Insights into the genome structure and copy-number variation of Eimeria tenella

ABSTRACT: BACKGROUND: Eimeria is a genus of parasites in the same phylum (Apicomplexa) as human parasites such as Toxoplasma, Cryptosporidium and the malaria parasite Plasmodium. As an apicomplexan whose life-cycle involves a single host, Eimeria is a convenient model for understanding this group of organisms. Although the genomes of the Apicomplexa are diverse, that of Eimeria is unique in being composed of large alternating blocks of sequence with very different characteristics - an arrangement seen in no other organism. This arrangement has impeded efforts to fully sequence the genome of Eimeria, which remains the last of the major apicomplexans to be fully analyzed. In order to increase the value of the genome sequence data and aid in the effort to gain a better understanding of the Eimeria tenella genome, we constructed a whole genome map for the parasite. RESULTS: A total of 1245 contigs representing 70.0% of the whole genome assembly sequences (Wellcome Trust Sanger Institute) were selected and subjected to marker selection. Subsequently, 2482 HAPPY markers were developed and typed. Of these, 795 were considered as usable markers, and utilized in the construction of a HAPPY map. Markers developed from chromosomally-assigned genes were then integrated into the HAPPY map and this aided the assignment of a number of linkage groups to their respective chromosomes. BAC-end sequences and contigs from whole genome sequencing were also integrated to improve and validate the HAPPY map. This resulted in an integrated HAPPY map consisting of 60 linkage groups that covers approximately half of the estimated 60 Mb genome. Further analysis suggests that the segmental organization first seen in Chromosome 1 is present throughout the genome, with repeat-poor (P) regions alternating with repeat-rich (R) regions. Evidence of copy-number variation between strains was also uncovered. CONCLUSIONS: This paper describes the application of a whole genome mapping method to improve the assembly of the genome of E. tenella from shotgun data, and to help reveal its overall structure. A preliminary assessment of copy-number variation (extra or missing copies of genomic segments) between strains of E. tenella was also carried out. The emerging picture is of a very unusual genome architecture displaying inter-strain copy-number variation. We suggest that these features may be related to the known ability of this parasite to rapidly develop drug resistance.     

The genome of Eimeria spp., with special reference to Eimeria tenella--a coccidium from the chicken

Eimeria spp. contain at least four genomes. The nuclear genome is best studied in the avian species Eimeria tenella and comprises about 60 Mbp DNA contained within ca. 14 chromosomes; other avian and lupine species appear to possess a nuclear genome of similar size. In addition, sequence data and hybridisation studies have provided direct evidence for extrachromosomal mitochondrial and plastid DNA genomes, and double-stranded RNA segments have also been described. The unique phenotype of "precocious" development that characterises some selected lines of Eimeria spp. not only provides the basis for the first generation of live attenuated vaccines, but offers a significant entrée into studies on the regulation of an apicomplexan life-cycle. With a view to identifying loci implicated in the trait of precocious development, a genetic linkage map of the genome of E. tenella is being constructed in this laboratory from analyses of the inheritance of over 400 polymorphic DNA markers in the progeny of a cross between complementary drug-resistant and precocious parents. Other projects that impinge directly or indirectly on the genome and/or genetics of Eimeria spp. are currently in progress in several laboratories, and include the derivation of expressed sequence tag data and the development of ancillary technologies such as transfection techniques. No large-scale genomic DNA sequencing projects have been reported.     

A genetic linkage map for the apicomplexan protozoan parasite Eimeria maxima and comparison with Eimeria tenella

