Dasineura oxycoccana (Johnson) (Diptera: Cecidomyiidae) from cranberry Vaccinium macrocarpon is similar morphologically to D. oxycoccana from blueberry V. corymbosum, but a recent study revealed that individuals from cranberry do not mate with those from blueberry. To seek genetic differences between D. oxycoccana from cranberry (common name cranberry tipworm) and from blueberry (common name blueberry gall midge), we compared a 559-bp region of the mitochondrial cytochrome oxidase I (COI) gene from 65 individuals. Analysis of the COI sequences based on general time reversible with gamma distribution (GTRG) distance model revealed 10.7–13.1% divergence between cranberry tipworm and blueberry gall midge, whereas little divergence was observed within cranberry tipworm (0– 1.2%) or blueberry gall midge (0–1.3%) sequences. In neighbour-joining analysis, conducted for species identification, blueberry gall midge sequences generated in this study clustered with known D. oxycoccana sequences from National Council of Biotechnology (NCBI), but the cranberry tipworm sequences grouped into a separate cluster. To identify and discriminate cranberry tipworm and blueberry gall midge, we developed diagnostic PCR primers based on COI sequence differences. In a duplex PCR assay, these primers successfully discriminated D. oxycoccana originating from cranberry or blueberry. The concordance between data from our genetic studies and data from mating experiments by Cook et al. (2011) suggests cryptic speciation in D. oxycoccana populations on cranberry and blueberry.
The gall midge Dasineura oxycoccana (Johnson) (Diptera: Cecidomyiidae) has been recorded in North America from cultivated Vaccinium species including cranberry V. macrocarpon (Gagné 1989; Landry et al. 2002; Mahr 2005); highbush blueberry V. corymbosum (Sampson et al. 2002; Yang 2005); rabbiteye blueberry V. ashei (Lyrene and Payne 1995; Sarzynski & Liburd 2003); and lowbush blueberry V. angustifolium (Dernisky et al. 2005). On cranberry, D. oxycoccana is commonly called cranberry tipworm; on blueberry, it is called blueberry gall midge (Sampson et al. 2006; Fitzpatrick 2009). Recently, blueberry gall midge has been reported on highbush blueberries in Italy (Bosio et al. 1998) and in Britain (Collins & Eyre 2010; Collins et al. 2010). On cranberry and blueberry, adult female D. oxycoccana oviposit in developing buds, and larvae feed on meristem tissue within the buds. Larval damage to buds can result in serious economic loss to the crop (Sampson et al. 2002; Mahr 2005).
In British Columbia, Canada, the first records of economic damage caused by D. oxycoccana came from young highbush blueberry plants east of Mission (49°12′58″N, 122°14′11″W ) in 1991 (Fitzpatrick, unpublished). Adults reared from field-collected larvae were identified by R. J. Gagné (R. J. Gagné, USDA, Systematic Entomology Lab c/o Smithsonian Institution, personal communication). In 1991, D. oxycoccana was also observed on highbush blueberry in Richmond, British Columbia, Canada, (49°10′16″N, 123°5′40″W) but was not present on nearby cranberry farms (Fitzpatrick, unpublished). In 1998, D. oxycoccana was detected for the first time on cranberry in BC, in Pitt Meadows (49°13′15″ N, 122°41′25″W) (British Columbia Ministry of Agriculture and Lands 2009). This insect is now widespread on highbush blueberry and cranberry in BC, and is of particular concern to cranberry growers, who wish to know if blueberry farms are the source of D. oxycoccana infestation on cranberry.
A recent study of phenology, life history and reproductive behavior of D. oxycoccana on cranberry and blueberry in BC revealed differences in characteristics of this insect on the 2 crops (Cook 2011; Cook et al. 2011). Under controlled conditions, D. oxycoccana from cranberry (cranberry tipworm) did not mate with D. oxycoccana from blueberry (blueberry gall midge) (Cook et al. 2011). This result suggests that, although D. oxycoccana infesting cranberry and blueberry are virtually identical morphologically, the 2 populations probably represent cryptic species (Cook et al. 2011); that is, 2 distinct species classified as a single nominal species because they are morphologically indistinguishable (Bickford et al. 2007).
