The isolation of Naegleria italica from Peru indicates that this potentially pathogenic species occurs worldwide

The amoeboflagellate genus Naegleria includes a few species that are virulent in experimental animals. One of these species, Naegleria italica, has been isolated from the environment only in Italy and Australia. I report here the isolation of a strain of N. italica from a water sample collected in Peru. This broadens the occurrence of this species to encompass three different continents. This new N. italica isolate from Peru has the same ITS1, 5.8S rDNA and ITS2 sequence as that of the type strain from Italy and the isolate from Australia. From the same water body in Peru a Naegleria strain was isolated that differs from N. italica by only one additional base pair in the ITS2 sequence. The maximum growth temperature tolerated by this particular isolate is 40 degrees C, which is different from that of N. italica, which is 42 degrees C.     

Analysis of the 5.8S rRNA gene and the internal transcribed spacers in Naegleria spp. and in N. fowleri

Internal transcribed spacers (ITS) and the 5.8S ribosomal gene of 21 Naegleria fowleri strains and eight other species including Naegleria gruberi were sequenced. The results showed that this region can help differentiate between and within species. The phylogeny of Naegleria spp. deduced from the ITS and the 5.8S gene produced four major lineages, fowleri-lovaniensis, galeacystis-italica-clarki-gruberi-australiensis, andersoni-jamiesoni, and pussardi, that fit perfectly with those inferred from the 18S rRNA gene analysis. The N. gruberi isolate, NG260, was closely related to Naegleria pussardi. The other N. gruberi isolates branched together with Naegleria australiensis in another lineage. The ITS and 5.8S results for N. fowleri were congruent with those previously deduced by RAPD analysis. The phylogenetic analysis inferred from ITS and RAPD data revealed two major groups. The French Cattenom and Chooz and South Pacific strains constituted the first group. The second group encompassed the strains corresponding to the Euro-American and Widespread RAPD variants and shared the same substitution in the 5.8S gene. In addition, it was possible to define species specific primers in ITS regions to rapidly identify N. fowleri.     

The amoeba-to-flagellate transformation test is not reliable for the diagnosis of the genus Naegleria. Description of three new Naegleria spp.

Trophozoites of several isolates from one location in Australia have failed consistently to transform into flagellates, although they display all other characteristics of the genus Naegleria. When changing the standard transformation test, flagellates were produced. In phylogenetic trees derived from partial small subunit ribosomal DNA (SSUrDNA) sequences, one of these strains branches close to a cluster comprising N. clarki, N. australiensis, N. italica and N. jadini. It is proposed that these Australian isolates represent a new species, named N. fultoni (strain NG885). Failing to form flagellates since their isolation, even when different transformation procedures are used, are two Naegleria strains from Chile and Indonesia. In SSUrDNA-based phylogenetic trees the Chilean strain clusters with N. pussardi and the Indonesian strain clusters with N. galeacystis, but the degree of sequence difference from these described species (3.5% and 2.2%, respectively) is sufficient to propose that both of the strains represent new species, named N. chilensis (strain NG946) and N. indonesiensis (strain NG945), respectively. The close relationships between each of the new species and the Naegleria species with which they cluster in SSUrDNA-based trees were confirmed by ribosomal internal transcribed spacer region (ITS) sequence comparisons. In France, several non-flagellating N. fowleri strains were isolated from one location. ITS rDNA sequence comparisons indicated that they correspond to a 'type' of N. fowleri found in both Europe and the USA. A redefinition of the genus Naegleria is proposed as a consequence of these and previous findings.     

