Chromosomal localization and evolution of satellite DNAs and heterochromatin in grasses (Poaceae), especially tribe Aveneae

The physical mapping of three abundant tandemly repeated DNA sequences, CON1, CON2, and COM2, and the distributional pattern of AT- and GC-rich regions in the chromosomes of 32 species of the grass family Poaceae have been established by means of fluorescence in situ hybridization and fluorochrome banding with chromomycin and DAPI. Additionally, locations of 5S, 35S rDNA, and the C-banding pattern were examined. All satellite DNAs (satDNA) tested are situated predominantly subtelomerically in the chromosomes, but occur also colocalized with 35S and 5S ribosomal DNAs (rDNA). Especially, CON2 is most often colocalized with the 5S rDNA, but is evolutionarily not derived from it. Subtelomeric heterochromatin bands are frequently, but not always correlated with satDNA bands. Moreover, the DAPI- or rarely chromomycin-positive stainability of heterochromatin is not caused by these satDNAs as revealed by their sequence organization, showing too few clusters of AT or GC base pairs as required for binding of the fluorochromes. The occurrence of satDNAs is not correlated with that of other components of the heterochromatin. Proportions of satDNAs and other sequences of the heterochromatin relative to the entire genome appear subjected to a much faster evolutionary change than the rather stable proportions of the rDNAs. Heteromorphism in banding patterns found in many species is related in most instances with breeding system and life form. The independent evolution and amplification of different satDNAs is discussed in relation to molecular phylogenetic data. The value and limitations of satDNA data in addressing systematic questions in grasses is exemplified for several grass subfamilies and tribes.     

Accumulation of Y-specific satellite DNAs during the evolution of <Emphasis Type="Italic">Rumex acetosa</Emphasis> sex chromosomes

The study of the molecular structure of young heteromorphic sex chromosomes of plants has shed light on the evolutionary forces that control the differentiation of the X and Y during the earlier stages of their evolution. We have used the model plant Rumex acetosa, a dioecious species with multiple sex chromosomes, 2n = 12 + XX female and 2n = 12 + XY₁Y₂ male, to analyse the significance of repetitive DNA accumulation during the differentiation of the Y. A bulk segregant analysis (BSA) approach allowed us to identify and isolate random amplified polymorphic DNA (RAPD) markers linked to the sex chromosomes. From a total of 86 RAPD markers in the parents, 6 markers were found to be linked to the Ys and 1 to the X. Two of the Y-linked markers represent two AT-rich satellite DNAs (satDNAs), named RAYSII and RAYSIII, that share about 80% homology, as well as with RAYSI, another satDNA of R. acetosa. Fluorescent in situ hybridisation demonstrated that RAYSII is specific for Y₁, whilst RAYSIII is located in different clusters along Y₁ and Y₂. The two satDNAs were only detected in the genome of the dioecious species with XX/XY₁Y₂ multiple sex chromosome systems in the subgenus Acetosa, but were absent from other dioecious species with an XX/XY system of the subgenera Acetosa or Acetosella, as well as in gynodioecious or hermaphrodite species of the subgenera Acetosa, Rumex and Platypodium. Phylogenetic analysis with different cloned monomers of RAYSII and RAYSIII from both R. acetosa and R. papillaris indicate that these two satDNAs are completely separated from each other, and from RAYSI, in both species. The three Y-specific satDNAs, however, evolved from an ancestral satDNA with repeating units of 120 bp, through intermediate satDNAs of 360 bp. The data therefore support the idea that Y-chromosome differentiation and heterochromatinisation in the Rumex species having a multiple sex chromosome system have occurred by different amplification events from a common ancestral satDNA. Since dioecious species with multiple XX/XY₁Y₂ sex chromosome systems of the section Acetosa appear to have evolved from dioecious species with an XX/XY system, the amplification of tandemly repetitive elements in the Ys of the section Acetosa is a recent evolutionary process that has contributed to an increase in the size and differentiation of the already non-recombining Y chromosomes.     