Accurate species identifications are crucial for the identification of invasive and pest species (Bickford et al. 2007). In the case of D. oxycoccana in BC, results from Cook et al. (2011) raise the possibility that cranberry tipworm arrived later than blueberry gall midge, possibly as a hitchhiker on plant material from other cranberry-growing regions. To further explore the relationship between D. oxycoccana on cranberry and blueberry in British Columbia, we examined the cytochrome oxidase I (COI) region of mitochondrial DNA, which is a popular marker for studying differences among populations or host races (Kambhampati & Smith 1995; Shirota et al. 1999; Sperling et al. 1999). DNA barcodes from the COI region have been used in many studies to successfully diagnose cryptic diversity (Hebert et al. 2004; Smith et al. 2006; Li et al. 2010; Lumley & Sperling 2010).
Here we show differences between the COI region of the mitochondrial gene of D. oxycoccana reared from cranberry farms and COI region of D. oxycoccana reared from highbush blueberry farms in British Columbia. Based on these genetic differences, we developed diagnostic primers to detect and differentiate D. oxycoccana originating from cranberry or blueberry.
MATERIALS AND METHODS
Insects
Cranberry (V. macrocarpon) shoots infested with cranberry tipworm larvae and highbush blueberry (V. corymbosum) shoots infested with blueberry gall midge larvae were collected from 3 cranberry and 2 blueberry farms in Pitt Meadows, British Columbia, Canada in 2009 and 2010. To rear cranberry tipworm larvae to adult, infested cranberry shoots were placed individually into containers made from 2 glass scintillation vials, such that the stem end of the shoot pierced a parafilm seal and rested in water, while the infested tip was covered with an inverted scintillation vial. Infested blueberry shoots were placed on moist soil (60% peat 40% perlite) in 1-liter plastic buckets covered with a chiffon screen (mesh approx. 40/ cm) and moist paper towel. All reared insects were maintained at 21 ∓ 2 °C under fluorescent lighting at 16:8 h L:D. Emerged adults were stored in 70% ethanol for identification by Sinclair or in 95% ethanol for DNA extraction by Mathur. Voucher specimens were deposited at the Canadian National Collection (CNC) of Insects, Agriculture and Agri-Food Canada, Ottawa, Ontario, Canada.
Isolation of Genomic DNA
Genomic DNA was isolated from individual cranberry tipworm and blueberry gall midge adults with a DNeasy tissue kit® (Qiagen Inc., Mississauga, Ontario). Ten to 16 individuals from each farm (total 34 individuals from cranberry and 31 from blueberry) were used for DNA extraction. Each insect was air dried to remove ethanol, homogenized using a disposable microtube pestle (Mandel Scientific Company Inc., Guelph, Ontario) in the extraction buffer provided with the kit, and then processed using the manufacturer's proprietary protocol. DNA was eluted in 50 µL eluting buffer and stored at -80 °C for further use.
Polymerase Chain Reaction (PCR) and Sequencing of DNA
The COI region of the mitochondrial genome of cranberry tipworm and blueberry gall midge was amplified by PCR using the universal insect primer set, LCO 1490 (5′GGTCAACAAATCATAAAGATATTGG) and HCO 2198 (5′TAAACTTCAGGGTGACCAAAAAATCA) (Folmer et al. 1994). The 50-µL reaction mix contained 1X PCR buffer solution (GeneSys Ltd., Medicorp Inc., Montreal, Quebec), 0.2 mM of dNTPs, 0.2 µM of each primer, 1.25 U of Taq DNA polymerase (GeneSys Ltd., Medicorp Inc., Montreal, Quebec), and 30–50 ng of DNA template. DNA amplification was performed using a thermal cycler (iCycler, Bio-Rad Laboratories (Canada) Ltd., Mississauga, Ontario). The amplification conditions for all PCR reactions were as follows: an initial denaturing step of 2 min at 94 °C followed by 35 cycles consisting of 30 s at 94 °C, 45 s at 50 °C, 60 s at 72 °C, and a final extension step of 7 min at 72 °C. The amplified fragment was analyzed in a 1.5% agarose gel by electrophoresis in IXTBE buffer (90 mM Tris-borate, 2 mM EDTA), using 2 µL of the PCR mixture, then followed by staining with ethidium bromide (0.5 µg/ mL) and visualizing with a UV transilluminator (260 nm). The amplified products were purified with the QIAquick® PCR purification kit (Qiagen Inc., Mississauga, Ontario). Sequencing of the COI region was done by the Nucleic Acid and Protein Synthesis Unit (NAPS) at the University of British Columbia, Vancouver, British Columbia, using an Applied Biosystem sequencer and the universal insect primers described above. All sequences were confirmed by sequencing in both directions. Sequences were checked for errors and for sequence variation within cranberry and blueberry populations. Sequences from cranberry tipworm and blueberry gall midge were deposited in the National Center for Biotechnology Information (NCBI) GenBank with the accession numbers HQ542180-HQ542185 and HQ542186-HQ542191, respectively.