Eimeria maxima is one of the seven Eimeria spp. that infect the chicken and cause the disease coccidiosis. The well characterised immunogenicity and genetic diversity associated with E. maxima promote its use in genetics-led studies on avian coccidiosis. The development of a genetic map for E. maxima, presented here based upon 647 amplified fragment length polymorphism markers typed from 22 clonal hybrid lines and assembled into 13 major linkage groups, is a major new resource for work with this parasite. Comparison with genetic maps produced for other coccidial parasites indicates relatively high levels of genetic recombination. Conversion of ∼14% of the markers representing the major linkage groups to sequence characterised amplified region markers can provide a scaffold for the assembly of future genomic sequences as well as providing a foundation for more detailed genetic maps. Comparison with the Eimeria tenella genetic map produced 10 years ago has revealed a less biased marker distribution, with no more than nine markers mapped within any unresolved heritable unit. Nonetheless, preliminary bioinformatic characterisation of the three largest publicly available genomic E. maxima sequences suggest that the feature-poor/feature-rich structure which has previously been found to define the first sequenced E. tenella chromosome also defines the E. maxima genome. The significance of such a segmented genome and the apparent potential for variation in genetic recombination will be relevant to haplotype stability and the longevity of future anticoccidial strategies based upon multiple loci targeted by novel chemotherapeutic drugs or recombinant subunit vaccines.     

柔嫩艾美耳球虫HSP基因的克隆、表达及鉴定

为研究柔嫩艾美耳球虫热激蛋白(Heat shock proteins,HSPs)的生物学特性,应用RACE和RT-PCR技术,从柔嫩艾美耳球虫子孢子中首次克隆获得了EtHSP的全长cDNA(GenBank Accession No.FJ911605)。EtHSP包含一个1455 bp的开放阅读框,编码484个氨基酸,预测表达蛋白的分子量大小为53.5 kD。应用Real-time PCR对柔嫩艾美耳球虫不同发育阶段(未孢子化卵囊、孢子化卵囊、子孢子和裂殖子)表达量进行分析,发现该基因在子孢子阶段的表达明显高于其他阶段。同时,构建了原核表达重组质粒pET28a(+)-EtHSP,转化到大肠杆菌BL21(DE3)中,经IPTG诱导表达后,对表达产物进行SDS-PAGE及Western blotting分析。结果显示,重组质粒pET28a(+)-EtHSP在大肠杆菌中以包涵体形式表达,经1 mmol/L IPTG诱导6 h后的表达量最高,该蛋白可被抗柔嫩艾美耳球虫的多克隆抗血清识别,表明该蛋白具有较好的反应原性。本研究结果为进一步研究该基因的生物学功能奠定了基础。     

Development of SCAR markers for the DNA-based detection of the Asian long-horned beetle,Anoplophora glabripennis (Motschulsky)

DNA markers were identified for the molecular detection of the Asian long-horned beetle (ALB), Anoplophora glabripennis (Mot.), based on sequence characterized amplified regions (SCARs) derived from random amplified polymorphic DNA (RAPD) fragments. A 2,740-bp DNA fragment that was present only in ALB and not in other Cerambycids was identified after screening 230 random primers in a PCR-based assay system. Three pairs of nested 22-mer oligonucleotide primers were designed on the basis of the sequence of this fragment and were used to perform diagnostic PCR. The first pair of primers (SCAR1) amplified a single 745-bp fragment of ALB DNA, but this did not differentiate ALB from other species. The other two pairs of SCAR primers (SCAR2 and SCAR3) amplified bands of 1,237- and 2,720-bp, respectively, that were capable of differentiating ALB from other closely related non-native and native Cerambycids, such as A. chinensis (Forster), A. malasiaca (Thomson), A. nobilis (Ganglbauer), Monochamus scutellatus (Say), Plectrodera scalator (Fab), Saperda tridentata (Olivier), and Graphisurus fasciatus (Degeer). The latter two SCAR markers could be amplified using DNA extracted from body parts of ALB such as the wing, the leg, and the antennae as well as tissues from all the developmental stages including the egg, larva, pupa, and adult. These markers were also capable of identifying ALB using the DNA extracted from frass. Our results demonstrate that the SCAR markers we have identified can be used for unambiguously identifying ALB from other closely related Cerambycids using a simple PCR procedure.     

