Biochemical aspects of plant interactions with parasite nematodes. (A review)

The review summarizes reports on molecular aspects of interactions of phytoparasitic nematodes with plant hosts. Data on the secrets of nematodes affecting plants (elicitors, toxins, products of parasitism genes, etc.) are analyzed and information flow pathways comprising all elements of the plant-parasite interaction (from elicitors to defense responses of plant cells), described. Emphasis is placed on the mechanisms whereby plants are protected from nematode invasion (hypesensitivity reactions, apoptosis, phytoalexins, proteinase inhibitors, PR-proteins, etc.). Consideration is given to genetic aspects of plant-parasite relationships. Promising practical approaches to defending plants from phytoparasitic nematodes, developed based on the results of studies of molecular mechanisms of plant-parasite interactions are provided in conclusion.     

Identification of genes involved in Meloidogyne incognita-induced gall formation processes in Arabidopsis thaliana

Root-knot nematodes (RKN; Meloidogyne incognita) are phytoparasitic nematodes that cause significant damage to crop plants worldwide. Recent studies have revealed that RKNs disrupt various physiological processes in host plant cells to induce gall formation. However, little is known about the molecular mechanisms of gall formation induced by nematodes. We have previously found that RNA expression levels of some of genes related to micro-RNA, cell division, membrane traffic, vascular formation, and meristem maintenance system were modified by nematode infection. Here we evaluated these genes importance during nematode infection by using Arabidopsis mutants and/or β-glucronidase (GUS) marker genes, particularly after inoculation with nematodes, to identify the genes involved in successful nematode infection. Our results provide new insights not only for the basic biology of plant–nematode interactions but also to improve nematode control in an agricultural setting.     

Isolation and characterization of microsatellite loci in the sugar beet cyst nematode Heterodera schachtii

We report the isolation of five microsatellites loci from the sugar beet cyst nematode (Heterodera schachtii). Multilocus genotypes were obtained on individual larvae freshly emerged from cysts. Allelic diversity ranged from four to 27 among the five loci. The primers were tested for cross‐species amplification in six other species of phytoparasitic nematodes of the Heterodera genus. Those molecular markers will be used to study the genetic structure of this obligatory parasite and how it is affected by the use of resistant plants.     

Control of foliar phytoparasitic nematodes through sustainable natural materials: Current progress and challenges

Nematodes are hidden enemies that inhibit the entire ecosystem causing adverse effects on animals and plants, leading to economic losses. Management of foliar phytoparasitic nematodes is an excruciating task. Various approaches were used to control nematodes dispersal, i.e., traditional practices, resistant cultivars, plant extract, compost, biofumigants, induced resistance, nano-biotechnology applications, and chemical control. This study reviews the various strategies adopted in combating plant-parasitic nematodes while examining the benefits and challenges. The significant awareness of biological and environmental factors determines the effectiveness of nematode control, where the incorporation of alternative methods to reduce the nematodes population in plants with increasing crop yield. The researchers were interested in explaining the fundamental molecular mechanisms, providing an opportunity to deepen our understanding of the sustainable management of nematodes in croplands. Eco-friendly pesticides are effective as a sustainable nematodes management tool and safe for humans. The current review presents the eco-friendly methods in controlling nematodes to minimize yield losses, and benefit the agricultural production efficiency and the environment.     

Engineering Natural and Synthetic Resistance for Nematode Management

Bioengineering strategies are being developed that will provide specific and durable resistance against plant-parasitic nematodes in crops. The strategies come under three categories: (i) transfer of natural resistance genes from plants that have them to plants that do not, to mobilize the defense mechanisms in susceptible crops; (ii) interference with the biochemical signals that nematodes exchange with plants during parasitic interactions, especially those resulting in the formation of specialized feeding sites for the sedentary endoparasites—many nematode genes and many plant genes are potential targets for manipulation; and (iii) expression in plant cells of proteins toxic to nematodes.     

