Association of phytoplasmas with the decline of European hazel in southern Italy

In the Campania region of southern ltaly. commercial orchards of European hazel ( Corylus avellana ) are severely affected by yellowing and decline. To determine whether phytoplasmas are associated with the disorder, stem samples from diseased trees were examined using polymerase chain reaction assays. No visible products were obtained by amplification of sample DNA with universal and group-specific phytoplasma primers. However, when the products obtained with universal primers were re-amplified with nested primers that were specific for the fruit tree phytoplasmas of the apple proliferation group, most samples tested positively. Restriction site analysis revealed that the trees were infected with the apple proliferation, pear decline, and European stone fruit yellows phytoplasmas in about the same proportion. Some of the trees were doubly infected with one of the fruit tree phytoplasmas and the aster yellows agent. Most of the infected trees were also identified by hybridization of the products obtained in the initial amplification with suitable oligonucleotide probes.     

European stone fruit yellows phytoplasmas associated with a decline disease of apricot in southern England

Phytoplasmas detected by fluorescence microscopy and polymerase chain reaction (PCR) have been discovered infecting Prunus trees at a site in south-east England. The pathogens were detected in tissue samples taken in autumn and also in spring. The symptoms in infected trees varied from severe decline to absence. PCR experiments using group-specific primers to amplify regions of the 16S RNA gene indicated that the phytoplasmas are similar to European stone fruit yellows isolates occurring in southern and eastern Europe. This is the first record of phytoplasmas in Prunus species in the UK. The origin of the infection is unknown. The implications of this new disease for the fruit industry are discussed.     

Genetic comparison of the peach yellow leaf roll agent with European fruit tree phytoplasmas of the apple proliferation group

Restriction fragment length polymorphism (RFLP) analysis of PCR-amplified ribosomal DNA and Southern blot hybridization using cloned chromosomal DNA fragments from the apple proliferation (AP) phytoplasma as probes were used to investigate the genetic relationship of the California peach yellow leaf roll (PYLR) agent with phytoplasmas causing fruit tree diseases in Europe. This comparison showed that the California PYLR phytoplasma is closely related to apple proliferation (AP), pear decline, and European stone fruit yellows phytoplasmas and that it is a member of the phylogenetic AP group. The PYLR agent could clearly be distinguished from the AP and European stone fruit yellows phytoplasmas by Southern blot hybridization with DNA fragments from the AP phytoplasma and by RFLP analysis of ribosomal DNA employing Ssp I, Bsa AI, and Rsa I restriction endonucleases. However, the PYLR phytoplasma was indistinguishable from the pear decline agent by RFLP analysis of PCR-amplified ribosomal DNA.     

Detection and Indentification of European Stone Fruit Yellows and Other Phytoplasmas in Wild Plants in the Surroundings of Apricot Chlorotic Leaf Roll-affected Orchards in Southern France

Between 1994 and 1998 a field study was conducted to identify plant hosts of the European stone fruit yellows (ESFY) phytoplasma in two apricot growing regions in southern and southwestern France where the incidence of apricot chlorotic leaf roll was high. A total of 431 samples from 51 different plant species were tested for the presence of phytoplasmas by PCR using universal and ESFY-specific primers. ESFY phytoplasma was detected in six different wild growing Prunus species exhibiting typical ESFY symptoms as well as in symptomless dog rose bushes (Rosa canina), ash trees (Fraxinus excelsior) and a declining hackberry (Celtis australis). The possible role of these plant species in the spread of ESFY phytoplasma is discussed. PCR-RFLP analysis of ribosomal DNA amplified with the universal primers was carried out to characterize the other phytoplasmas found. Thus, elm yellows phytoplasma, alder yellows phytoplasma and rubus stunt phytoplasma were detected in declining European field elm trees (Ulmus carpinifolia Gled), in declining European alder trees (Alnus glutinosa) and in proliferating Rubus spp. respectively. The presence of rubus stunt phytoplasma in great mallow (Malva sylvestris) and dog rose was demonstrated for the first time. Furthermore, the stolbur phytoplasma was detected in proliferating field bindweed (Convolvulus arvensis) and a previously undescribed phytoplasma type was detected in red dogwood (Cornus sanguinea). According to the 16S rDNA-RFLP pattern this new phytoplasma belongs to the stolbur phytoplasmas group.     

