Skip to main content

Dynamics of genetic variability in Anastrepha fraterculus(Diptera: Tephritidae) during adaptation to laboratory rearing conditions

Abstract

Background

Anastrepha fraterculus is one of the most important fruit fly plagues in the American continent and only chemical control is applied in the field to diminish its population densities. A better understanding of the genetic variability during the introduction and adaptation of wild A. fraterculus populations to laboratory conditions is required for the development of stable and vigorous experimental colonies and mass-reared strains in support of successful Sterile Insect Technique (SIT) efforts.

Methods

The present study aims to analyze the dynamics of changes in genetic variability during the first six generations under artificial rearing conditions in two populations: a) a wild population recently introduced to laboratory culture, named TW and, b) a long-established control line, named CL.

Results

Results showed a declining tendency of genetic variability in TW. In CL, the relatively high values of genetic variability appear to be maintained across generations and could denote an intrinsic capacity to avoid the loss of genetic diversity in time.

Discussion

The impact of evolutionary forces on this species during the adaptation process as well as the best approach to choose strategies to introduce experimental and mass-reared A. fraterculus strains for SIT programs are discussed.

Introduction

The introduction of species into artificial conditions with the aim to establish laboratory lines is necessary and useful in numerous situations for experimental or mass rearing purposes. Laboratory conditions are different from the ones a species encounters in nature and often favor a small group of individuals with specific reproductive advantages [1]. For insect species, it has been observed that the adaptation to laboratory conditions frequently favors individuals with faster life cycles, females with high fecundity at the beginning of the reproductive stage, and males that do not necessarily accomplish all parts of the courting sequences /courtship [24]. At a molecular level, changes in the genetic variability have also been observed during the adaptation to laboratory conditions [511]. Specifically, the reduction of the population effective size in combination with the confinement to finite spaces has high impact on the genetic variability [12]. These changes could lead to a reduction in the ability of the species to confront changes in the environment or to survive if returned to wild conditions [13, 14].

The adaptation of wild populations to laboratory conditions is a crucial step in modern biological control programs, such as in the case of the Sterile Insect Technique (SIT) [1517]. The implementation of SIT requires the mass rearing and sterilization of insects for release into the natural environment. Once in the field, sterile males are expected to survive and mate with wild females. This leads to no offspring and therefore the population size is effectively reduced in time [18]. The quality control of the insects that are released is of vital importance to the success of the SIT. Therefore, it is important to assess the processes that may drive genetic changes during the introduction and adaptation of insects to laboratory conditions and the impact of these changes on life-history traits.

The South American fruit fly Anastrepha fraterculus Wiedemann (Diptera: Tephritidae), is among the targeted species of integral pest control programs in Latin America, given its great economic importance. Although SIT is currently being applied in Central America to control the population density of other species of Anastrepha genus [1921], only chemical approaches have been used to control A. fraterculus populations [22]. This species infests a wide variety of fruit species, therefore being the reason of high crop losses and restrictions to potential markets, especially for Uruguay, Argentina, Peru and South of Brazil [23, 24]. Currently, A. fraterculus is considered a complex of cryptic species (see [2527]). In Argentina and southern Brazil, only one biological entity is described as A. fraterculus sp. 1 [26] or Brazilian 1 morphotype [27, 28]. Numerous studies about biological, behavioral and genetic traits of this species have been carried out in the last 15 years as they are requirements before SIT can be applied to control this pest [2932]. Viscarret et al. [33] were the first to assess the effects of adaptation to laboratory conditions in A. fraterculus sp. 1 populations. These authors found that recently introduced populations suffer drastic changes in survival and fecundity parameters.

Despite the limited information at genetic level available for this species, we have recently developed a set of species-specific microsatellite markers [34]. The development and availability of these markers are of major importance as very powerful tools for population genetics analyses [35, 36]. In fact, these markers have been successfully used to assess intra-specific genetic diversity in wild and laboratory populations of this pest [34]. As a first approach to understand the dynamics of change of the genetic variability during the first generations under laboratory conditions in A. fraterculus sp. 1, we used a subset of these markers to analyze the genetic variability and differentiation of a laboratory and a wild population of this pest across six generations in the laboratory environment. We also discuss the driving evolutionary processes occurring during early laboratory adaptation and make suggestions regarding the maintenance of the natural vigor of laboratory populations aiming to support SIT development for A. fraterculus.