Field evidence for indirect interactions between foliar‐feeding insect and root‐feeding nematode communities on Nicotiana tabacum

Abstract 1. As herbivory often elicits systemic changes in plant traits, indirect interactions via induced plant responses may be a pervasive feature structuring herbivore communities. Although the importance of this phenomenon has been emphasised for herbivorous insects, it is unknown if and how induced responses contribute to the organisation of other major phytoparasitic taxa. 2. Survey and experimental field studies were used to investigate the role of plants in linking the dynamics of foliar‐feeding insects and root‐feeding nematodes on tobacco, Nicotiana tabacum. 3. Plant‐mediated interactions between insects and nematodes could largely be differentiated by insect feeding guild, with positive insect–nematode interactions predominating with leaf‐chewing insects (caterpillars) and negative interactions occurring with sap‐feeding insects (aphids). For example, insect defoliation was positively correlated with the abundance of root‐feeding nematodes, but aphids and nematodes were negatively correlated. Experimental field manipulations of foliar insect and nematode root herbivory also tended to support this outcome. 4. Overall, these results suggest that plants indirectly link the dynamics of divergent consumer taxa in spatially distinct ecosystems. This lends support to the growing perception that plants play a critical role in propagating indirect effects among a diverse assemblage of consumers.     

An overview of arbuscular mycorrhizal fungi–nematode interactions

Plant parasitic nematodes and arbuscular mycorrhizal fungi (AMF) share plant roots as a resource for food and space. The interest in AMF-nematode interactions lies in the possibility of enhanced resistance or tolerance of AMF-infected plants to nematodes, and the potential value of this for control of crop pests. Data collated from previous studies revealed a great diversity of AMF-nematode responses and we seek to generalise from these by evaluating and discussing interactions involving three groups of nematodes distinguished by their mode of parasitism: (i) ectoparasites; (ii) sedentary endoparasites; and (iii) migratory endoparasites. Based on proximity in tissue, we expected that the interactions between endoparasites and AMF would be stronger, i.e. more reciprocal effects of endoparasitic nematodes on AMF, than those between ectoparasites and AMF. Contrary to this hypothesis, we found that, relative to AMF-free plants, AMF-infected plants were damaged more by ectoparasites than by endoparasites. Of the sedentary endoparasites, numbers of root-knot nematodes were reduced more by mycorrhizal infection than were those of cyst nematodes. The reduction in nematode damage by AMF was not different for root-knot or cyst nematode infested plants. Migratory endoparasitic nematodes were the only group whose numbers were greater on AMF-infected plants. However, the experiments involving migratory nematodes were characterised by relatively high levels of AMF infection and little nematode damage compared to the other feeding types. The outcomes of the AMF-nematode interactions are determined by many factors during the interactions between organisms and their physical, physiological and temporal environments. Assessing effects by recording plant sizes and total nematode or AMF populations at the end of experiments gives very little information on the mechanisms of the interactions. It is time to stop doing studies of black boxes and time to start observing processes, directly by using microscopy and indirectly by application of molecular genetics.     

Interaction between structure of plant steroids and their effect on phytonematodes

The effects of certain plant steroids of the groups of furostanol glycosides, glycoalkaloids, and alpha-ecdysone on growth and development of phytoparasitic nematodes were studied. It was shown using an experimental system including tomato, Lycopersicon esculentum Mill., and root-knot nematode, Meloidogyne incognita Kofoid et White, that steroid molecule had significant nematicidic activity if it contained a carbohydrate moiety and an additional heterocycle in the steroid core. The maximum nematicidic activity is inherent in glycosides containing chacotriose as the carbohydrate moiety of the molecule. Some compounds tested in this work could be used for protecting plants against phytoparasitic nematodes.     

