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Plant function and evolutionary biology
FOREWORD

Actinorhizal plants

Ana Ribeiro A E , Alison M. Berry B , Katharina Pawlowski C and Patrícia Santos A D
+ Author Affiliations
- Author Affiliations

A ECO-BIO/Tropical Research Institute, Av. da República (EAN), Quinta do Marquês, 2784-505 Oeiras, Portugal.

B Department of Plant Sciences, University of California, Davis, CA 95616, USA.

C Department of Botany, Stockholm University, 10691 Stockholm, Sweden.

D Department of Plant Pathology, Michigan State University, East Lansing, MI 48824, USA.

E Corresponding author. Email: aribeiro@itqb.unl.pt; aribeiro@iict.pt

Functional Plant Biology 38(9) v-vii https://doi.org/10.1071/FPv38n9_FO
Published: 16 August 2011

Abstract

Actinorhizal plants are a group of taxonomically diverse angiosperms with remarkable economic and ecological significance. Most actinorhizal plants are able to thrive under extreme adverse environmental conditions as well as to fix atmospheric nitrogen due to their capacity to establish root nodule symbioses with Frankia bacteria. This special issue of Functional Plant Biology is dedicated to actinorhizal plant research, covering part of the work presented at the 16th International Meeting onFrankia and Actinorhizal Plants, held on 5–8 September 2010, in Oporto, Portugal. The papers (4 reviews and 10 original articles) give an overall picture of the status of actinorhizal plant research and the imposed challenges, covering several aspects of the symbiosis, ecology and molecular tools.

Additional keywords: actinorhizal plants, Frankia, nodulation, root nodule symbioses.

The importance of actinorhizal plants

Actinorhizal plants are a group of taxonomically diverse angiosperms distributed over 8 plant families and 25 genera, mostly woody shrubs or trees (Table 1). Most actinorhizal plants are capable of high rates of biological nitrogen (N2) fixation due their capacity to establish root nodule symbioses with N2-fixing actinomycetes of the genus Frankia (Sprent and Parsons 2000). Besides that, the formation of tripartite symbiotic relationships (i.e. root nodules and endo- and ectomycorhizal fungi) has implications for ecosystem nutrient cycling as well as plant nutrition. As pioneer species in many environments, actinorhizal plants have demonstrated an impressive capacity to tolerate extreme environmental conditions, such as salinity, drought or heavy metals. Hence, several actinorhizal species are of remarkable economic and ecological significance (Schwencke and Carú 2001). Notably, trees in the Casuarinaceae family have a wide range of applications in agroforestry and land reclamation, including the production of biomass, fuel and timber; interplanting with crop trees; as shelter belts in crop fields; prevention of desertification; coastal dunes stabilisation; and restoration of degraded soils (Diem and Dommergues 1990). Another promising actinorhizal species is Hippophae rhamnoides, which is now being domesticated because its fruits are very nutritious (rich in vitamin C) and their seed oil is highly unsaturated making it suitable for cosmetics and phytopharmaceuticals (Beveridge et al. 1999; Li et al. 2007).


Table 1.  Families and genera of actinorhizal plants
T1


The 16th International Meeting on Frankia and Actinorhizal Plants

For decades, several groups have been working to evaluate the genetic and ecological potential of actinorhizal plants as well as to understand the mechanisms underlying their capacity to establish N2-fixing root nodule symbiosis with Frankia. Due to the woody nature of actinorhizal plants, which interferes with the isolation of proteins and nucleic acids, and their long generation time, which prevents experimentally feasible genetic analysis, as well as the fact that Frankia is slow growing and non-transformable, research on the topic has been hampered for many years and therefore the information available is still limited. Nevertheless, with the availability of new research technologies, considerable advances have been achieved over the last few years.

This special issue of Functional Plant Biology is dedicated to actinorhizal plant research, covering part of the work presented at the 16th International Meeting onFrankia and Actinorhizal Plants, held on 5–8 September 2010, in Oporto, Portugal (Fig. 1). Such meetings have a biennial periodicity and constitute a unique opportunity for the small actinorhizal research community to meet and discuss the major advances, perspectives and constraints and to strengthen and build up new partnerships. Three main topics were addressed: (i) Systems Biology (‘omics’); (ii) Ecology and Biodiversity; and (iii) Physiology and Biochemistry. A total of 35 communications (20 oral presentations and 15 posters) covering different aspects of actinorhizal research were presented. From the plant side, the following issues were highlighted: (i) major advances in functional genomics of Alnus glutinosa, Casuarina glauca and Datisca glomerata root nodule symbioses; (ii) hairy-root genetic transformation of Coriaria trinervis and Datisca glomerata; (iii) comparative studies through the heterologous expression of nodulin gene (i.e. genes up-regulated in nodules versus roots) promoters; (iv) ecological potentialities and the main effects of Alnus, Casuarina, Ceanothus and Coriaria in natural and limiting environments; (v) biogeography studies in Africa; (vi) nodulation signalling and nodule nitrogen metabolism; and (vii) photosynthetic and antioxidant abilities. Regarding Frankia, major breakthroughs in genomics, nodulation factors, transformation tools, phylogeny and metabolism, were discussed. The papers focusing on Frankia research are being published in parallel, in a special issue of Archives of Microbiology.


