Your search keyword '"Parasponia"' showing total 50 results

1. Ectopic expression of the GRAS-type transcriptional regulator NSP2 in Parasponia triggers contrasting effects on symbioses

Author

Sultan Alhusayni, Nick Kersten, Rik Huisman, Rene Geurts, and Joël Klein

Subjects

arbuscular mycorrhiza, nodulation, Parasponia, NSP2, CYCLOPS, phytoene synthase, Plant culture, SB1-1110

Abstract

IntroductionPlants strictly control root endosymbioses with nutrient-scavenging arbuscular endomycorrhizal fungi or nodule inducing diazotrophic bacteria. The GRAS-type transcriptional regulator NODULATION SIGNALING PATHWAY 2 (NSP2) is a conserved hub in this process. The NSP2-regulated transcriptional network is instrumental in balancing nutrient homeostasis with symbiotic interactions. NSP2 activity is modulated post-transcriptionally by a specific microRNA. Overriding this control mechanism by ectopic expression of a miRNA-resistant NSP2 transgene enhances the symbiotic permissiveness to arbuscular endomycorrhizal fungi. Such engineered plants may possess enhanced capacities for nutrient uptake. However, the trade-off of this strategy on plant development or other symbiotic interactions, like nodulation, is yet to be fully understood.MethodWe used the nodulating Cannabaceae species Parasponia andersonii as an experimental system to study the effect of ectopic NSP2 expression. Parasponia and legumes (Fabaceae) diverged 100 million years ago, providing a unique comparative system to dissect the nodulation trait.ResultsSix independent transgenic Parasponia lines were generated that differed in the level of NSP2 expression in the root from 6 to 95-fold higher when compared to the empty vector control plants. Analysis of these plants revealed a positive correlation between mycorrhization and the NSP2 expression level, as well as with the expression of the symbiosis transcription factor CYCLOPS and the rate-limiting enzyme in the carotenoid biosynthetic pathway PHYTOENE SYNTHASE1 (PSY1). Yet ectopic expression of NSP2 affected plant architecture and root nodule organogenesis.DiscussionThis indicates a significant trade-off when leveraging NSP2 over-expression to enhance endomycorrhization.

Published

2024

2. Plant–Environment Response Pathway Regulation Uncovered by Investigating Non-Typical Legume Symbiosis and Nodulation.

Author

Wilkinson, Helen, Coppock, Alice, Richmond, Bethany L., Lagunas, Beatriz, and Gifford, Miriam L.

Subjects

RHIZOBIUM, LEGUMES, SYMBIOSIS, ATMOSPHERIC nitrogen, ABIOTIC stress

Abstract

Nitrogen is an essential element needed for plants to survive, and legumes are well known to recruit rhizobia to fix atmospheric nitrogen. In this widely studied symbiosis, legumes develop specific structures on the roots to host specific symbionts. This review explores alternate nodule structures and their functions outside of the more widely studied legume–rhizobial symbiosis, as well as discussing other unusual aspects of nodulation. This includes actinorhizal-Frankia, cycad-cyanobacteria, and the non-legume Parasponia andersonii-rhizobia symbioses. Nodules are also not restricted to the roots, either, with examples found within stems and leaves. Recent research has shown that legume–rhizobia nodulation brings a great many other benefits, some direct and some indirect. Rhizobial symbiosis can lead to modifications in other pathways, including the priming of defence responses, and to modulated or enhanced resistance to biotic and abiotic stress. With so many avenues to explore, this review discusses recent discoveries and highlights future directions in the study of nodulation. [ABSTRACT FROM AUTHOR]

Published

2023

3. Pseudogenization of the rhizobium-responsive EXOPOLYSACCHARIDE RECEPTOR in Parasponia is a rare event in nodulating plants

Author

Simon Dupin, Joël Klein, Luuk Rutten, Rik Huisman, and Rene Geurts

Subjects

EXOPOLYSACCHARIDE RECEPTOR, EPR3, Parasponia, Trema, Nodulation, Botany, QK1-989

Abstract

Abstract Background Nodule symbiosis with diazotrophic Frankia or rhizobium occurs in plant species belonging to ten taxonomic lineages within the related orders Fabales, Fagales, Cucurbitales, and Rosales. Phylogenomic studies indicate that this nitrogen-fixing nodulation trait has a single evolutionary origin. In legume model plants, the molecular interaction between plant and rhizobium microsymbiont is mapped to a significant degree. A specific LysM-type receptor kinase, LjEPR3 in Lotus japonicus and MtLYK10 in Medicago truncatula, was found to act in a secondary identity-based mechanism, controlling intracellular rhizobium infection. Furthermore, LjEPR3 showed to bind surface exopolysaccharides of Mesorhizobium loti, the diazotrophic microsymbiont of L. japonicus. EPR3 orthologous genes are not unique to legumes. Surprisingly, however, its ortholog EXOPOLYSACCHARIDE RECEPTOR (EPR) is pseudogenized in Parasponia, the only lineage of non-legume plants that nodulate also with rhizobium. Results Analysis of genome sequences showed that EPR3 orthologous genes are highly conserved in nodulating plants. We identified a conserved retrotransposon insertion in the EPR promoter region in three Parasponia species, which associates with defected transcriptional regulation of this gene. Subsequently, we studied the EPR gene of two Trema species as they represent the sister genus of Parasponia for which it is assumed it lost the nitrogen-fixing nodulation trait. Both Trema species possess apparently functional EPR genes that have a nodulation-specific expression profile when introduced into a Parasponia background. This indicates the EPR gene functioned in nodulation in the Parasponia-Trema ancestor. Conclusion We conclude that nodule-specific expression of EPR3 orthologous genes is shared between the legume and Parasponia-Trema lineage, suggesting an ancestral function in the nitrogen-fixing nodulation trait. Pseudogenization of EPR in Parasponia is an exceptional case in nodulating plants. We speculate that this may have been instrumental to the microsymbiont switch -from Frankia to rhizobium- that has occurred in the Parasponia lineage and the evolution of a novel crack entry infection mechanism.

Published

2022

4. Plant–Environment Response Pathway Regulation Uncovered by Investigating Non-Typical Legume Symbiosis and Nodulation

Author

Helen Wilkinson, Alice Coppock, Bethany L. Richmond, Beatriz Lagunas, and Miriam L. Gifford

Subjects

nodulation, legumes, rhizobia, actinorhizal interactions, stress responses, Parasponia, Botany, QK1-989

Abstract

Nitrogen is an essential element needed for plants to survive, and legumes are well known to recruit rhizobia to fix atmospheric nitrogen. In this widely studied symbiosis, legumes develop specific structures on the roots to host specific symbionts. This review explores alternate nodule structures and their functions outside of the more widely studied legume–rhizobial symbiosis, as well as discussing other unusual aspects of nodulation. This includes actinorhizal-Frankia, cycad-cyanobacteria, and the non-legume Parasponia andersonii-rhizobia symbioses. Nodules are also not restricted to the roots, either, with examples found within stems and leaves. Recent research has shown that legume–rhizobia nodulation brings a great many other benefits, some direct and some indirect. Rhizobial symbiosis can lead to modifications in other pathways, including the priming of defence responses, and to modulated or enhanced resistance to biotic and abiotic stress. With so many avenues to explore, this review discusses recent discoveries and highlights future directions in the study of nodulation.

Published

2023

5. Pseudogenization of the rhizobium-responsive EXOPOLYSACCHARIDE RECEPTOR in Parasponia is a rare event in nodulating plants.

Author

Dupin, Simon, Klein, Joël, Rutten, Luuk, Huisman, Rik, and Geurts, Rene

Subjects

*MEDICAGO, *LEGUMES, *LOTUS japonicus, *GENETIC regulation, *GENETIC transcription regulation, *PROMOTERS (Genetics), *MEDICAGO truncatula

Abstract

Background: Nodule symbiosis with diazotrophic Frankia or rhizobium occurs in plant species belonging to ten taxonomic lineages within the related orders Fabales, Fagales, Cucurbitales, and Rosales. Phylogenomic studies indicate that this nitrogen-fixing nodulation trait has a single evolutionary origin. In legume model plants, the molecular interaction between plant and rhizobium microsymbiont is mapped to a significant degree. A specific LysM-type receptor kinase, LjEPR3 in Lotus japonicus and MtLYK10 in Medicago truncatula, was found to act in a secondary identity-based mechanism, controlling intracellular rhizobium infection. Furthermore, LjEPR3 showed to bind surface exopolysaccharides of Mesorhizobium loti, the diazotrophic microsymbiont of L. japonicus. EPR3 orthologous genes are not unique to legumes. Surprisingly, however, its ortholog EXOPOLYSACCHARIDE RECEPTOR (EPR) is pseudogenized in Parasponia, the only lineage of non-legume plants that nodulate also with rhizobium. Results: Analysis of genome sequences showed that EPR3 orthologous genes are highly conserved in nodulating plants. We identified a conserved retrotransposon insertion in the EPR promoter region in three Parasponia species, which associates with defected transcriptional regulation of this gene. Subsequently, we studied the EPR gene of two Trema species as they represent the sister genus of Parasponia for which it is assumed it lost the nitrogen-fixing nodulation trait. Both Trema species possess apparently functional EPR genes that have a nodulation-specific expression profile when introduced into a Parasponia background. This indicates the EPR gene functioned in nodulation in the Parasponia-Trema ancestor. Conclusion: We conclude that nodule-specific expression of EPR3 orthologous genes is shared between the legume and Parasponia-Trema lineage, suggesting an ancestral function in the nitrogen-fixing nodulation trait. Pseudogenization of EPR in Parasponia is an exceptional case in nodulating plants. We speculate that this may have been instrumental to the microsymbiont switch -from Frankia to rhizobium- that has occurred in the Parasponia lineage and the evolution of a novel crack entry infection mechanism. [ABSTRACT FROM AUTHOR]