Identification and characterization of repetitive DNA in the genus Didelphis Linnaeus, 1758 (Didelphimorphia,Didelphidae) and the use of satellite DNAs as phylogenetic markers

Didelphis species have been shown to exhibit very conservative karyotypes, which mainly differ in their constitutive heterochromatin, known to be mostly composed by repetitive DNAs. In this study, we used genome skimming data combined with computational pipelines to identify the most abundant repetitive DNA families of Lutreolina crassicaudata and all six Didelphis species. We found that transposable elements (TEs), particularly LINE-1, endogenous retroviruses, and SINEs, are the most abundant mobile elements in the studied species. Despite overall similar TE proportions, we report that species of the D. albiventris group consistently present a less diverse TE composition and smaller proportions of LINEs and LTRs in their genomes than other studied species. We also identified four new putative satDNAs (sat206, sat907, sat1430 and sat2324) in the genomes of Didelphis species, which show differences in abundance and nucleotide composition. Phylogenies based on satDNA sequences showed well supported relationships at the species (sat1430) and groups of species (sat206) level, recovering topologies congruent with previous studies. Our study is one of the first attempts to present a characterization of the most abundant families of repetitive DNAs of Lutreolina and Didelphis species providing insights into the repetitive DNA composition in the genome landscape of American marsupials.     

The extensive amplification of heterochromatin in Melipona bees revealed by high throughput genomic and chromosomal analysis

Satellite DNAs (satDNAs) and transposable elements (TEs) are among the main components of constitutive heterochromatin (c-heterochromatin) and are related to their functionality, dynamics, and evolution. A peculiar case regarding the quantity and distribution of c-heterochromatin is observed in the genus of bees, Melipona, with species having a low amount of heterochromatin and species with high amount occupying almost all chromosomes. By combining low-pass genome sequencing and chromosomal analysis, we characterized the satDNAs and TEs of Melipona quadrifasciata (low c-heterochromatin) and Melipona scutellaris (high low c-heterochromatin) to understand c-heterochromatin composition and evolution. We identified 15 satDNA families and 20 TEs for both species. Significant variations in the repeat landscapes were observed between the species. In M. quadrifasciata, the repetitive fraction corresponded to only 3.78% of the genome library studied, whereas in M. scutellaris, it represented 54.95%. Massive quantitative and qualitative changes contributed to the differential amplification of c-heterochromatin, mainly due to the amplification of exclusive repetitions in M. scutellaris, as the satDNA MscuSat01-195 and the TE LTR/Gypsy_1 that represent 38.20 and 14.4% of its genome, respectively. The amplification of these two repeats is evident at the chromosomal level, with observation of their occurrence on most c-heterochromatin. Moreover, we detected repeats shared between species, revealing that they experienced mainly quantitative variations and varied in the organization on chromosomes and evolutionary patterns. Together, our data allow the discussion of patterns of evolution of repetitive DNAs and c-heterochromatin that occurred in a short period of time, after separation of the Michmelia and Melipona subgenera.

     

The non-regular orbit: three satellite DNAs in Drosophila martensis (buzzatii complex, repleta group) followed three different evolutionary pathways

The genome of species from the buzzatii cluster (buzzatii complex, repleta group) is hosted by a number of satellite DNAs (satDNAs) showing contrasting structural characteristics, genomic organization and evolution, such as pBuM-alpha (~190 bp repeats), pBuM-alpha/beta (~370 bp repeats) and the DBC-150 (~150 bp repeats). In the present study, we aimed to investigate the evolution of these three satDNAs by looking for homologous sequences in the genome of the closest outgroup species: Drosophila martensis (buzzatii complex). After PCR, we isolated and sequenced 9 alpha, 8 alpha/beta and 11 DBC-150 sequences from this species. The results were compared to all pBuM and DBC-150 sequences available in literature. After D. martensis split from the buzzatii cluster some 6 Mya, the three satDNAs evolved differently in the genome of D. martensis by: (1) maintenance of a collection of major types of ancestral repeats in the genome (alpha); (2) fixation for a single major type of ancestral repeats (alpha/beta) or (3) fixation for new divergent species-specific repeat types (DBC-150). Curiously, D. seriema and D. martensis, although belonging to different and allopatric clusters, became independently fixed for the same major type of alpha/beta ancestral repeats, illustrating a rare case of parallelism in satDNA evolution. The contrasting pictures illustrate the diversity of evolutionary pathways a satDNA can follow, defining a “non-regular orbit” with outcomes difficult to predict.     

