Sequencing of the internal transcribed spacer region ITS1 as a molecular tool detecting variation in the Stylosanthes guianensis species complex

 The internal transcribed spacer (ITS) regions 1 and 2 of the ribosomal DNA from Stylosanthes guianensis CIAT 1283 and cv ‘Schofield’ were amplified by polymerase chain reaction using conserved ITS primers from the 18S, 5.8S and 26S ribosomal genes flanking those regions. The entire region of 683 bp long was cloned, and seven clones were sequenced. Comparison of the ITS spacer regions with published DNA sequences of other plant species revealed limited homology only; this was in contrast to their comparison with the 5.8S rDNA sequences. The ITS1 region of 45 S. guianensis accessions was amplified by PCR and sequenced on both strands using the conserved primers ITS2-ITS5. These sequences, ranging from 201 to 204 bp, were aligned to each other to assess intra-specific polymorphism. Within the S. guianensis (Aubl.) Sw. species complex, 11 DNA sequence types could be distinguished based on an insertion/deletion (indel) event and 15 single base-pair substitutions. In 1 of the S. guianensis types, two kinds of ITS1 sequence were observed in each individual, reminiscent of an incomplete homogenization of the repeat structure in this type. Polymorphisms in the sequence of the ITS1 region were used to define molecular markers for S. guianensis on the basis of PCR-restriction fragment length polymorphism and selective PCR. Received: 24 June 1997 / Accepted: 31 October 1997     

Molecular genetic delineation of Phaeocystis species (Prymnesiophyceae) using coding and non-coding regions of nuclear and plastid genomes

Sequence variation among 22 isolates representing a global distribution of the prymnesiophyte genus Phaeocystis has been compared using nuclear-encoded 18S rRNA genes and two non-coding regions: the ribosomal DNA internal transcribed spacer 1 (ITS1) separating the 18S rRNA and 5.8S rRNA genes and the plastid ribulose-1,5-bisphosphate carboxylase/oxygenase (RUBISCO) spacer flanked by short stretches of the adjacent large and small subunits (rbcL and rbcS). 18S rRNA can only resolve major species complexes. The analysis suggests that an undescribed unicellular Phaeocystis sp. (isolate PLY 559) is a sister taxon to the Mediterranean unicellular Phaeocystis jahnii; this clade branched prior to the divergence of all other Phaeocystis species, including the colonial ones. Little divergence was seen among the multiple isolates sequenced from each colonial species complex. RUBISCO spacer regions are even more highly conserved among closely related colonial Phaeocystis species and are identical in Phaeocystis antarctica, Phaeocystis pouchetii and two warm-temperate strains of Phaeocystis globosa, with a single base substitution in two cold-temperate strains of P. globosa. The RUBISCO spacer sequences from two predominantly unicellular Phaeocystis isolates from the Mediterranean Sea and PLY 559 were clearly different from other Phaeocystis strains. In contrast, ITS1 exhibited substantial inter- and intraspecific sequence divergence and showed more resolution among the taxa. Distinctly different copies of the ITS1 region were found in P. globosa, even among cloned DNA from a single strain, suggesting that it is a species complex and making this region unsuitable for phylogenetic analysis in this species. However, among nine P. antarctica strains, four ITS1 haplotypes could be separated. Using the branching order in the ITS1 tree we have attempted to trace the biogeographic history of the dispersal of strains in Antarctic coastal waters.     

PCR and sequencing from a single pollen grain

In order to eliminate the laborious step of DNA extraction preceding all studies within the field of plant molecular biology we attempted to do PCR amplifications directly on pollen grains. Successful PCR amplification was obtained in reactions including a single pollen grain from Hordeum vulgare or Secale strictum. Both the plastid gene encoding ribulose-1,5-biphosphate carboxylase/oxygenase (rbcL) and the nuclear-encoded internal transcribed spacer regions (ITS) and the 5.8S rDNA region were amplified and sequenced to verify PCR amplification.     

