Phylogenetic relationships within the phylum Nematoda as revealed by ribosomal DNA, and their biological implications

Nematodes – “eel worms”; members of the phylum Nematoda – can be considered as a success story within the Metazoa (multicellular, heterotrophic eukaryotes in which cells lack cell walls): they are speciose and – probably - the most numerous group of multicellular animals on our planet. Nematodes are present in virtually all terrestrial, freshwater and marine habitats. Nematodes are trophically diverse; they may feed on bacteria, fungi/oomycetes, algae and protozoa, other nematodes or on a combination of these (omnivores), or live as facultative or obligatory parasites of plants or animals. As they are abundant, ubiquitous and occupy several trophic levels, they play an important role in the soil food web. Nematode parasites of animals affect billions of humans and livestock, while plant parasites such as cyst, root knot and lesion nematodes cause large agricultural losses worldwide. Despite their undisputed ecological and economical relevance, the systematics of the phylum Nematoda is far from established. One of the aims of this research was to further elucidate nematode phylogeny using molecular data. First a phylogenetic tree was constructed of 349 taxa, spanning the entire phylum Nematoda, on the basis of full length small subunit ribosomal DNA (SSU rDNA) sequences. A series of mostly well-supported bifurcations defined twelve major clades, whereas the most basal clade was defined by representatives of the Enoplida and Triplonchida. Our analysis confirmed the paraphyly of the Adenophorea. Furthermore it was found that the SSU rDNA from representatives of the distal clades evolved at a higher rate than the SSU rDNA from the basal clades. In the meantime, a substantial number of sequences was added to our overall SSU rDNA nematode alignment - both public data (GenBank) and data generated by ourselves (≈ 1,500 sequences in total; February 2008). It is noted that the clade division as proposed in 2006 on the basis of “only” 349 taxa still seems to be valid. Subsequent research focused on three specific groups; Dorylaimia, Chromadoria and Tylenchomorpha. Within the suborder Dorylaimina, the SSU rDNA provided an exceptionally low phylogenetic signal, and - therefore – a part (≈ 1,000 bp) of the more variable large subunit ribosomal DNA (LSU rDNA) was analyzed. In most cases nematode relationships could be elucidated with good support, although some areas in the trees remained unresolved. Generally speaking the results of molecular phylogenetics corresponded fairly well with classical nematode taxonomy. The main exception was the order Dorylaimida where twelve subclades could be distinguished which bore little resemblance to classical taxonomy. Furthermore the suitability of ribosomal DNA for a (semi-) quantative molecular identification method was demonstrated using quantitative PCR (q-PCR) and primers designed to specifically amplify members of the order Mononchida and the potato cyst nematodes Globodera pallida and G. rostochiensis. Plant parasitism has arisen several times within the phylum Nematoda (once in the Triplonchida, at least three times in the Dorylaimida and at least twice in the Tylenchomorpha). The long-standing and generally accepted hypothesis states that plant parasites evolved from fungal feeding ancestors. However, while in most cases plant parasites were associated with fungal feeding nematodes, this hypothesis could neither be confirmed nor denied with the results of our phylogenetic analyses. In the case of two Dorylaimida (Pungentus and Longidorella), however, the ancestor was probably an omnivore. The analysis of this problem was substantially hampered by the lack of knowledge on feeding behavior of basal Tylenchomorpha. Presumably, the common ancestor of the nematodes lived in a marine environment and - if this assumption is correct - the transition to a limnoterrestrial environment must have taken place at least once. Surprisingly, analysis of the Chromadoria (minus the Rhabditida) revealed that transitions from a thalassic to a limnoterrestrial habitat (and vice versa) have taken place at least 11 times in the Chromadoria. Given their frequency these transitions are apparently fairly easy to achieve for nematodes and the possible adaptations involved were discussed. Nematodes vary widely in their responses to environmental disturbance, making them good bio-indicators of soil health. Yet it is not known with certainty which traits are responsible for tolerance to stress in nematodes. A framework was laid out to study correlations between nematode traits and stress tolerance. Furthermore the importance of accounting for the confounding effects of phylogeny was demonstrated. This is a first step towards a transparent, ecological grouping of free-living nematodes. It is worthwhile mentioning that - on the basis of the rDNA-based molecular framework described in this PhD thesis - DNA sequences signatures were identified for nearly all North-West European terrestrial and freshwater nematodes families. The relationship between quantitative PCR signal and numbers of individuals has been established for nearly all families and a first testing of DNA barcode-based community analysis is planned for spring 2008