Plant actin cytoskeleton re-modeling by plant parasitic nematodes

The cytoskeleton is an important component of the plant’s defense mechanism against the attack of pathogenic organisms. Plants however, are defenseless against parasitic rootknot and cyst nematodes and respond to the invasion by the development of a special feeding site that supplies the parasite with nutrients required for the completion of its life cycle. Recent studies of nematode invasion under treatment with cytoskeletal drugs and in mutant plants where normal functions of the cytoskeleton have been affected, demonstrate the importance of the cytoskeleton in the establishment of a feeding site and successful nematode reproduction. It appears that in the case of microfilaments, nematodes hijack the intracellular machinery that regulates actin dynamics and modulate the organization and properties of the actin filament network. Intervening with this process reduces the nematode infection efficiency and inhibits its life cycle. This discovery uncovers a new pathway that can be exploited for the protection of plants against nematodes.Key words: cytoskeleton, actin, actin depolymerizing factor, nematode, giant cells, syncytium, cytochalasin, taxol     

Nematode resistance in plants: the battle underground

Parasitic nematodes infect thousands of plant species, but some plants harbor specific resistance genes that defend against these pests. Several nematode resistance genes have been cloned in plants, and most resemble other plant resistance genes. Nematode resistance is generally characterized by host plant cell death near or at the feeding site of the endoparasitic worm. The timing and localization of the resistance response varies with the particular resistance gene and nematode interaction. Although there is genetic evidence that single genes in the nematode can determine whether a plant mounts a resistance response, cognate nematode effectors corresponding to a plant resistance gene have not been identified. However, recent progress in genetics and genomics of both plants and nematodes, and developments in RNA silencing strategies are improving our understanding of the molecular players in this complex interaction. In this article, we review the nature and mechanisms of plant-nematode interactions with respect to resistance in plants.     

Plant-microbe interactions to probe regulation of plant carbon metabolism

Plant growth and development is dependent on coordinated assimilate production, distribution and allocation. Application of biochemical and molecular techniques substantially contributed to a better understanding of these processes, although the underlying regulatory mechanisms are still not fully elucidated and attempts to improve crop yield by modulating carbon partitioning were only partially successful. Plant pathogens also interfere with source–sink interaction. To this end they have evolved a wide range of sophisticated strategies to allow their systemic spread, suppression of plant defence and induction of sink function to support nutrient acquisition for their growth. Studying compatible interactions of plants and pathogens like viruses, bacteria and fungi can be exploited to investigate different levels of source–sink regulation. The identification of microbial factors and their host targets involved in regulation of plant primary metabolism may allow developing novel strategies to increase crop yield. Here we will discuss recent studies on plant–microbe interactions aimed at elucidating mechanisms of compatibility.     

Chitooligosaccharide sensing and downstream signaling: contrasted outcomes in pathogenic and beneficial plant–microbe interactions

In plants, short chitin oligosaccharides and chitosan fragments (collectively referred to as chitooligosaccharides) are well-known elicitors that trigger defense gene expression, synthesis of antimicrobial compounds, and cell wall strengthening. Recent findings have shed new light on chitin-sensing mechanisms and downstream activation of intracellular signaling networks that mediate plant defense responses. Interestingly, chitin receptors possess several lysin motif domains that are also found in several legume Nod factor receptors. Nod factors are chitin-related molecules produced by nitrogen-fixing rhizobia to induce root nodulation. The fact that chitin and Nod factor receptors share structural similarity suggests an evolutionary conserved relationship between mechanisms enabling recognition of both deleterious and beneficial microorganisms. Here, we will present an update on molecular events involved in chitooligosaccharide sensing and downstream signaling pathways in plants and will discuss how structurally related signals may lead to such contrasted outcomes during plant–microbe interactions.     