Conserved DNA Motifs,Including the CENP-B Box-like,Are Possible Promoters of Satellite DNA Array Rearrangements in Nematodes

Tandemly arrayed non-coding sequences or satellite DNAs (satDNAs) are rapidly evolving segments of eukaryotic genomes, including the centromere, and may raise a genetic barrier that leads to speciation. However, determinants and mechanisms of satDNA sequence dynamics are only partially understood. Sequence analyses of a library of five satDNAs common to the root-knot nematodes Meloidogyne chitwoodi and M. fallax together with a satDNA, which is specific for M. chitwoodi only revealed low sequence identity (32–64%) among them. However, despite sequence differences, two conserved motifs were recovered. One of them turned out to be highly similar to the CENP-B box of human alpha satDNA, identical in 10–12 out of 17 nucleotides. In addition, organization of nematode satDNAs was comparable to that found in alpha satDNA of human and primates, characterized by monomers concurrently arranged in simple and higher-order repeat (HOR) arrays. In contrast to alpha satDNA, phylogenetic clustering of nematode satDNA monomers extracted either from simple or from HOR array indicated frequent shuffling between these two organizational forms. Comparison of homogeneous simple arrays and complex HORs composed of different satDNAs, enabled, for the first time, the identification of conserved motifs as obligatory components of monomer junctions. This observation highlights the role of short motifs in rearrangements, even among highly divergent sequences. Two mechanisms are proposed to be involved in this process, i.e., putative transposition-related cut-and-paste insertions and/or illegitimate recombination. Possibility for involvement of the nematode CENP-B box-like sequence in the transposition-related mechanism and together with previously established similarity of the human CENP-B protein and pogo-like transposases implicate a novel role of the CENP-B box and related sequence motifs in addition to the known function in centromere protein binding.     

Phosphorylation of double-stranded DNAs by T4 polynucleotide kinase.

The phosphorylation by T4 polynucleotide kinase of various double-stranded DNAs containing defined 5'-hydroxyl end group structures has been studied. Particular emphasis was placed on finding conditions that allow complete phosphorylation. The DNAs employed were homodeoxyoligonucleotides annealed on the corresponding homopolymers, DNA duplexes corresponding to parts of the genes for alanine yeast tRNA, and a suppressor tyrosine tRNA from Escherichia coli. The rate of phosphoylation of DNAs with 5'-hydroxyl groups in gaps was approximately ten times slower than for the corresponding single-stranded DNA. At low concentrations of ATP, 1 muM, incomplete phosphorylation was obtained, whereas with higher concentrations of ATP, 30 muM, complete phosphorylation was achieved. In the case of DNAs with 5'-hydroxyl groups at nicks approximately 30% phosphorylation could be detected using 30 muM ATP. A DNA containing protruding 5'-hydroxyl group ends was phosphorylated to completion using the same conditions as for single-stranded DNA, i.e., a ratio between the concentrations of ATP and 5'-hydroxyl groups of 5:1 and a concentration of ATP of approximately 1 muM. For a number of DNAs containing protruding 3'-hydroxyl group ends and one DNA containing even ends incomplete phosphorylation was found under similar conditions. For all these DNAs a plateau level was observed varying from 20 to 45% of complete phosphorylation. At 20 muM and higher ATP concentrations, the phosphorylation was complete also for these DNAs. With low concentrations of ATP a rapid production of inorganic phosphate was noted for all the latter DNAs. The apparent equilibrium constants for the forward and reverse reaction were determined for a number of different DNAs, and these data revealed that the plateau levels of phosphorylation obtained at low concentrations of ATP for DNAs with protruding 3'-hydroxyl group and even ends is not a true equilibrium resulting from the forward and reverse reaction. It is suggested that the plateau levels are due to formation of inactive enzyme-substrate and enzyme-product complexes. For all double-stranded DNAs tested, except DNAs containing protruding 5'-hydroxyl group ends, addition of KCl to the reaction mixture resulted in a drastic decrease in the rate of phosphorylation, as well as in the maximum level phosphorylated. Spermine, on the other hand, had little influence. Both of these agents have previously been shown to activate T4 polynucleotide kinase using single-stranded DNAs as substrates (Lillehaug, J.R., and Kleppe, K. (1975), Biochemistry 14, 1221). The inhibition of phosphorylation of double-stranded DNAs by salt might be the result of stabilization of the 5'-hydroxyl group regions of these DNAs.     

Molecular properties of orthopteran DNA

DNAs from three grasshopper species and three locust species (Family Acrididae, Order Orthoptera) have been characterised by a variety of biochemical techniques as part of a general investigation of their molecular evolution. Base compositions were inferred from thermal denaturation profiles and analytical CsCl and Cs2SO4 pcynography. Repeated sequence content of the genomes was studied by renaturation kinetics incorporating absorption measurements. Relative genome size was measured by microdensitometry of nuclear preparations.     