Small Subunit rDNA-Based Phylogeny of the Tylenchida Sheds Light on Relationships Among Some High-Impact Plant-Parasitic Nematodes and the Evolution of Plant Feeding

Cyst (Heteroderidae), root knot (Meloidogyne spp.), and lesion (Pratylenchus spp.) nematodes all belong to a single nematode order, Tylenchida. However, the relationships between and within these economically highly relevant groups, and their relatedness to other parasitic Tylenchida is unclear. We constructed a phylogeny of 116 Tylenchida taxa based on full length small subunit ribosomal DNA (small subunit [SSU] rDNA) sequences. Ancestral state reconstruction points at a gradual development of simple to more complex forms of plant parasitism. Good resolution was observed in distal clades that include cyst, root knot, and lesion nematodes, and monophyly of most families was confirmed. Our data suggest that root knot nematodes have evolved from an ancestral member of the genus Pratylenchus, but it remains unclear which species is closest to this branching point. Contrary to the notoriously polyphagous distal representatives, basal members of the genus Meloidogyne (and probably, their common ancestor) have narrow host ranges. Our analysis also shows that mitotic parthenogeny has arisen at least two times independently among root knot nematodes. In many cases resolution till species was observed, suggesting that SSU rDNA sequences have a potential for DNA barcode-based species identification with, due to the overall conserved nature of this gene, limited intra-species variatio

Comparison of two short DNA barcoding loci (COI and COII) and two longer ribosomal DNA genes (SSU & LSU rRNA) for specimen identification among quarantine root-knot nematodes (Meloidogyne spp.) and their close relatives

Root-knot nematodes (Meloidogyne spp.) are important pests of numerous crops worldwide. Some members of this genus have a quarantine status, and accurate species identification is required to prevent further spreading. DNA barcoding is a method for organism identification in non-complex DNA backgrounds based on informative motifs in short DNA stretches (˜600 bp). As part of the EU 7th Framework project QBOL, 15 Meloidogyne species were chosen to compare the resolutions offered by two typical DNA barcoding loci, COI and COII, with the distinguishing signals produced by two ribosomal DNA genes (small and large subunit rDNA; SSU¿˜¿1,700 and LSU¿˜¿3,400 bp). None of the four markers distinguished between the tropical species Meloidogyne incognita, M. javanica and M. arenaria. Taking P ID (Liberal) values =0.93 as a measure for species delimitation, the four mtDNA and rDNA markers performed well for the tropical Meloidogyne species complex, M. enterolobii, M. hapla, and M. maritima. Within cluster III A (Holterman et al. Phytopathology, 99, 227–235, 2009), SSU rDNA did not offer resolution at species level. Both mtDNA loci COI and COII did, whereas for LSU rDNA a longer fragment (=700 bp) is required. The high level of mitochondrial heteroplasmy recently reported for M. chitwoodi (Humphreys-Pereira and Elling Nematology, 15, 315–327, 2013) was not found in the populations under investigation, suggesting this could be a regional phenomenon. For identification of RKNs, we suggest the combined use of SSU rDNA with one of three other markers presented here