DNA Sequence Analysis
To determine the percentage genetic divergence (%D) within and between sequences from the 2 populations, the sequences generated in this study were compared with those of blueberry gall midge reported from Britain (Collins et al. 2010) and 5 other Dasineura species (Table 1) obtained from NCBI. The COI sequences of cranberry tipworm, blueberry gall midge and the other Dasineura spp. were aligned using CLUSTAL W (Accelrys Gene 2.5; Accelrys®, Inc., San Diego, California). To determine a model of DNA substitution that fits the COI data set, Modeltest 3.0 (Posada & Crandall 1998) was applied to the data set. The Akaike criteria of Modeltest selected the general time reversible model with gamma distribution (GTRG) as the best fit for the COI sequence data (base frequencies: πA = 0.3455, πC = 0.1372, πG = 0.1118, πT = 0.4055; substitution rates: A/C = 9.11, A/G = 55.4044, A/T = 19.8145, C/G = 26.1111, C/T = 55.4044, G/T = 1.0000; gamma distribution shape parameter = 0.2543). The observed distances, obtained from multiple sequence alignments were used to generate a distance matrix using the GTRG correction model and neighbour-joining (NJ) (Saitou & Nei 1987) distance method. The NJ analysis was performed to determine genetic distances and to construct a phylogenetic tree using PAUP* version 4.0b10b software (Swofford 2002) and 1000 bootstrap replicates (Felsenstein 1985). FigTree v1.1.2 (Rambaut 2007) was used to view the NJ tree.
Primer Design and PCR Analysis
From the differences between cranberry tipworm and blueberry gall midge sequences, diagnostic PCR primer sets were developed that distinguish the two populations. The primer sites were searched based on variable nucleotide positions between sequences of cranberry tipworm and blueberry gall midge, where no variation was observed within cranberry tipworm or blueberry gall midge sequences. From these primer sites, the positions unique for cranberry tipworm or blueberry gall midge were used to develop specific diagnostic primer sets. Several primers were evaluated for suitable base composition, annealing temperature (Tm), and self compatibility using Primer3 (Rozen & Skaletsky 2000). Primers were synthesized by Integrated DNA Technologies (IDT, Coralville, Iowa) and the Tm of the primers was determined from the specification sheet provided by IDT. Various primer combinations were first tested for PCR specificity for cranberry tipworm and blueberry gall midge sequences using a singleplex PCR assay. Amplicon size was estimated based on comparison with 100-bp ladder (Invitrogen Canada Inc., Burlington, Ontario). The most suitable primers were then selected based on the annealing temperatures and the fragment size of the amplicons so that they could be used simultaneously in a duplex PCR assay, with the same temperature program (Table 2). PCR conditions and visualization of PCR products were as described previously except that the annealing temperature used was 52 °C.
TABLE 1.
CECIDOMYIIDS (DIPTERA) USED IN THIS STUDY AND THEIR ACCESSION NUMBERS FROM THE NCBI GENBANK.
In a duplex PCR assay, the diagnostic primers specific for cranberry tipworm and blueberry gall midge were mixed in a single reaction tube. PCR conditions and visualization of PCR product were as described previously. The annealing temperature (52 °C) for these 2 primer sets used in combination allowed both primer sets to give specific products for cranberry tipworm or blueberry gall midge DNA.
RESULTS
Analysis of COI Gene from Cranberry Tipworm and Blueberry Gall Midge
DNA from 34 cranberry tip worms and 31 blueberry gall midges successfully amplified with the universal insect primer set. Based on agarose gel separation, all tested specimens produced PCR amplicons of equal size (∼700 bp). Sequences generated from these amplicons were 625 bp in size and showed a strong A+T bias (70–71%; Fig. 1). Out of 34 sequences generated from cranberry tipworm and 31 from blueberry gall midge individuals, a total of 12 sequences showing nucleotide variations but originating from different cranberry and blueberry farms in Pitt Meadows, British Columbia, were submitted to NCBI.