Development of a novel molecular marker on the mitochondrial genome of a toxic dinoflagellate, <Emphasis Type="Italic">Alexandrium</Emphasis> spp., and its application in single-cell PCR

Although the molecular data currently used for identifying dinoflagellates are generally limited to nuclear ribosomal RNA genes, some dinoflagellates cannot be identified by their gene sequence or morphotype, suggesting that additional effective molecular makers are required. We report here a novel species-specific marker on the mitochondrial (mt) genome of dinoflagellates belonging to six Alexandrium spp., namely, A. tamarense, A. catenella, A. tamiyavanichii, A. affine, A. hiranoi, and A. pseudogonyaulax. This new mt marker was able to clearly differentiate these six species. PCR analysis using a primer set for the A. tamarense-specific sequence confirmed that this sequence is conserved in A. tamarense strains but not in other dinoflagellate species. We also sequenced the mt genome containing the developed molecular marker using a single cell from a field sample, which suggests that this marker is a powerful tool for identifying unculturable dinoflagellates. The sequenced molecular region was also used to identify Alexandrium-like cells isolated from environmental seawater as A. tamarense and A. affine.     

ALLOPOLYPLOIDY IN NATURAL AND CULTIVATED POPULATIONS OF PORPHYRA (BANGIALES,RHODOPHYTA)1

To confirm whether allopolyploidy occurs in samples of previously identified Porphyra yezoensis Ueda, P. tenera Kjellm., and P. yezoensis × P. tenera from natural and cultivated populations, we examined these samples by using PCR‐RFLP and microsatellite analyses of multiple nuclear and chloroplast regions [nuclear regions: type II DNA topoisomerase gene (TOP2), actin‐related protein 4 gene (ARP4), internal transcribed spacer (ITS) rDNA and three microsatellite loci; chloroplast region: RUBISCO spacer]. Except for the ITS region, these multiple nuclear markers indicated that the wild strain MT‐1 and the cultivated strain 90‐02 (previously identified as P. yezoensis × P. tenera and cultivated P. tenera, respectively) are heterozygous and possess both genotypes of P. tenera and P. yezoensis in the conchocelis phase. Furthermore, gametophytic blades of two pure lines, HG‐TY1 and HG‐TY2 (F₁ strains of MT‐1 and 90‐02, respectively), were also heterozygous, and six chromosomes per single cell could be observed in each blade of the two pure lines. These results demonstrate that allopolyploidy occurs in Porphyra strains derived from both natural and cultivated populations, even though ITS genotypes of these strains showed homogenization toward one parental ITS.     

A technique for identifying the roots of different species in mixed samples using nuclear ribosomal DNA

Abstract. Question: Is it possible to determine the species composition of root samples containing multiple species, without first disentangling individual roots? Methods: The internal transcribed spacer (ITS) region of nuclear ribosomal DNA was amplified and sequenced from four California annual grassland species (two Poaceae and two Asteraceae). Restriction enzymes that cut the ITS region of each species into uniquely sized fragments were identified based on DNA sequence variation of the ITS regions. Mixed root samples were analysed to test the ability of the method to identify the presence or absence of each species in multi‐species samples. Results: The technique successfully identified species present in multi‐species samples. ITS regions were shorter in Poaceae than in Asteraceae, so size differences alone were sufficient to distinguish these taxonomic groups. At the species level, digestion of ITS regions with the appropriate restriction enzymes yielded at least one uniquely sized fragment for each species. Conclusions: This method is the first to identify the species composition of mixed root samples. It should be applicable to most plant species because the ITS region is flanked by universal primers and most species have unique ITS sequences. The ability to determine species‐specific rooting distributions has broad applications in vegetation science.     

