The pea (Pisum sativum L.) genes sym33 and sym40 control infection thread formation and root nodule function

Two novel non-allelic mutants that were unable to fix nitrogen (Fix^?) were obtained after EMS (ethyl methyl sulfonate) mutagenesis of pea (Pisum sativum L.). Both mutants, SGEFix^?–1 and SGEFix^?–2, form two types of nodules: SGEFix^?–1 forms numerous white and some pink nodules, while mutant SGEFix^?–2 forms white nodules with a dark pit at the distal end and also some pinkish nodules. Both mutations are monogenic and recessive. In both lines the manifestation of the mutant phenotype is associated with the root genotype. White nodules of SGEFix^?–1 are characterised by hypertrophied infection threads and infection droplets, mass endocytosis of bacteria, abnormal morphological differentiation of bacteroids, and premature degradation of nodule symbiotic structures. The structure of the pink nodules of SGEFix^?–1 does not differ from that of the parental line, SGE. White nodules of SGEFix^?–2 are characterised by “locked” infection threads surrounded with abnormally thick plant cell walls. In these nodules there is no endocytosis of bacteria into host-cell cytoplasm. The pinkish nodules of SGEFix^?–2 are characterised by virtually undifferentiated bacteroids and premature degradation of nodule tissues. Thus, the novel pea symbiotic genes, sym40 and sym33, identified after complementation analysis in SGEFix^?–1 and SGEFix^?–2 lines, respectively, control early nodule developmental stages connected with infection thread formation and function.     

Features of expression of the <Emphasis Type="Italic">PsSst1</Emphasis> and <Emphasis Type="Italic">PsIgn1</Emphasis> genes in nodules of pea (<Emphasis Type="Italic">Pisum sativum</Emphasis> L.) symbiotic mutants

The sequences of the PsSst1 and PsIgn1 genes of pea (Pisum sativum L.) homologous to the symbiotic LjSST1 and LjIGN1 genes of Lotus japonicus (Regel.) K. Larsen are determined. The expression level of PsSst1 and PsIgn1 genes is determined by real-time PCR in nodules of several symbiotic mutants and original lines of pea. Lines with increased (Sprint-2Fix^– (Pssym31)) and decreased (P61 (Pssym25)) expression level of both genes are revealed along with the lines characterized by changes in the expression level of only one of these genes. The revealed features of the PsSst1 and PsIgn1 expression allow us to expand the phenotypic characterization of pea symbiotic mutants. In addition, PsSst1 and PsIgn1 cDNA is sequenced in selected mutant lines, characterized by a decreased expression level of these genes in nodules, but no mutations are found.     

The pea ( Pisum sativum L.) genes sym33 and sym40 control infection thread formation and root nodule function

Two novel non-allelic mutants that were unable to fix nitrogen (Fix⁻) were obtained after EMS (ethyl methyl sulfonate) mutagenesis of pea (Pisum sativum L.). Both mutants, SGEFix⁻–1 and SGEFix⁻–2, form two types of nodules: SGEFix⁻–1 forms numerous white and some pink nodules, while mutant SGEFix⁻–2 forms white nodules with a dark pit at the distal end and also some pinkish nodules. Both mutations are monogenic and recessive. In both lines the manifestation of the mutant phenotype is associated with the root genotype. White nodules of SGEFix⁻–1 are characterised by hypertrophied infection threads and infection droplets, mass endocytosis of bacteria, abnormal morphological differentiation of bacteroids, and premature degradation of nodule symbiotic structures. The structure of the pink nodules of SGEFix⁻–1 does not differ from that of the parental line, SGE. White nodules of SGEFix⁻–2 are characterised by “locked” infection threads surrounded with abnormally thick plant cell walls. In these nodules there is no endocytosis of bacteria into host-cell cytoplasm. The pinkish nodules of SGEFix⁻–2 are characterised by virtually undifferentiated bacteroids and premature degradation of nodule tissues. Thus, the novel pea symbiotic genes, sym40 and sym33, identified after complementation analysis in SGEFix⁻–1 and SGEFix⁻–2 lines, respectively, control early nodule developmental stages connected with infection thread formation and function. Received: 12 June 1998 / Accepted: 25 June 1998     