Real-time PCR detection systems for Flavescence dorée and Bois noir phytoplasmas in grapevine: comparison with conventional PCR detection and application in diagnostics

A new real-time PCR detection system was developed for grapevine yellows (GY) using TaqMan minor groove binder probes and including two amplicons for group-specific detection of Flavescence dorée (FD) and Bois noir (BN) phytoplasmas, plus a universal phytoplasma amplicon. FD and BN amplicons were designed to amplify species-specific genomic DNA fragments and the universal amplicon to amplify the 16S ribosomal DNA region. Efficiency of PCR amplification, limit of detection, range of linearity and dynamic range were assessed for all three amplicons. The specificity of detection systems was tested on several other isolates of phytoplasmas and bacteria and on healthy field grapevine and insect samples. No cross-reactivity with other phytoplasma strains, plant or insect DNA was detected. The assay was compared with conventional PCR on more than 150 field grapevine, insect and field bindweed samples. Real-time PCR showed higher sensitivity as phytoplasmas were detected in several PCR-negative and in all PCR-positive samples. A data-mining analysis of results from both detection approaches also favoured real-time PCR over conventional PCR diagnostics. The developed procedure for detection of phytoplasmas in grapevine also included amplification of plant DNA co-extracted with phytoplasmic DNA, providing additional quality control for the DNA extraction and PCR amplification for each sample. The newly developed assay is a reliable, specific and sensitive method easily applicable to high-throughput diagnosis of GY.     

Molecular Identification of a New Member of the Clover Proliferation Phytoplasma Group (16SrVI) Associated with Centaurea Solstitialis Virescence in Italy

In the United States, yellow starthistle (Centaurea solstitialis) is an annual invasive weed with Mediterranean origins. Malformed plants displaying witches' broom, fasciations, abortion of buds and flower virescence symptoms were observed in central Italy. Attempts to transmit the causal agent from the natural yellow starthistle host to periwinkle by grafting, resulted in typical symptoms of a phytoplasma, i.e. yellowing and shortening of internodes. The detection of phytoplasmas was obtained from both symptomatic yellow starthistle and periwinkle by the specific amplification of their 16S-23S rRNA genes. PCR amplification of extracted DNA from symptomatic plant samples gave a product of expected size. Asymptomatic plants did not give positive results. An amplicon obtained by direct PCR with universal primers P1/P7 was cloned and sequenced. The homology search using CLUSTALW program showed more than 99% similarity with Illinois elm yellows (ILEY) phytoplasma from Illinois (United States) and 97% with Brinjal little leaf (BLL) phytoplasma from India. Digestion of the nested-PCR products with restriction enzymes led to restriction fragment length polymorphism patterns referable to those described for phytoplasmas belonging to the clover proliferation (16S-VI) group. Since this is a previously undescribed disease, the name Centaurea solstitialis virescence has been tentatively assigned to it. This is a new phytoplasma with closest relationships to ILEY and BLL, but distinguishable from them on the basis of 16S rDNA homology, the different associated plant hosts and their geographical origin.     

广东桉树黄化(丛枝)病植原体分子鉴定与检测

从表现黄化(丛枝)症状的桉树上采集病叶,抽提主脉总DNA,采用植原体通用引物与巢式引物进行PCR和巢式PCR扩增,对扩增产物进行克隆和序列测定,获得了植原体的近全长16S rRNA基因及部分16～23S rRNA基因间隔区序列.序列分析揭示,所获得的序列与已知植原体基因组相应区段的序列高度同源,与柳叶菜变叶植原体(epilobium phyllody)和白腊树丛枝植原体(ash witches'-broom)相应序列(GenBank登录号:AY101386和AY566302)同源率为99.9%,与白腊树黄化植原体(aster yellows BD2)相应序列和番茄巨芽植原体(tomato big bud)相应序列同源率分别为99.6%和99.3%.该序列构建的系统进化树表明,引起我国广州地区桉树黄化(丛枝)病的植原体属于16SrI组(即翠菊黄化组),将其暂命名为桉树黄化(丛枝)植原体广东株系(Eucalyp-tus yellowing and witches'-broom phytoplasma strain Guangdong,EYWB-Gd).建立了桉树植原体巢式PCR检测方法,对疑似病样及桉树组培苗进行了检测,多数疑似病样检测结果为阳性,供试的10株组培苗未发现阳性样品.     