DNA barcoding identifies Eimeria species and contributes to the phylogenetics of coccidian parasites (Eimeriorina, Apicomplexa, Alveolata)

Partial (～ 780 bp) mitochondrial cytochrome c oxidase subunit I (COI) and near complete nuclear 18S rDNA (～ 1,780 bp) sequences were directly compared to assess their relative usefulness as markers for species identification and phylogenetic analysis of coccidian parasites (phylum Apicomplexa). Fifteen new COI partial sequences were obtained using two pairs of new primers from rigorously characterised (sensu Reid and Long, 1979) laboratory strains of seven Eimeria spp. infecting chickens as well as three additional sequences from cloned laboratory strains of Toxoplasma gondii (ME49 and GT1) and Neospora caninum (NC1) that were used as outgroup taxa for phylogenetic analyses. Phylogenetic analyses based on COI sequences yielded robust support for the monophyly of individual Eimeria spp. infecting poultry except for the Eimeria mitis/mivati clade; however, the lack of a phenotypically characterised strain of E. mivati precludes drawing any firm conclusions regarding this observation. Unlike in the 18S rDNA-based phylogenetic reconstructions, Eimerianecatrix and Eimeria tenella formed monophyletic clades based on partial COI sequences. A species delimitation test was performed to determine the probability of making a correct identification of an unknown specimen (sequence) based on either complete 18S rDNA or partial COI sequences; in almost all cases, the partial COI sequences were more reliable as species-specific markers than complete 18S rDNA sequences. These observations demonstrate that partial COI sequences provide more synapomorphic characters at the species level than complete 18S rDNA sequences from the same taxa. We conclude that COI performs well as a marker for the identification of coccidian taxa (Eimeriorina) and will make an excellent DNA 'barcode' target for coccidia. The COI locus, in combination with an 18S rDNA sequence as an 'anchor', has sufficient phylogenetic signal to assist in the resolution of apparent paraphylies within the coccidia and likely more broadly within the Apicomplexa.     

Development of SRAP,SNP and Multiplexed SCAR molecular markers for the major seed coat color gene in <Emphasis Type="Italic">Brassica rapa L.</Emphasis>

Seed coat color inheritance in B. rapa was studied in F(1), F(2), F(3), and BC(1) progenies from a cross of a Canadian brown-seeded variety 'SPAN' and a Bangladeshi yellow sarson variety 'BARI-6'. A pollen effect was found when the yellow sarson line was used as the maternal parent. Seed coat color segregated into brown, yellow-brown and bright yellow classes. Segregation was under digenic control where the brown or yellow-brown color was dominant over bright yellow seed coat color. A sequence related amplified polymorphism (SRAP) marker linked closely to a major seed coat color gene (Br1/br1) was developed. This dominant SRAP molecular marker was successfully converted into single nucleotide polymorphism (SNP) markers and sequence characterized amplification region (SCAR) markers after the extended flanking sequence of the SRAP was obtained with chromosome walking. In total, 24 SNPs were identified with more than 2-kb sequence. A 12-bp deletion allowed the development of a SCAR marker linked closely to the Br1 gene. Using the five-fluorescence dye set supplied by ABI, four labeled M13 primers were integrated with different SCAR primers to increase the throughput of SCAR marker detection. Using multiplexed SCAR markers targeting insertions and deletions in a genome shows great potential for marker assisted selection in plant breeding.     

Use of intersimple sequence repeats markers to develop strain-specific SCAR markers for Lentinula edodes

Although Lentinula edodes is the second most important cultivated mushroom worldwide, most industrially cultivated strains have been identified only through traditional phenotypic analysis. Here, we report for the first time the use of sequence characterized amplified region (SCAR) markers for strain differentiation. SCAR markers were created by first generating and sequencing single intersimple sequence repeats fragments, and then designing primers based on these sequences to amplify strain-specific fragments of a certain size. One SCAR primer pair, ISL450F/R7 (amplifying a band of c. 450 bp), was designed to identify one strain of L. edodes (strain No. 7). The SCAR primer pair was then used to correctly amplify the single unique fragment from DNA samples taken from a total of 85 strains representing three separate species. Our data provide the foundation for a precise and rapid PCR-based strain-diagnostic system for L. edodes.     

Molecular characterization of Eimeria species in macropods

A total of 597 faecal samples were collected from western grey kangaroos (Macropus fuliginosus), Euros (M. robustus), red kangaroos (M. rufus) in Western Australia and Eastern Grey Kangaroos (M. giganteus) from Victoria and screened for the presence of Eimeria by PCR at the 18S ribosomal RNA (rRNA) locus. The overall prevalence was 24.3% (145/597). At the 18S rRNA locus, sequences were obtained for 25 of the 145 positives. Phylogenetic analysis indicated that all the macropod-derived Eimeria species grouped in a separate marsupial clade that included Eimeria trichosuri from brushtail possums. At least 6 different clades were identified within the marsupial isolates and many of the genotypes identified are likely to be valid species, however morphological and biological data need to be collected to match sequences to previously characterized Eimeria species or identify if they are new species.     