DEVELOPMENT OF SEMI‐QUANTITATIVE PCR ASSAYS FOR THE DETECTION AND ENUMERATION OF GAMBIERDISCUS SPECIES (GONYAULACALES,DINOPHYCEAE)1

Ciguatera fish poisoning (CFP) is a serious health problem in tropical regions and is caused by the bioaccumulation of lipophilic toxins produced by dinoflagellates in the genus Gambierdiscus. Gambierdiscus species are morphologically similar and are difficult to distinguish from one another even when using scanning electron microscopy. Improved identification and detection methods that are sensitive and rapid are needed to identify toxic species and investigate potential distribution and abundance patterns in relation to incidences of CFP. This study presents the first species‐specific, semi‐quantitative polymerase chain reaction (qPCR) assays that can be used to address these questions. These assays are specific for five Gambierdiscus species and one undescribed ribotype. The assays utilized a SYBR green format and targeted unique sequences found within the SSU, ITS, and the D1/D3 LSU ribosomal domains. Standard curves were constructed using known concentrations of cultured cells and 10‐fold serial dilutions of rDNA PCR amplicons containing the target sequence for each specific assay. Assay sensitivity and accuracy were tested using DNA extracts purified from known concentrations of multiple Gambierdiscus species. The qPCR assays were used to assess Gambierdiscus species diversity and abundance in samples collected from nearshore areas adjacent to Ft. Pierce and Jupiter, Florida USA. The results indicated that the practical limit of detection for each assay was 10 cells per sample. Most interestingly, the qPCR analysis revealed that as many as four species of Gambierdiscus were present in a single macrophyte sample.     

IDENTIFICATION OF ALEXANDRIUM (DINOPHYCEAE) SPECIES USING PCR AND rDNA-TARGETED PROBES

A PCR (polymerase chain reaction)-based assay for the detection of Alexandrium species in cultured samples using rDNA-targeted probes was developed. The internal transcribed spacers 1 and 2 (ITS1 and ITS2) and the 5.8S ribosomal RNA gene (rDNA) from cultured isolates of A. tamarense (Lebour) Taylor, A. catenella (Whedon et Kofoid) Balech, A. fundyense Balech and A. lusitanicum Balech were amplified using PCR and sequenced. Sequence comparisons showed that the 5.8S and ITS1-ITS2 regions contain sequences specific for the Alexandrium genus, especially at the 3' end of the 5.8S coding region. PCR primers and a radioactive ³²P-labeled DNA probe were devised for this region. The cross-reactivity of the PCR primers and probe was tested against cultured isolates of Alexandrium and other dinoflagellates and diatoms. All the Alexandrium isolates screened reacted toward the genus-specific probe; in contrast, the other groups of microalgae (dinoflagellates and diatoms) did not react with the probe. Furthermore, the PCR amplification technique combined with the use of the rDNA-target probe allowed us to develop a method for the detection of Alexandrium cells in cultured samples. This PCR method might offer a new approach for the identification and enumeration of the HAB (harmful algal bloom) species present in natural phytoplankton populations.     

IDENTIFICATION OF PFIESTERIA PISCICIDA (DINOPHYCEAE) AND PFIESTERIA‐LIKE ORGANISMS USING INTERNAL TRANSCRIBED SPACER‐SPECIFIC PCR ASSAYS1

The putative harmful algal bloom dinoflagellate, Pfiesteria piscicida (Steidinger et Burkholder), frequently co‐occurs with other morphologically similar species collectively known as Pfiesteria‐like organisms (PLOs). This study specifically evaluated whether unique sequences in the internal transcribed spacer (ITS) regions, ITS1 and ITS2, could be used to develop PCR assays capable of detecting PLOs in natural assemblages. ITS regions were selected because they are more variable than the flanking small subunit or large subunit rRNA genes and more likely to contain species‐specific sequences. Sequencing of the ITS regions revealed unique oligonucleotide primer binding sites for Pfiesteria piscicida, Pfiesteria shumwayae (Glasgow et Burkholder), Florida “Lucy” species, two cryptoperidiniopsoid species, “H/V14” and “PLO21,” and the estuarine mixotroph, Karlodinium micrum (Leadbetter et Dodge). These PCR assays had a minimum sensitivity of 100 cells in a 100‐mL sample (1 cell·mL^?1) and were successfully used to detect PLOs in the St. Johns River system in Florida, USA. DNA purification and aspects of PCR assay development, PCR optimization, PCR assay controls, and collection of field samples are discussed.     