Mapping the spread of apricot chlorotic leaf roll (ACLR) in southern France and implication of Cacopsylla pruni as a vector of European stone fruit yellows (ESFY) phytoplasmas

An epidemiological study on European stone fruit yellows (ESFY) phytoplasmas infecting Prunus fruit trees was carried out from 1994 to 2000 in Languedoc-Roussillon (southern France). The spread of the disease was monitored for 7 years by visual observation of symptoms and by PCR detection of the phytoplasma in an experimental orchard planted with apricot hybrid seedlings. This indicated that aerial vectors were responsible for disease spread, and that transmission rates were low at the beginning of the spread. Seventy thousand homopteran insects were captured within and in the surroundings of highly ESFY-infected apricot orchards, of which about 10 000 were used in PCR and nested-PCR assays with universal ribosomal and ESFY-specific nonribosomal primers to detect ESFY phytoplasmas. The other insects were confined in cages for trials of transmission to test plants. ESFY phytoplasmas could not be detected by PCR in any of the leafhopper species captured but could be detected in the psyllid Cacopsylla pruni caught on Prunus domestica and Prunus cerasifera rootstock suckers of apricot trees and on Prunus spinosa . Nested PCR revealed ESFY phytoplasmas in one individual of the deltocephalid Synophropsis lauri captured on an apricot tree. Transmission trials confirmed the role of Cacopsylla pruni as the ESFY phytoplasma vector in France. When apricot seedlings were used as bait plants from April to November during two consecutive years, no natural transmission could be demonstrated. However, one out of 50 apricot seedlings left for the whole year in the orchard became infected. An early spring ESFY infection is in agreement with both the natural transmission results and the life cycle of Cacopsylla pruni .     

Detection and identification of a phytoplasma from lucerne with Australian lucerne yellows disease

Foliar and root symptoms are described for Australian lucerne yellows (ALuY), a disease common in Australian lucerne seed crops. A phytoplasma was detected in plants exhibiting symptoms, but not in symptomless lucerne plants. Oligonucleotide primers specific to the phytoplasma 16S-23S rRNA intergenic spacer region (SR) were used in polymerase chain reaction (PCR) assays on DNA extracted from lucerne plants with and without symptoms. Identical restriction fragment length polymorphism (RFLP) enzyme profiles were obtained for PCR products amplified from 10 yellows-affected lucerne samples. RFLP profiles obtained for four restriction enzymes were different from those of the tomato big bud (TBB) phytoplasma. ALuY phytoplasma PCR products were sequenced to determine phylogeny and were found to fall within the faba bean phyllody phytoplasma group, or phytoplasma group 16srII. Transmission electron microscopy revealed phytoplasmas in the phloem of yellows-affected plant samples, but not in symptomless plant samples. Fungal, bacterial and viral agents in the aetiology of Australian lucerne yellows were ruled out.     

Fast and sensitive on-site isothermal assay (LAMP) for diagnosis and detection of three fruit tree phytoplasmas

Over the years, real-time PCR outflanked endpoint PCR in phytopathogen diagnostics, mainly because of the increase in sensitivity and timesaving aspects of the technique. However, a time consuming 16S rRNA-based nested PCR method is still the gold standard for phytoplasma diagnosis. This is also the case for phytoplasma detection in Malus, Pyrus and Prunus, the three main host plants of apple proliferation (AP), pear decline (PD) and European stone fruit yellows (ESFY) phytoplasma, respectively. The last decade, loop-mediated isothermal amplification (LAMP) (Notomi et al. 2000) is gaining a lot in significance and is also for phytoplasmas expected to become a widely used reliable diagnostic tool. High specificity and sensitivity which also requires a less stringent need for DNA purification, and the short analysis time and the limited equipment requirements makes the LAMP method a fast and affordable alternative with great point-of-care diagnostic potential. In this paper, we present a LAMP primer set for the ribosomal group 16SrX, containing the important fruit tree phytoplasmas AP, PD and ESFY. The primers were developed and validated for fast and sensitive detection and general use for diagnosis. We foresee that the LAMP technique will also have its application in on-site diagnosis of the fruit tree phytoplasmas during inspections and surveys.     

