8 research outputs found
Classical Soybean (Glycine max (L.) Merr) Symbionts, Sinorhizobium fredii USDA191 and Bradyrhizobium diazoefficiens USDA110, Reveal Contrasting Symbiotic Phenotype on Pigeon Pea (Cajanus cajan (L.) Millsp)
Pigeon pea (Cajanus cajan (L.) Millspaugh) is cultivated widely in semiarid agricultural regions in over 90 countries around the world. This important legume can enter into symbiotic associations with a wide range of rhizobia including Bradyrhizobium and fast-growing rhizobia. In comparison with other major legumes such as soybean and common bean, only limited information is available on the symbiotic interaction of pigeon pea with rhizobia. In this study, we investigated the ability of two classical soybean symbionts—S. fredii USDA191 and B. diazoefficiens USDA110—and their type 3 secretion system (T3SS) mutants, to nodulate pigeon pea. Both S. fredii USDA191 and a T3SS mutant S. fredii RCB26 formed nitrogen-fixing nodules on pigeon pea. Inoculation of pigeon pea roots with B. diazoefficiens USDA110 and B. diazoefficiens Δ136 (a T3SS mutant) resulted in the formation of Fix− and Fix+ nodules, respectively. Light and transmission electron microscopy of Fix- nodules initiated by B. diazoefficiens USDA110 revealed the complete absence of rhizobia within these nodules. In contrast, Fix+ nodules formed by B. diazoefficiens Δ136 revealed a central region that was completely filled with rhizobia. Ultrastructural investigation revealed the presence of numerous bacteroids surrounded by peribacteroid membranes in the infected cells. Analysis of nodule proteins by one- and two-dimensional gel electrophoresis revealed that leghemoglobin was absent in B. diazoefficiens USDA110 nodules, while it was abundantly present in B. diazoefficiens Δ136 nodules. Results of competitive nodulation assays indicated that B. diazoefficiens Δ136 had greater competitiveness for nodulation on pigeon pea than did the wild type strain. Our results suggest that this T3SS mutant of B. diazoefficiens, due to its greater competitiveness and ability to form Fix+ nodules, could be exploited as a potential inoculant to boost pigeon pea productivity
Effect of Heat Stress on Seed Protein Composition and Ultrastructure of Protein Storage Vacuoles in the Cotyledonary Parenchyma Cells of Soybean Genotypes That Are Either Tolerant or Sensitive to Elevated Temperatures
High growth temperatures negatively affect soybean (Glycine max (L.) Merr) yields and seed quality. Soybean plants, heat stressed during seed development, produce seed that exhibit wrinkling, discoloration, poor seed germination, and have an increased potential for incidence of pathogen infection and an overall decrease in economic value. Soybean breeders have identified a heat stress tolerant exotic landrace genotype, which has been used in traditional hybridization to generate experimental genotypes, with improved seed yield and heat tolerance. Here, we have investigated the seed protein composition and ultrastructure of cotyledonary parenchyma cells of soybean genotypes that are either susceptible or tolerant to high growth temperatures. Biochemical analyses of seed proteins isolated from heat-tolerant and heat-sensitive genotypes produced under 28/22 °C (control), 36/24 °C (moderate), and 42/26 °C (extreme) day/night temperatures revealed that the accumulation in soybean seeds of lipoxygenase, the β-subunit of β-conglycinin, sucrose binding protein and Bowman-Birk protease inhibitor were negatively impacted by extreme heat stress in both genotypes, but these effects were less pronounced in the heat-tolerant genotype. Western blot analysis showed elevated accumulation of heat shock proteins (HSP70 and HSP17.6) in both lines in response to elevated temperatures during seed fill. Transmission electron microscopy showed that heat stress caused dramatic structural changes in the storage parenchyma cells. Extreme heat stress disrupted the structure and the membrane integrity of protein storage vacuoles, organelles that accumulate seed storage proteins. The detachment of the plasma membrane from the cell wall (plasmolysis) was commonly observed in the cells of the sensitive line. In contrast, these structural changes were less pronounced in the tolerant genotype, even under extreme heat stress, cells, for the most part, retained their structural integrity. The results of our study demonstrate the contrasting effects of heat stress on the seed protein composition and ultrastructural alterations that contribute to the tolerant genotype’s ability to tolerate high temperatures during seed development