Rapid, sensitive, and discriminating identification of Naegleria spp. by real-time PCR and melting-curve analysis

The free-living amoeboflagellate genus Naegleria includes one pathogenic and two potentially pathogenic species (Naegleria fowleri, Naegleria italica, and Naegleria australiensis) plus numerous benign organisms. Monitoring of bathing water, water supplies, and cooling systems for these pathogens requires a timely and reliable method for identification, but current DNA sequence-based methods identify only N. fowleri or require full sequencing to identify other species in the genus. A novel closed-tube method for distinguishing thermophilic Naegleria species is presented, using a single primer set and the DNA intercalating dye SYTO9 for real-time PCR and melting-curve analysis of the 5.8S ribosomal DNA gene and flanking noncoding spacers (ITS1, ITS2). Collection of DNA melting data at close temperature intervals produces highly informative melting curves with one or more recognizable melting peaks, readily distinguished for seven Naegleria species and the related Willaertia magna. Advantages over other methods used to identify these organisms include its comprehensiveness (encompassing all species tested to date), simplicity (no electrophoresis required to verify the product), and sensitivity (unambiguous identification from DNA equivalent to one cell). This approach should be applicable to a wide range of microorganisms of medical importance.     

Molecular definition and the ubiquity of species in the genus Naegleria

To investigate the variability within species of the genus Naegleria, the ITS1,5.8S and ITS2 rDNA were sequenced of several strains of N. lovaniensis and its Western Australian variants, N. australiensis, N. fowleri, N. andersoni, N. jamiesoni, N. tihangensis, N. pringsheimi, N. pagei, N. gruberi sensu lato and a Naegleria lineage that lost a group I intron from the SSUrDNA twintron. As a result, it is possible to define a molecular species within the Naegleria genus. In addition, one strain of each different allozyme cluster was sequenced to investigate whether they belong to described species or should be treated as distinct new species. This leads to the proposal of eleven new species. The sequencing results from those Naegleria spp. of which several strains are available indicate that these species are ubiquitous. The only exception might be the species represented by the WA variants. However, there are still many Naegleria spp. for which only one strain has been isolated, hence, it is important that the search for more isolates should be continued worldwide.     

Sequence Variation of Ribosomal Internal Transcribed Spacers (ITS) in Commercially Important Phytoseiidae Mites

Preliminary work is needed to assess the usefulness of different markers at different taxonomic scales when a new group is analyzed, such as the commercially important Phytoseiidae mites. We investigate here the level of sequence variation of the nuclear ribosomal spacers ITS 1 and 2 and the 5.8S gene in six species of Phytoseiidae: Neoseiulus californicus, N. fallacis, Euseius concordis, Metaseiulus occidentalis, Typhlodromus pyri and Phytoseiulus persimilis. As expected, the 5.8S gene (148 base pairs) is markedly conserved and displays little variation in between genera comparisons. ITS1 and ITS2 show contrasting patterns: while the ITS2 is short (80–89 bp) and shows little variation, the ITS1 is longer (303–404 bp) and is very variable in sequence. This fact compromises reliable nucleotide homologies when comparing the genera. The comparison of ITS1 sequence similarity at the species level might be useful for species identification, however, the value of ITS in taxonomic studies does not extend to the level of the family. The intraspecific variations of ITS were investigated in three species: N. californicus, N. fallacis and E. concordis. The first species has identical ITS1 sequences and the last two display low polymorphism (2 nucleotide substitutions). The ITS2 and 5.8S sequences were identical in all three subspecies comparisons.     

Detection of Naegleria sp. in a thermal, acidic stream in Yellowstone National Park

An initial survey of sequences of PCR-amplified portions of the 18S rRNA genes from a community DNA clone library, prepared from an algal mat in a thermal, acidic stream in Yellowstone National Park, WY, USA, revealed among other sequences, several that matched Vahlkampfia. This finding prompted further investigation using primers specific for Naegleria. Sequences from a subsequent DNA clone library, prepared from the 5.8S rRNA gene and the adjacent internal transcribed spacer (ITS) regions of the rRNA, closely matched Naegleria and formed an independent lineage within a clade containing Naegleria sturti and Naegleria niuginiensis. The sequences may represent a new Naegleria species.     