Out of 6 sequences from different cranberry farms (HQ542180, HQ542181, HQ542182, HQ542183, HQ542184 and HQ542185), sequences HQ542181 and HQ542183; HQ542180 and HQ542184; and HQ542182 and HQ542185 were, respectively, identical. Out of 6 blueberry gall midge sequences submitted to NCBI (HQ542186, HQ542187, HQ542188, HQ542189, HQ542190 and HQ542191) from different farms, the 3 sequences HQ542187, HQ542188 and HQ542190 were identical. The identical sequences were removed and 3 sequences from cranberry tipworm (HQ542180, HQ542181 and HQ542182) and 4 from blueberry gall midge (HQ542186, HQ542187, HQ542189 and HQ542191) showing nucleotide variations were selected for subsequent analysis. To accommodate the shorter sequences from blueberry gall midge (British population) obtained from NCBI in the alignment for NJ analysis, all other sequences used in this study were trimmed down at the terminal ends. The length of the aligned sequences was 559 bp; the alignment was gap-free.
TABLE 2.
SPECIFIC PRIMERS DEVELOPED IN THIS STUDY TO DIFFERENTIATE D. OXYCOCCANA FROM CRANBERRY (CB) OR BLUEBERRY (BB). F = FORWARD; R = REVERSE.
Alignment of sequences obtained in this study and those obtained from NCBI GenBank showed high percentage genetic divergence (%D = 10.7– 13.1%) between cranberry tipworm (Table 3: #1, 2 and 3) and blueberry gall midge (Table 3: #4, 5, 6 and 7) but low divergence within cranberry tipworm (%D = 0–1.2%) and blueberry gall midge (%D = 0–1.3). The population of blueberry gall midge from Pitt Meadows, British Columbia, was genetically similar (%D = 0–1.3%) to the British population of D. oxycoccana (Table 3: #8, 9 and 10) on highbush blueberry. Cranberry tipworm and blueberry gall midge sequences showed a high %D (22.3–34.8%) from other species of Dasineura (Table 3: #11 to 16) available on NCBI website.
In the neighbor-joining tree, the sequences from cranberry tipworm, blueberry gall midge and other Dasineura species from NCBI GenBank separated into 3 distinct clusters: blueberry gall midge from Pitt Meadows, British Columbia, and from Britain; cranberry tipworm from Pitt Meadows, British Columbia; and the 5 other species of Dasineura from GenBank (Fig. 2). Distinction of blueberry gall midge from cranberry tipworm was supported by high bootstrap values (100%). Cranberry tipworm and blueberry gall midge separated from other Dasineura species with 58% and 84% bootstrap values. Two of the blueberry gall midge sequences reported in this study are identical to the British sequences. The Canadian blueberry gall midge sequence HQ542186 is identical to sequence FR694174 of British blueberry gall midge, and the Canadian blueberry gall midge sequence HQ5421191 is identical to the British blueberry gall midge sequence FR694171 (Fig 2).
Molecular Identification of D. oxycoccana from Cranberry or Blueberry
The location of the cranberry tipworm and blueberry gall midge specific primers selected in this study are shown (Table 2) in relation to the Drosophila yakuba mitochondrial genome (Clary & Wolstenholme 1985). For the insects whose complete mitochondrial region has not been sequenced, mitochondrial genome organization of D. yakuba is generally taken as a standard to show the primer positions. When DNA from 34 cranberry tipworms and 31 blueberry gall midges was tested in a singleplex PCR assay, the specific primer set CBF and CBR (Table 2) developed for cranberry tipworm produced a 270-bp fragment from cranberry tipworm DNA, and no fragment from blueberry gall midge DNA. The specific primer set BBF and BBR (Table 2) developed for blueberry gall midge produced a 500-bp fragment from DNA of blueberry gall midge and no fragment from cranberry tipworm DNA. These specific primer sets were selected for a duplex PCR assay because of their similar annealing temperatures and different PCR product size. For the duplex PCR assay, the primer sets CBF-CBR and BBF-BBR were used simultaneously in a PCR mix and tested on DNA from cranberry tipworm and blueberry gall midge individuals from British Columbia. DNA from the cranberry tipworms produced a 270-bp fragment (Fig. 3: lanes 1–5); DNA from the blueberry gall midges produced a 500-bp fragment (Fig. 3: lanes 6–10) in the duplex assay. Using this duplex PCR assay, detection and differentiation of cranberry tipworm from blueberry gall midge can be achieved in a single reaction.