SCAR Makers and Multiplex PCR-Based Rapid Molecular Typing of Lentinula edodes Strains

Lentinula edodes is the second most important cultivated mushroom worldwide, the most commercial strains have been identified only through traditional phenotypic analysis. In this study, a simple rapid PCR-based molecular method was developed for distinguishing commercial strains of L. edodes by developing specific sequence characterized amplified region (SCAR) markers and establishing multiplex PCR assays with the SCAR primers. Derived from the randomly amplified polymorphic DNA (RAPD) and sequence-related amplified polymorphism (SRAP) techniques, 10 informative SCAR markers were generated from 10 polymorphic RAPD and SRAP bands. The differences in SCAR phenotypes among different strains made these SCAR markers potentially useful to characterize 6 strains and identify them from other studied strains. Moreover, different SCAR phenotypes also made the other 17 studied strains to be divided into four distinguishable groups. The multiplex PCR assays were further established for the joint use of some SCAR markers efficiently. Compared with some identification methods reported previously, the special feature of this new molecular method is technically rapid and convenient in the practical use and suitable for analyzing large numbers of samples. Thus, the simple rapid PCR-based molecular method can be used as a helpful assistant tool for the lentinula industry. To our knowledge, this study is the first to describe a development of a new SCAR maker-based multiplex PCR assay for rapid molecular typing of edible mushroom.     

Genome-wide identification of intron fragment insertion mutations and their potential use as SCAR molecular markers in the soybean

Introns often have a high probability of mutation as a result of DNA insertions and deletions (indels). In this study, 503 introns with exon-derived insertions were identified using a comprehensive search of the soybean genome. Of the 375 pairs of PCR primer sets designed for the loci in question, 161 primer sets amplified length polymorphism among nine soybean varieties and were identified as soybean gene-intron-driven functional sequence characterized amplified region (SCAR) markers. These SCAR markers are distributed among all 20 of the soybean chromosomes, and they developed from numerous genes involved in various physiological and biochemical processes that influence important agronomic traits of the soybean. The development of these novel gene-driven functional SCAR markers was fast and cost effective, and their use will facilitate molecular-assisted breeding of the soybean.     

DEVELOPMENT OF SEQUENCE CHARACTERIZED AMPLIFIED REGION MARKERS FROM INTERSIMPLE SEQUENCE REPEAT FINGERPRINTS FOR THE MOLECULAR DETECTION OF TOXIC PHYTOPLANKTON ALEXANDRIUM CATENELLA (DINOPHYCEAE) AND PSEUDO‐NITZSCHIA PSEUDODELICATISSIMA (BACILLARIOPHYCEAE) FROM FRENCH COASTAL WATERS1

Harmful algal blooms are a serious threat to shellfish farming and human health all over the world. The monitoring of harmful algae in coastal waters originally involved morphological identification through microscopic examinations, which was often difficult unless performed by specialists and even then often did not permit identification of toxic species. More recently, specific molecular markers have been used to identify specific phytoplankton species or strains. Here we report on the use of the intersimple sequence repeat (ISSR) technique to develop specific sequence characterized amplified region markers (SCAR) and to identify with these tools two toxic species in French coastal waters, the diatom Pseudo‐nitzschia pseudodelicatissima (Hasle) Hasle and the dinoflagellate Alexandrium catenella (Whedon and Kofoid 1936), Balech 1985. Six polymorphic ISSR regions were selected among amplified fingerprints of a representative sample of phytoplankton species. After cloning and sequencing the selected polymorphic ISSR regions, pairs of internal primers were designed to amplify a unique and specific sequence designed as a SCAR marker. Of the six selected SCAR markers, three were specific to P. pseudodelicatissima and one for A. catenella. The SCAR marker specificity was confirmed by using basic local alignment search tool comparison, by experimental assays on different strains from 11 countries, and by checking that the sequence amplified was the expected one. When tested on water samples collected along the French shores, the four specific SCAR markers proved to be efficient tools for fast and low‐cost detection of toxic phytoplankton species.     