人工栽培蛹虫草退化现象的分子分析*

利用PCR-RFLP和RAPD方法对野生驯化蛹虫草及其退化菌种进行了基因水平的分析。PCR-RFLP实验,采用真菌通用引物ITS1和ITS4,扩增出5.8S和其两端的两个转录间隔区(ITS),选用5种识别四个碱基的内切酶(HaeIII、AfaI、TagI、AluI和XspI),其中只XspI酶切结果在两个菌种中存在差异,进一步测序表明,整个片段全长534bp,共有13个位点发生碱基突变,且都为c转换为t。RAPD实验,选用4组计80个随机引物进行PCR扩增,共筛选出9个对所有供试个体均存在明显差异的引物。结果表明了退化菌株较野生驯化菌株在DNA水平上发生了频率较高的突变,这些突变可能直接与导致菌种退化的基因相关联。     

帘蛤科贝类rDNA内转录间隔区序列的研究

根据18SrDNA、5．8SrDNA和28SrDNA保守序列设计引物,应用聚合酶链式反应（PCR）扩增了文蛤（Meretrix meretrix L．）、青蛤（Cyclina sinensis G）、硬壳蛤（Mercenaria mercenaria L．）和江户布目蛤（Protothaca jedoensis L．）4种帘蛤科贝类的第一内转录间隔区（ITS1）和第二内转录间隔区（ITS2）序列,并进行了测序。结果表明,文蛤、青蛤、硬壳蛤和江户布目蛤的ITS1扩增产物大小分别为978bp、663bp、757bp和942bp,GC含量分别为61．55％、60．78％、62．48％和64．86％～64．97％,其中ITS1序列长度分别为900bp、585bp、679bp和864bp,是迄今已报道双壳贝类中变化范围最大的,GC含量分别为61．67％、61．03％、63．03％和65．51％～65．62％,江户布目蛤种内ITS1序列有个体差异;ITS2扩增产物大小分别为644bp、618～620bp、593bp和513～514bp,GC含量分别为61．18％、61．29％～61．81％、62．73％和61．48％61．60％,其中ITS2序列长度分别为412bp、386～388bp、361bp和281～282bp,GC含量分别为65．29％、65．21％～66．06％、67．87％和67．38％～67．62％,青蛤和江户布目蛤种内ITS2序列有个体差异。4种蛤ITS1和ITS2序列种间差异很大,有明显的长度多态性,ITS2种间序列相似度73．0％～89．1％,与ITS1的种间序列相似度48．7％～81．5％相比略高。此外,在4种蛤ITS1和ITS2序列中各发现2个与rRNA加工有关的保守区。通过对ITS1和ITS2序列的组装获得了4种蛤5．8SrRNA基因完整序列,序列长度都是157bp,GC含量57．96％～58．60％,4种蛤5．8SrRNA基因相对保守,种间序列差异度0-6．0％,共有10个变异位点,其中转换4处,颠换6处,硬壳蛤和江户布目蛤5．8SrRNA基因序列完全相同。以ITS2序列（包含5．8SrRNA和28SrRNA基因部分序列）为标记,调用北极蛤科的Arctica islandica相应序列数据作外群,构建了帘蛤科贝类的系统发育树,其拓扑结构显示江户布目蛤与硬壳蛤亲缘关系最近,青蛤与其他3物种的亲缘关系最远。     

Length Variation of the Nuclear Ribosomal DNA Internal Transcribed Spacer in the Genus Abies,with Reference to Its Systematic Utility in Pinaceae

The internal transcribed spacer (1TS) region (1TS1, ITS2 and 5.8S rDNA) of the nuclear ribosomal DNA (nrDNA) was amplified via PCR in 28 taxa of Abies Mill. The amplified fragments showed length polymorphism among species, with species from Central America and two species from North America having a length of approximately 2 500 base pairs (bp) and the remaining taxa having a length of approximately 1 700 bp based on 100 bp and 1 kb ladder standard markers. The complete sequencing of ITS of Abies bracteata showed that the shorter type is 1 697 bp (1TS1 is 1 296 bp, 5.8S + 1TS2 is 401 bp). For the longer one, the partial rrs1 and complete 5.8S + ITS2 sequencing revealed that thelength of 5.8S + ITS2 is the same as that of the shorter type. The length difference of ITS in Abies is mainly due to the length difference in the ITS1 region, a result similar to the previous findings in other genera of Pinaceae. Variation in ITS length seems well correlated with morphological and geographic characters in Abies, suggesting that the length variation may be a phylogenetically informative character within the genus, long ITS was also found in other genera of Pinaceae in the previous studies. The long length of ITS in the family makes the sequencing of the region and subsequent alignment of sequences among species or genera more difficult than in taxa with short ITS, such as angiosperms. Although the length variation of ITS in the genus Abies is significant, the homogenous of ITS sequence between the longer one and the shorter one is obvious if the insertion in the longer ITS is ignored.     