LjCOCH interplays with LjAPP1 to maintain the nodule development in <Emphasis Type="Italic">Lotus japonicus</Emphasis>

Legume plants develop nodules during their symbiotic interaction with rhizobia, and much progress has been made towards understanding Nod factor perception and downstream signaling pathways, while our knowledge about the maintenance of nodule organogenesis was limited. We report here the knockdown mutants of LjCOCH, an ortholog of COCHLEATA in Pisum sativum, cause severe defects in nodule organogenesis in Lotus japonicus. The mature nodule number was drastically decreased accompanied with abnormal lenticel and vascular bundle developmental defects, but not produce roots from nodules in both Ljcoch mutants and LjCOCH-RNAi transgenic hairy roots. LjAPP1, a membrane-associated soluble aminopeptidase P1, was identified to interact with LjCOCH through yeast two-hybrid screening. Unlike that of Ljcoch mutants, insertion mutants of LjAPP1 and LjAPP1-RNAi transgenic hairy roots showed increased nodule number, while the lenticel and vascular development were not affected. Gene expression analysis indicated that LjCOCH and LjAPP1 were differentially upregulated by rhizobia inoculation, and LjNF-YA1 was the major downstream target of LjCOCH and LjAPP1. Our findings suggested that LjCOCH acts as a key factor involved in determinate nodule development through direct interaction with LjAPP1 to regulate the expression of LjNF-YA1, opposite effects of LjCOCH and LjAPP1 provide a dynamic regulation of nodule development in L. japonicus.     

Diversity and symbiotic effectiveness of <Emphasis Type="Italic">Adesmia</Emphasis> spp. root nodule bacteria in central and southern Chile

Legumes in the genus Adesmia are wild species with forage and medicinal potential. Their nitrogen fixation efficiency depends on their association with soil bacteria known as rhizobia. The aim of this work was to assess the diversity and symbiotic effectiveness of root nodule bacteria from Adesmia boronioides, Adesmia emarginata and Adesmia tenella from different regions of Chile. Adesmia spp. nodules were collected from seven sites obtaining 47 isolates, which resulted in 19 distinct strains. The diversity of the strains was determined via partial sequencing of the dnaK, 16srRNA and nodA genes. The strains were authenticated as root nodule bacteria on their original host and assessed for symbiotic effectiveness on A. emarginata and A. tenella. The strains from Adesmia tenella clustered within the Mesorhizobium clade. Adesmia boronioides nodulated with Mesorhizobium sp., Rhizobium leguminosarum and Bradyrhizobium sp. The rhizobia from A. emarginata were identified as Burkholderia spp, which was symbiotically ineffective on this species and on A. tenella. Strains isolated from Adesmia emarginata nodules, but unable to induce nodulation, were identified as Labrys methylaminiphilus. Labrys strain AG-49 significantly increased root dry weight in A. emarginata. The nodA genes from Adesmia strains were unique and correlated to legume host. A. emarginata was effectively nodulated by Bradyrhizobium AG-64 and A. tenella by Mesorhizobium strains AG-51 and AG.52. It is concluded that Adesmia emarginata, A. tenella and A. boronioides are associated to diverse bacterial symbionts and selection of an effective inoculant is a key step to assist Adesmia spp. adaptation and restoration.     

The crucial role of roots in increased cadmium-tolerance and Cd-accumulation in the pea mutant <Emphasis Type="Italic">SGECd</Emphasis><Superscript><Emphasis Type="Italic">t</Emphasis></Superscript>