Whole genome amplification of Chelex-extracted DNA from a single mite: a method for studying genetics of the predatory mite Phytoseiulus persimilis

We developed and optimized a method using Chelex DNA extraction followed by whole genome amplification (WGA) to overcome problems conducting molecular genetic studies due to the limited amount of DNA obtainable from individual small organisms such as predatory mites. The DNA from a single mite, Phytoseiulus persimilis Athias-Henrot (Acari: Phytoseiidae), isolated in Chelex suspension was subjected to WGA. More than 1000-fold amplification of the DNA was achieved using as little as 0.03 ng genomic DNA template. The DNA obtained by the WGA was used for polymerase chain reaction followed by direct sequencing. From WGA DNA, nuclear DNA intergenic spacers ITS1 and ITS2 and a mitochondrial DNA 12S marker were tested in three different geographical populations of the predatory mite: California, the Netherlands, and Sicily. We found a total of four different alleles of the 12S in the Sicilian population, but no polymorphism was identified in the ITS marker. The combination of Chelex DNA extraction and WGA is thus shown to be a simple and robust technique for examining molecular markers for multiple loci by using individual mites. We conclude that the methods, Chelex extraction of DNA followed by WGA, provide a large quantity of DNA template that can be used for multiple PCR reactions useful for genetic studies requiring the genotypes of individual mites.     

Characterization of Variability in Some Pathogenic Species of Alternaria Based on the Nucleotide Sequence of Ribosomal DNA

The internal transcribed spacer (ITS) sequences within the ribosomal DNA (rDNA) region were targeted to delineate genetic variability among eight Alternaria species that cause economically important diseases in crops. The rDNA regions of Alternaria species comprising of rRNA genes and the ITS regions were cloned and sequenced. Phylogenetic relationship based on the rDNA sequences and PCR-RFLP of amplified rDNA sequences clustered eight species of Alternaria into three major groups. A. macrospora and A. helianthi accumulated wide genetic variations and are distantly related to rest of the six species which formed two major groups. Group I comprised of three species viz., A. dianthicola, A. brassicae and A. citri, while group II had A. longipes, A. porri and A. alternata. Incorporation of unique stretches of nucleotides and single nucleotide substitutions within relatively conserved ITS1 and ITS2 regions led to clustering of the members of Alternaria species in each group. The divergent sequences within the ITS regions can be employed to design species-specific PCR primer for use in molecular diagnostics.     

Phylogenetic analysis of the internal transcribed spacer region of Japanese Lilium species

 The DNA from 16 Lilium species and one variety endemic to or naturalized in Japan were obtained and their internal transcribed spacer regions of nuclear ribosomal DNA (nrDNA) were amplified by PCR and sequenced by cycle sequencing. Phylogenetic analysis of the ITS sequences supported the validity of Comber’s classification system. It has also provided molecular evidence for the transfer of Lilium dauricum to sect. Sinomartagon. The phylogenetic relationships revealed by ITS DNA analysis were supported by previously published crossability data. The molecular phylogeny of Japanese Lilium species was discussed with reference to the putative migration routes of these species. Received: 30 June 1998 / Accepted: 19 October 1998     

A NEW METHOD FOR OBTAINING NUCLEAR GENE SEQUENCES FROM FIELD SAMPLES AND TAXONOMIC REVISIONS OF THE PHOTOSYNTHETIC EUGLENOIDS LEPOCINCLIS (EUGLENA) HELICOIDEUS AND LEPOCINCLIS (PHACUS) HORRIDUS (EUGLENOPHYTA)1

