Article: Plant Pathology

Assessment of inoculation methods for screening black alder resistance to Phytophthora× alni. A Chandelier, C Husson, P Druart, B Marçais. Plant Pathology

Abstract

Identification of resistance to Phytophthora ×alni could provide the basis for a management strategy against alder decline in riparian ecosystems in Europe. Our objectives were to test methods to evaluate the resistance of riparian alders to the disease, and to screen alder genotypes for resistance. P. ×alni isolates were compared for their aggressiveness (lesion length on stem) and sporulation capacity (sporangia). While no difference of lesion lengths was found between isolates, sporangia production was dependent on isolate, highlighting the need to select carefully isolates for inoculation methods dealing with zoospores suspension. Inoculation tests carried out at different periods of the year revealed a seasonal change in susceptibility to the disease, with the period from June to September being the most efficient for inoculation tests. Stem-wounded inoculations tests carried out on excised shoots were unreliable for evaluating the level of resistance of alder genotypes to P. ×alni infection, with divergent results between two successive years or between two inoculation periods during the same year. In contrast, a method which mimics the natural conditions of infection based on flooding of rooted cuttings in artificially infected river water was found promising. Another method based on the inoculation of foliated terminal shoots with zoospore suspensions was found to be repeatable and could be used for high throughput analyses. Altogether, the results show a continuous resistance response from highly susceptible to moderately resistant genotypes. This suggests that breeding might be a useful strategy to manage alder decline caused by P. ×alni.

Article: Environmental Microbiology

Fine-scale spatial genetic structure analysis of the black truffle Tuber aestivum and its link to aroma variability. V Molinier, C Murat, H Crochet, D Wipf, R Splivallo. Environmental Microbiology

Abstract

Truffles are symbiotic fungi in high demand by food connoisseurs. Improving yield and product quality requires a better understanding of truffle genetics and aroma biosynthesis. One aim here was to investigate the diversity and fine-scale spatial genetic structure of the Burgundy truffle Tuber aestivum. The second aim was to assess how genetic structuring along with fruiting body maturation and geographical origin influenced single constituents of truffle aroma.

A total of thirty-nine Burgundy truffles collected in two orchards were characterized in terms of aroma profile (SPME-GC/MS) and genotype (microsatellites). A moderate genetic differentiation was observed between the populations of the two orchards. An important seasonal and spatial genetic structuring was detected. Within one orchard individuals belonging to the same genet were generally collected during a single season and in the close vicinity from each other. Maximum genet size nevertheless ranged from 46-92 m. Geographical origin or maturity only had minor effects on aroma profiles but genetic structuring, specifically clonal identity, had a pronounced influence on the concentrations of C8– and C4-VOCs.

Our results highlight a high seasonal genetic turnover and indicate that the aroma of Burgundy truffle is influenced by the identity of single clones/genets.

Article: Soil Biology and Biochemistry

Functional guild classification predicts the enzymatic role of fungi in litter and soil biogeochemistry JM Talbot, F Martin, A Kohler, B Henrissat, KG Peay. Soil Biology and Biochemistry

Abstract

Linking community composition to ecosystem function is a challenge in complex microbial communities. We tested the hypothesis that key biological features of fungi – evolutionary history, functional guild, and abundance of functional genes – can predict the biogeochemical activity of fungal species during decay. We measured the activity of 10 different enzymes produced by 48 model fungal species on leaf litter in laboratory microcosms. Taxa included closely related species with different ecologies (i.e. species in different “functional guilds”) and species with publicly available genomes. Decomposition capabilities differed less among phylogenetic lineages of fungi than among different functional guilds. Activity of carbohydrases and acid phosphatase was significantly higher in litter colonized by saprotrophs compared to ectomycorrhizal species. By contrast, oxidoreductase activities per unit fungal biomass were statistically similar across functional guilds, with white rot fungi having highest polyphenol oxidase activity and ectomycorrhizal fungi having highest peroxidase activity. On the ecosystem level, polyphenol oxidase activity in soil correlated with the abundance of white rot fungi, while soil peroxidase activity correlated with the abundance of ectomycorrhizal fungi in soil. Copy numbers of genes coding for different enzymes explained the activity of some carbohydrases and polyphenol oxidase produced by fungi in culture, but were not significantly better predictors of activity than specific functional guild. Collectively, our data suggest that quantifying the specific functional guilds of fungi in soil, potentially through environmental sequencing approaches, allows us to predict activity of enzymes that drive soil biogeochemical cycles.

Article: Annals of Forest Science

An evolutionary ecology perspective to address forest pathology challenges of today and tomorrow. ML Desprez-Loustau, J Aguayo, C Dutech, KJ Hayden, C Husson, … Annals of Forest Science, 1-23

Abstract

Key message

Increasing human impacts on forests, including unintentional movement of pathogens, climate change, and large-scale intensive plantations, are associated with an unprecedented rate of new diseases. An evolutionary ecology perspective can help address these challenges and provide direction for sustainable forest management.