Elucidation of mechanisms underlying plant tolerance to cadmium, a widespread toxic soil pollutant, and accumulation of Cd in plants are urgent tasks. For this purposes, the pea (Pisum sativum L.) mutant SGECd^t (obtained by treatment of the laboratory pea line SGE with ethylmethane sulfonate) was reciprocally grafted with the parental line SGE, and four scion/rootstock combinations were obtained: SGE/SGE, SGECd^t/SGECd^t, SGE/SGECd^t, and SGECd^t/SGE. They were grown in hydroponics in the presence of 1 μM CdCl₂ for 30 d. The SGE and SGECd^t scions on the SGECd^t rootstock had a higher root and shoot biomass and an elevated root and shoot Cd content compared with the grafts having SGE rootstock. Only the grafts with the SGE rootstock showed chlorosis and roots demonstrating symptoms of Cd toxicity. The content of nutrient elements in roots (Fe, K, Mg, Mn, Na, P, and Zn) was higher in the grafts having the SGECd^t rootstock, and three elements, namely Ca, Fe, and Mn, were efficiently transported by the SGECd^t root to the shoot of these grafts. The content of other measured elements (K, Mg, Na, P, and Zn) was similar in the root and shoot in all the grafts. Then, the non-grafted plants were grown in the presence of Cd and subjected to deficit or excess concentrations of Ca, Fe, or Mn. Exclusion of these elements from the nutrient solution retained or increased differences between SGE and SGECd^t in growth response to Cd toxicity, whereas excess of Ca, Fe, or Mn decreased or eliminated such differences. The obtained results assign a principal role of roots to realizing the increased Cd-tolerance and Cdaccumulation in the SGECd^t mutant. Efficient translocation of Ca, Fe, and Mn from roots to shoots appeared to counteract Cd toxicity, although Cd was actively taken up by roots and accumulated in shoots.     

Single point mutations enhance activity of <Emphasis Type="Italic">cis</Emphasis>-epoxysuccinate hydrolase

Objectives

To enhance activity of cis-epoxysuccinate hydrolase from Klebsiella sp. BK-58 for converting cis-epoxysuccinate to tartrate.

Results

By semi-saturation mutagenesis, all the mutants of the six important conserved residues almost completely lost activity. Then random mutation by error-prone PCR and high throughput screening were further performed to screen higher activity enzyme. We obtained a positive mutant F10D after screening 6000 mutations. Saturation mutagenesis on residues Phe10 showed that most of mutants exhibited higher activity than the wild-type, and the highest mutant was F10Q with activity of 812 U mg^?1 (k _cat /K _m , 9.8 ± 0.1 mM^?1 s^?1), which was 230 % higher than that of wild-type enzyme 355 U mg^?1 (k _cat /K _m , 5.3 ± 0.1 mM^?1 s^?1). However, the thermostability of the mutant F10Q slightly decreased.

Conclusions

The catalytic activity of a cis-epoxysuccinate hydrolase was efficient improved by a single mutation F10Q and Phe10 might play an important role in the catalysis.

     

Characterization and Proteomic Analysis of the <Emphasis Type="Italic">Pseudomonas</Emphasis> sp. HK-6 <Emphasis Type="Italic">xenB</Emphasis> Knockout Mutant Under RDX (Hexahydro-1,3,5-trinitro-1,3,5-triazine) Stress

Pseudomonas sp. HK-6 is able to utilize RDX (hexahydro-1,3,5-trinitro-1,3,5-triazine) as its sole nitrogen source. The role of the xenB gene, encoding xenobiotic reductase B, was investigated using HK-6 xenB knockout mutants. The xenB mutant degraded RDX to a level that was 10-fold less than that obtained with the wild-type HK-6 strain. After 60 days of culture with 25 or 50 μM RDX, no residual RDX was detected in the supernatants of the wild-type aerobically grown cultures, whereas approximately 90 % of the RDX remained in the xenB mutant cultures. The xenB mutant bacteria exhibited a 10²–10⁴-fold decrease in survival rate compared to the wild-type. The expression of DnaK and GroEL proteins, two typical stress shock proteins (SSPs), in the xenB mutant increased after immediate exposure to RDX, yet dramatically decreased after 4 h of exposure. In addition, DnaK and GroEL were more highly expressed in the cultures with 25 μM RDX in the medium but showed low expression in the cultures with 50 or 75 μM RDX. The expression levels of the dnaK and groEL genes measured by RT-qPCR were also much lower in the xenB genetic background. Analyses of the proteomes of the HK-6 and xenB mutant cells grown under conditions of RDX stress showed increased induction of several proteins, such as Alg8, alginate biosynthesis sensor histidine kinase, and OprH in the xenB mutants when compared to wild-type. However, many proteins, including two SSPs (DnaK and GroEL) and proteins involved in metabolism, exhibited lower expression levels in the xenB mutant than in the wild-type HK-6 strain. The xenB knockout mutation leads to reduced RDX degradation ability, which renders the mutant more sensitive to RDX stress and results in a lower survival rate and an altered proteomic profile under RDX stress.     

