Exo- and endophytic fungi enable rapid transfer of nutrients from ant waste to orchid tissue

Application of an environmentally friendly nanopesticide translocation system based on Metarhizium anisopliae: Using biodegradable chitosan nanopesticides to control Spodoptera frugiperda

The widespread application of pesticides has resulted in considerable environmental and human health risks. As a result, there is increasing interest in nanopesticides as alternatives to conventional pesticides. This study employed a chemical cross-linking technology to prepare nanopesticides, encapsulating cyantraniliprole (Cya) within biodegradable chitosan (CS) and carboxymethyl chitosan (CMCS), leading to the production of the nanopesticide CS/CMCS/Cya. This nanopesticide was combined with the entomopathogenic fungus Metarhizium anisopliae to prevent and control Spodoptera frugiperda. The findings indicated that CS/CMCS/Cya did not inhibit the growth of M. anisopliae, while significantly enhancing spore wettability on S. frugiperda and improving the sedimentation stability of the spore suspension. A strong adhesion was observed between CS/CMCS/Cya and M. anisopliae spores, with an adsorption rate exceeded 150 %. Furthermore, CS/CMCS/Cya nanoparticles were able to infiltrate S. frugiperda through the hyphae of M. anisopliae. >50 % and 40 % of CS/CMCS/Cya nanoparticles entered the hemolymph and intestine of S. frugiperda respectively, demonstrating superior control efficacy compared to other treatments. This study integrated biological and chemical control methods, establishing a novel strategy for synergistic effects of nanopesticides and entomopathogenic fungi, thereby providing a new approach for transitioning from traditional pest management to safe, effective and environmentally friendly pest management.

Comprehensive characterization and phylogenetic analysis of the complete plastomes of two ant-orchids, Caularthron bicornutum and Myrmecophila thomsoniana

BACKGROUND

Myrmecophytes, characterized by specialized structures like hollow stems that facilitate mutualistic relationships with ants, serve as an important system for studying ant-plant interactions and the adaptation mechanisms. Caularthron and Myrmecophila are exemplary myrmecophytes within Orchidaceae. Previous studies suggested a genetic relationship between these two genera, placing them within Laeliinae (Epidendreae), yet the precise phylogenetic positioning remained uncertain. The absence of available plastome resources has hindered investigations into plastome evolution and phylogeny.

RESULTS

In this study, we sequenced and assembled the complete plastomes of Caularthron bicornutum and Myrmecophila thomsoniana to elucidate their plastome characteristics and phylogenetic relationships. The determined plastome sizes were 150,557 bp for C. bicornutum and 156,905 bp for M. thomsoniana, with GC contents of 37.3% and 37.1%, respectively. Notably, M. thomsoniana exhibited a distinctive IR expansion and SSC contraction, with the SSC region measuring only 4532 bp and containing five genes (ccsA, ndhD, rpl32, psaC, and trnL-UAG), a unique feature observed for the first time in Epidendreae. Comparative analyses with species from the related genus Epidendrum revealed that C. bicornutum plastome exhibited conserved genome size, GC content, gene content, and gene order. A total of 32 and 33 long sequence repeats, 50 and 40 tandem repeats, and 99 and 109 SSRs were identified in the plastomes of C. bicornutum and M. thomsoniana, respectively. The RSCU analysis demonstrated a consistent pattern in both plastomes, with 29 out of 30 codons with RSCU values greater than 1 featuring A/U at the third codon position. Leucine was the most prevalent amino acid, while Cysteine was the least common. Four potential DNA barcoding regions with Pi values exceeding 0.07, namely ycf1, ccsA-psaC, petN-psbM, and accD-psaI, were identified for subsequent phylogenetic reconstructions within Laeliinae. Phylogenetic analysis underscored the close relationships among Caularthron, Epidendrum, and Myrmecophila.

CONCLUSIONS

This study represents the first comprehensive analysis of the plastome characteristics of Caularthron bicornutum and Myrmecophila thomsoniana. Through our characterization and phylogenetic analyses, we unveiled the unique IR expansion/SSC contraction and further elucidated their phylogenetic positions. Our research contributes significant data and insights into the dynamic evolution of ant-orchid plastomes and the phylogeny of the Laeliinae.

Phosphorus/nitrogen sensing and signaling in diverse root-fungus symbioses

Establishing mutualistic relationships between plants and fungi is crucial for overcoming nutrient deficiencies in plants. This review highlights the intricate nutrient sensing and uptake mechanisms used by plants in response to phosphate and nitrogen starvation, as well as their interactions with plant immunity. The coordination of transport systems in both host plants and fungal partners ensures efficient nutrient uptake and assimilation, contributing to the long-term maintenance of these mutualistic associations. It is also essential to understand the distinct responses of fungal partners to external nutrient levels and forms, as they significantly impact the outcomes of symbiotic interactions. Our review also highlights the importance of evolutionarily younger and newly discovered root-fungus associations, such as endophytic associations, which offer potential benefits for improving plant nutrition. Mechanistic insights into the complex dynamics of phosphorus and nitrogen sensing within diverse root-fungus associations can facilitate the identification of molecular targets for engineering symbiotic systems and developing plant phenotypes with enhanced nutrient use efficiency. Ultimately, this knowledge can inform tailored fertilizer management practices to optimize plant nutrition.