One of the foremost issues in the field of algal taxonomy is the inability to acquire, grow, and sequence new taxa. This problem is particularly true in the study of photosynthetic euglenoids where most of the distinct taxa in culture collections have been sequenced, and many other taxa of interest have been resistant to culturing, and thus, sequencing. In an effort to address this problem, we have utilized a new technique, novel to the field of taxonomy, which allows for the sequencing of nuclear genes from a very small number of cells. Through this procedure, a DNA extraction followed by a multiple displacement amplification (MDA), taxa obtained by field collection had their genomic DNA (gDNA) amplified many fold to microgram quantities. The DNA was then used as template DNA for PCR reactions, and multiple nuclear genes were amplified successfully from several different taxa. By applying this procedure, we were able to shed new light on taxa that have been historically difficult to classify, resulting in the assignment of Euglena helicoideus (C. Bernard) M. S. Benn. et Triemer and Phacus horridus (Pochm.) M. S. Benn. et Triemer to the genus Lepocinclis.     

Taxon-specific oligonucleotide primers for detection of Glomus etunicatum

The 5.8S subunit and flanking internal transcribed spacer (ITS) regions in nuclear ribosomal DNA (rDNA) from spores of Glomus etunicatum MD107, MD127, TN101, and FL329 were amplified by polymerase chain reaction (PCR) using ITS1Kpn and ITS4Pst as primers. The amplification products (597, 599, 598, and 613 bp, respectively) were cloned and sequenced. The similarity among ITS region sequences from MD107, MD127, and TN101 was 99%, whereas the sequence similarity between the ITS regions of these three DNAs and that from FL329 was 91%. The 5.8S rDNA sequences of all four G. etunicatum isolates were identical. In contrast, major dissimilarities in the corresponding rDNA sequence regions of other glomalean taxa were observed. Oligonucleotide sequences unique to G. etunicatum were tested for their specificity in PCR amplification of genomic DNA from spores of 55 isolates comprising 29 glomalean fungi: 18 isolates of G. etunicatum, five G. intraradices, three G. claroideum, 16 other Glomus isolates, and 11 other glomalean taxa from each of four other genera. The G. etunicatum isolates were from a broad range of geographic regions and soils. The oligonucleotide pair GETU1:GETU2 primed specific amplification of an oligonucleotide sequence (approximately 400 bp) present in all G. etunicatum. This primer pair did not prime PCR when template consisted of DNA from any of the other glomalean fungi or any of the non-mycorrhizal controls, including roots of corn (Zea mays). In addition, the pair successfully detected G. etunicatum in nested PCR using a primary PCR product amplified from highly diluted extracts of colonized corn roots using modified ITS1:ITS4 primers. In the phylogenetic analysis of Glomus 5.8S and ITS2 rDNA region sequences, which included 500 bootstrap data sets, confidence in the G. etunicatum branch was very strong (90%) and clearly independent of G. claroideum and G. intraradices, to which it is very closely related. Accepted: 15 October 2000     