Correlation between the Structure of Plant Steroids and Their Effects on Phytoparasitic Nematodes

The effects of certain plant steroids (belonging to furostanol glycosides or glycoalkaloids) and -ecdysone on growth and development of phytoparasitic nematodes were studied. It was shown using an experimental system including tomato Lycopersicon esculentum Mill. and root-knot nematode, Meloidogyne incognita Kofoid et White, that a steroid molecule exhibits significant nematicidal activity if it contains a carbohydrate moiety and an additional heterocycle in the steroid core. The maximum nematicidal activity is inherent in glycosides containing chacotriose as the carbohydrate moiety of the molecule. Some compounds tested in this work could be used for protecting plants against phytoparasitic nematodes.     

The Arabidopsis thaliana Sucrose Transporter Gene AtSUC4 is Expressed in Meloidogyne incognita-induced Root Galls

The plant parasitic nematode Meloidogyne incognita is as an obligate parasite entirely dependent on the plants solute supply. Therefore, the nematodes induce the formation of several giant cells which are embedded into root galls. At present only little information is available about the solute transfer mechanisms of the plants to supply the induced galls and giant cells and consequently the nematodes. In the present work we could show by phloem-loading experiments that giant cells in the roots of Arabidopsis thaliana are not symplasmically connected to the phloem elements, thus differing considerably form the comparable plant–nematode interaction of Arabidopsis and Heterodera schachtii . Consequently the gene expression of the sucrose transporter AtSUC4 ( AtSUT4 ) was studied during nematode development, and its functionality was shown using RNAi gene silencing lines.     

Parameters affecting plant defense pathway mediated recruitment of entomopathogenic nematodes

Entomopathogenic nematodes are natural enemies and effective biological control agents of subterranean insect herbivores. Interactions between herbivores, plants, and entomopathogenic nematodes are mediated by plant defense pathways. These pathways can induce release of volatiles and recruit entomopathogenic nematodes. Stimulation of these plant defense pathways for induced defense against belowground herbivory may enhance biological control in the field. Knowledge of the factors affecting entomopathogenic nematode behaviour belowground is needed to effectively implement such strategies. To that end, we explore the effect of elicitor, elicitor dose, mechanical damage, and entomopathogenic nematode release distance on recruitment of entomopathogenic nematode infective juveniles to corn seedlings. Increasing doses of methyl jasmonate and methyl salicylate elicitors recruited more entomopathogenic nematodes as did mechanical damage. Recruitment of entomopathogenic nematodes was higher at greater release distances. These results suggest entomopathogenic nematodes are highly tuned to plant status and present a strategy for enhancing biological control using elicitor-stimulated recruitment of entomopathogenic nematodes.     

A chorismate mutase from the soybean cyst nematode Heterodera glycines shows polymorphisms that correlate with virulence

Parasitism genes from phytoparasitic nematodes are thought to be essential for nematode invasion of the host plant, to help the nematode establish feeding sites, and to aid nematodes in the suppression of host plant defenses. One gene that may play several roles in nematode parasitism is chorismate mutase (CM). This secreted enzyme is produced in the nematode's esophageal glands and appears to function within the plant cell to manipulate the plant's shikimate pathway, which controls plant cell growth, development, structure, and pathogen defense. Using degenerate polymerase chain reaction primers, we amplified and cloned a chorismate mutase (Hg-cm-1) from Heterodera glycines, the soybean cyst nematode (SCN), and showed it had CM activity. RNA in situ hybridization of Hg-cm-1 cDNA to SCN sections confirms that it is specifically expressed in the nematodes' esophageal glands. DNA gel blots of genomic DNA isolated from SCN inbred lines that have differing virulence on SCN resistant soybean show Hg-cm-1 is a member of a polymorphic gene family. Some Hg-cm family members predominate in SCN inbred lines that are virulent on certain SCN resistant soybean cultivars. The same polymorphisms and correlation with virulence are seen in the Hg-cm-1 expressed in the SCN second-stage juveniles. Based on the enzymatic activity of Hg-cm-1 and the observation that different forms of the mutase are expressed in virulent nematodes, we hypothesize that the Hg-cm-1 is a virulence gene, some forms of which allow SCN to parasitize certain resistant soybean plants.     