Enhancing dendrobine production in Dendrobium nobile through mono-culturing of endophytic fungi, Trichoderma longibrachiatum (MD33) in a temporary immersion bioreactor system

INTRODUCTION

Dendrobine, a valuable alkaloid found in Dendrobium nobile, possesses significant pharmaceutical potential.

METHODS

In this study, we explored innovative approaches to enhance dendrobine production by utilizing endophytic fungi in a Temporary Immersion Bioreactor System (TIBS, Nanjing BioFunction Co. Ltd., China) and traditional test bottles. Dendrobine was unequivocally identified and characterised in D. nobile co-culture seedlings through UHPLC analysis and LC-MS qTOF analysis, supported by reference standards.

RESULTS

The CGTB (control group) and EGTB (experimental group) 12-month-old D. nobile seedlings exhibited similar peak retention times at 7.6±0.1 minutes, with dendrobine identified as C16H25NO2 (molecular weight 264.195). The EGTB, co-cultured with Trichoderma longibrachiatum (MD33), displayed a 2.6-fold dendrobine increase (1804.23 ng/ml) compared to the CGTB (685.95 ng/ml). Furthermore, a bioanalytical approach was applied to investigate the mono-culture of T. longibrachiatum MD33 with or without D. nobile seedlings in test bottles. The newly developed UHPLC-MS method allowed for dendrobine identification at a retention time of 7.6±0.1 minutes for control and 7.6±0.1 minutes for co-culture. Additionally, we explored TIBS to enhance dendrobine production. Co-culturing D. nobile seedlings with Trichoderma longibrachiatum (MD33) in the TIBS system led to a substantial 9.7-fold dendrobine increase (4415.77 ng/ml) compared to the control (454.01 ng/ml) after just 7 days. The comparative analysis of dendrobine concentration between EGTB and EGTIBS highlighted the remarkable potential of TIBS for optimizing dendrobine production. Future research may focus on scaling up the TIBS approach for commercial dendrobine production and investigating the underlying mechanisms for enhanced dendrobine biosynthesis in D. nobile. The structural elucidation of dendrobine was achieved through 1H and 13C NMR spectroscopy, revealing a complex array of proton environments and distinct carbon environments, providing essential insights for the comprehensive characterization of the compound.

DISCUSSION

These findings hold promise for pharmaceutical and industrial applications of dendrobine and underline the role of endophytic fungi in enhancing secondary metabolite production in medicinal plants.

Responses of a common tropical epiphyte, Asplenium nidus, to changes in water and nutrient availability

Epiphytes are highly dependent on atmospheric inputs of water and nutrients. Reductions in water availability associated with warming and climate change and continual atmospheric nitrogen (N) deposition can affect plant growth but few studies have evaluated the effects of changes in both water and nutrient availabilities on epiphytes. We experimentally tested whether epiphyte growth is more water- or nutrient-limited, if nutrient limitation was stronger for nitrogen or phosphorus, and whether nutrient limitation interacts with water availability. We applied watering (high and low) and nutrient addition (control, +N, +P, +N+P) treatments to greenhouse-grown Asplenium nidus, a common epiphytic fern found in many tropical and subtropical wet forests. We measured leaf area production and leaf elemental concentrations to assess how A. nidus growth and physiology respond to changes in water and nutrient availabilities. We found that leaf growth of A. nidus was more affected by water availability than nutrient addition and the effect of adding nutrients was not fully realized under low-water availability. Among the different nutrient treatments, +N+P had the greatest effects on A. nidus growth and physiology in both watering treatments. Watering treatment changed leaf elemental concentrations but not their ratios (i.e. C:N and N:P). Nutrient addition altered C:N and N:P ratios and increased the concentration of the added elements in leaves, with more pronounced increases in the high-watering treatment. We conclude that the growth of A. nidus is more water- than nutrient-limited. When nutrient limitation occurs (i.e. under high-water availability), nutrient co-limitation is stronger than limitation by N or P alone. This result taken together with studies of other epiphytes suggests greater water than nutrient limitation is likely widespread among epiphytic plants. The limited effects of nutrient addition in the low-water treatment suggest that the effect of atmospheric N deposition on epiphyte growth will be limited when water availability is low.

Fungi as mutualistic partners in ant-plant interactions

Associations between fungi and ants living in mutualistic relationship with plants ("plant-ants") have been known for a long time. However, only in recent years has the mutualistic nature, frequency, and geographical extent of associations between tropical arboreal ants with fungi of the ascomycete order Chaetothyriales and Capnodiales (belonging to the so-called "Black Fungi") become clear. Two groups of arboreal ants displaying different nesting strategies are associated with ascomycete fungi: carton-building ants that construct nest walls and galleries on stems, branches or below leaves which are overgrown by fungal hyphae, and plant-ants that make their nests inside living plants (myrmecophytes) in plant provided cavities (domatia) where ants cultivate fungi in small delimited "patches". In this review we summarize the current knowledge about these unsuspected plant-ant-fungus interactions. The data suggest, that at least some of these ant-associated fungi seem to have coevolved with ants over a long period of time and have developed specific adaptations to this lifestyle.