DISCUSSION
There is substantial genetic variability between the mtDNA COI gene region of D. oxycoccana collected from British Columbia cranberry farms (cranberry tipworm) and the mtDNA COI gene region of D. oxycoccana collected from British Columbia blueberry farms (blueberry gall midge). The separation of cranberry tipworm from blueberry gall midge populations is supported by NJ analysis at high bootstrap value with high average percentage (10.7–13.1%) of genetic divergence between them based on GTRG distance matrix method. Other species of Dasineura separated from both cranberry tipworm and blueberry gall midge sequences, which shows that cranberry tipworm is very different genetically from blueberry gall midge as well as from other Dasineura species recorded in the NCBI GenBank. The populations of blueberry gall midge from British Columbia, and from Britain grouped together in the NJ analysis. Some Canadian and British sequences were identical, which strongly suggests that these 2 populations are the same species and confirms the identity of the blueberry gall midge sequences generated in this study.
The host plant of D. oxycoccana populations in British Columbia can be identified as cranberry or blueberry through use of the duplex PCR assay developed in the present study, even though adults from the 2 host-plant populations cannot be distinguished on the basis of morphological characters (Sinclair, this study). Genetic separation of the 2 populations supports the conclusion of Cook et al. (2011) that D. oxycoccana populations on cranberry and blueberry in British Columbia are reproductively isolated and probably represent cryptic species (per: Bickford et al. 2007; Schonrogge et al. 2002).
Molecular analysis using the COI region of mtDNA has revealed cryptic species in many insects including mayflies Baetis vernus (Stahls & Savolainen 2008) and flower beetle (Blair et al. 2005). Hebert et al. (2004) differentiated 10 cryptic species in a single morphologically identified skipper butterfly species which differed in their larval appearance, food plants and habitat preference. Similarly, Smith et al. (2006) differentiated morphologically indistinguishable parasitoid flies (Tachinidae) to groups of separate host-specific cryptic species.
TABLE 3.
PERCENT SEQUENCE DIVERGENCE (%D) BETWEEN SPECIES OF DASINEURA (DIPTERA: CECIDOMYIIDAE) BASED ON GENERAL TIME REVERSIBLE WITH GAMMA DISTRIBUTION MODEL (GTRG) FOR COI MTDNA SEQUENCES.
Cook et al. (2011) postulated that D. oxycoccana has diverged into 2 specialist species on cranberry and blueberry. Our genetic data support this idea, but do not provide information on the direction or time-frame of divergence. The gall-midge D. folliculi, which shows host-associated differentiation (possibly cryptic speciation) on 2 species of goldenrod, is thought to have shifted from Solidago rugosa to S. gigantea, according to evidence provided by genetic data, oviposition preference, reproductive success and natural-enemy attack (Dorchin et al. 2009). In the case of D. oxycoccana in British Columbia, it is extremely unlikely that a host-shift from blueberry to cranberry took place in British Columbia during the 1990's. A more probable scenario is that D. oxycoccana on cranberry (cranberry tipworm) is a cryptic invader that arrived on plant material imported from another region of North America. Cranberry is not native to British Columbia, therefore during industry expansion in the 1990's, some new or more vigorous cultivars were imported. Host-divergence or host-shifting among populations of D. oxycoccana could have occurred where V. macrocarpon and V. corymbosum are native, in eastern North America (VanderKloet 1988).
Our study opens the door to a comprehensive examination of genetic and morphological variation among D. oxycoccana populations in cranberry- and blueberry-growing regions of North America, particularly the states of Florida, Massachusetts, Michigan, New Jersey, Oregon, Washington, Wisconsin, and the provinces of British Columbia and Quebec. We anticipate greater genetic variability among D. oxycoccana from the species and hybrids of commercially harvested blueberry (Hancock et al. 2008) than among D. oxycoccana from cranberry cultivars, which are not far removed from native selections (Rodriguez-Saona et al. 2011). Our duplex PCR assay will be a valuable tool, and we recognize that the use of other molecules, like nuclear genes, would provide additional information on the relationships between D. oxycoccana on Vaccinium host plants.
ACKNOWLEDGMENTS
We thank Daniel A. H. Peach (Simon Fraser University) for collecting the larvae used in this study, and R. J. Gagné (USDA Systematic Entomology Laboratory c/o Smithsonian Institution) for identifying specimens. Funding was provided by Agriculture and Agri-Food Canada Growing Forward Initiative (S. M. and S. M. F), B. C. Cranberry Marketing Commission and B. C. Cranberry Growers Association (S. M. F), Canadian Food Inspection Agency (B. J. S.) and Natural Sciences and Engineering Research Council (M. A. C). This is publication number 794, Pacific Agri-Food Research Centre, Agassiz, British Columbia, Canada. Use of trade names or trademarks does not imply endorsement of the companies or products named nor criticism of similar ones not named.