Published

2022

6. The Non-Legume Parasponia andersonii Mediates the Fitness of Nitrogen-Fixing Rhizobial Symbionts Under High Nitrogen Conditions

Author

Simon E. Dupin, René Geurts, and E. Toby Kiers

Subjects

Parasponia, nitrogen fixing bacteria, plant nutrition, host control, rhizobium fitness, nitrogen fertilizer, Plant culture, SB1-1110

Abstract

Organisms rely on symbiotic associations for metabolism, protection, and energy. However, these intimate partnerships can be vulnerable to exploitation. What prevents microbial mutualists from parasitizing their hosts? In legumes, there is evidence that hosts have evolved sophisticated mechanisms to manage their symbiotic rhizobia, but the generality and evolutionary origins of these control mechanisms are under debate. Here, we focused on the symbiosis between Parasponia hosts and N2-fixing rhizobium bacteria. Parasponia is the only non-legume lineage to have evolved a rhizobial symbiosis and thus provides an evolutionary replicate to test how rhizobial exploitation is controlled. A key question is whether Parasponia hosts can prevent colonization of rhizobia under high nitrogen conditions, when the contribution of the symbiont becomes nonessential. We grew Parasponia andersonii inoculated with Bradyrhizobium elkanii under four ammonium nitrate concentrations in a controlled growth chamber. We measured shoot and root dry weight, nodule number, nodule fresh weight, nodule volume. To quantify viable rhizobial populations in planta, we crushed nodules and determined colony forming units (CFU), as a rhizobia fitness proxy. We show that, like legumes and actinorhizal plants, P. andersonii is able to control nodule symbiosis in response to exogenous nitrogen. While the relative host growth benefits of inoculation decreased with nitrogen fertilization, our highest ammonium nitrate concentration (3.75 mM) was sufficient to prevent nodule formation on inoculated roots. Rhizobial populations were highest in nitrogen free medium. While we do not yet know the mechanism, our results suggest that control mechanisms over rhizobia are not exclusive to the legume clade.

Published

2020

7. A Roadmap toward Engineered Nitrogen-Fixing Nodule Symbiosis

Author

Rik Huisman and Rene Geurts

Subjects

nodulation, legumes, actinorhizal plants, Parasponia, engineering nitrogen fixation, Botany, QK1-989

Abstract

In the late 19th century, it was discovered that legumes can establish a root nodule endosymbiosis with nitrogen-fixing rhizobia. Soon after, the question was raised whether it is possible to transfer this trait to non-leguminous crops. In the past century, an ever-increasing amount of knowledge provided unique insights into the cellular, molecular, and genetic processes controlling this endosymbiosis. In addition, recent phylogenomic studies uncovered several genes that evolved to function specifically to control nodule formation and bacterial infection. However, despite this massive body of knowledge, the long-standing objective to engineer the nitrogen-fixing nodulation trait on non-leguminous crop plants has not been achieved yet. In this review, the unsolved questions and engineering strategies toward nitrogen-fixing nodulation in non-legume plants are discussed and highlighted.

Published

2020

8. Mutant analysis in the nonlegume Parasponia andersonii identifies NIN and NF‐YA1 transcription factors as a core genetic network in nitrogen‐fixing nodule symbioses.

Author

Bu, Fengjiao, Rutten, Luuk, Roswanjaya, Yuda Purwana, Kulikova, Olga, Rodriguez‐Franco, Marta, Ott, Thomas, Bisseling, Ton, Zeijl, Arjan, and Geurts, Rene

Subjects

*TRANSCRIPTION factors, *LEGUMES, *SYMBIOSIS, *ENDOSYMBIOSIS, *BACTERIAL diseases, *MORPHOGENESIS

Abstract

Summary: ●Nitrogen‐fixing nodulation occurs in 10 taxonomic lineages, with either rhizobia or Frankia bacteria. To establish such an endosymbiosis, two processes are essential: nodule organogenesis and intracellular bacterial infection. In the legume–rhizobium endosymbiosis, both processes are guarded by the transcription factor NODULE INCEPTION (NIN) and its downstream target genes of the NUCLEAR FACTOR Y (NF‐Y) complex.●It is hypothesized that nodulation has a single evolutionary origin c. 110 Ma, followed by many independent losses. Despite a significant body of knowledge of the legume–rhizobium symbiosis, it remains elusive which signalling modules are shared between nodulating species in different taxonomic clades. We used Parasponia andersonii to investigate the role of NIN and NF‐YA genes in rhizobium nodulation in a nonlegume system.●Consistent with legumes, P. andersonii PanNIN and PanNF‐YA1 are coexpressed in nodules. By analyzing single, double and higher‐order CRISPR‐Cas9 knockout mutants, we show that nodule organogenesis and early symbiotic expression of PanNF‐YA1 are PanNIN‐dependent and that PanNF‐YA1 is specifically required for intracellular rhizobium infection.●This demonstrates that NIN and NF‐YA1 have conserved symbiotic functions. As Parasponia and legumes diverged soon after the birth of the nodulation trait, we argue that NIN and NF‐YA1 represent core transcriptional regulators in this symbiosis. [ABSTRACT FROM AUTHOR]

Published

2020

9. The Non-Legume Parasponia andersonii Mediates the Fitness of Nitrogen-Fixing Rhizobial Symbionts Under High Nitrogen Conditions.

Author

Dupin, Simon E., Geurts, René, and Kiers, E. Toby

Subjects

RHIZOBIUM, NITROGEN fixation, ROOT formation, AMMONIUM nitrate, NITROGEN, BRADYRHIZOBIUM, PLANT nutrition

Abstract

Organisms rely on symbiotic associations for metabolism, protection, and energy. However, these intimate partnerships can be vulnerable to exploitation. What prevents microbial mutualists from parasitizing their hosts? In legumes, there is evidence that hosts have evolved sophisticated mechanisms to manage their symbiotic rhizobia, but the generality and evolutionary origins of these control mechanisms are under debate. Here, we focused on the symbiosis between Parasponia hosts and N2-fixing rhizobium bacteria. Parasponia is the only non-legume lineage to have evolved a rhizobial symbiosis and thus provides an evolutionary replicate to test how rhizobial exploitation is controlled. A key question is whether Parasponia hosts can prevent colonization of rhizobia under high nitrogen conditions, when the contribution of the symbiont becomes nonessential. We grew Parasponia andersonii inoculated with Bradyrhizobium elkanii under four ammonium nitrate concentrations in a controlled growth chamber. We measured shoot and root dry weight, nodule number, nodule fresh weight, nodule volume. To quantify viable rhizobial populations in planta , we crushed nodules and determined colony forming units (CFU), as a rhizobia fitness proxy. We show that, like legumes and actinorhizal plants, P. andersonii is able to control nodule symbiosis in response to exogenous nitrogen. While the relative host growth benefits of inoculation decreased with nitrogen fertilization, our highest ammonium nitrate concentration (3.75 mM) was sufficient to prevent nodule formation on inoculated roots. Rhizobial populations were highest in nitrogen free medium. While we do not yet know the mechanism, our results suggest that control mechanisms over rhizobia are not exclusive to the legume clade. [ABSTRACT FROM AUTHOR]

Published

2020

10. Expression studies in transgenic Parasponia containing TorEPR

Author

Dupin, Simon, Klein, Joël, Rutten, Luuk, Huisman, Rik, Geurts, Rene, Dupin, Simon, Klein, Joël, Rutten, Luuk, Huisman, Rik, and Geurts, Rene