Fig. 1.  After the final banquet of the 16th International Meeting on Frankia and Actinorhizal Plants, 5–8 September 2010, Oporto, Portugal. Back row (left to right): Katharina Pawlowski, Valérie Hocher, Louis Tisa, Linda Stoxen, Arnab Sen, Mike Anderson, Arvind Misra, Sergio Svistoonoff, Teal Furnholm, Hiroyuki Tobita, Faiza Benabdoun, Roger Ruess, Aude Herrera-Belaroussi, Alison Berry, Philippe Normand and Masatoshi Yamaura; Sitting: Ana Ribeiro, Nicholas Beauchemin, Luis Wall, Michaela Swanson, Ken-ichi Kucho, Didier Bogusz, Jeffrey Dawson and Kentaro Kakoi; Front row: Catarina Santos, Fernando Tavares and Perpétua Tavares.
F1

In this issue, 14 articles (4 reviews and 10 original papers) are presented. In the first review, Pawlowski et al. (2011) give a general overview of actinorhizal plant research, focusing on Nod factor signal transduction, phytohormones and nodule formation, symbiosis versus pathogenesis and general stress, nitrogen assimilation and transcriptome profiling. The induction of host stress-related genes and their putative function during symbiosis is further detailed in the review of Ribeiro et al. (2011). Berry et al. (2011) summarises the recent advances in actinorhizal nodule nitrogen assimilation with emphasis on D. glomerata. The last review (Gtari and Dawson 2011) is quite pioneering as it presents the first comprehensive report on species distribution and current uses in Africa.

The first group of original papers focuses on the initial steps of actinorhizal symbiosis. Gabbarini and Wall (2011a, 2011b) present two papers in which the modulation of diffusible Frankia factors by A. acuminata and Discaria trinervis is exploited. Popovici et al. (2011) focus on the adaptation of the secondary metabolism of plants from the Myricaceae family according to the compatibility status of Frankia strains. Auguy et al. (2011) provide the first (though preliminary) insights on the involvement of isoflavonoids as signal molecules during C. glauca nodulation. Regarding nodule functioning, Goyal et al. (2011) discusses the antioxidant profiling of Hippophae salicifolia from the sacred forests of Sikkim, India. A detailed evaluation of the effects of elevated atmospheric CO2 concentration, soil nutrients and water conditions on photosynthetic and growth responses of Alnus hirsuta is provided by Tobita et al. (2011). From a more ecological perspective, Taft and Dawson (2011) discuss the influence of Ceanothus americanus on the species composition and diversity in tallgrass prairie. Additionally, Reyes et al. (2011) presented the results of reproductive ecology studies in Ochetophila trinervis from north-west Patagonia in view of reclamation of disturbed lands. Finally, the last group of papers (Rashidi et al. 2011; Yanthan et al. 2011) discuss the suitability of some molecular tools for different purposes. Rashidi et al. (2011) present the main constraints of using the C. glaucametallothionein I promoter as a tool for the expression of transgenes in hairy roots. Yanthan et al. (2011) provide molecular taxonomic tools to discriminate Myrica species.

Altogether, as molecular genetic and global analytical tools continue to evolve, and as additional Frankia genomes as well as root nodule EST sequences are becoming available, such new options will continue to expand our horizons for the study of actinorhizal symbioses.



References

Auguy F, Abdel-Lateif K, Doumas P, Badin P, Guerin V, Bogusz D, Hocher V (2011) Activation of the isoflavonoid pathway in actinorhizal symbioses. Functional Plant Biology 38, 720–726.
Activation of the isoflavonoid pathway in actinorhizal symbioses.Crossref | GoogleScholarGoogle Scholar |

Berry AM, Mendoza-Herrera A, Guo YY, Hayashi J, Persson T, Barabote R, Zhang S, Pawlowski K (2011) New perspectives on nodule nitrogen assimilation in actinorhizal symbioses. Functional Plant Biology 38, 645–652.
New perspectives on nodule nitrogen assimilation in actinorhizal symbioses.Crossref | GoogleScholarGoogle Scholar |

Beveridge T, Li TSC, Oomah BD, Smith A (1999) Sea buckthorn products: manufacture and composition. Journal of Agricultural and Food Chemistry 47, 3480–3488.
Sea buckthorn products: manufacture and composition.Crossref | GoogleScholarGoogle Scholar |

Diem HG, Dommergues YR (1990) Current and potential uses and management of Casuarinaceae in the tropics and subtropics. In: The Biology of Frankia and Actinorhizal Plants, Schwintzer CR, Tjepkema JD (Eds.) Academic Press, New York, 317–342.