Analysis of DNA from related and diverse species of Barley

DNAs of three closely related diploid species Hordeum vulgare, H. agriocrithon and H. spontaneum were compared among themselves and with a group of three species related to each other H. californicum (2x), H. jubatum (4x), and H. arizonicum (6x) having one genome in common.Buoyant densities of the DNAs from these species fall within a narrow range (1.700–1.701 g cm⁻³). Melting temperatures (T_m) of the DNAs are also similar (85.2–86.2°C). None of the DNAs showed any satellite band in neutral Cesium chloride gradients. In silver-cesium sulphate gradients, however, DNAs of all the species formed satellites on both the light and heavy sides of the main. band The diploid series have similar but not identical satellite patterns. The members of the polyploid series showed similar satellite patterns among themselves but distinct from those of the diploid series. In the polyploid group the amount of satellite showed a progressive decrease with the increase in the ploidy.The amount of repeated DNA (reassociating up to Cot 100) in H. vulgare was 69% and in H. arizonicum 65% of the total. The two species differed in their Cot curves. The low Cot fractions of H. arizonicum contained components of low buoyant densities which were absent in the corresponding Cot fractions of H. vulgare DNA.     

An ultracentrifugation analysis of two hundred fish genomes

The goal of this study was to provide a comprehensive view of the compositional characteristics of fish genomes. We therefore expanded the number of fish species that we had explored so far in their DNAs by analytical ultracentrifugation in CsCl density gradient from 122 to 201. This study included representatives from three out of nine orders of Elasmobranchs (sharks and rays), both orders of dipnoan lungfishes, and both orders of chondrosteans (sturgeons and bichirs). We also studied 19 out of 38 teleostean orders, which represent all but four (minor) superorders of the subdivision Teleostei, a group comprising about 23,600 species (96% of all extant fishes). This leaves for further studies two subclasses, Holocephali (chimaeras), and Coelacanthimorpha (gombessas). In spite of this substantial increase in the number of species and orders analysed, all average properties (the modal buoyant density, rho(0), the average buoyant density, , the CsCl profile asymmetry, A, and the compositional heterogeneity, H), and all their ranges were unchanged compared to a previous study [J. Mol. Evol. 31 (1990) 265]. This suggests that, in all likelihood, the properties reported in the present paper can be considered as generally valid for all fish genomes.     

Variability in Complementarity for Chloroplastic and Cytoplasmic Ribosomal Ribonucleic Acid among Plant Nuclear Deoxyribonucleic Acids

The nuclear DNAs from a number of angiosperm species were tested for hybridization to the RNAs contained in 70 S (chloroplastic) and 80 S (cytoplasmic) ribosomes. All of the DNAs contained regions complementary to RNAs from chloroplastic as well as cytoplasmic ribosomes. DNAs from closely related plants varied widely in their proportion of coding for these RNAs. About 0.15% of the DNAs from a number of different species of Nicotiana were found to be complementary to the RNAs of each kind of ribosome; however, DNAs from some other members of this genus had more than three times this proportion of coding for ribosomal RNAs. These and other data suggest that hybridization percentage for ribosomal RNA is not a familial or generic characteristic.     

DNA homologies among homothallic, pseudo-homothallic and heterothallic species of Neurospora.

Summary Highly purified DNAs from three homothallic speciesNeurospora africana, N. dodgei andN. lineolata; three reference strains representing authentic heterothallic species,N. crassa, N. intermedia andN. sitophila; and two strains of pseudo-homothallic speciesN. tetrasperma were characterized by spectrophotometry and DNA reassociation using hydroxyapatite chromatography. All of these known species are closely related on the basis of DNA characteristics such as base composition and thermal denaturation profiles of major DNA components. Minor components of ascospore DNA was, however, only 5–7% of total DNA instead of 15–20% minor component DNA shown by mycelial DNA. Species belonging to same group were not distinguishable morphologically, but all of these species were distinguishable by DNA:DNA homology studies. Greater DNA homology was noticed between DNAs of heterothallic species and DNAs of pseudohomothallic species than DNA of true homothallic species. Difference on DNA-nucleiotide sequences among homothallic species was very little. Pseudo-homothallic speciesN. tetrasperma was found to be distinctly different from homothallic species but closer to heterothallic species based on such studies.Supported in part by a contract No. E(40-1)4182 with the U.S. Energy Research and Development Administration. We are grateful to Departments of Oncology and Radiotherapy, College of Medicine, Howard University, Washington, D.C. for providing us with material assistance     