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Impact of overexpression of cytosolic isoform of O-acetylserine sulfhydrylase on soybean nodulation and nodule metabolome
Abstract Nitrogen-fixing nodules, which are also major sites of sulfur assimilation, contribute significantly to the sulfur needs of whole soybean plants. Nodules are the predominant sites for cysteine accumulation and the activity of O-acetylserine(thiol)lyase (OASS) is central to the sulfur assimilation process in plants. Here, we examined the impact of overexpressing OASS on soybean nodulation and nodule metabolome. Overexpression of OASS did not affect the nodule number, but negatively impacted plant growth. HPLC measurement of antioxidant metabolites demonstrated that levels of cysteine, glutathione, and homoglutathione nearly doubled in OASS overexpressing nodules when compared to control nodules. Metabolite profiling by LC-MS and GC-MS demonstrated that several metabolites related to serine, aspartate, glutamate, and branched-chain amino acid pathways were significantly elevated in OASS overexpressing nodules. Striking differences were also observed in the flavonoid levels between the OASS overexpressing and control soybean nodules. Our results suggest that OASS overexpressing plants compensate for the increase in carbon requirement for sulfur assimilation by reducing the biosynthesis of some amino acids, and by replenishing the TCA cycle through fatty acid hydrolysis. These data may indicate that in OASS overexpressing soybean nodules there is a moderate decease in the supply of energy metabolites to the nodule, which is then compensated by the degradation of cellular components to meet the needs of the nodule energy metabolism
Development and Characterization of a Soybean Experimental Line Lacking the α′ Subunit of β‑Conglycinin and G1, G2, and G4 Glycinin
A soybean
experimental line (BSH-3) devoid of a subset of seed
storage proteins was developed by crossing a mutant donor line “HS99B”
with a Chinese cultivar “Dongnong47” (DN47). One-dimensional
and high-resolution 2-D gel electrophoresis revealed the absence of
G1 (A1<sub>a</sub>B<sub>2)</sub>, G2 (A<sub>2</sub>B1<sub>a)</sub>, and G4 (A<sub>5</sub>A<sub>4</sub>B<sub>3)</sub> glycinin and the
α′ subunit of β-conglycinin in BSH-3 seeds. Despite
the lack of these abundant seed proteins, BSH-3 seeds still accumulated
38% protein. BSH-3 seeds also accumulated high levels of free amino
acids as compared with DN47 seeds, particularly arginine, and the
amount of several essential amino acids were significantly elevated
in BSH-3 seeds. Elevated accumulation of α and β-subunit
of β-conglycinin, G5 glycinin, Kunitz trypsin inhibitor, and
Bowman-Birk protease inhibitor indicates seed proteome rebalancing
in BSH-3 seeds. Immunoblot analysis using sera from soybean allergic
patients demonstrated the complete lack of a major allergen (α′
subunit of β-conglycinin) in BSH-3 seeds. However, elevated
levels of other allergens were found in BSH-3 seeds due to proteome
rebalancing. Transmission electron microscopy observation of mature
seeds of BSH-3 revealed striking differences in the appearance of
the protein storage vacuoles when compared with DN47
Proteomic Analysis of Pigeonpea (Cajanus cajan) Seeds Reveals the Accumulation of Numerous Stress-Related Proteins
Pigeonpea
is one of the major sources of dietary protein for more
than a billion people living in South Asia. This hardy legume is often
grown in low-input and risk-prone marginal environments. Considerable
research effort has been devoted by a global research consortium to
develop genomic resources for the improvement of this legume crop.