Abstract

RNA-seq data of root nodules from Parasponia andersonnii containing the Trema orientalis EPR gene., Background Nodule symbiosis with diazotrophic Frankia or rhizobium occurs in plant species belonging to ten taxonomic lineages within the related orders Fabales, Fagales, Cucurbitales, and Rosales. Phylogenomic studies indicate that this nitrogen-fixing nodulation trait has a single evolutionary origin. In legume model plants, the molecular interaction between plant and rhizobium microsymbiont is mapped to a significant degree. A specific LysM-type receptor kinase, LjEPR3 in Lotus japonicus and MtLYK10 in Medicago truncatula, was found to act in a secondary identity-based mechanism, controlling intracellular rhizobium infection. Furthermore, LjEPR3 showed to bind surface exopolysaccharides of Mesorhizobium loti, the diazotrophic microsymbiont of L. japonicus. EPR3 orthologous genes are not unique to legumes. Surprisingly, however, its ortholog EXOPOLYSACCHARIDE RECEPTOR (EPR) is pseudogenized in Parasponia, the only lineage of non-legume plants that nodulate also with rhizobium. Results Analysis of genome sequences showed that EPR3 orthologous genes are highly conserved in nodulating plants. We identified a conserved retrotransposon insertion in the EPR promoter region in three Parasponia species, which associates with defected transcriptional regulation of this gene. Subsequently, we studied the EPR gene of two Trema species as they represent the sister genus of Parasponia for which it is assumed it lost the nitrogen-fixing nodulation trait. Both Trema species possess apparently functional EPR genes that have a nodulation-specific expression profile when introduced into a Parasponia background. This indicates the EPR gene functioned in nodulation in the Parasponia-Trema ancestor. Conclusion We conclude that nodule-specific expression of EPR3 orthologous genes is shared between the legume and Parasponia-Trema lineage, suggesting an ancestral function in the nitrogen-fixing nodulation trait. Pseudogenization of EPR in Parasponia is an exceptional case in nod

Published

2022

11. Root-based N2-fixing symbioses: Legumes, actinorhizal plants, Parasponia sp. and cycads

Author

Kevin Vessey, J., Pawlowski, Katharina, Bergman, Birgitta, De Kok, Luit J., editor, Stulen, Ineke, editor, Lambers, Hans, editor, and Colmer, Timothy D., editor

Published

2005

12. Expression studies in transgenic Parasponia containing TorEPR

Subjects

Biological sciences, Raw sequence reads, Evolution, Parasponia, Genetics, Plant Biology, Laboratorium voor Moleculaire Biologie, Laboratory of Molecular Biology, EPS

Abstract

RNA-seq data of root nodules from Parasponia andersonnii containing the Trema orientalis EPR gene.

Published

2022

13. Bacterial-induced calcium oscillations are common to nitrogen-fixing associations of nodulating legumes and nonlegumes.

Author

Granqvist, Emma, Sun, Jongho, Op den Camp, Rik, Pujic, Petar, Hill, Lionel, Normand, Philippe, Morris, Richard J., Downie, J. Allan, Geurts, Rene, and Oldroyd, Giles E. D.

Subjects

*MYCORRHIZAL plants, *CALCIUM ions, *ACTINORHIZAL plants, *NITROGEN-fixing plants, *VESICULAR-arbuscular mycorrhizas

Abstract

Plants that form root-nodule symbioses are within a monophyletic 'nitrogen-fixing' clade and associated signalling processes are shared with the arbuscular mycorrhizal symbiosis. Central to symbiotic signalling are nuclear-associated oscillations in calcium ions (Ca2+), occurring in the root hairs of several legume species in response to the rhizobial Nod factor signal., In this study we expanded the species analysed for activation of Ca2+ oscillations, including nonleguminous species within the nitrogen-fixing clade., We showed that Ca2+ oscillations are a common feature of legumes in their association with rhizobia, while Cercis, a non-nodulating legume, does not show Ca2+ oscillations in response to Nod factors from Sinorhizobium fredii NGR234. Parasponia andersonii, a nonlegume that can associate with rhizobia, showed Nod factor-induced calcium oscillations to S. fredii NGR234 Nod factors, but its non-nodulating sister species, Trema tomentosa, did not. Also within the nitrogen-fixing clade are actinorhizal species that associate with Frankia bacteria and we showed that Alnus glutinosa induces Ca2+ oscillations in root hairs in response to exudates from Frankia alni, but not to S. fredii NGR234 Nod factors., We conclude that the ability to mount Ca2+ oscillations in response to symbiotic bacteria is a common feature of nodulating species within the nitrogen-fixing clade. [ABSTRACT FROM AUTHOR]

Published

2015

14. Mutant analysis in the non‐legume Parasponia andersonii identifies NIN and NF‐YA1 transcription factors as a core genetic network in nitrogen‐fixing nodule symbioses

Author

Bu, F., Rutten, L.J.J., Roswanjaya, Yuda, Kulikova, O., Rodriguez-Franco, Marta, Ott, Thomas, Bisseling, A.H.J., van Zeijl, A.L., Geurts, R., Bu, F., Rutten, L.J.J., Roswanjaya, Yuda, Kulikova, O., Rodriguez-Franco, Marta, Ott, Thomas, Bisseling, A.H.J., van Zeijl, A.L., and Geurts, R.

Abstract

Nitrogen‐fixing nodulation occurs in ten taxonomic lineages, either with rhizobia or Frankia bacteria. To establish such an endosymbiosis, two processes are essential: nodule organogenesis and intracellular bacterial infection. In the legume‐rhizobium endosymbiosis, both processes are guarded by the transcription factor NODULE INCEPTION (NIN) and its downstream target genes of the NUCLEAR FACTOR Y (NF‐Y) complex.It is hypothesized that nodulation has a single evolutionary origin ~ 110 million years ago, followed by many independent losses. Despite a significant body of knowledge of the legume‐rhizobium symbiosis, it remains elusive which signalling modules are shared between nodulating species in different taxonomic clades. We used Parasponia andersonii to investigate the role of NIN and NF‐YA genes in rhizobium nodulation in a non‐legume system.Consistent with legumes, P. andersonii PanNIN and PanNF‐YA1 are co‐expressed in nodules. By analyzing single, double and higher‐order CRISPR‐Cas9 knockout mutants, we show that nodule organogenesis and early symbiotic expression of PanNF‐YA1 are PanNIN‐dependent and that PanNF‐YA1 is specifically required for intracellular rhizobium infection.This demonstrates that NIN and NF‐YA1 commit conserved symbiotic functions. As Parasponia and legumes diverged soon after the birth of the nodulation trait, we argue that NIN and NF‐YA1 represent core transcriptional regulators in this symbiosis.

Published

2020

15. A roadmap towards engineered nitrogen-fixing nodule symbiosis

Author

Huisman, R.H.J., Geurts, R., Huisman, R.H.J., and Geurts, R.

Abstract

In the late 19th century, it was discovered that legumes can establish a root nodule endosymbiosis with nitrogen-fixing rhizobia. Soon after, the question was raised whether it is possible to transfer this trait to non-leguminous crops. In the past century, an ever-increasing amount of knowledge provided unique insights into the cellular, molecular, and genetic processes controlling this endosymbiosis. In addition, recent phylogenomic studies uncovered several genes that evolved to function specifically to control nodule formation and bacterial infection. However, despite this massive body of knowledge, the long-standing objective to engineer the nitrogen-fixing nodulation trait on non-leguminous crop plants has not been achieved yet. In this review, the unsolved questions and engineering strategies toward nitrogen-fixing nodulation in non-legume plants are discussed and highlighted.

Published

2020

16. Mutant analysis in the non‐legume Parasponia andersonii identifies NIN and NF‐YA1 transcription factors as a core genetic network in nitrogen‐fixing nodule symbioses

Author

Arjan van Zeijl, Olga Kulikova, Luuk Rutten, René Geurts, Fengjiao Bu, Marta Rodriguez-Franco, Yuda Purwana Roswanjaya, Thomas Ott, and Ton Bisseling

Subjects

0106 biological sciences, 0301 basic medicine, Physiology, Nitrogen, Frankia, Mutant, Organogenesis, Plant Science, 01 natural sciences, Plant Root Nodulation, Rhizobia, 03 medical and health sciences, rhizobium, Symbiosis, Nitrogen Fixation, evolution, Laboratorium voor Moleculaire Biologie, Gene Regulatory Networks, nodulation, Gene, Plant Proteins, Genetics, Endosymbiosis, biology, Full Paper, Research, intracellular infection, Parasponia, NODULE INCEPTION (NIN), Full Papers, biology.organism_classification, 030104 developmental biology, Rhizobium, Laboratory of Molecular Biology, NF‐YA1, Root Nodules, Plant, NF-YA1, 010606 plant biology & botany, Transcription Factors

Abstract

Nitrogen‐fixing nodulation occurs in ten taxonomic lineages, either with rhizobia or Frankia bacteria. To establish such an endosymbiosis, two processes are essential: nodule organogenesis and intracellular bacterial infection. In the legume‐rhizobium endosymbiosis, both processes are guarded by the transcription factor NODULE INCEPTION (NIN) and its downstream target genes of the NUCLEAR FACTOR Y (NF‐Y) complex. It is hypothesized that nodulation has a single evolutionary origin ~ 110 million years ago, followed by many independent losses. Despite a significant body of knowledge of the legume‐rhizobium symbiosis, it remains elusive which signalling modules are shared between nodulating species in different taxonomic clades. We used Parasponia andersonii to investigate the role of NIN and NF‐YA genes in rhizobium nodulation in a non‐legume system. Consistent with legumes, P. andersonii PanNIN and PanNF‐YA1 are co‐expressed in nodules. By analyzing single, double and higher‐order CRISPR‐Cas9 knockout mutants, we show that nodule organogenesis and early symbiotic expression of PanNF‐YA1 are PanNIN‐dependent and that PanNF‐YA1 is specifically required for intracellular rhizobium infection. This demonstrates that NIN and NF‐YA1 commit conserved symbiotic functions. As Parasponia and legumes diverged soon after the birth of the nodulation trait, we argue that NIN and NF‐YA1 represent core transcriptional regulators in this symbiosis.