CONSPECIFICITY AND INDO-PACIFIC DISTRIBUTION OF SYMBIODINIUM GENOTYPES (DINOPHYCEAE) FROM GIANT CLAMS

We previously reported the occurrence of genetically‐diverse symbiotic dinoflagellates (zooxanthellae) within and between 7 giant clam species (Tridacnidae) from the Philippines based on the algal isolates' allozyme and random amplified polymorphic DNA (RAPD) patterns. We also reported that these isolates all belong to clade A of the Symbiodinium phylogeny with identical 18S rDNA sequences. Here we extend the genetic characterization of Symbiodinium isolates from giant clams and propose that they are conspecific. We used the combined DNA sequences of the internal transcribed spacer (ITS)1, 5.8S rDNA, and ITS2 regions (rDNA‐ITS region) because the ITS1 and ITS2 regions evolve faster than 18S rDNA and have been shown to be useful in distinguishing strains of other dinoflagellates. DGGE of the most variable segment of the rDNA‐ITS region, ITS1, from clonal representatives of clades A, B, and C showed minimal intragenomic variation. The rDNA‐ITS region shows similar phylogenetic relationships between Symbiodinium isolates from symbiotic bivalves and some cnidarians as does 18S rDNA, and that there are not many different clade A species or strains among cultured zooxanthellae (CZ) from giant clams. The CZ from giant clams had virtually identical sequences, with only a single nucleotide difference in the ITS2 region separating two groups of isolates. These data suggest that there is one CZ species and perhaps two CZ strains, each CZ strain containing individuals that have diverse allozyme and RAPD genotypes. The CZ isolated from giant clams from different areas in the Philippines (21 isolates, 7 clam species), the Australian Great Barrier Reef (1 isolate, 1 clam species), Palau (8 isolates, 7 clam species), and Okinawa, Japan (1 isolate, 1 clam species) shared the same rDNA‐ITS sequences. Furthermore, analysis of fresh isolates from giant clams collected from these geographical areas shows that these bivalves also host indistinguishable clade C symbionts. These data demonstrate that conspecific Symbiodinium genotypes, particularly clade A symbionts, are distributed in giant clams throughout the Indo‐Pacific.     

Label-free amperometric immunosensor for the detection of human serum chorionic gonadotropin based on nanoporous gold and graphene

Identifying a good transgenic event from the pool of putative transgenics is crucial for further characterization. In transgenic plants, the transgene can integrate in either single or multiple locations by disrupting the endogenes and/or in heterochromatin regions causing the positional effect. Apart from this, to protect the unauthorized use of transgenic plants, the signature of transgene integration for every commercial transgenic event needs to be characterized. Here we show an affinity-based genome walking method, named locus-finding (LF) PCR (polymerase chain reaction), to determine the transgene flanking sequences of rice plants transformed by Agrobacterium tumefaciens. LF PCR includes a primary PCR by a degenerated primer and transfer DNA (T-DNA)-specific primer, a nested PCR, and a method of enriching the desired amplicons by using a biotin-tagged primer that is complementary to the T-DNA. This enrichment technique separates the single strands of desired amplicons from the off-target amplicons, reducing the template complexity by several orders of magnitude. We analyzed eight transgenic rice plants and found the transgene integration loci in three different chromosomes. The characteristic illegitimate recombination of the Agrobacterium sp. was also observed from the sequenced integration loci. We believe that the LF PCR should be an indispensable technique in transgenic analysis.     

Algae or Protozoa: Phylogenetic Position of Euglenophytes and Dinoflagellates as Inferred from Mitochondrial Sequences

The chloroplasts of euglenophytes and dinoflagellates have been suggested to be the vestiges of endosymbiotic algae acquired during the process of evolution. However, the evolutionary positions of these organisms are still inconclusive, and they have been tentatively classified as both algae and protozoa. A representative gene of the mitochondrial genome, cytochrome oxidase subunit I (coxI), was chosen and sequenced to clarify the phylogenetic positions of four dinoflagellates, two euglenophytes and one apicomplexan protist. This is the first report of mitochondrial DNA sequences for dinoflagellates and euglenophytes. Our COXI tree shows clearly that dinoflagellates are closely linked to apicomplexan parasites but not with algae. Euglenophytes and algae appear to be only remotely related, with euglenophytes sharing a possible evolutionary link with kinetoplastids. The COXI tree is in general agreement with the tree based on the nuclear encoded small subunit of ribosomal RNA (SSU rRNA) genes, but conflicts with that based on plastid genes. These results support the interpretation that chloroplasts present in euglenophytes and dinoflagellates were captured from algae through endosymbioses, while their mitochondria were inherited from the host cell. We suggest that dinoflagellates and euglenophytes were originally heterotrophic protists and that their chloroplasts are remnants of endosymbiotic algae. Received: 24 March 1997 / Accepted: 21 April 1997     