Molecular identification of a new phytoplasma associated with alfalfa witches'-broom in oman

ABSTRACT Alfalfa (Medicago sativa) plants showing witches'-broom symptoms typical of phytoplasmas were observed from Al-Batinah, Al-Sharqiya, Al-Bureimi, and interior regions of the Sultanate of Oman. Phytoplasmas were detected from all symptomatic samples by the specific amplification of their 16S-23S rRNA gene. Polymerase chain reaction (PCR), utilizing phytoplasma-specific universal primer pairs, consistently amplified a product of expected lengths when DNA extract from symptomatic samples was used as template. Asymptomatic plant samples and the negative control yielded no amplification. Restriction fragment length polymorphism profiles of PCR-amplified 16S-23S rDNA of alfalfa using the P1/P7 primer pair identified phytoplasmas belonging to peanut witches'-broom group (16SrII or faba bean phyllody). Restriction enzyme profiles showed that the phytoplasmas detected in all 300 samples belonged to the same ribosomal group. Extensive comparative analyses on P1/P7 amplimers of 20 phytoplasmas with Tru9I, Tsp509I, HpaII, TaqI, and RsaI clearly indicated that this phytoplasma is different from all the other phytoplasmas employed belonging to subgroup 16SrII, except tomato big bud phytoplasma from Australia, and could be therefore classified in subgroup 16SrII-D. The alfalfa witches'-broom (AlfWB) phytoplasma P1/P7 PCR product was sequenced directly after cloning and yielded a 1,690-bp product. The homology search showed 99% similarity (1,667 of 1,690 base identity) with papaya yellow crinkle (PapayaYC) phytoplasma from New Zealand. A phylogenetic tree based on 16S plus spacer regions sequences of 35 phytoplasmas, mainly from the Southern Hemisphere, showed that AlfWB is a new phytoplasma species, with closest relationships to PapayaYC phytoplasmas from New Zealand and Chinese pigeon pea witches'-broom phytoplasmas from Taiwan but distinguishable from them considering the different associated plant hosts and the extreme geographical isolation.     

Production of Monoclonal Antibodies against Apple Proliferation Phytoplasma and their Use in Serological Detection

Two monoclonal antibodies were obtained against the apple proliferation phytoplasma that provide easy, rapid, specific and sensitive serological detection. They reacted specifically by using ELISA and immunofluorescence techniques with apple proliferation-infected periwinkles and apple trees from different regions in northern Italy and Slovenia, but not with several other phytoplasma isolates. We did not observe any monoclonal antibody reaction even using phytoplasmas belonging to the same phylogenetic group such as European stone fruit yellows and pear decline. Two serological techniques, immunofluorescence and ELISA, were compared with DAPI staining and PCR. From July until leaf fall ELISA was as sensitive as PCR but was more rapid and convenient than PCR; immunofluorescence was useful for specific detection of apple proliferation phytoplasma on roots throughout the year. Serological techniques could be conveniently applied in the roots, stems and leaves of apple trees depending on specific phenological stages of the plants.     

Detection and characterization of phytoplasmas in diseased stone fruits and pear by PCR-RFLP analysis in Turkey

During the late summer-early autumn of 2002, surveys were carried out in Turkey to determine the presence of phytoplasma diseases in fruit trees. Phytoplasmas were detected and characterized by PCR-RFLP analysis and TEM technique in stone fruit and pear trees in the eastern Mediterranean region of the country. Six out of 24 samples, including almond, apricot, peach, pear and plum, gave positive results in PCR assays. RFLP analysis usingSspI andBsaAI enzymes of PCR products obtained with primer pair f01/r01 enabled identification of the phytoplasmas involved in the diseases. Stone fruit trees, including a local apricot variety (‘Sakıt’) and a pear sample, were found to be infected with European stone fruit yellows (ESFY, 16SrX-B) and pear decline (PD, 16SrX-C) phytoplasmas, respectively. This is the first report in Turkey of PD phytoplasma infecting pear and of ESFY phytoplasma infecting almond, apricot, myrobalan plum and peach; ESFY phytoplasma infecting Japanese plum was previously reported. http://www.phytoparasitica.org posting July 21, 2005.     