Published

2020

17. The Non-Legume Parasponia andersonii Mediates the Fitness of Nitrogen-Fixing Rhizobial Symbionts Under High Nitrogen Conditions

Author

E. Toby Kiers, René Geurts, Simon E. Dupin, and Animal Ecology

Subjects

0106 biological sciences, 0301 basic medicine, plant nutrition, Plant Science, lcsh:Plant culture, 01 natural sciences, Rhizobia, 03 medical and health sciences, nitrogen fixing bacteria, SDG 17 - Partnerships for the Goals, Symbiosis, Botany, Laboratorium voor Moleculaire Biologie, lcsh:SB1-1110, nodulation, rhizobium fitness, Bradyrhizobium elkanii, Original Research, biology, Parasponia, food and beverages, host control, biology.organism_classification, 030104 developmental biology, non-legume, Nitrogen fixation, Rhizobium, Laboratory of Molecular Biology, EPS, Actinorhizal plant, Plant nutrition, Bacteria, nitrogen fertilizer, 010606 plant biology & botany

Abstract

Organisms rely on symbiotic associations for metabolism, protection, and energy. However, these intimate partnerships can be vulnerable to exploitation. What prevents microbial mutualists from parasitizing their hosts? In legumes, there is evidence that hosts have evolved sophisticated mechanisms to manage their symbiotic rhizobia, but the generality and evolutionary origins of these control mechanisms are under debate. Here, we focused on the symbiosis between Parasponia hosts and N2-fixing rhizobium bacteria. Parasponia is the only non-legume lineage to have evolved a rhizobial symbiosis and thus provides an evolutionary replicate to test how rhizobial exploitation is controlled. A key question is whether Parasponia hosts can prevent colonization of rhizobia under high nitrogen conditions, when the contribution of the symbiont becomes nonessential. We grew Parasponia andersonii inoculated with Bradyrhizobium elkanii under four ammonium nitrate concentrations in a controlled growth chamber. We measured shoot and root dry weight, nodule number, nodule fresh weight, nodule volume. To quantify viable rhizobial populations in planta, we crushed nodules and determined colony forming units (CFU), as a rhizobia fitness proxy. We show that, like legumes and actinorhizal plants, P. andersonii is able to control nodule symbiosis in response to exogenous nitrogen. While the relative host growth benefits of inoculation decreased with nitrogen fertilization, our highest ammonium nitrate concentration (3.75 mM) was sufficient to prevent nodule formation on inoculated roots. Rhizobial populations were highest in nitrogen free medium. While we do not yet know the mechanism, our results suggest that control mechanisms over rhizobia are not exclusive to the legume clade.

Published

2020

18. Biological nitrogen fixation in non-legume plants.

Author

Santi, Carole, Bogusz, Didier, and Franche, Claudine

Subjects

*NITROGEN fixation, *PLANT nutrition, *PLANT growth, *ENDOSYMBIOSIS, *PLANT-bacterial symbiosis, *PLANT ecology, *PLANT diversity

Abstract

Background Nitrogen is an essential nutrient in plant growth. The ability of a plant to supply all or part of its requirements from biological nitrogen fixation (BNF) thanks to interactions with endosymbiotic, associative and endophytic symbionts, confers a great competitive advantage over non-nitrogen-fixing plants. Scope Because BNF in legumes is well documented, this review focuses on BNF in non-legume plants. Despite the phylogenic and ecological diversity among diazotrophic bacteria and their hosts, tightly regulated communication is always necessary between the microorganisms and the host plant to achieve a successful interaction. Ongoing research efforts to improve knowledge of the molecular mechanisms underlying these original relationships and some common strategies leading to a successful relationship between the nitrogen-fixing microorganisms and their hosts are presented. Conclusions Understanding the molecular mechanism of BNF outside the legume–rhizobium symbiosis could have important agronomic implications and enable the use of N-fertilizers to be reduced or even avoided. Indeed, in the short term, improved understanding could lead to more sustainable exploitation of the biodiversity of nitrogen-fixing organisms and, in the longer term, to the transfer of endosymbiotic nitrogen-fixation capacities to major non-legume crops. [ABSTRACT FROM PUBLISHER]

Published

2013

19. Efficiency of Agrobacterium rhizogenes-mediated root transformation of Parasponia and Trema is temperature dependent.

Author

Cao, Qingqin, Op den Camp, Rik, Seifi Kalhor, Maryam, Bisseling, Ton, and Geurts, Rene

Abstract

Parasponia trees are the only non-legume species that form nitrogen-fixing root nodules with rhizobium. Based on its taxonomic position in relation to legumes ( Fabaceae), it is most likely that both lineages have gained this symbiotic capacity independently. Therefore, Parasponia forms a bridging species to understand the evolutionary constraints underlying this symbiosis. However, absence of key technologies to genetically modify Parasponia seriously impeded studies on these species. We employed Agrobacterium rhizogenes to create composite Parasponia andersonii plants that harbour transgenic roots. Here, we provide an optimized protocol to infect P. andersonii as well as its non-symbiotic sister species Trema tomentosa with A. rhizogenes. We show that the transformation efficiency is temperature dependent. Whereas the optimal growth temperature for both these species is 28 °C, the transformation is most efficient when co-cultivation with A. rhizogenes occurs at 21 °C. Using this optimized protocol up to 80 % transformation efficiency can be obtained. These robust transformation platforms will provide a strong tool to unravel the Parasponia-rhizobium symbiosis. [ABSTRACT FROM AUTHOR]

Published

2012

20. Root-based N2-fixing Symbioses: Legumes, Actinorhizal Plants, Parasponia sp. and Cycads.

Author

Vessey, J. Kevin, Pawlowski, Katharina, and Bergman, Birgitta

Subjects

*SYMBIOSIS, *LEGUMES, *PLANT root ecology, *PLANT-soil relationships, *PLANT ecology, *ACTINORHIZAL plants, *CYCADS

Abstract

In the mutualistic symbioses between legumes and rhizobia, actinorhizal plants and Frankia, Parasponia sp. and rhizobia, and cycads and cyanobacteria, the N2-fixing microsymbionts exist in specialized structures (nodules or cyanobacterial zones) within the roots of their host plants. Despite the phylogenetic diversity among both the hosts and the microsymbionts of these symbioses, certain developmental and physiological imperatives must be met for successful mutualisms. In this review, phylogenetic and ecological aspects of the four symbioses are first addressed, and then the symbioses are contrasted and compared in regard to infection and symbio-organ development, supply of carbon to the microsymbionts, regulation of O2 flux to the microsymbionts, and transfer of fixed-N to the hosts. Although similarities exist in the genetics, development, and functioning of the symbioses, it is evident that there is great diversity in many aspects of these root-based N2-fixing symbioses. Each symbiosis can be admired for the elegant means by which the host plant and microsymbiont integrate to form the mutualistic relationships so important to the functioning of the biosphere. [ABSTRACT FROM AUTHOR]

Published

2005

21. Root-based N2-fixing symbioses: Legumes, actinorhizal plants,Parasponiasp. and cycads.

Author

Vessey, J. Kevin, Pawlowski, Katharina, and Bergman, Birgitta

Subjects

*ACTINORHIZAL plants, *PLANT roots, *CYANOBACTERIA, *CYCADS, *LEGUMES, *MUTUALISM (Biology), *SYMBIOSIS

Abstract

In the mutualistic symbioses between legumes and rhizobia, actinorhizal plants andFrankia, Parasponiasp. and rhizobia, and cycads and cyanobacteria, the N2-fixing microsymbionts exist in specialized structures (nodules or cyanobacterial zones) within the roots of their host plants. Despite the phylogenetic diversity among both the hosts and the microsymbionts of these symbioses, certain developmental and physiological imperatives must be met for successful mutualisms. In this review, phylogenetic and ecological aspects of the four symbioses are first addressed, and then the symbioses are contrasted and compared in regard to infection and symbio-organ development, supply of carbon to the microsymbionts, regulation of O2 flux to the microsymbionts, and transfer of fixed-N to the hosts. Although similarities exist in the genetics, development, and functioning of the symbioses, it is evident that there is great diversity in many aspects of these root-based N2-fixing symbioses. Each symbiosis can be admired for the elegant means by which the host plant and microsymbiont integrate to form the mutualistic relationships so important to the functioning of the biosphere. [ABSTRACT FROM AUTHOR]

Published

2004

22. Phylogenetic Framework forTrema(Celtidaceae).

Author

Yesson, C., Russell, S. J., Parrish, T., Dalling, J. W., and Garwood, N. C.