杉木种子随体染色体SCAR标记的建立

回收、纯化由引物OPB07(5’-GGTGACGCAG-3’) OPB18(5’-CCACAGCAGT-3’)扩增而得的杉木(Cunninghamia lanceolata(Lamb.)Hook)种子随体染色体特异性RAPD(随机扩增的DNA多态性分析)片段OPB07-18907,将该片段克隆至pUCm-T载体,转化受体菌后筛选出阳性克隆,并对插入片段进行测序,根据序列特点设计两对SCAR(序列特异性扩增区)引物,PCR结果显示,这两对引物的4种组合都可以扩增出属于随体染色体的特征带,适宜退火温度为57℃。成功将特异RAPD标记OPB07-18907转化为稳定的SCAR标记。开发随体染色体SCAR标记目的是:一方面能在分子水平上鉴定微分离的杉木随体染色体,另一方面,也可以将杉木已构建的遗传图谱中连锁群与染色体进行对应。探讨了该SCAR标记对杉木核型分析的作用。     

Development of PCR-based SCAR and CAPS markers linked to beta-glucan and protein content QTL regions in oat.

A key breeding objective in oat (Avena sativa L.) is cultivars with high and low beta-glucan content. In a targeted strategy to develop PCR-based markers linked to published beta-glucan content quantitative trait loci (QTLs) regions, 15 random amplified polymorphic DNA (RAPD) fragments were cloned and their sequences used to design sequence-characterized amplified region (SCAR) and cleaved amplified polymorphic sequence (CAPS) primers. The 13 derived SCAR markers and 2 derived CAPS markers were mapped on either the 'Kanota' x 'Ogle' (KO) or the 'Terra' x 'Marion' (TM) oat reference map. In addition, 3 previously reported SCAR markers were characterized further. Ten SCAR markers and one CAPS marker were associated with beta-glucan QTL regions and many of these are also associated with QTLs for protein content or other traits. These markers have the potential to help define homologous and homologous relationships in oat and investigate the complex genetics of beta-glucan and protein content.     

Characterization of the complete mitochondrial genomes of five Eimeria species from domestic chickens

Chicken coccidiosis caused by members of the genus Eimeria causes significant economic losses worldwide. In the present study we sequenced the complete mitochondrial DNA (mtDNA) sequences of six Eimeria species and analyzed features of their gene contents and genome organizations. The complete mt genomes of E. acervulina, E. brunetti, E. maxima, E. necatrix, E. tenella and E. praecox were 6179bp, 6148bp, 6169bp, 6214bp, 6213bp and 6174bp in size, respectively. All of the mt genomes consist of 3 genes for proteins (cox1, cox3, and cytb), 12 gene fragments for the large subunit (LSU) rRNA, and 7 gene fragments for the small subunit (SSU) rRNA, but no transfer RNA genes. The organization of the mt genomes is similar to that of Plasmodium, but distinct from Babesia and Theileria. The putative direction of translation for 3 genes (cox1, cox3, and cytb) was the same in all six Eimeria species. The contents of A+T of the mt genomes were 65.35% for E. acervulina, 65.43% for E. brunetti, 64.53% for E. maxima, 65.04% for E. necatrix, 64.98% for E. tenella and 65.59% for E. praecox. The AT bias has a significant effect on both the codon usage pattern and amino acid composition of proteins. Phylogenetic analyses using concatenated nucleotide sequences of the 2 protein-coding genes (cytb and cox1), with three different computational algorithms (Bayesian analysis, maximum parsimony and maximum likelihood), all revealed distinct groups with high statistical support, indicating that the six Eimeria spp. represent six distinct but closely-related species. These data provide novel mtDNA markers for studying the molecular epidemiology and population genetics of the six Eimeria spp., and should have implications for the molecular diagnosis, prevention and control of coccidiosis in domestic chickens.     