Efficacy of chemical and fluorescent protein markers in studying plant colonization by endophytic non-pathogenic <Emphasis Type="Italic">Fusarium oxysporum</Emphasis> isolates

In studying plant colonization by inoculated Fusarium oxysporum endophytes, it is important to be able to distinguish inoculated isolates from saprophytic strains. In the current study, F. oxysporum isolates were transformed with the green (GFP) and red fluorescent protein (DsRed) genes, and benomyl- and chlorate-resistant mutant isolates were also developed. The benomyl- and chlorate-resistant mutants, and the fluorescently labelled transformants, were able to grow on potato dextrose agar amended with 20 mg Benlate^® l^?1, 30 g chlorate l^?1 and 150 μg hygromycin ml^?1, respectively. Single spores of all mutants remained stable after several transfers on non-selective media. Most mutants and transformants produced colony diameters that did not differ significantly from that of their wild-type progenitors after 7 days of growth on non-selective media. Few mutants, however, had growth rates that were either slower or faster than for their wild-types. Plant colonization studies showed that root and rhizome tissue colonization by most benomyl- and chlorate-resistant mutants was similar to that of their wild-type isolates. Unlike GFP transformants, DsRed transformants were difficult to visualize in planta. Both the mutants and transformants can be used for future studies to investigate colonization, distribution and survival of biocontrol F. oxysporum endophytes in banana plants.     

The rice <Emphasis Type="Italic">OsSAG12-2</Emphasis> gene codes for a functional protease that negatively regulates stress-induced cell death

Senescence is the final stage of plant development. Although expression of most of the genes is suppressed during senescence, a set of genes referred as senescence-associated genes (SAGs) is induced. Arabidopsis thaliana SAG12 (AtSAG12) is one such gene that has been mostly studied for its strict association with senescence. AtSAG12 encodes a papain-like cysteine protease, expressed predominantly in senescence-associated vacuoles. Rice genome contains multiple AtSAG12 homologues (OsSAGs). OsSAG12-1, the closest structural homologue of AtSAG12, is a negative regulator of developmental and stress-induced cell death. Proteolytic activity has not been established for any SAG12 homologues in vitro. Here, we report that OsSAG12-2, the second structural homologue of AtSAG12 from rice, codes for a functional proteolytic enzyme. The recombinant OsSAG12-2 protein produced in Escherichia coli undergoes autolysis to generate a functional protease. The matured OsSAG12-2 protein shows 27% trypsin-equivalent proteolytic activity on azocasein substrate. Dark-induced senescence activates OsSAG12-2 expression. Down-regulation of OsSAG12-2 in the transgenic artificial miRNA lines results in enhanced salt- and UV-induced cell death, even though it does not affect cell viability in the stress-free condition. Our results show that OsSAG12-2 codes for a functional protease that negatively regulates stress-induced cell death in rice.     

Nitrate and flooding induce N<Subscript>2</Subscript>O emissions from soybean nodules

Nitrous oxide (N₂O) is one of the three main biogenic greenhouse gases (GHGs) and agriculture represents close to 30 % of the total N₂O net emissions. In agricultural soils, N₂O is emitted by two main microbial processes, nitrification and denitrification, both of which can convert synthetic nitrogen fertilizer into N₂O. Legume-rhizobia symbiosis could be an effective and environmental-friendly alternative to nitrogen fertilization and hence, to mitigate soil N₂O emissions. However, legume crops also contribute to N₂O emissions. A better understanding of the environmental factors involved in the emission of N₂O from nodules would be instrumental for mitigating the release of this GHG gas. In this work, in vivo N₂O emissions from nodulated soybean roots in response to nitrate (0, 1, 2 and 4 mM) and flooding have been measured. To investigate the contribution of rhizobial denitrification in N₂O emission from nodules, plants were inoculated with B. japonicum USDA110 and napA and nosZ denitrification mutants. The results showed that nitrate was essential for N₂O emissions and its concentration enhanced N₂O fluxes showing a statistical linear correlation, being the highest N₂O fluxes obtained with 4 mM nitrate. When inoculated plants grown with 4 mM nitrate were subjected to flooding, a 150- and 830-fold induction of N₂O emission rates from USDA110 and nosZ nodulated roots, respectively, was observed compared to non-flooded plants, especially during long-term flooding. Under these conditions, N₂O emissions from detached nodules produced by the napA mutant were significantly lower (p?<?0.05) than those produced by the wild-type strain (382 versus 1120 nmol N₂O h^?1 g^?1 NFW, respectively). In contrast, nodules from plants inoculated with the nosZ mutant accumulated statistically higher levels of N₂O compared to wild-type nodules (2522 versus nmol 1120 N₂O h^?1 g^?1 NFW, p?<?0.05). These results demonstrate that flooding is an important environmental factor for N₂O emissions from soybean nodules and that B. japonicum denitrification is involved in such emission.     