海洋喇叭虫rRNA基因18S-ITS1序列及其系统发育分析

海洋喇叭虫Maristentor dinoferus 1996年在关岛(Guam)的珊瑚暗礁上被发现,至今尚未阐明其确切的系统发育地位.克隆到的海洋喇叭虫的18S-ITS1-5.8S rDNA序列包括222 bp的18S序列,77 bp的ITS1序列和22 bp的5.8S序列.比较分析了纤毛虫主要类群的ITS1序列后得出:短的ITS1序列可能是异毛类纤毛虫的特征.根据18S序列,利用邻接法构建,最大简约法和最大似然法构建系统发育树.其拓扑结构显示海洋喇叭虫属于异毛纲纤毛虫,但并不隶属喇叭虫科,应予以新的分类地位.     

Genetic Variations in the Internal Transcribed Spacer and Mitochondrial Small Subunit rRNA Gene of Naegleria spp.

ABSTRACT: Naegleria spp. are widely distributed free-living amebas, but one species in the genus, N. fowleri , causes acute fulminant primary amebic meningoencephalitis in humans and other animals. Thus, it is important to differentiate N. fowleri from the rest in the genus of Naegleria , and to develop tools for the detection of intra-specific genetic variations. In this study, one isolate each of N. australiensis, N. gruberi, N. jadini , and N. lovaniensis and 22 isolates of N. fowleri were characterized at the internal transcribed spacers (ITS) and mitochondrial small subunit rRNA (mtSSU rRNA) gene. The mtSSU rRNA primers designed amplified DNA of all isolates, with distinct sequences obtained from all species examined. In contrast, the ITS primers only amplified DNA from N. lovaniensis and N. fowleri , with minor sequence differences between the two. Three genotypes of N. fowleri were found among the isolates analyzed in both the mtSSU rRNA gene and ITS. The extent of sequence variation was greater in the mtSSU rRNA gene, but the ITS had the advantage of length polymorphism. These data should be useful in the development of molecular tools for rapid species differentiation and genotyping of Naegleria spp.     

金针菇rDNA序列结构特征分析

rDNA序列中的ITS作为DNA barcoding广泛应用于真菌的系统发育与物种辅助鉴定,IGS被认为可以用于种内水平不同菌株的鉴别。食用菌中还没有完整的rDNA序列的报道。本研究采用二代和三代测序技术分别对金针菇单核菌株“6-3”进行测序,用二代测序的数据对三代测序组装得到的基因组序列进行修正,得到一个在基因完整性、连续性和准确性均较好的基因组序列,对比Fibroporia vaillantii rDNA序列,获得金针菇完整的rDNA序列。金针菇rDNA序列结构分析表明,它有8个rDNA转录单元,长度均为5 903bp,有9个基因间隔区,其长度有较大差异,3 909-4 566bp。rDNA转录单元中,各元件的序列长度分别为：18S rDNA 1 796bp、ITS1 234bp、5.8S rDNA 173bp、ITS2 291bp、28S rDNA 3 410bp。基因间间隔区中,IGS1 1 351-1 399bp、5S rDNA 124bp、IGS2 2 435-3 092bp。金针菇的5S、5.8S、18S、28S rDNA序列准确性得到转录组数据的验证,也得到系统发育分析结果的支持。多序列比对发现,不同拷贝的基因间间隔区序列（IGS1和IGS2）存在丰富的多态性,多态性来源于SNP、InDel和TRS（串联重复序列）,而TRS来源于重复单元的类型和数量。9个基因间间隔区之间,IGS1只有少量的SNP和InDel,IGS2不仅有SNP和InDel,还有TRS。本研究结果提示,在应用IGS进行种内水平不同菌株之间的鉴别时,需要选取不同拷贝之间的保守IGS序列。     