Analysis of transcripts from intracellular stages of Eimeria acervulina using expressed sequence tags

Coccidiosis in chickens is caused by 7 species of Eimeria. Even though coccidiosis is a complex disease that can be caused by any combination of these species, most of the molecular research concerning chicken coccidiosis has been limited to Eimeria tenella. The present study describes the first large-scale analysis of expressed sequence tags (ESTs) generated primarily from second-stage merozoites (and schizonts) of E. acervulina. In total, 1,847 ESTs were sequenced; these represent 1,026 unique sequences. Approximately half of the ESTs encode proteins of unknown function, or hypothetical proteins. Twenty-nine percent of the E. acervulina ESTs share significant sequence identity with sequences in the E. tenella genome. Additionally, EST hits seem to be much different compared with those of E. tenella. One of the differences is the very low number of ESTs that encode putative microneme proteins. This study underlines the potential differences in the molecular aspects of 2 Eimeria species that in the past were thought to be highly similar in nature.     

Pinning down a polymorphic parasite: new genetic and morphological descriptions of Eimeria macropodis from the Tammar wallaby (Macropus eugenii)

Identification of the protozoan parasite, Eimeria has traditionally relied on oocyst morphology, host range and life-cycle attributes. However, it is increasingly recognized that Eimeria species can vary in size and shape across their host range, an attribute known as 'polymorphism' that presents a unique challenge for identification. Advances in molecular tools hold promise for characterising Eimeria that may otherwise be misclassified based on morphology. Our study used morphologic and molecular traits of the oocyst life stage to identify a polymorphic parasite, Eimeria macropodis in a captive Tammar wallaby (Macropus eugenii) population in Australia. Molecular characterization highlighted the need to use multiple genetic markers (18S SSU and cytochrome c oxidase subunit I) to accurately identify E. macropodis owing to heterozygous alleles at the 18S SSU locus. This study provided an opportunity to assess the utility and shortcomings of morphologic and molecular techniques for 'pinning down' a polymorphic species. Moreover, our study was able to place E. macropodis in an evolutionary context and enhance resolution of the under-studied marsupial clade.     

Three new species of Eimeria from Bolivian marsupials

Faecal samples collected from 300 Bolivian marsupials (Didelphimorphia: Didelphidae) between 1984 and 1993 were examined for coccidian parasites. Sporulated oocysts were present in the faeces of 50 (17%) marsupials representing 11 genera and 22 species. Three new species of Eimeria are described and named from six host species. One species occurred in Marmosops dorothea, Monodelphis domestica and Thylamys venustus, another in Micoureus constantiae constantiae and Micoureus constantiae budini and a third in Marmosops dorothea. A discriminant analysis performed on five quantitative oocyst measurements revealed similarities between the first and third Eimeria species because of similar sizes and shapes of the oocysts, whereas the second Eimeria species was structurally discrete. The Eimeria that infects multiple hosts may be a common widespread species. Future surveys are advised for a thorough assessment of the coccidian biodiversity within Bolivian marsupials.     

SCAR markers to detect mycorrhizas of an American Laccaria bicolor strain inoculated in European Douglas-fir plantations

The American strain S238N of the ectomycorrhizal fungus Laccaria bicolor (Maire) Orton has been used to inoculate Douglas-fir [Pseudotsuga menziesii (Mir.) Franco] plantations in France over the last two decades. Laccaria fruit bodies are scarce in mature plantations, which precludes further assessment of its persistence by fruit body surveys. Our objective was to develop new markers to identify this strain and its eventual non-fruiting progeny on root tips. We converted nine random amplified polymorphic DNA markers into sequence characterized amplified region (SCAR) markers. Two of these SCAR markers enabled us to detect S238N on roots of seedlings and mature trees. No amplification of non-fungal (host plant, bacterial, etc.) DNA was observed. Moreover, both SCARs were amplified from Laccaria-like mycorrhizas in a Douglas-fir plantation inoculated 14 years ago, demonstrating the long-term persistence of the inoculant strain. We also obtained a SCAR marker to detect one strain of European origin (L. bicolor 81306), indicating that SCARs are potential markers to type the naturally occurring genets. Thus, SCAR markers are of great value in studying the persistence of inoculant strains and the effects on local populations of introducing foreign strains.