Isolation of salt-tolerant mutants of <Emphasis Type="Italic">Mesorhizobium ciceri</Emphasis> strain Rch125 and identification of genes involved in salt sensitivity

Mesorhizobium ciceri Rch125 is a salt-sensitive strain isolated from root nodules of chickpea (Cicer arietinum L.). The aim of this work was to investigate the genes responsible for the sensitivity to salinity. Twelve Rch125 salt-tolerant mutants were isolated after random Tn5 mutagenesis and selected using a medium containing 300 mM NaCl, where growth of the wild-type is totally inhibited. In addition to this NaCl tolerance, the mutants also displayed higher tolerance to LiCl, CaCl₂ and sucrose. Genes that were disrupted in the salt-tolerant mutants were in one of three functional categories: membrane transporters, outer membrane proteins, and genes of unknown function. Genetic complementation experiments demonstrated that the genes identified were involved in the salt sensitivity of the Rch125 strain. In most cases, disruption of the salt-sensitivity genes did not negatively affect the free-living or the symbiotic capabilities of Rch125 under non-saline conditions.     

A nodule endophytic plant growth-promoting <Emphasis Type="Italic">Pseudomonas</Emphasis> and its effects on growth,nodulation and metal uptake in <Emphasis Type="Italic">Medicago lupulina</Emphasis> under copper stress

The aim of this study was to determine the plant growth-promoting potential of the nodule endophytic Pseudomonas brassicacearum strain Zy-2-1 when used as a co-inoculant of Medicago lupulina with Sinorhizobium meliloti under copper (Cu) stress conditions. Strain Zy-2-1 was capable of producing ACC deaminase activity, IAA and siderophores, and was able to grow in the presence of Cu²⁺ up to 2.0 mmol/L. Co-inoculation of S. meliloti with Zy-2-1 enhanced M. lupulina root fresh weight, total plant dry weight, number of nodules, nodule fresh weight and nitrogen content in the presence of 100 or 300 mg/kg Cu²⁺. In the presence of 500 mg/kg Cu²⁺, co-inoculation with S. meliloti and strain Zy-2-1 increased plant height, number of nodules, nodule fresh weight and nitrogen content in comparison to S. meliloti inoculation alone. Furthermore, a higher amount of Cu accumulation in both shoots and roots and a higher level of Cu translocation to shoots were observed in co-inoculated plants. These results demonstrate that co-inoculation of M. lupulina with S. meliloti and P. brassicacearum Zy-2-1 improves plant growth, nitrogen nutrition and metal extraction potential. This can be of practical importance in the remediation of heavy metal-contaminated soils.     

Salt oversensitivity derived from mutation breeding improves salinity tolerance in barley <Emphasis Type="Italic">via</Emphasis> ion homeostasis

Salt stress imposes a major environmental threat to agriculture, therefore, understanding the basic physiology and genetics of cell under salt stress is crucial for developing any breeding strategy. In the present study, the expression profile of genes involved in ion homeostasis including salt overly sensitive (HvSOS1, HvSOS2, HvSOS3), vacuolar Na⁺/H⁺ antiporter (HvNHX1), and H⁺-ATPase (HVA) along with ion content measurement were investigated in two genotypes of Hordeum vulgare under 300 mM NaCl. The gene expressions were measured in the roots and shoots of a salt-tolerant mutant genotype M4-73-30 and in its wild-type cv. Zarjou by real-time qPCR technique. The critical differences between the salt-tolerant mutant and its wild-type were observed in the expressions of HvSOS1 (105-fold), HvSOS2 (24-fold), HvSOS3 (31-fold), and HVA (202-fold) genes in roots after 6-h exposure to NaCl. The parallel early up-regulation of these genes in root samples of the salt-tolerant mutant genotype indicated induction of Na⁺/H⁺ antiporters activity and Na+ exclusion into apoplast and vacuole. The earlier up-regulation of HvSOS1, HVA, and HvNHX1 genes in shoot of the wild-type genotype corresponded to the relative accumulation of Na⁺ which was not observed in salt-tolerant mutant genotype because of efficient inhibitory role of the root in Na+ transport to the shoot. In conclusion, the lack of similarity in gene expression patterns between the two genotypes with similar genetic background may confirm the hypothesis that mutation breeding could change the ability of salt-tolerant mutant genotype for efficient ion homeostasis via salinity oversensitivity response.     