Differential detection and genetic relatedness of phytoplasmas in papaya

The genetic relatedness of phytoplasmas associated with dieback (PDB), yellow crinkle (PYC) and mosaic (PM) diseases in papaya was studied by restriction fragment length polymorphism (RFLP) analysis of the 16S rRNA gene and 16S rRNA/23S rRNA spacer region (SR). RFLP and SR sequence comparisons indicated that PYC and PM phytoplasmas were identical and most closely related to members of the faba bean phyllody strain cluster. By comparison the PDB phytoplasma was most closely related to Phormium yellow leaf (PYL) phytoplasma from New Zealand and the Australian grapevine yellows (AGY) phytoplasma from Australia. These three phytoplasmas cluster with the stolbur and German grapevine yellows (VK) phytoplasmas within the aster yellows strain cluster. Primers based on the phytoplasma tuf gene, which amplify gene products from members of the AY strain cluster, also amplified a DNA product from the PDB phytoplasma but not from either the PYC or PM phytoplasmas. Primers deduced from the 16S rRNA/SR selectively amplified rDNA sequences from the PDB and AGY phytoplasmas but not from other members of the stolbur strain cluster. Similarly, primers designed from 16S rRNA/SR amplified rDNA from the PYC and PM phytoplasmas but not from the PDB phytoplasma. These primers may provide for more specific detection of these pathogens in epidemiological studies.     

The occurrence of two phytoplasmas associated with stunted Rubus species in the UK

Polymerase chain reaction using universal primers to sequences in the 16S rRNA gene, and group-specific primers to sequences in the 16S/23S spacer region, revealed two distinct phytoplasmas occurring in Rubus plants showing symptoms of rubus stunt. One phytoplasma appeared similar to phytoplasmas in the elm yellows group; the other appeared to fall into the X disease group. This finding was confirmed by RFLP analysis of PCR products. This is the first identification of phytoplasmas from either of these groups occurring in the UK, and the first report of a phytoplasma belonging to the X disease group in Rubus .     

A phytoplasma closely related to the pigeon pea witches'-broom phytoplasma (16Sr IX) is associated with citrus huanglongbing symptoms in the state of São Paulo, Brazil

In February 2007, sweet orange trees with characteristic symptoms of huanglongbing (HLB) were encountered in a region of S?o Paulo state (SPs) hitherto free of HLB. These trees tested negative for the three liberibacter species associated with HLB. A polymerase chain reaction (PCR) product from symptomatic fruit columella DNA amplifications with universal primers fD1/rP1 was cloned and sequenced. The corresponding agent was found to have highest 16S rDNA sequence identity (99%) with the pigeon pea witches'-broom phytoplasma of group 16Sr IX. Sequences of PCR products obtained with phytoplasma 16S rDNA primer pairs fU5/rU3, fU5/P7 confirm these results. With two primers D7f2/D7r2 designed based on the 16S rDNA sequence of the cloned DNA fragment, positive amplifications were obtained from more than one hundred samples including symptomatic fruits and blotchy mottle leaves. Samples positive for phytoplasmas were negative for liberibacters, except for four samples, which were positive for both the phytoplasma and 'Candidatus Liberibacter asiaticus'. The phytoplasma was detected by electron microscopy in the sieve tubes of midribs from symptomatic leaves. These results show that a phytoplasma of group IX is associated with citrus HLB symptoms in northern, central, and southern SPs. This phytoplasma has very probably been transmitted to citrus from an external source of inoculum, but the putative insect vector is not yet known.     

Development and evaluation of a one‐hour DNA extraction and loop‐mediated isothermal amplification assay for rapid detection of phytoplasmas

A rapid DNA extraction and loop‐mediated isothermal amplification (LAMP) procedure was developed and evaluated for the detection of two specific groups of phytoplasmas from infected plant material. Primers based upon the 16–23S intergenic spacer (IGS) region were evaluated in LAMP assays for amplification of group 16SrI (aster yellows group) and group 16SrXXII (Cape St Paul wilt group) phytoplasma strains. DNA could be extracted from leaf material (16SrI phytoplasmas) or coconut trunk borings (16SrXXII phytoplasmas) onto the membranes of lateral flow devices, and small sections of these membranes were then added directly into the LAMP reaction mixture and incubated for 45 min at 65°C. Positive reactions were detected through the hydroxyl napthol blue colorimetric assay within 1 h of the start of DNA extraction, and were confirmed by subsequent agarose gel electrophoresis of the LAMP products. The level of detection was comparable to that obtained by nested PCR using conventional 16S rDNA phytoplasma‐specific primers. Furthermore, the assays were specific for the phytoplasmas they were designed to detect – the 16SrI assay only detected 16SrI phytoplasmas and not those from any other phylogenetic groups, whilst the 16SrXXII assay only detected 16SrXXII phytoplasmas. The DNA extractions and LAMP assay are easy to perform, requiring minimal equipment, and may therefore form the basis of a rapid and reliable field‐detection system for phytoplasmas.     