Fylogenetische SSU rDNA-analyse van het fylum Nematoda

Nematoden vormen één van de meestgevarieerde en succesvolle diergroepen ter wereld. Ze zijn waarschijnlijk de meest talrijke dieren op aarde, komen in uiteenlopende milieus voor (zowel terrestrische als marien) en spelen een belangrijke rol in het ecosysteem. De verscheidenheid van voedingstypes en habitats maken deze groep ook erg interessant vanuit een evolutionair oogpunt. Ons onderzoek richt zich op het uitzoeken van de evolutionaire verwantschappen tussen nematoden aan de hand van het ribosomaal DNA - een neutraal gen dat niets te maken heeft met dier- of plantparasitisme - en de evolutie van kenmerken als voedingstypen, stresstrolerantie en de overgang van een marien leefmilieu naar het land. Nematodentaxonomie is een onderzoeksveld dat sinds het begin in beweging is geweest. De geconserveerde morfologie en de vaak moeilijk waarneembare kenmerken bemoeilijken de reconstructie van de evolutie van de nematoden. Dit heeft tot gevolg gehad dat de nematodensystemetiek steeds veranderde en er bijna net zoveel classificaties als taxonomen zijn. De laatste jaren is er veel veranderd door de opkomst van de moleculaire fylogenie. Het gebruik van DNA-sequenties - in het geval van vaak het small subunit ribosomal DNA (SSU rDNA)-gen - om de evolutie te traceren heeft geleid tot nieuwe inzichten en een hernieuwde interesses in nematodenevoluti

Small Subunit rDNA-Based Phylogeny of the Tylenchida Sheds Light on Relationships Among Some High-Impact Plant-Parasitic Nematodes and the Evolution of Plant Feeding

Cyst (Heteroderidae), root knot (Meloidogyne spp.), and lesion (Pratylenchus spp.) nematodes all belong to a single nematode order, Tylenchida. However, the relationships between and within these economically highly relevant groups, and their relatedness to other parasitic Tylenchida is unclear. We constructed a phylogeny of 116 Tylenchida taxa based on full length small subunit ribosomal DNA (small subunit [SSU] rDNA) sequences. Ancestral state reconstruction points at a gradual development of simple to more complex forms of plant parasitism. Good resolution was observed in distal clades that include cyst, root knot, and lesion nematodes, and monophyly of most families was confirmed. Our data suggest that root knot nematodes have evolved from an ancestral member of the genus Pratylenchus, but it remains unclear which species is closest to this branching point. Contrary to the notoriously polyphagous distal representatives, basal members of the genus Meloidogyne (and probably, their common ancestor) have narrow host ranges. Our analysis also shows that mitotic parthenogeny has arisen at least two times independently among root knot nematodes. In many cases resolution till species was observed, suggesting that SSU rDNA sequences have a potential for DNA barcode-based species identification with, due to the overall conserved nature of this gene, limited intra-species variatio

Mapping of long-term impact of conventional and organic soil management on resident and active fractions of rhizosphere communities of barley (Hordeum vulgare)

Soil biota plays an essential role in ecosystem services such as carbon fixation, nitrogen and phosphorous cycling, and disease suppressiveness. Conventional soil management with large inputs of mineral fertilizers and pesticides have a significant impact on primary decomposer communities (bacteria and fungi), as well as on protists and metazoa, representatives of the next trophic level. Organic soil management is thought to contribute to a more diverse and stable soil food web. However, information to pinpoint this supposed beneficial effect is sparse and fragmented. Keeping in mind that a substantial fraction of the soil biota is dormant, we set out to map both the resident and the active the bacterial, fungal, protozoan and metazoan communities under various soil management regimes in two distinct soil types with barley as main crop. For all four organismal groups, the contrast between resident (rDNA-based) and active (rRNA-based) was the most important explanatory variable explaining 22%, 14%, 21% and 25% of the variance among bacterial, fungal, protozoan, and metazoan communities. Less prominent were the effects of soil management and soil type, however significant as well for all four organismal groups. LEfSe was used to identify indicator taxa for both the contrasts between resident and active communities, and the effects of soil management. Our results suggest that - next to DNA-based community characterisation - mapping of the active microbial community could provide essential insights in the effects of variables such as crop and soil management on the soil living community