Sitona lineatus L. (Coleoptera: Curculionidae) in crops of Pisum sativum L. (Fabales: Fabaceae) in Western Canada

Vankosky, Meghan Ann

Unknown Date

No description available.

Sitona lineatus

Field pea

Integrated pest management

Biological control

Thiamethoxam

Rhizobium leguminosarum

Ground beetles