The stay-green phenotype of wheat mutant <Emphasis Type="Italic">tasg1</Emphasis> is associated with altered cytokinin metabolism

Key message

By measuring the cytokinin content directly and testing the sensitivity to the cytokinin inhibitor lovastatin, we demonstrated that tasg1 cytokinin metabolism is different from wild-type.

Abstract

Our previous studies have indicated that compared with wild-type (WT) plants, a wheat stay-green mutant tasg1 exhibited delayed senescence. In this study, we found that the root development of tasg1 occurred later than that of WT. The number of lateral roots was fewer, but the lateral root length was longer in tasg1 than in WT, which resulted in a lower root to shoot ratio in tasg1 than WT. The levels of cytokinin (CK), CK activity, and expression of CK metabolic genes were measured. We found that the total CK content in the root tips and leaf of tasg1 was greater than in WT. The accumulation of mRNA of the CK synthetic gene (TaIPT) in tasg1 was higher than in WT at 9 and 11 days during seedling growth, but the expression of CK oxidase gene (TaCKX) was significantly lower in tasg1. Furthermore, the CK inhibitor lovastatin was used to inhibit CK activity. When treated with lovastatin, both the chlorophyll content and thylakoid membrane protein stability were significantly lower in tasg1 than WT, consistent with the inhibited expression of senescence-associated genes (TaSAGs) in tasg1. Lovastatin treatment also inhibited the antioxidative capability of wheat seedlings, and tasg1 was more sensitive to lovastatin than WT, as indicated by the MDA content, protein carbonylation, and antioxidant enzyme activity. The decreased antioxidative capability after lovastatin treatment may be related to the down-regulation of some antioxidase genes. These results suggest that the CK metabolism was altered in tasg1, which may play an important role in its ability to delay senescence.

     

Characterization of surface motility in <Emphasis Type="Italic">Sinorhizobium meliloti</Emphasis>: regulation and role in symbiosis

Sinorhizobium meliloti can exhibit diverse modes of surface translocation whose manifestation depends on the strain. The mechanisms involved and the role played by the different modes of surface motility in the establishment of symbiosis are largely unknown. In this work, we have characterized the surface motility shown by two S. meliloti reference strains (Rm1021 and GR4) under more permissive conditions for surface spreading and analyzed the symbiotic properties of two flagella-less S. meliloti mutants with different behavior on surfaces. The use of Noble agar in semisolid minimal medium induces surface motility in GR4, a strain described so far as non-motile on surfaces. The motility exhibited by GR4 is swarming as revealed by the non-motile phenotype of the flagella-less flaAB mutant. Intriguingly, a flgK mutation which also abolishes flagella production, triggers surface translocation in GR4 through an as yet unknown mechanism. In contrast to GR4, Rm1021 moves over surfaces using mostly a flagella-independent motility which is highly reliant on siderophore rhizobactin 1021 production. Surprisingly, this motility is absent in a flagella-less flgE mutant. In addition, we found that fadD loss-of-function, known to promote surface motility in S. meliloti, exerts different effects on the two reference strains: while fadD inactivation promotes a flagella-independent type of motility in GR4, the same mutation interferes with the surface translocation exhibited by the Rm1021 flaAB mutant. The symbiotic phenotypes shown by GR4flaAB and GR4flgK, non-flagellated mutants with opposite surface motility behavior, demonstrate that flagella-dependent motility positively influences competitiveness for nodule occupation, but is not crucial for optimal infectivity.