Methods

Introduction and adaptation of lines

Wild individuals were obtained in March 2012 from infested guava (Psidium guajava L.) in the vicinity of Tafi Viejo (Horco Molle, Tucumán, Argentina). The infested fruit was carried to the laboratory and placed in containers with sand as a substrate for pupation. Pupae were retrieved from the sand weekly and placed into glass containers. Emerged adults were introduced in 40-cm3 cages, with water and food (MP Biomedical hydrolyzed yeast as protein source and sugar) to establish a replicated parental line named Tucumán Wild (TW). Each replicate population (TW1, TW2) was started with 760 individuals at a sex rate of 1:1. As control, a replicated parental line named Castelar Lab (CL) was started with pupae obtained from the experimental rearing at the Instituto de Genética 'Ewald A. Favret', Instituto Nacional de Tecnología Agropecuaria (IGEAF, INTA Castelar; Buenos Aires, Argentina). This laboratory strain was established in 2007 and maintained for 56 generations under artificial rearing according to Jaldo et al. [37], and since then no wild material has been introduced to refresh the genetic background. The strain was derived from a semi-mass rearing colony kept at Estación Experimental Agroindustrial Obispo Colombres, Tucumán, Argentina, originally initiated in 1997 with wild pupae recovered from infested guavas (P. guajava L.) collected at the vicinity of Tafi Viejo (Horco Molle, Tucumán, Argentina) [29].

Replication procedures for the CL populations (CL1, CL2) were similar to those described above for the TW line. TW and CL were kept isolated from each other for six generations under the same laboratory conditions (25°C, 45% humidity and 16-8 (L : D) photoperiod).

A cylindrical container (5 cm tall and 2 cm in diameter) filled with red colored water and covered by a plastic film was used as substrate for oviposition. These artificial fruits were checked every 24-48 h and the eggs were deposited into containers with artificial larval diet [38]. Containers were placed in other recipients containing sand as pupation substrate. Pupae were recovered after 17 days and placed in cages until adult emergence for the establishment of the next generation. Mean pupae-adult time was 15 days [37].

Microsatellite genotyping methods

Replicates from each line, named as TW1, TW2, CL1 and CL2 respectively, were analyzed at generations 0, 3 and 6 (Gn, Gn+3 and Gn+6) under laboratory rearing conditions. At each generation, 30-40 randomly chosen flies (in a 1:1 sex ratio) were obtained from each of the four populations to perform molecular analysis.

Individuals were kept at -20°C until processed. DNA was extracted following the protocol described by Baruffi et al. [39]. The genetic material was analyzed by electrophoresis (agarose 0.8 % in buffer TBE 0.5 × and revealed with ethidium bromide [40]). Images were captured with an UVP reveler (Fotodyne Inc. Hartland, WI, USA) and analyzed with Photoshop (Adobe Microsoft). The DNA was quantified with Nanodrop 1000 (Thermo Scientific).

The genetic variability of each population was analyzed with 10 microsatellite markers (A7, A120, A102, D12, A10, C103, D105, A122, A112 and D4) developed in Lanzavecchia et al. [34]. These microsatellite markers were selected from a set of 14 highly polymorphic microsatellites tested in wild and laboratory A. fraterculus populations [34]. Forward primers were 5´-labeled with fluorescent dyes (FAM-HEX). PCR reactions were done in a final volume of 10 µl containing: 2 mM dNTPs, 1.5 mM MgCl2, 0.4U Taq DNA polymerase (Inbio Highway, Tandil, Argentina) and 0.5 µM of each primer, using 40 ng of total DNA as template. Amplification was carried in a thermal cycler (MultiGene, Labnet, USA) with a denaturalization step of 2 minutes at 94°C followed by 29 cycles of 30 seconds at 94°C, 30 seconds at 58-60°C (see optimized annealing temperature [34]) and 30 seconds at 72°C, with a final elongation step of 10 minutes at 72°C. PCR products were evaluated with electrophoresis (agarose 1.5 % w/v) and run in an ABI 3130 XL DNA Analyzer (Applied Biosystems, Life Technologies, USA) with GeneScan 500 ROX Size Standard (Applied Biosystems). The results were processed using GeneMarker Software [41] to assign the genotype to each sample for each locus. All allele scores were visually inspected.