Rapid, Sensitive, and Discriminating Identification of Naegleria spp. by Real-Time PCR and Melting-Curve Analysis

The free-living amoeboflagellate genus Naegleria includes one pathogenic and two potentially pathogenic species (Naegleria fowleri, Naegleria italica, and Naegleria australiensis) plus numerous benign organisms. Monitoring of bathing water, water supplies, and cooling systems for these pathogens requires a timely and reliable method for identification, but current DNA sequence-based methods identify only N. fowleri or require full sequencing to identify other species in the genus. A novel closed-tube method for distinguishing thermophilic Naegleria species is presented, using a single primer set and the DNA intercalating dye SYTO9 for real-time PCR and melting-curve analysis of the 5.8S ribosomal DNA gene and flanking noncoding spacers (ITS1, ITS2). Collection of DNA melting data at close temperature intervals produces highly informative melting curves with one or more recognizable melting peaks, readily distinguished for seven Naegleria species and the related Willaertia magna. Advantages over other methods used to identify these organisms include its comprehensiveness (encompassing all species tested to date), simplicity (no electrophoresis required to verify the product), and sensitivity (unambiguous identification from DNA equivalent to one cell). This approach should be applicable to a wide range of microorganisms of medical importance.     

Study on Sequences of Ribosomal DNA Internal Transcribed Spacers of Clams Belonging to the Veneridae Family (Mollusca: Bivalvia)

The first and second internal transcribed spacer (ITS1 and ITS2) regions of the ribosomal DNA from four species, Meretrix meretrix L., Cyclina sinensis G., Mercenaria mercenaria L., and Protothaca jedoensis L., belonging to the family Veneridae were amplified by PCR and sequenced. The size of the ITS1 PCR amplification product ranged from 663 bp to 978 bp, with GC contents ranging from 60.78% to 64.97%. The size of the ITS1 sequence ranged from 585 bp to 900 bp, which is the largest range reported thus far in bivalve species, with GC contents ranging from 61.03% to 65.62%. The size of the ITS2 PCR amplification product ranged from 513 bp to 644 bp, with GC contents ranging from 61.29% to 62.73%. The size of the ITS2 sequence ranged from 281 bp to 412 bp, with GC contents ranging from 65.21% to 67.87%. Extensive sequence variation and obvious length polymorphisms were noted for both regions in these species, and sequence similarity of ITS2 was higher than that of ITS1 across species. The complete sequences of 5.8S ribosomal RNA gene were obtained by assembling ITS1 and ITS2 sequences, and the sequence length in all species was 157 bp. The phylogenetic tree of Veneridae clams was reconstructed using ITS2-containing partial sequences of both 5.8S and 28S ribosomal DNA as markers and the corresponding sequence information in Arctica islandica as the outgroup. Tree topologies indicated that P. jedoensis shared a close relationship with M. mercenaria and C. sinensis, a distant relationship with other species.     

Sequence analysis of the ribosomal DNA internal transcribed spacer region in some scallop species (Mollusca: Bivalvia: Pectinidae).