食微线虫对植物生长及土壤养分循环的影响

近二十多年来, 土壤动物的生态功能受到广泛重视。越来越多的证据表明, 土壤动物和微生物间的相互作用对土壤生态系统过程和植物生长起着重要的调节作用。本文综述了食细菌线虫和食真菌线虫对土壤微生物、土壤氮矿化和植物生长的影响。大量研究发现, 食细菌线虫和食真菌线虫都有助于土壤氮素等养分矿化, 从而促进植物生长。这种作用主要是线虫通过取食活动加速微生物周转, 并通过代谢分泌和释放微生物所固持的养分而实现的。但这种作用会因不同的线虫、微生物和植物的种类以及土壤基质的C/N营养状况而异, 此外还受线虫的营养类群及其与其他土壤动物之间复杂关系的影响。今后应该加强以下几方面的研究: (1)深入研究线虫、微生物和植物之间相互作用的机制; (2) 增加控制实验系统的复杂性, 研究线虫不同功能群之间及其与其他土壤动物之间的关系; (3)加强长期实验和观察, 在较长的时间尺度上了解线虫的生态功能; (4)加强对不同生态系统的研究, 在更大的空间尺度上综合了解土壤线虫的生态功能; (5)在全球气候变化的背景下了解土壤线虫的响应, 并预测土壤线虫对全球变化的反馈。     

A combined parasitological molecular approach for noninvasive characterization of parasitic nematode communities in wild hosts

Most hosts are concurrently or sequentially infected with multiple parasites; thus, fully understanding interactions between individual parasite species and their hosts depends on accurate characterization of the parasite community. For parasitic nematodes, noninvasive methods for obtaining quantitative, species‐specific infection data in wildlife are often unreliable. Consequently, characterization of gastrointestinal nematode communities of wild hosts has largely relied on lethal sampling to isolate and enumerate adult worms directly from the tissues of dead hosts. The necessity of lethal sampling severely restricts the host species that can be studied, the adequacy of sample sizes to assess diversity, the geographic scope of collections and the research questions that can be addressed. Focusing on gastrointestinal nematodes of wild African buffalo, we evaluated whether accurate characterization of nematode communities could be made using a noninvasive technique that combined conventional parasitological approaches with molecular barcoding. To establish the reliability of this new method, we compared estimates of gastrointestinal nematode abundance, prevalence, richness and community composition derived from lethal sampling with estimates derived from our noninvasive approach. Our noninvasive technique accurately estimated total and species‐specific worm abundances, as well as worm prevalence and community composition when compared to the lethal sampling method. Importantly, the rate of parasite species discovery was similar for both methods, and only a modest number of barcoded larvae (n = 10) were needed to capture key aspects of parasite community composition. Overall, this new noninvasive strategy offers numerous advantages over lethal sampling methods for studying nematode–host interactions in wildlife and can readily be applied to a range of study systems.     

Perception, signaling and molecular basis of oviposition-mediated plant responses

Eggs deposited on plants by herbivorous insects represent a threat as they develop into feeding larvae. Plants are not a passive substrate and have evolved sophisticated mechanisms to detect eggs and induce direct and indirect defenses. Recent years have seen exciting development in molecular aspects of egg-induced responses. Some egg-associated elicitors have been identified, and signaling pathways and egg-induced expression profiles are being uncovered. Depending on the mode of oviposition, both the jasmonic acid and salicylic acid pathways seem to play a role in the induction of defense responses. An emerging concept is that eggs are recognized like microbial pathogens and innate immune responses are triggered. In addition, some eggs contain elicitors that induce highly specific defenses in plants. Examples of egg-induced suppression of defense or, on the contrary, egg-induced resistance highlight the complexity of plant–egg interactions in an on-going arms race between herbivores and their hosts. A major challenge is to identify plant receptors for egg-associated elicitors, to assess the specificity of these elicitors and to identify molecular components that underlie various responses to oviposition.