Identification of insect cell lines and cell‐line cross‐contaminations by nuclear ribosomal ITS sequences

This report shows how the internal transcribed spacer (ITS) region of nuclear ribosomal DNA (rDNA) can be used to determine the species identity of insect cell lines and to distinguish between cell lines derived from closely related insect species. A PCR‐RFLP method with the endonucleases HincII and PstI produces restriction fragment profiles that could distinguish between insect cell lines at the species level. Another PCR‐based method used three species‐specific primer sets, Ly‐ITS1/Ly‐ITS2, ITS1‐1/Ld‐ITS1 and Sf9‐F2/ITS4, to identify the cell lines from Lymantria xylina, L. dispar and Spodoptera frugiperda, respectively. This method also detected cell‐line cross‐contaminations (CLCC) with contamination levels as low as 1% (10 cells in a population of 1000 cells) even when the contaminating cells were from a closely related species. Compared with conventional methods used for cell‐line identification and CLCC detection, the methods presented here are fast and sensitive and could easily be applied to other cell culture laboratories.     

A taxon-specific oligonucleotide probe for temperate zone soil isolates of Glomus mosseae

 The 5.8 S subunit and flanking internal transcribed spacer (ITS) regions in nuclear ribosomal DNA (rDNA) from spores of Glomus mosseae FL156 and UK118 were amplified by polymerase chain reaction (PCR) using ITS1 and ITS4 as primers. The amplification product from template DNA of UK118 was cloned and sequenced (569 bp); the amplified DNA from FL156 was sequenced directly (582 bp). There was a 95% sequence similarity between DNAs amplified from the two isolates; in contrast, major dissimilarities with partial sequences of seven other glomalean taxa were observed. Four oligonucleotide sequences unique to Glomus mosseae were identified as potential primers. Their specificity to Glomus mosseae was assessed by PCR amplification of genomic DNA from spores from 36 glomalean fungi: 13 isolates of Glomus mosseae, two Glomus monosporum, 10 other Glomus isolates, and 11 other glomalean taxa from each of four other genera. The Glomus mosseae isolates were from a broad range of temperate zone agricultural soils. Oligonucleotide pair GMOS1 : GMOS2 primed specific amplification of an oligonucleotide sequence (approximately 400 bp) present in all Glomus mosseae isolates and two isolates of the closely related Glomus monosporum. This primer pair did not prime PCR when the template consisted of DNA from any of the other glomalean fungi or any of the nonmycorrhizal controls. In addition, a 24-mer oligonucleotide, designated GMOS5, hybridized with Glomus mosseae and Glomus monosporum DNA amplified by PCR using primer pairs ITS1 : ITS4 and GMOS1 : GMOS2. Colony-blot assays showed that GMOS5 hybridized to 100% and 97% of E. coli pUC19 clones of amplification products from Glomus mosseae FL156 and UK118 DNA templates, respectively, indicating that nearly all clones contained an homologous sequence. GMOS5 was used successfully to detect specifically Glomus mosseae in DNA extracted from colonized sudan grass (Sorghum sudanense L.) roots and amplified by PCR using the primer pair GMOS1 : GMOS2. The results confirm several previous indications that Glomus mosseae and Glomus monosporum are indistinguishable taxonomic entities. Accepted: 14 February 1998     

Hypervariable spacer regions are good sites for developing specific PCR-RFLP markers and PCR primers for screening actinorhizal symbionts

While the ribosomal RNA like highly conserved genes are good molecular chronometers for establishing phylogenetic relationships, they can also be useful in securing the amplification of adjoining hyper-variable regions. These regions can then be used for developing specific PCR primers or PCR-RFL profiles to be used as molecular markers. We report here the use of ITS region ofrrn operon ofFrankia for developing PCR-RFL profiles capable of discriminating between closely related frankiae. We have also made use of the ITS 1 region of the nuclearrrn operon ofAlnus nepalensis (D Don) for designing a PCR primer for specific amplification of nuclear DNA of this tree.