Study of morphology and genome structure of Pseudomonas putida bacteriophages for their classification

A group of 27 bacteriophages specific for Pseudomonas putida strains PpG1 and PpN has been isolated. The phages were characterized and compared with the previously described virulent (pf 16, af, tf and PMW) and temperate (PP56 and PP71) phages. The new phages belong to B1 and C1 morphotypes, according to Ackerman's classification. Phage DNAs were digested with several endonucleases; the molecular weights and homology of the DNAs were determined. All phages of P. putida isolated up to now were distributed into 10 species (groups), on the basis of particle morphology, genome size and the results of homology studies. Recombination processes are believed to participate in formation of phages belonging to certain species.     

Comparative analysis of different satellite DNAs in four Mytilus species.

We report the characterization of three satellite DNAs in four species of mussel: Mytilus edulis, Mytilus galloprovincialis, Mytilus trossulus, and Mytilus californianus. The monomers of the Apa I satellite DNAs were 173, 161, and 166 bp long. These satellite monomers were used to construct phylogenetic trees to infer relationships among these species. The topologies obtained clearly indicate that M. californianus is the most divergent species with respect to the other three. Furthermore, localization of satellite DNAs on metaphase chromosomes was performed using fluorescent in situ hybridization (FISH). Fluorescent signals revealed a different organization and distribution of these three satellite DNAs.     

Transforming Region of Group A, B, and C Adenoviruses: DNA Homology Studies with Twenty-Nine Human Adenovirus Serotypes

The 31 human adenovirus (Ad) serotypes form five groups based upon DNA genome homologies: group A (Ad12, 18, 31), group B (Ad3, 7, 11, 14, 16, 21), group C (Ad1, 2, 5, 6), group D (Ad8, 9, 10, 13, 15, 17, 19, 20, 22-30), and group E (Ad4) (M. Green, J. Mackey, W. Wold, and P. Rigden, Virology, in press). Group A Ads are highly oncogenic in newborn hamsters, group B Ads are weakly oncogenic, and other Ads are nononcogenic. However, most or all Ads transform cultured cells. We have studied the homology of Ad5, Ad7, and Ad12 transforming restriction endonuclease DNA fragments with DNAs of 29 Ad types. Ad5 HindIII-G (map position 0-7.3), Ad7 XhoI-C (map position 0-10.8), and Ad12 (strain Huie) EcoRI-C (map position 0-16) and SalI-C (map position 0-10.6) fragments were purified, labeled in vitro (nick translation), and annealed with DNAs of Ad1 to Ad16, Ad18 to Ad24, and Ad26 to Ad31. Hybrids were assayed by using hydroxylapatite. Ad5 HindIII-G hybridized 98 to 100% with DNAs of group C Ads, but only 1 to 15% with DNAs of other types. Ad7 XhoI-C fragment hybridized 85 to 99% with DNAs of group B Ads, but only 6 to 21% with DNAs of other types. Ad12 (Huie) EcoRI-C hybridized 53 to 68% with DNAs of five other Ad12 strains, 53% with Ad18 DNA, 56% with Ad31 DNA, but only 3 to 13% with DNAs of other types. In vitro-labeled Ad12 (Huie) SalI-C hybridized 35 to 71% with DNAs of 6 other Ad12 strains, 44% with Ad18 DNA, 52% with Ad31 DNA, but only 2 to 7% with DNAs Ad7, Ad2, Ad26, or Ad4. When assayed using S-1 nuclease, SalI-C annealed 17 to 44% with DNAs of group A Ads. The melting temperatures of the hybrids of Ad5 HindIII-G with all group C Ad DNAs were 84 degrees C in 0.12 M sodium phosphate (pH 6.8). The melting temperature of the Ad12 (Huie) EcoRI-C hybrid with Ad12 (Huie) DNA was 83 degrees C, but was only 71 to 77 degrees C with DNAs of other group A Ads. Thus, group C and group B Ads both have very homologous transforming regions that are not represented in DNAs of non-group C Ads or non-group B Ads, respectively. Similarily, group A Ads have unique but less homologous transforming regions. These different transforming nucleotide sequences may be reflected in the different oncogenic properties of group A, B, and C Ads.     

Genetic diversity among Rhizobium strains from Cicer arietinum L.