Gabbarini LA, Wall LG (2011a) Diffusible factors from Frankia modify nodulation kinetics in Discaria trinervis, an intercellular root-infected actinorhizal symbiosis. Functional Plant Biology 38, 662–670.
Diffusible factors from Frankia modify nodulation kinetics in Discaria trinervis, an intercellular root-infected actinorhizal symbiosis.Crossref | GoogleScholarGoogle Scholar |

Gabbarini LA, Wall LG (2011b) Diffusible factors involved in early interactions of the actinorhizal symbiosis are modulated by the host plant but are not enough to break host range barrier. Functional Plant Biology 38, 701–711.
Diffusible factors involved in early interactions of the actinorhizal symbiosis are modulated by the host plant but are not enough to break host range barrier.Crossref | GoogleScholarGoogle Scholar |

Goyal AK, Basistha BC, Sen A, Middha SK (2011) Antioxidant profiling of Hippophae salicifolia growing in sacred forests of Sikkim, India. Functional Plant Biology 38, 727–731.
Antioxidant profiling of Hippophae salicifolia growing in sacred forests of Sikkim, India.Crossref | GoogleScholarGoogle Scholar |

Gtari M, Dawson JO (2011) An overview of actinorhizal plants in Africa. Functional Plant Biology 38, 653–661.
An overview of actinorhizal plants in Africa.Crossref | GoogleScholarGoogle Scholar |

Li TSC, Beveridge THJ, Drover JCG (2007) Phytosterol content of sea buckthorn (Hippophae rhamnoides L.) seed oil: Extraction and identification. Food Chemistry 101, 1633–1639.
Phytosterol content of sea buckthorn (Hippophae rhamnoides L.) seed oil: Extraction and identification.Crossref | GoogleScholarGoogle Scholar |

Pawlowski K, Bogusz D, Ribeiro A, Berry AM (2011) Progress on research on actinorhizal plants. Functional Plant Biology 38, 633–638.
Progress on research on actinorhizal plants.Crossref | GoogleScholarGoogle Scholar |

Popovici J, Walker V, Bertrand C, Bellvert F, Fernandez MP, Comte G (2011) Strain specificity in the Myricaceae-Frankia symbiosis is correlated to plant root phenolics. Functional Plant Biology 38, 712–719.
Strain specificity in the Myricaceae-Frankia symbiosis is correlated to plant root phenolics.Crossref | GoogleScholarGoogle Scholar |

Rashidi B, Mehrabi S, Demchenko K, Pawlowski K (2011) The Casuarina glaucametallothionein I promoter in nodulated transgenic hairy roots of the actinorhizal plant Datisca glomerata. Functional Plant Biology 38, 758–767.
The Casuarina glaucametallothionein I promoter in nodulated transgenic hairy roots of the actinorhizal plant Datisca glomerata.Crossref | GoogleScholarGoogle Scholar |

Reyes MF, Gobbi ME, Chaia EE (2011) Reproductive ecology of Ochetophila trinervis in northwest patagonia. Functional Plant Biology 38, 750–757.
Reproductive ecology of Ochetophila trinervis in northwest patagonia.Crossref | GoogleScholarGoogle Scholar |

Ribeiro A, Graça I, Pawlowski K, Santos P (2011) Actinorhizal plant defence-related genes in response to symbiotic Frankia. Functional Plant Biology 38, 639–644.
Actinorhizal plant defence-related genes in response to symbiotic Frankia.Crossref | GoogleScholarGoogle Scholar |

Schwencke J, Carú M (2001) Advances in actinorhizal symbiosis: Host plant-Frankia interactions, biology, and applications in arid land reclamation. Arid Land Research and Management 15, 285–327.
Advances in actinorhizal symbiosis: Host plant-Frankia interactions, biology, and applications in arid land reclamation.Crossref | GoogleScholarGoogle Scholar |

Sprent JI, Parsons R (2000) Nitrogen fixation in legume and non-legume trees. Field Crops Research 65, 183–196.
Nitrogen fixation in legume and non-legume trees.Crossref | GoogleScholarGoogle Scholar |

Taft JB, Dawson JO (2011) Evidence for community structuring associated with the actinorhizal shrub Ceanothus americanus in tallgrass prairies in Illinois, USA. Functional Plant Biology 38, 741–749.
Evidence for community structuring associated with the actinorhizal shrub Ceanothus americanus in tallgrass prairies in Illinois, USA.Crossref | GoogleScholarGoogle Scholar |

Tobita H, Uemura A, Kitao M, Kitaoka S, Maruyama Y, Utsugi H (2011) Effects of elevated atmospheric carbon dioxide soil nutrients and water conditions on photosynthetic and growth responses of Alnus hirsuta. Functional Plant Biology 38, 732–740.
Effects of elevated atmospheric carbon dioxide soil nutrients and water conditions on photosynthetic and growth responses of Alnus hirsuta.Crossref | GoogleScholarGoogle Scholar |

Yanthan M, Biate D, Misra AK (2011) Taxonomic resolution of actinorhizal Myrica species from Meghalaya (India) through nuclear rDNA sequence analyses. Functional Plant Biology 38, 768–776.
Taxonomic resolution of actinorhizal Myrica species from Meghalaya (India) through nuclear rDNA sequence analyses.Crossref | GoogleScholarGoogle Scholar |