Subjects

*TREES, *MOLECULAR phylogeny, *MOLECULAR biology, *PHYLOGENY, *PLANT evolution

Abstract

We used ITS and trnL sequence data, analyzed separately and combined by MP, to explore species relationships and concepts in Trema (Celtidaceae), a pantropical genus of pioneer trees. Whether Trema is monophyletic or includes Parasponia is still unresolved. Three clades within Trema received moderate to high support, one from the New World and two from the Old World, but their relationships were not resolved. In the New World, specimens of T. micrantha formed two groups consistent with endocarp morphology. Group I, with smaller brown endocarps, is a highly supported clade sister to T. lamarckiana. Group II, with larger black endocarps, is poorly resolved with several subclades, including the highly supported T. integerrima clade. Both Old World clades contain Asian and African species, with three or more species in each region. Trema orientalty is not monophyletic: specimens from Africa formed a highly supported clade sister to T. cifricana, while those from Asia were sister to T. aspera from Australia. [ABSTRACT FROM AUTHOR]

Published

2004

23. Expression of phosphinothricin acetyltransferase from the root specific par promoter in transgenic tobacco plants is sufficient for herbicide tolerance.

Author

Hoeven, Cornelia, Dietz, Antje, and Landsmann, Jörg

Abstract

The pat gene, coding for phosphinothricin acetyltransferase (PAT) from Streptomyces viridochromogenes, was cloned behind the par promoter of the hemoglobin gene from Parasponia andersonii, Introduction into tobacco ( Nicotiana tabacum) resulted in predominantly root specific PAT expression. Application of 5 l/ha BASTA (herbicidal component: phosphinothricin) did not effect growth morphology and vigor of the plants. After application of 20 l/ha BASTA the plants showed herbicide damage. Nevertheless, they all recovered by forming new undamaged leaves and resumed full growth despite virtually non-detectable expression of the PAT enzyme in the leaves. [ABSTRACT FROM AUTHOR]

Published

1994

24. Early development of Rhizobium-induced root nodules of Parasponia rigida. I. Infection and early nodule initiation.

Author

Lancelle, Susan and Torrey, J.

Abstract

The first of two major steps in the infection process in roots of Parasponia rigida (Ulmaceae) following inoculation by Rhizobium strain RP501 involves the invasion of Rhizobium into the intercellular space system of the root cortex. The earliest sign of root nodule initiation is the presence of clumps of multicellular root hairs (MCRH), a response apparently unique among Rhizobium-root associations. At the same time or shortly after MCRH are first visible, cell divisions are initiated in the outer root cortex of the host plant, always subjacent to the MCRH. No infection threads were observed in root hairs or cortical cells in early stages. Rhizobial entry through the epidermis and into the root cortex was shown to occur via intercellular invasion at the bases of MCRH. The second major step in the infection process is the actual infection per se of host cells by the rhizobia and formation of typical intracellular infection threads with host cell accommodation. This infection step is probably the beginning of the truly symbiotic relationship in these nodules. Rhizobial invasion and infection are accompanied by host cortical cell divisions which result in a callus-like mass of cortical cells. In addition to infection thread formation in some of these host cortical cells, another type of rhizobial proliferation was observed in which large accumulations of rhizobia in intercellular spaces are associated with host cell wall distortion, deposition of electron-dense material in the walls, and occasional deleterious effects on host cell cytoplasm. [ABSTRACT FROM AUTHOR]

Published

1984

25. Bacterial‐induced calcium oscillations are common to nitrogen‐fixing associations of nodulating legumes and non‐legumes

Author

Emma Granqvist, Jongho Sun, J. Allan Downie, Petar Pujic, Richard J. Morris, René Geurts, Rik Op den Camp, Lionel Hill, Giles E. D. Oldroyd, Philippe Normand, Laboratoire d'Ecologie Microbienne - UMR 5557 (LEM), Centre National de la Recherche Scientifique (CNRS)-Ecole Nationale Vétérinaire de Lyon (ENVL)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut National de la Recherche Agronomique (INRA)-VetAgro Sup - Institut national d'enseignement supérieur et de recherche en alimentation, santé animale, sciences agronomiques et de l'environnement (VAS), Institut National de la Recherche Agronomique (INRA)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS)-VetAgro Sup - Institut national d'enseignement supérieur et de recherche en alimentation, santé animale, sciences agronomiques et de l'environnement (VAS)-Ecole Nationale Vétérinaire de Lyon (ENVL), BBSRC [BB/J004553/1], European Research Council, John Innes Foundation, NWO [VICI 865.13.001], and Oldroyd, Giles E. D.

Subjects

Microinjections, Symbiotic signalling, Physiology, [SDV]Life Sciences [q-bio], Calcium oscillations, Frankia, nodosité racinaire, Plant Science, nitrogen‐fixing clade, Nodulation, Sinorhizobium fredii, Plant Root Nodulation, Rhizobia, Nod factor, Nitrogen-fixing clade, Bacterial Proteins, protéine bactérienne, Nitrogen Fixation, Botany, Laboratorium voor Moleculaire Biologie, Calcium Signaling, Phylogeny, Frankia alni, Vegetal Biology, calcium, Bacteria, Rapid Report, EPS-1, biology, Research, Parasponia, Fabaceae, 15. Life on land, Actinorhizal, Legumes, biology.organism_classification, actinorhizal, calcium oscillations, legumes, nitrogen-fixing, clade, nodulation, symbiotic signalling, fixation de l'azote, Rapid Reports, Laboratory of Molecular Biology, Actinorhizal plant, Biologie végétale

Abstract

* Plants that form root-nodule symbioses are within a monophyletic \textquoteleftnitrogen-fixing' clade and associated signalling processes are shared with the arbuscular mycorrhizal symbiosis. Central to symbiotic signalling are nuclear-associated oscillations in calcium ions (Ca2+), occurring in the root hairs of several legume species in response to the rhizobial Nod factor signal. * In this study we expanded the species analysed for activation of Ca2+ oscillations, including nonleguminous species within the nitrogen-fixing clade. * We showed that Ca2+ oscillations are a common feature of legumes in their association with rhizobia, while Cercis, a non-nodulating legume, does not show Ca2+ oscillations in response to Nod factors from Sinorhizobium fredii NGR234. Parasponia andersonii, a nonlegume that can associate with rhizobia, showed Nod factor-induced calcium oscillations to S. fredii NGR234 Nod factors, but its non-nodulating sister species, Trema tomentosa, did not. Also within the nitrogen-fixing clade are actinorhizal species that associate with Frankia bacteria and we showed that Alnus glutinosa induces Ca2+ oscillations in root hairs in response to exudates from Frankia alni, but not to S. fredii NGR234 Nod factors. * We conclude that the ability to mount Ca2+ oscillations in response to symbiotic bacteria is a common feature of nodulating species within the nitrogen-fixing clade.

Published

2015

26. Biological nitrogen fixation in non-legume plants

Author

Carole Santi, Didier Bogusz, and Claudine Franche

Subjects

Crops, Agricultural, Microorganism, actinorhizal, Biodiversity, plant, Plant Science, Biology, Cyanobacteria, Plant Roots, cyanobacteria, Competitive advantage, Nitrogen fixation, Symbiosis, Nitrogen Fixation, Endophytes, nodulation, rhizobacteria, Ecosystem diversity, chemistry.chemical_classification, Invited Review, Ecology, Parasponia, food and beverages, symbiosis, non-legume, chemistry, PGPR, plant growth-promoting, Frankia, Diazotroph, Essential nutrient

Abstract

Background Nitrogen is an essential nutrient in plant growth. The ability of a plant to supply all or part of its requirements from biological nitrogen fixation (BNF) thanks to interactions with endosymbiotic, associative and endophytic symbionts, confers a great competitive advantage over non-nitrogen-fixing plants. Scope Because BNF in legumes is well documented, this review focuses on BNF in non-legume plants. Despite the phylogenic and ecological diversity among diazotrophic bacteria and their hosts, tightly regulated communication is always necessary between the microorganisms and the host plant to achieve a successful interaction. Ongoing research efforts to improve knowledge of the molecular mechanisms underlying these original relationships and some common strategies leading to a successful relationship between the nitrogen-fixing microorganisms and their hosts are presented. Conclusions Understanding the molecular mechanism of BNF outside the legume-rhizobium symbiosis could have important agronomic implications and enable the use of N-fertilizers to be reduced or even avoided. Indeed, in the short term, improved understanding could lead to more sustainable exploitation of the biodiversity of nitrogen-fixing organisms and, in the longer term, to the transfer of endosymbiotic nitrogen-fixation capacities to major non-legume crops.