The internal transcribed spacer (ITS) region of the ribosomal DNA from the European scallops Aequipecten opercularis, Mimachlamys varia, Hinnites distortus, and Pecten maximus was PCR amplified and sequenced. For each species, three or five clones were examined. The size ranged between 636 and 713 bp (ITS1, 209-276 bp; 5.8S rRNA gene, 157 bp; ITS2, 270-294 bp) and GC content ranged between 47 and 50% (ITS1, 43-49%; 5.8S rRNA gene, 56-57%; ITS2, 44-49%). Variation within repeats was minimal; only clones from M. varia and P. maximus displayed a few variable sites in ITS2. Among scallops, including Chlamys farreri whose ITS sequence appears in databases, significant variation was observed in both ITS1 and ITS2. Phylogenetic analysis using ITS1, ITS2, or both spacer sequences always yielded trees with similar topology. Aequipecten opercularis and P. maximus grouped in one clade and the other three scallops (C. farreri, M. varia, and H. distortus) in another, where M. varia and H. distortus are the more closely related species. These results provide new insights into the evolutionary relationships of scallop species and corroborate the close evolutionary relationship between the tribes Aequipectinini and Pectinini previously deduced from 18S rDNA sequences.     

Primers are designed for amplification and direct sequencing of ITS region of rDNA from Myxomycetes

Four new primers were designed, based on comparison of Physarum polycephalum sequences retrieved from Genbank (primers PHYS-5 and PHYS-4) and our own sequences (primers PHYS-3 and PHYS-2), to amplify the ITS regions of rDNA, including the 5.8S gene segment from Lamproderma species. Sequencing analysis shows that Lamproderma contains ITS1-5.8S-ITS2 regions of approximately 900 bp, which is similar in size to most eukaryotes. However, the corresponding region in another common myxomycete, Fuligo septica, is more than 2000 bp due to the presence of large direct-repeat motifs in ITS1. Myxomycete rDNA ITS regions are interesting both as phylogenetic markers in taxonomic studies and as model sequences for molecular evolution.     

Molecular identification of free-living amoebae of the Vahlkampfiidae and Acanthamoebidae isolated in Arizona (USA)

Sediment samples from rivers, canals and lakes in Arizona (USA) were cultured for free-living amoebae at three different incubation temperatures (22, 37 and 40 degrees C). Isolates belonging to the Vahlkampfiidae were identified by sequencing the PCR-amplified ITS1, 5.8S and ITS2 rDNA. With this molecular method three Naegleria spp. were identified, N. gruberi sensu stricto, N. australiensis and N. tihangensis. Also a strain each of Willaertia magna and Vahlkampfia avara were identified. Three samples yielded two new Tetramitus spp. of which the closest relative is T. ovis. Many Acanthamoeba strains were also isolated. The genotype of these strains was identified using Acanthamoeba-specific primers (JDP1 and JDP2) amplifying a part of the SSUrDNA and sequencing with an internal primer (892c). Five of the Acanthamoeba isolates belong to genotype T5 (A. lenticulata), while five are genotype T4.     

Torulaspora maleeae sp. nov., a novel ascomycetous yeast species from Japan and Thailand

Nine strains of a new Torulaspora species were isolated from natural samples collected in Japan and Thailand including one strain obtained from a leaf of Rhizophora stylosa (NBRC 11061T), one strain from soil (NBRC 11062), six strains from mosses (ST-14, ST-266, ST-510, ST-511, ST-513 and ST-581) and one strain from sediment in mangrove forest (RV-51). On the basis of morphological, biochemical, physiological and chemotaxonomic characteristics, and the sequence analyses of the D1/D2 domain of the large subunit (LSU) rRNA gene and the internal transcribed spacer (ITS) (ITS1-5.8S rRNA gene-ITS2) region, the nine strains were found to represent a single novel species of the genus Torulaspora, which were named Torulaspora maleeae sp. nov. The type strain is NBRC 11061T (BCC 25515T=CBS 10694T). In the phylogenetic trees based on the sequences of the D1/D2 domain of the LSU rRNA gene, T. maleeae showed a close relationship with the five recognized species of the genus Torulaspora, Torulaspora delbrueckii, Torulaspora franciscae, Torulaspora globosa, Torulaspora microellipsoides and Torulaspora pretoriensis. Torulaspora maleeae differed from the five recognized species of the genus Torulaspora by six to 12 nucleotide substitutions (1.1-2.1%) in the D1/D2 domain of the LSU rRNA gene and by 6.4-11.7% nucleotide substitutions in the ITS (ITS1-5.8S rRNA gene-ITS2) region.