These efforts have resulted in the elucidation of the complete genome
sequence of pigeonpea. Despite these developments, little is known
about the seed proteome of this important crop. Here, we report the
proteome of pigeonpea seed. To enable the isolation of maximum number
of seed proteins, including those that are present in very low amounts,
three different protein fractions were obtained by employing different
extraction media. High-resolution two-dimensional (2-D) electrophoresis
followed by MALDI-TOF-TOF-MS/MS analysis of these protein fractions
resulted in the identification of 373 pigeonpea seed proteins. Consistent
with the reported high degree of synteny between the pigeonpea and
soybean genomes, a large number of pigeonpea seed proteins exhibited
significant amino acid homology with soybean seed proteins. Our proteomic
analysis identified a large number of stress-related proteins, presumably
due to its adaptation to drought-prone environments. The availability
of a pigeonpea seed proteome reference map should shed light on the
roles of these identified proteins in various biological processes
and facilitate the improvement of seed composition
Biochemical and Anatomical Investigation of Sesbania herbacea (Mill.) McVaugh Nodules Grown under Flooded and Non-Flooded Conditions
Sesbania herbacea, a native North American fast-growing legume, thrives in wet and waterlogged conditions. This legume enters into symbiotic association with rhizobia, resulting in the formation of nitrogen-fixing nodules on the roots. A flooding-induced anaerobic environment imposes a challenge for the survival of rhizobia and negatively impacts nodulation. Very little information is available on how S. herbacea is able to thrive and efficiently fix N2 in flooded conditions. In this study, we found that Sesbania plants grown under flooded conditions were significantly taller, produced more biomass, and formed more nodules when compared to plants grown on dry land. Transmission electron microscopy of Sesbania nodules revealed bacteroids from flooded nodules contained prominent polyhydroxybutyrate crystals, which were absent in non-flooded nodules. Gas and ion chromatography mass spectrometry analysis of nodule metabolites revealed a marked decrease in asparagine and an increase in the levels of gamma aminobutyric acid in flooded nodules. 2-D gel electrophoresis of nodule bacteroid proteins revealed flooding-induced changes in their protein profiles. Several of the bacteroid proteins that were prominent in flooded nodules were identified by mass spectrometry to be members of the ABC transporter family. The activities of several key enzymes involved in nitrogen metabolism was altered in Sesbania flooded nodules. Aspartate aminotransferase (AspAT), an enzyme with a vital role in the assimilation of reduced nitrogen, was dramatically elevated in flooded nodules. The results of our study highlight the potential of S. herbacea as a green manure and sheds light on the morphological, structural, and biochemical adaptations that enable S. herbacea to thrive and efficiently fix N2 in flooded conditions
Introgression of Leginsulin, a Cysteine-Rich Protein, and High-Protein Trait from an Asian Soybean Plant Introduction Genotype into a North American Experimental Soybean Line
Soybean is an important protein source
for both humans and animals.
However, soybean proteins are relatively poor in the sulfur-containing
amino acids, cysteine and methionine. Improving the content of endogenous
proteins rich in sulfur-containing amino acids could enhance the nutritive
value of soybean meal. Leginsulin, a cysteine-rich peptide, predominantly
accumulates in Asian soybean accessions but not in most North American
cultivars. By screening diverse soybean accessions from the USDA Soybean
Germplasm Collection, we were able to identify one plant introduction,
PI 427138, as a high-protein line with relatively high amounts of
both elemental sulfur and leginsulin. We introgressed these desirable
traits from PI 427138 into an experimental line with the aim of improving
the overall protein content and quality of seed proteins. Biochemical
characterization of inbred progenies from the cross of LD00-3309 with
PI 427138 grown at six locations revealed stable ingression of high
protein, high elemental sulfur, and high leginsulin accumulation.
Comparison of soybean seed proteins resolved by high-resolution 2-D
gel electrophoresis in combination with Delta2D image analysis software
revealed preferential accumulation of a few glycinin subunits contributed
to the increased protein content in the introgressed lines. Amino
acid analysis revealed that even though the leginsulin introgressed
lines had higher protein, leginsulin, and elemental sulfur, the overall
concentration of sulfur-containing amino acids was not significantly
altered when compared with the parental lines. The experimental soybean
lines developed during this study (Leg-3, Leg-7, and Leg-8) lack A5,
A4, and B3 glycinin subunits and could be utilized in breeding programs
to develop high-quality tofu cultivars