Published

2013

27. Biology of the Pavasponia-Bradyrhizobium symbiosis

Author

Trinick, M. J., Hadobas, P. A., Skinner, F. A., editor, Boddey, R. M., editor, and Fendrik, I., editor

Published

1989

28. Genetic constraints that determine rhizobium-root nodule formation in Parasponia andersonii

Author

Seifi Kalhor, M., Wageningen University, Ton Bisseling, and Rene Geurts

Subjects

rhizobium rhizogenes, nitrates, food and beverages, temperature, genetica, wortelknolletjes, symbiosis, rhizobium, parasponia, root nodules, temperatuur, Laboratorium voor Moleculaire Biologie, genetics, nitraten, Laboratory of Molecular Biology, EPS, symbiose

Abstract

Bacteria of the genus Rhizobium play a very important role in agriculture by inducing nitrogen-fixing nodules on the roots of legumes. Root nodule symbiosis enables nitrogen‐fixing bacteria (Rhizobium) to convert atmospheric nitrogen into a form that is directly available for plant growth. This symbiosis can relieve the requirements for added nitrogenous fertilizer during the growth of leguminous crops. Research on legume-rhizobium symbioses has emphasized fitness benefits to plants but in our research, we take a different vantage point, focusing on the Parasponia-rhizobium symbiosis. Parasponia is the only non-legume plant capable of establishing mutualistic relation with rhizobia. This study will provide background knowledge for use in applied objectives as well as yielding a wealth of fundamental knowledge with wide implications from rhizobium symbiosis evolution. This thesis describes my research on genetic constrains that determine rhizobium-root nodule formation. To identify these constraints we used Parasponia anadersnii as only non-legume capable to establish nitrogen fixing rhizobium symbiosis. Our main attempt in this thesis was to find the genetic constraints using Parasponia as a key and reconstruct an auto active symbiotic signaling cascade in the non- legume plants. In line with this, a simple and efficient hairy root transformation method was established in this thesis. To determine the genetic elements that underlie the rhizobium symbiosis, we aimed to compare Parasponia with closest non nodulating specious, Trema tomentosa. To do so, we also developed an efficient genetic transformation method for Trema mediated by Agrobacterium tumefaciens. In different attempt we implemented in a physiological study on symbiotic response of Parasponia to nitrate. This research opened a novel view on the Parasponia-rhizobium symbiosis by discovering a different mechanism that control root nodule formation in Parasponia in compare with legumes. We discovered that Parasponai-rhizbium symbiosis is not evolved to regulate the nodule number in presence of the nitrate. According to the fact that Parasponia and legumes are remotely related, it was hypothesized that, Parasponia-rhizobium symbiosis evolved independently. Therefore we put forward our attempt to determine the genes required for nodule formation in Parasponia, by extending our research on symbiotic genes which are available in non nodulating plants with different function, namely NSP1 and NSP2. We showed that NSP1 and NSP2 are involved in both nodulation and mycorrhization. This result highlight the idea that RN and AM symbiosis are conserved in part of the pathway and probably bifurcates into two branches by NSP transcription factor allowing specific activation of nodulation or mycorrhization. Aiming to know the role of hormones in symbiotic behavior, we focused on ethylene as a negative regulator of nodule formation in legumes. We found the negative effect of ethylene on root nodulation of Parasponia. For the first time we reported a hyper nodulation (20 fold nodule number in compare with control plants) phenotype in Parasponia by performing knocked down mutant of EIN2 gene. Finally, the results obtained in this study provide new insight into the fact that rhizobium symbiosis are under tight genetic constraints that guide endosymbiosis in remotely evolved host plants, legumes and Parasponia.

Published

2016

29. Genetic constraints that determine rhizobium-root nodule formation in Parasponia andersonii

Author

Bisseling, Ton, Geurts, Rene, Seifi Kalhor, M., Bisseling, Ton, Geurts, Rene, and Seifi Kalhor, M.

Abstract

Bacteria of the genus Rhizobium play a very important role in agriculture by inducing nitrogen-fixing nodules on the roots of legumes. Root nodule symbiosis enables nitrogen‐fixing bacteria (Rhizobium) to convert atmospheric nitrogen into a form that is directly available for plant growth. This symbiosis can relieve the requirements for added nitrogenous fertilizer during the growth of leguminous crops. Research on legume-rhizobium symbioses has emphasized fitness benefits to plants but in our research, we take a different vantage point, focusing on the Parasponia-rhizobium symbiosis. Parasponia is the only non-legume plant capable of establishing mutualistic relation with rhizobia. This study will provide background knowledge for use in applied objectives as well as yielding a wealth of fundamental knowledge with wide implications from rhizobium symbiosis evolution. This thesis describes my research on genetic constrains that determine rhizobium-root nodule formation. To identify these constraints we used Parasponia anadersnii as only non-legume capable to establish nitrogen fixing rhizobium symbiosis. Our main attempt in this thesis was to find the genetic constraints using Parasponia as a key and reconstruct an auto active symbiotic signaling cascade in the non- legume plants. In line with this, a simple and efficient hairy root transformation method was established in this thesis. To determine the genetic elements that underlie the rhizobium symbiosis, we aimed to compare Parasponia with closest non nodulating specious, Trema tomentosa. To do so, we also developed an efficient genetic transformation method for Trema mediated by Agrobacterium tumefaciens. In different attempt we implemented in a physiological study on symbiotic response of Parasponia to nitrate. This research opened a novel view on the Parasponia-rhizobium symbiosis by discovering a different mechanism that control root nodule formation in Parasponia in compare with legumes. We discovered that Pa

Published

2016

30. Evolutionary origin of rhizobium Nod factor signaling

Author

Arend Streng, Rik Op den Camp, Ton Bisseling, and René Geurts

Subjects

Lipopolysaccharides, Cell signaling, Review, Plant Science, Fungus, Nod, Evolution, Molecular, Nod factor, Glomeromycota, Symbiosis, Mycorrhizae, Botany, Laboratorium voor Moleculaire Biologie, EPS-1, biology, Parasponia, fungi, food and beverages, Fabaceae, Legumes, biology.organism_classification, Rhizobium, Laboratory of Molecular Biology, Signal Transduction

Abstract

For over two decades now, it is known that the nodule symbiosis between legume plants and nitrogen fixing rhizobium bacteria is set in motion by the bacterial signal molecule named nodulation (Nod) factor.1 Upon Nod factor perception a signaling cascade is activated that is also essential for endomycorrhizal symbiosis (Fig. 1). This suggests that rhizobium co-opted the evolutionary far more ancient mycorrhizal signaling pathway in order to establish an endosymbiotic interaction with legumes.2 As arbuscular mycorrhizal fungi of the Glomeromycota phylum can establish a symbiosis with the vast majority of land plants, it is most probable that this signaling cascade is wide spread in the plant kingdom.3 However, Nod factor perception generally is considered to be unique to legumes. Two recent breakthroughs on the evolutionary origin of rhizobium Nod factor signaling demonstrate that this is not the case.4,5 The purification of Nod factor-like molecules excreted by the mycorrhizal fungus Glomus intraradices and the role of the LysM-type Nod factor receptor PaNFP in the non-legume Parasponia andersonii provide novel understanding on the evolution of rhizobial Nod factor signaling.

Published

2011

31. A Roadmap toward Engineered Nitrogen-Fixing Nodule Symbiosis.

Author

Huisman R and Geurts R

Subjects

Crops, Agricultural metabolism, Crops, Agricultural microbiology, Fabaceae microbiology, Fabaceae physiology, Mycorrhizae physiology, Nitrogen Fixation, Plant Development, Plant Breeding methods, Plant Root Nodulation physiology, Symbiosis genetics

Abstract

In the late 19 th century, it was discovered that legumes can establish a root nodule endosymbiosis with nitrogen-fixing rhizobia. Soon after, the question was raised whether it is possible to transfer this trait to non-leguminous crops. In the past century, an ever-increasing amount of knowledge provided unique insights into the cellular, molecular, and genetic processes controlling this endosymbiosis. In addition, recent phylogenomic studies uncovered several genes that evolved to function specifically to control nodule formation and bacterial infection. However, despite this massive body of knowledge, the long-standing objective to engineer the nitrogen-fixing nodulation trait on non-leguminous crop plants has not been achieved yet. In this review, the unsolved questions and engineering strategies toward nitrogen-fixing nodulation in non-legume plants are discussed and highlighted., (© 2020 The Authors.)