Context

Forest pathology has historically relied on an ecological approach to understand and address the practical management of forest diseases. A widening of this perspective to include evolutionary considerations has been increasingly developed in response to the rising rates of genetic change in both pathogen populations and tree populations due to human activities.

Aims

Here, five topics for which the evolutionary perspective is especially relevant are highlighted.

Results

The first relates to the evolutionary diversity of fungi and fungal-like organisms, with issues linked to the identification of species and their ecological niches. The second theme deals with the evolutionary processes that allow forest pathogens to adapt to new hosts after introductions or to become more virulent in homogeneous plantations. The third theme presents issues linked to disease resistance in tree breeding programs (e.g., growth-defense trade-offs) and proposes new criteria and methods for more durable resistance. The last two themes are dedicated to the biotic environment of the tree–pathogen system, namely, hyperparasites and tree microbiota, as possible solutions for health management.

Conclusion

We conclude by highlighting three major conceptual advances brought by evolutionary biology, i.e., that (i) “not everything is everywhere”, (ii) evolution of pathogen populations can occur on short time scales, and (iii) the tree is a multitrophic community. We further translate these into a framework for immediate policy recommendations and future directions for research.

Article: Environmental Microbiology

Compartmentalized and contrasted response of ectomycorrhizal and soil fungal communities of Scots pine forests along elevation gradients in France and Spain

A Rincón, B Santamaría‐Pérez, SG Rabasa, A Coince, B Marçais, …
Environmental Microbiology

Abstract

Fungi are principal actors of forest soils implied in many ecosystem services and the mediation of tree’s responses. Forecasting fungal responses to environmental changes is necessary for maintaining forest productivity, although our partial understanding of how abiotic and biotic factors affect fungal communities is restricting the predictions. We examined fungal communities of P. sylvestris along elevation gradients to check potential responses to climate change associated factors. Fungi of roots and soils were analysed at a regional scale, by using a high-throughput sequencing approach. Overall soil fungal richness increased with pH, while did not vary with climate. However, when representative sub-assemblages, i.e. Ascomycetes/Basidiomycetes, and families were analysed, they differentially answered to climatic and edaphic variables. This response was dependent on where they settled, i.e. soil vs roots, and/or on their life style, i.e. mycorrhizal or not, suggesting different potential functional weights within the community. Our results revealed a highly compartmentalized and contrasted response of fungal communities in forest soils. The different response of fungal sub-assemblages indicated a range of possible selective direct and indirect (i.e. via host) impacts of climatic variations on these communities, of unknown functional consequences, that helps understanding potential fungal responses under future global change scenarios.

Article: Microbial Ecology Resources

Decoding the oak genome: public release of sequence data, assembly, annotation and publication strategies

C Plomion, JM Aury, J Amselem, T Alaeitabar, V Barbe, C Belser, …
Molecular Ecology Resources

Abstract

The 1.5 Gbp/2C genome of pedunculate oak (Quercus robur) has been sequenced. A strategy was established for dealing with the challenges imposed by the sequencing of such a large, complex and highly heterozygous genome by a whole-genome shotgun (WGS) approach, without the use of costly and time-consuming methods, such as fosmid or BAC clone-based hierarchical sequencing methods. The sequencing strategy combined short and long reads. Over 49 million reads provided by Roche 454 GS-FLX technology were assembled into contigs and combined with shorter Illumina sequence reads from paired-end and mate-pair libraries of different insert sizes, to build scaffolds. Errors were corrected and gaps filled with Illumina paired-end reads and contaminants detected, resulting in a total of 17,910 scaffolds (> 2 kb) corresponding to 1.34 Gb. Fifty percent of the assembly was accounted for by 1,468 scaffolds (N50 of 260 kb). Initial comparison with the phylogenetically related Prunus persica gene model indicated that genes for 84.6% of the proteins present in peach (mean protein coverage of 90.5%) were present in our assembly. The second and third steps in this project are genome annotation and the assignment of scaffolds to the oak genetic linkage map. In accordance with the Bermuda and Fort Lauderdale agreements and the more recent Toronto Statement, the oak genome data have been released into public sequence repositories in advance of publication. In this presubmission paper, the oak genome consortium describes its principal lines of work and future directions for analyses of the nature, function and evolution of the oak genome.

Article: Plant Journal

PtaRHE1, a Populus tremula x P. alba RING‐H2 protein of the ATL family, has a regulatory role in secondary phloem fiber development

F Baldacci‐Cresp, J Moussawi, JC Leplé, R Van Acker, A Kohler, …
The Plant Journal

Summary

REALLY INTERESTING NEW GENE (RING) proteins play important roles in the regulation of many processes by recognizing target proteins for ubiquitination. Previously, we have shown that the expression of PtaRHE1, encoding a Populus tremula x P. alba RING-H2 protein with E3 ubiquitin ligase activity, is associated with tissues undergoing secondary growth. To further elucidate the role of PtaRHE1 in vascular tissues, we have undertaken a reverse genetic analysis in poplar. Within stem secondary vascular tissues, PtaRHE1 and its corresponding protein are expressed predominantly in the phloem. Down-regulation of PtaRHE1 in poplar by artificial miRNA triggers alterations in phloem fiber patterning characterized by an increased portion of secondary phloem fibers that have a reduced cell wall thickness and a change in lignin composition with lower amounts of syringyl units as compared to wild type plants. Following a RNA-seq analysis, a biological network involving hormone, stress signalling as well as developmental processes could be delineated. Several candidate genes possibly associated with the altered phloem fiber phenotype observed in amiRPtaRHE1 poplar were identified. Altogether, our data suggest a regulatory role for PtaRHE1 in secondary phloem fiber development.