Following bacteriological cloning and determination of their symbiotic performance, 15 representative, diverse strains of chickpea rhizobia were genetically analysed for restriction fragment length polymorphisms. Analyses of genomic DNAs showed several different groups. Almost half (7) of the strains examined were very similar and clearly represented a single species. There was a related group of four strains which could be a subspecies. There was also one distinct group of four strains which were apparently unrelated to the reference strain 3377. This latter group may constitute a separate species. Phenotypic differences should be investigated further.     

Actinomyces georgiae sp. nov., Actinomyces gerencseriae sp. nov., designation of two genospecies of Actinomyces naeslundii, and inclusion of A. naeslundii serotypes II and III and Actinomyces viscosus serotype II in A. naeslundii genospecies 2

DNAs of type strains and representative members of Actinomyces groups from the human periodontal flora and from other habitats were compared by using the S1 nuclease procedure to determine their genetic relatedness. One rather common group from the human periodontal flora, previously called "Actinomyces D08," is phenotypically distinct from, and genetically unrelated to, previously described species. We propose the name of Actinomyces georgiae for this organism; the type strain is strain ATCC 49285. Another common group from the human periodontal flora is Actinomyces israelii serotype II, which was found genetically distinct from the type strain of A. israelii (serotype I) and from other previously described species of Actinomyces. We propose the name Actinomyces gerencseriae for this organism; the type strain is strain ATCC 23860. A. naeslundii serotype I strains were distinct from the other strains studied. A separate genospecies which included strains of A. naeslundii serotypes II and III and A. viscosus serotype II was delineated. Strains of Actinomyces serotype WVA 963 constitute an additional distinct genospecies. Because there are no reliable phenotypic tests, other than serological analyses, to differentiate Actinomyces serotype WVA 963 and the two genospecies of A. naeslundii, no taxonomic changes are proposed for these three genospecies.     

Comparative electrophoretical analysis of plasmid-like mitochondrial DNAs in Vicia faba and in some other legumes

Minicircular DNAs found in mitochondria of 6-d-old etiolated seedlings of Vicia faba L. were also present in mitochondria isolated from cell suspension cultures and from green leaves of this plant. These results support the suggestion that the plasmid-like molecules found in mitochondria of V. faba are an essential component of the mitochondrial genome. The minicircular DNAs were, apparently, peculiar for the species V. faba since they were found in all three cultivars of this species which were studied. The distribution pattern of plasmid-like DNAs in Vicia villosa L. was completely different and mitochondria from Medicago sativa L. also contained specific minicircular DNAs. Thus, minicircular DNAs are typical for the mitochondrial genomes of several legumes and different plant species have their specific mitochondrial plasmid-like DNAs     

The response of a three trophic level soil food web to the identity and diversity of plant species and functional groups

Despite considerable recent interest in how biodiversity may influence ecosystem properties, the issue of how plant diversity and composition may affect multiple trophic levels in soil food webs remains essentially unexplored. We conducted a glasshouse experiment in which three plant species of each of three functional groups (grasses, N‐fixing legumes and forbs) were grown in monoculture and in mixtures of three species (with the three species being in the same or different functional groups) and all nine species. Plant species identity had important effects on the biomasses or population densities of belowground primary consumers (microbial biomass, herbivorous nematodes) and two groups of secondary consumers (microbe‐feeding nematodes and enchytraeids); the third consumer trophic level (predatory nematodes) was marginally not significantly affected at P=0.05. Plant species also influenced the relative importance of the bacterial‐based and fungal‐based energy channels for both the primary and secondary consumer trophic levels. Within‐group diversity of only the soil microflora and herbivorous nematodes (both representing the basal consumer trophic level) were affected by plant species identity. However, community composition within all trophic groupings considered (herbivorous nematodes, microbes, microbe‐feeding nematodes, predatory nematodes) was strongly influenced by what plant species were present. Despite the strong responses of the soil biota to plant species identity, there were few effects of plant species or functional group richness on any of the belowground response variables measured. Further, net primary productivity (NPP) was unaffected by plant diversity. Since some belowground response variables were correlated with NPP across treatments, it is suggested that belowground responses to plant diversity might become more apparent in situations when NPP itself responds to plant diversity. Our results point to plant species identity as having important multitrophic effects on soil food webs, both at the whole trophic group and within‐group levels of resolution, and suggest that differences in plant traits across species may be important in driving the decomposer subsystem.