Published

2019

32. Evolution of Rhizobium Nodulation: From Nodule-Specific Genes (Nodulins) to Recruitment of Common Processes

Author

Sjef Moling and Ton Bisseling

Subjects

Nodule (geology), biology, Evolution, Parasponia, Symbiotic interface, engineering.material, Legumes, biology.organism_classification, Arbuscular mycorrhiza, Symbiosis, Botany, engineering, Laboratorium voor Moleculaire Biologie, Rhizobium, Laboratory of Molecular Biology, Gene

Published

2015

33. Bacterial-induced calcium oscillations are common to nitrogen-fixing associations of nodulating legumes and non-legumes

Author

Granqvist, E., Sun, J., Op den Camp, R., Pujic, P., Hill, L., Normand, P., Morris, R.J., Downie, J.A., Geurts, R., Oldroyd, G.E.D., Granqvist, E., Sun, J., Op den Camp, R., Pujic, P., Hill, L., Normand, P., Morris, R.J., Downie, J.A., Geurts, R., and Oldroyd, G.E.D.

Abstract

•Plants that form root-nodule symbioses are within a monophyletic ‘nitrogen-fixing’ clade and associated signalling processes are shared with the arbuscular mycorrhizal symbiosis. Central to symbiotic signalling are nuclear-associated oscillations in calcium ions (Ca2+), occurring in the root hairs of several legume species in response to the rhizobial Nod factor signal. •In this study we expanded the species analysed for activation of Ca2+ oscillations, including non-leguminous species within the nitrogen-fixing clade. •We showed that Ca2+ oscillations are a common feature of legumes in their association with rhizobia, while Cercis, a non-nodulating legume, does not show Ca2+ oscillations in response to Nod factors from Sinorhizobium fredii NGR234. Parasponia andersonii, a non-legume that can associate with rhizobia, showed Nod factor-induced calcium oscillations to S. fredii NGR234 Nod factors, but its non-nodulating sister species, Trema tomentosa, did not. Also within the nitrogen-fixing clade are actinorhizal species that associate with Frankia bacteria and we showed that Alnus glutinosa induces Ca2+ oscillations in root hairs in response to exudates from Frankia alni, but not to S. fredii NGR234 Nod factors. •We conclude that the ability to mount Ca2+ oscillations in response to symbiotic bacteria is a common feature of nodulating species within the nitrogen-fixing clade.

Published

2015

34. Root-based N2-fixing Symbioses: Legumes, Actinorhizal Plants, Parasponia sp. and Cycads

Author

Vessey, J. Kevin, Pawlowski, Katharina, and Bergman, Birgitta

Published

2005

35. Natural abundance of 15N in actinorhizal plants and nodules

Author

Tjepkema, J.D., Schwintzer, C.R., Burris, R.H., Johnson, G.V., and Silvester, W.B.

Published

2000

36. Evolution of rhizobium symbiosis

Author

Op den Camp, R.H.M., Wageningen University, Ton Bisseling, and Rene Geurts

Subjects

genomen, mycorrhizas, evolutie, papilionoideae, symbiosis, moleculaire biologie, rhizobium, parasponia, evolution, molecular biology, Laboratorium voor Moleculaire Biologie, Laboratory of Molecular Biology, EPS, genomes, mycorrhizae, symbiose

Abstract

The evolution of rhizobium symbiosis is studied from several points of view in this thesis. The ultimate goal of the combined approaches is to unravel the genetic constrains of the symbiotic interaction. To this end the legume rhizobium symbiosis is studied in model plant species from the Papilionoideae subfamily such as Medicago truncatula and Lotus japonicus. In these model plants the genetic signaling cascade used for rhizobium symbiosis has been largely unraveled. The cascade is triggered by lipo-chitooligosaccharade-based signal molecules excreted by rhizobia, called Nod factors. In chapter 2 we make use of a whole genome duplication that has occurred at the root of the legume Papilionoideae subfamily to identify maintained paralogous gene pairs. We hypothesized that a substantial fraction of gene pairs which are maintained in distinct Papilionoideae lineages that split roughly 54 million years ago fulfill legume specific functions, among which is rhizobium symbiosis. Furthermore we argue that such approach could identify novel genes as it can also identify genes pairs that are (partially) redundant in function. With applying this approach specifically to the cytokinin phosphorelay pathway we identified a pair of type-A cytokinin Response Regulators that are involved in rhizobium symbiosis. This study provides a proof-of-principle for this strategy. It is known for over fifty years that cytokinin plays an important role in the symbiotic interaction between rhizobia and legume hosts. External application of cytokinin can even result in nodule formation. Only, never had cytokinin levels been quantified in legume root extracts upon symbiotic interaction. In chapter 3 we describe a method for extraction of both cytokinins and auxin from Medicago truncatula roots. We show that cytokinins accumulate in the root zone susceptible to symbiotic interaction upon Nod factor exposure and that this response is dependent on CCaMK; a key gene of the Nod factor signaling cascade. Furthermore, it was found that ethylene signaling has a negative effect on Nod factor induced cytokinin accumulation. The method set up to measure cytokinin as well as auxin provides a tool to further study hormone interactions in rhizobium symbiosis. Parasponia,the only non-legume that can engage the rhizobium symbiosis is also subject of study in this thesis. The genetics of the Parasponia-rhizobium symbiosis had not been studied before. It was therefore unknown whether this independently evolved rhizobium symbiosis makes use of the same symbiotic signaling cascade as legumes. In chapter 4 we provide first evidence that Parasponia indeed makes use of the same signaling cascade as found in legumes. Furthermore, we show that in Parasponia a single Nod factor-like receptor is indispensable for two symbiotic interactions; rhizobium and mycorrhiza, respectively. Therefore we conclude that the rhizobium Nod factor perception mechanism is recruited from the widespread endomycorrhizal symbiosis. Parallel to our studies in Parasponia (Chapter 4), the research team of Jean Dénarié of the French National Institute for Agricultural Research (INRA) published the structure of the signal molecule of the arbuscular endomycorrhizae; theMyc factor (Maillet et al., 2011, Fungal lipochitooligosaccharide symbiotic signals in arbuscular mycorrhiza. Nature, 469, 58-63). It appeared that Myc factors and Nod factors are structurally very similar. In chapter 5 we discuss these findings and present a more thorough phylogenetic analysis of the NFP-like LysM-type receptor kinases. Together, these results suggest that non-legumes that can engage an arbuscular endomycorrhizaesymbiosis can recognize Nod factor-like molecules as well. The last chapter is about a study on the promiscuity and effectiveness of the Parasponia-rhizobium symbiosis. Parasponia uses a single receptor to control entry of rhizobium as well as arbuscular endomycorrhizal fungi and has evolved the rhizobium symbiosis only recently. This made us to hypothesize that Parasponia Nod factor receptors did not coevolve yet with rhizobia and therefore did not diverge from mycorrhizal recognition to develop specificity for the Nod factor. This implies that Parasponia could be a very promiscuous host for rhizobium species. In chapter 6 we describe that Parasponia andersonii can be nodulated by a broad range of rhizobia belonging to 4 different genera, and therefore it is concluded that Parasponia is highly promiscuous for rhizobial engagement. There is a drawback to this high symbiotic promiscuity. Among the strains identified to nodulate Parasponia, a very inefficient rhizobium species, Rhizobium tropici WUR1, was characterized. As this species is able to make effective nodules on two different legume species it suggests that the ineffectiveness of Parasponia andersonii nodules is the result of the incompatibility between both partners. In Parasponia andersonii nodules rhizobia of the ineffective strain become embedded in a dense matrix, but remain vital. This suggests that sanctions or genetic control against underperforming microsymbionts may not be effective in Parasponia. Therefore we argue that the Parasponia-Rhizobium symbiosis is a delicate balance between mutual benefits and parasitic colonization. Parasponiahas been given little attention in the rhizobium symbiosis field over the past two decades but with our efforts renewed interest has been established. We believe that in the end, the comparison of Parasponia to its closest related non-symbiotic sister species Trema, will result in the determination of the genetic constrains of rhizobium symbiosis.