Identification of a phytoplasma causing yellows of Monarda

Monarda yellows occurring in southern Alberta was found to be associated with a phytoplasma. Using two pairs of universal primers, 16S ribosomal DNA fragments (about 1.5 and 1.2 kb) were amplified separately by polymerase chain reaction (PCR) from DNA samples that had been extracted from infected monarda. No such DNA bands were observed using DNA samples from uninfected monarda. The DNA fragment (1.2 kb) amplified by nested-PCR was analysed and compared with western aster yellows (AY27, Canada), eastern aster yellows (EAY, USA), French hydrangea aster yellows (AYHF), Belgium hydrangea aster yellows (AYHB), clover proliferation (CP, Canada) and potato witches'-broom (PWB, Canada) by means of restriction fragment length polymorphism (RFLP) using endonucleases Alu I, Mse I, Hpa II, Sau 3AI, Kpn I and Rsa I. The results showed that monarda yellows phytoplasma belongs to the aster yellows subclade and is different from CP and PWB. This is the first report of aster yellows phytoplasma infecting monarda.     

Electron Microscopy and Molecular Characterization of Phytoplasmas Associated with Strawflower Yellows in the Czech Republic

Strawflower (Helichrysum bracteatum) with symptoms resembling those associated to phytoplasma infection were observed in several areas in the Czech Republic during the period 1994–2001. Plants with leaf bronzing, reddening and necrosis, proliferation of secondary shoots, flower abnormalities and dwarfing died in advanced stages of the disease. The disease incidence ranged from 2% to 70% and caused significant loss to the flower and seed production. Transmission electron microscopy showed phytoplasmas in sieve cells of affected plants, but not in healthy ones. Association of phytoplasmas with the disease was confirmed by polymerase chain reaction using phytoplasma universal ribosomal primers R16F2n/R16R2. An amplification product of the expected size (1.2 kb) was observed in all samples of the symptomatic strawflowers. The restriction profiles obtained following separate digestion with three endonucleases (AluI, HhaI, MseI) showed that phytoplasmas infecting strawflowers from different localities in the Czech Republic were uniform and undistinguishable from aster yellows (subgroup 16SrI-B). Sequence analysis of 1771 bp of the ribosomal operon amplified with primers P1/U3, R16F2n/R2 and 16R758/P7 indicated that the closest related phytoplasmas were those associated with 'Rehmannia glutinosa var. purpurea', both originating from Bohemia. This is the first report on the occurrence of a phytoplasma-associated disease of strawflower in the Czech Republic.     

Use of terminal restriction fragment length polymorphism (T-RFLP) for identification of phytoplasmas in plants

A terminal restriction fragment analysis (T-RFLP) technique was developed for the simple and rapid detection and diagnosis of phytoplasmas in plants. The selected primers amplified part of the 23S rRNA gene to provide improved resolution between the taxonomic groups compared to conventional restriction enzyme analysis of the 16S rRNA. Using the restriction enzymes Bsh 12361 and Mse I on the PCR products, and fragment analysis in the range 68–640 bp, the technique was tested on 37 isolates from 10 of the 16Sr groups. Distinct and unambiguous T-RFLP profiles were produced for nine of the 10 taxonomic groups, such that almost all isolates within a group shared the same profile and could be distinguished from isolates in other groups. The technique also identified the presence of mixtures of phytoplasmas from different groups in samples. Furthermore, the primers were devised to amplify a terminal restriction fragment (TRF) product of a specific defined size (461 bp) from the host plant chloroplast DNA, so that there was a built-in internal control in the procedure to show that the absence of a phytoplasma peak in a sample was the result of no detectable phytoplasma being present, not the result of PCR inhibition. This method offers the possibility of simultaneously detecting and providing a taxonomic grouping for phytoplasmas in test samples using a single PCR reaction.