PhD Contract

Young scientist contract (PhD) offered by INRA within the doctoral school RP2E (Université de Lorraine)

Call for applications – April 2015: here

Inra and the Doctoral School RP2E offer during 2015 one “Contrat Jeune Scientifique” (Young Scientist Contract) for 3 years (duration for completion of a PhD). Research will take place at Nancy (France). Candidates may choose among the five topics offered this year:

Topic 1 : Calcium, magnesium and potassium sources in the soil and their bioavailability in forest ecosystems: identification and quantification of bioavailability processes in ex situ conditions at a very fine scale.

Topic 2 : Upscaling morphological, physiological and molecular determinisms of transpiration from the leaf level to water use at the whole plant level in poplar trees.

Topic 3: How are ectomycorrhizal fungi modulating plant hormonal signaling pathways, in particular jasmonic acid?

Topic 4 : Intra-annual dynamics of wood formation and carbon sequestration in conifer and deciduous temperate forests

Topic 5: Understanding detoxification systems developed by wood-decaying fungi and potential application to evaluate the natural durability of wood

The topics and contact persons for specific information are provided in the documents attached to this announcement.

Applications

Applicants to this contract should send the application files including:

  • –  A detailed CV with all details about obtained degrees, fulfilled training and results,
  • –  A motivation letter indicating the selected topic and the plans of the candidate for his/her future career,
  • –  A recommendation letter provided by a professor or a researcher who supervised the candidate during his/her training.

Article: New Phytologist

Plants, fungi and oomycetes: a 400‐million year affair that shapes the biosphere MA Selosse, C Strullu‐Derrien, FM Martin, S Kamoun, P Kenrick. New Phytologist 206 (2), 501-506

 In a rare gathering, genomics met palaeontology at the 10th New Phytologist Workshop on the ‘Origin and evolution of plants and their interactions with fungi’. An eclectic group of 17 experts met at The Natural History Museum (London, UK) on 9–10 September 2014 to discuss the latest findings on plant interactions with fungi (Eumycota) and oomycetes (Oomycota = Peronosporomycota), with topics ranging from the fossil record and comparative genomics to symbiosis and phytopathology. The discussions were largely disseminated via social media (Box 1). Highly diverse plant–fungal interactions have formed the backbone of land ecosystems and biogeochemical cycles since the Palaeozoic (see Fig. 1 for geological timeframe). As summarized by Christine Strullu-Derrien and Paul Kenrick (The Natural History Museum, London, UK) the first land plants arose c. 470 million years (Myr) ago (Kenrick et al., 2012; Edwards et al., 2014), at which time fungi and oomycetes had already colonized terrestrial ecosystems. Following their terrestrialization, these microbes began to abound within plant fossils (Taylor et al., 2014, and references therein). Ultimately, biological interactions sculpted the genomes of plants, fungi and oomycetes (e.g. Schmidt & Panstruga, 2011; Kohler et al., 2015). Here we illustrate the picture that has emerged from the discussions at the 10th New Phytologist Workshop, and point to some pending questions.

Article: Annals of Forest Science

Can mosses serve as model organisms for forest research? S Müller, D Gütle, JP Jacquot, R Reski. Annals of Forest Science.

Abstract

Key message

Based on their impact on many ecosystemswe review the relevance of mosses in research regarding stress tolerancemetabolism, and cell biology. We introduce the potential use of mosses as complementary model systems in molecular forest researchwith an emphasis on the most developed model moss Physcomitrella patens.

Context and aims

Mosses are important components of several ecosystems. The moss P. patensis a well-established non-vascular model plant with a high amenability to molecular biology techniques and was designated as a JGI plant flagship genome. In this review, we will provide an introduction to moss research and highlight the characteristics of P. patens and other mosses as a potential complementary model system for forest research.

Methods

Starting with an introduction into general moss biology, we summarize the knowledge about moss physiology and differences to seed plants. We provide an overview of the current research areas utilizing mosses, pinpointing potential links to tree biology. To complement literature review, we discuss moss advantages and available resources regarding molecular biology techniques.

Results and conclusion

During the last decade, many fundamental processes and cell mechanisms have been studied in mosses and seed plants, increasing our knowledge of plant evolution. Additionally, moss-specific mechanisms of stress tolerance are under investigation to understand their resilience in ecosystems. Thus, using the advantages of model mosses such as P. patens is of high interest for various research approaches, including stress tolerance, organelle biology, cell polarity, and secondary metabolism.