Published

2012

37. Evolution of rhizobium symbiosis

Subjects

genomen, mycorrhizas, evolutie, papilionoideae, symbiosis, moleculaire biologie, rhizobium, parasponia, evolution, molecular biology, Laboratorium voor Moleculaire Biologie, Laboratory of Molecular Biology, EPS, genomes, mycorrhizae, symbiose

Abstract

The evolution of rhizobium symbiosis is studied from several points of view in this thesis. The ultimate goal of the combined approaches is to unravel the genetic constrains of the symbiotic interaction. To this end the legume rhizobium symbiosis is studied in model plant species from the Papilionoideae subfamily such as Medicago truncatula and Lotus japonicus. In these model plants the genetic signaling cascade used for rhizobium symbiosis has been largely unraveled. The cascade is triggered by lipo-chitooligosaccharade-based signal molecules excreted by rhizobia, called Nod factors. In chapter 2 we make use of a whole genome duplication that has occurred at the root of the legume Papilionoideae subfamily to identify maintained paralogous gene pairs. We hypothesized that a substantial fraction of gene pairs which are maintained in distinct Papilionoideae lineages that split roughly 54 million years ago fulfill legume specific functions, among which is rhizobium symbiosis. Furthermore we argue that such approach could identify novel genes as it can also identify genes pairs that are (partially) redundant in function. With applying this approach specifically to the cytokinin phosphorelay pathway we identified a pair of type-A cytokinin Response Regulators that are involved in rhizobium symbiosis. This study provides a proof-of-principle for this strategy. It is known for over fifty years that cytokinin plays an important role in the symbiotic interaction between rhizobia and legume hosts. External application of cytokinin can even result in nodule formation. Only, never had cytokinin levels been quantified in legume root extracts upon symbiotic interaction. In chapter 3 we describe a method for extraction of both cytokinins and auxin from Medicago truncatula roots. We show that cytokinins accumulate in the root zone susceptible to symbiotic interaction upon Nod factor exposure and that this response is dependent on CCaMK; a key gene of the Nod factor signaling cascade. Furthermore, it was found that ethylene signaling has a negative effect on Nod factor induced cytokinin accumulation. The method set up to measure cytokinin as well as auxin provides a tool to further study hormone interactions in rhizobium symbiosis. Parasponia,the only non-legume that can engage the rhizobium symbiosis is also subject of study in this thesis. The genetics of the Parasponia-rhizobium symbiosis had not been studied before. It was therefore unknown whether this independently evolved rhizobium symbiosis makes use of the same symbiotic signaling cascade as legumes. In chapter 4 we provide first evidence that Parasponia indeed makes use of the same signaling cascade as found in legumes. Furthermore, we show that in Parasponia a single Nod factor-like receptor is indispensable for two symbiotic interactions; rhizobium and mycorrhiza, respectively. Therefore we conclude that the rhizobium Nod factor perception mechanism is recruited from the widespread endomycorrhizal symbiosis. Parallel to our studies in Parasponia (Chapter 4), the research team of Jean Dénarié of the French National Institute for Agricultural Research (INRA) published the structure of the signal molecule of the arbuscular endomycorrhizae; theMyc factor (Maillet et al., 2011, Fungal lipochitooligosaccharide symbiotic signals in arbuscular mycorrhiza. Nature, 469, 58-63). It appeared that Myc factors and Nod factors are structurally very similar. In chapter 5 we discuss these findings and present a more thorough phylogenetic analysis of the NFP-like LysM-type receptor kinases. Together, these results suggest that non-legumes that can engage an arbuscular endomycorrhizaesymbiosis can recognize Nod factor-like molecules as well. The last chapter is about a study on the promiscuity and effectiveness of the Parasponia-rhizobium symbiosis. Parasponia uses a single receptor to control entry of rhizobium as well as arbuscular endomycorrhizal fungi and has evolved the rhizobium symbiosis only recently. This made us to hypothesize that Parasponia Nod factor receptors did not coevolve yet with rhizobia and therefore did not diverge from mycorrhizal recognition to develop specificity for the Nod factor. This implies that Parasponia could be a very promiscuous host for rhizobium species. In chapter 6 we describe that Parasponia andersonii can be nodulated by a broad range of rhizobia belonging to 4 different genera, and therefore it is concluded that Parasponia is highly promiscuous for rhizobial engagement. There is a drawback to this high symbiotic promiscuity. Among the strains identified to nodulate Parasponia, a very inefficient rhizobium species, Rhizobium tropici WUR1, was characterized. As this species is able to make effective nodules on two different legume species it suggests that the ineffectiveness of Parasponia andersonii nodules is the result of the incompatibility between both partners. In Parasponia andersonii nodules rhizobia of the ineffective strain become embedded in a dense matrix, but remain vital. This suggests that sanctions or genetic control against underperforming microsymbionts may not be effective in Parasponia. Therefore we argue that the Parasponia-Rhizobium symbiosis is a delicate balance between mutual benefits and parasitic colonization. Parasponiahas been given little attention in the rhizobium symbiosis field over the past two decades but with our efforts renewed interest has been established. We believe that in the end, the comparison of Parasponia to its closest related non-symbiotic sister species Trema, will result in the determination of the genetic constrains of rhizobium symbiosis.

Published

2012

38. Expression of phosphinothricin acetyltransferase from the root specific par promoter in transgenic tobacco plants is sufficient for herbicide tolerance

Author

van der Hoeven, Cornelia, Dietz, Antje, and Landsmann, Jörg

Published

1994

39. Evolution of rhizobium symbiosis

Author

Bisseling, Ton, Geurts, Rene, Op den Camp, R.H.M., Bisseling, Ton, Geurts, Rene, and Op den Camp, R.H.M.

Abstract

The evolution of rhizobium symbiosis is studied from several points of view in this thesis. The ultimate goal of the combined approaches is to unravel the genetic constrains of the symbiotic interaction. To this end the legume rhizobium symbiosis is studied in model plant species from the Papilionoideae subfamily such as Medicago truncatula and Lotus japonicus. In these model plants the genetic signaling cascade used for rhizobium symbiosis has been largely unraveled. The cascade is triggered by lipo-chitooligosaccharade-based signal molecules excreted by rhizobia, called Nod factors. In chapter 2 we make use of a whole genome duplication that has occurred at the root of the legume Papilionoideae subfamily to identify maintained paralogous gene pairs. We hypothesized that a substantial fraction of gene pairs which are maintained in distinct Papilionoideae lineages that split roughly 54 million years ago fulfill legume specific functions, among which is rhizobium symbiosis. Furthermore we argue that such approach could identify novel genes as it can also identify genes pairs that are (partially) redundant in function. With applying this approach specifically to the cytokinin phosphorelay pathway we identified a pair of type-A cytokinin Response Regulators that are involved in rhizobium symbiosis. This study provides a proof-of-principle for this strategy. It is known for over fifty years that cytokinin plays an important role in the symbiotic interaction between rhizobia and legume hosts. External application of cytokinin can even result in nodule formation. Only, never had cytokinin levels been quantified in legume root extracts upon symbiotic interaction. In chapter 3 we describe a method for extraction of both cytokinins and auxin from Medicago truncatula roots. We show that cytokinins accumulate in the root zone susceptible to symbiotic interaction upon Nod factor exposure and that this response is dependent on CCaMK; a key gene of the Nod factor signaling cascad

Published

2012

40. Nodulation of Trifolium repens with modified Bradyrhizobium and the nodulation of Parasponia with Rhizobium leguminosarum biovar trifolii

Author

Trinick, M. J. and Hadobas, P. A.

Published

1990

41. Symbiotic effectiveness of Bradyrhizobium strains isolated from Parasponia and tropical legumes on Parasponia host species

Author

Trinick, M. J. and Hadobas, P. A.

Published

1990

42. Biology of theParasponia-Bradyrhizobium symbiosis

Author

Trinick, M. J. and Hadobas, P. A.

Published

1988

43. The role of Rhizobium conserved and host specific nodulation genes in the infection of the non-legume Parasponia andersonii

Author

Bender, Gregory L., Goydych, Walter, Rolfe, Barry G., and Nayudu, Murali

Published

1987

44. Early development ofRhizobium-induced root nodules ofParasponia rigida. I. Infection and early nodule initiation

Author

Lancelle, Susan A. and Torrey, J. G.

Published

1984

45. Sensitivity to oxygen of nitrogenase activity in Rhizobium strain ANU289 of the non-legume Parasponia (Ulmaceae)

Author

Gresshoff, P. M. and Mohapatra, S. S.

Published

1984

46. Formation of nodular structures on the non-legumes Brassica napus, B. campestris, B. juncea and Arabidopsis thaliana with Bradyrhizobium and Rhizobium isolated from Parasponia spp. or legumes grown in tropical soils

Author

Hadobas, P. A. and Trinick, M. J.

Subjects

ARABIDOPSIS thaliana

Published

1995

47. Root-nodule symbiosis between Rhizobium and Parasponia (Ulmaceae)

Author

Becking, J. H.

Subjects

RHIZOBIUM

Published

1979

48. N-fixing root nodules in Ulmaceae: Parasponia or (and) Trema spp.?

Author

Akkermans, A. D. L., Abdulkadir, S., and Trinick, M. F.

Subjects

ULMACEAE

Published

1978

49. Bacterial-induced calcium oscillations are common to nitrogen-fixing associations of nodulating legumes and nonlegumes

Published

2015

50. Tansley Review No.15. Which Steps are Essential for the Formation of Functional Legume Nodules?

Author

Sprent, J. I.

Published

1989