Microsatellite data analysis

Genetic variability of each population at each generation was measured as: mean number of alleles per locus (Na), mean observed heterozygosity (Ho), expected heterozygosity (He) and allelic richness (AR) using FSTAT 2.9.3 [42] and Arlequin v3.11 [43].

Departures from Hardy-Weinberg equilibrium (HWE) for each locus and each population were quantified using the intra-population fixation index (FIS). The statistical significance of FIS values was assessed using the randomization procedure implemented in FSTAT [42] and afterward sequential Bonferroni corrections for multiple comparisons were applied [44]. The frequencies of null alleles for each locus and linkage disequilibrium between pairs of loci were estimated using Microchecker [45] and FSTAT [42].

To assess the initial genetic variation between the parental populations (TW and CL at Gn) three different approaches were performed taking into account all loci: i) a hierarchical Analysis of Molecular Variance (AMOVA) using Arlequin [43]; ii) a genotypic differentiation test (Exact G test) implemented in GENEPOP 3.4 [46, 47]; and iii) the Wilcoxon Matched Pairs Test run in STATISTICA [48].

The genetic diversity of the three generations analyzed in each population (CL and TW) was compared through Friedman non-parametric ANOVA using STATISTICA [48].

To quantify the distribution of total variation among generations within lines (Gn, Gn+3 and Gn+6), among replicates within generations and within replicates, individual AMOVAs were performed for each line (TW and CL) with Arlequin [43].

Effects of positive selection were tested for each microsatellite locus by applying the Ln RH test [49, 50]. This test detects loci with a pattern of variability which is different from that expected under neutrality, and is based on the comparison of the logarithm of the ratio between expected heterozygosities obtained for each locus in two populations: Ln RH = [((1/(1- H pop1))2 - 1)/((1/(1- Hpop2))2 - 1)]. To apply the test, ratios of expected heterozygosities were calculated for each locus using data from Gn and Gn+6 (Gn+6/Gn ratios) and for each line (CL and TW). Since Ln RH values are expected to follow a normal distribution for neutrality evolving microsatellite loci [49], significant deviations of Ln RH values from the Z distribution indicate positive selective sweep. To detect loci under selection, a one-way ANOVA was also performed with locus as a factor and Ln RH values as dependent variable according to Simões at al. [51]. These analyses were done using STATISTICA [48].

Results

Over the four populations (TW1, TW2, CL1 and CL2 ), the ten microsatellite loci had different levels of polymorphism in terms of number of alleles, ranging from 2 to 15 and with a mean of 5.71 alleles per locus (data not shown). No linkage disequilibrium was detected with consistency across the populations (P > 0.05 in all cases). After the sequential Bonferroni correction, most of the populations sampled conformed to HWE at most of the loci. Out of the 120 tests performed (4 populations × 3 generations × 10 loci), only eight showed deviations from HWE (P < 0.05), measured using the fixation index (FIS) (Table S1, Additional file 1). The locus/population combinations that were not in HWE were not concentrated in any population or at any locus. Moreover, null alleles appeared to be present in various combinations of population/marker, which suggests that null alleles contribute to the heterozygote deficiency observed for some of these samples that exhibited deviations from HWE (Table S1, Additional file 1).

The two lines analyzed here, the long-established CL and the recently introduced TW, showed genetic heterogeneity. The AMOVA performed in Gn detected significant differences between the lines (F = 0.0196; P = 0.00098), with 2% of genetic variability explained by this source of variation. The results from the Exact G test considering all loci in this generation also showed that genotypic frequencies differ between the lines (P<0.05). In addition, the genetic variability parameters showed high initial values for these lines. Particularly, TW seemed to show higher diversity in terms of mean number of alleles per locus (Na), allelic richness (AR) and expected heterozygosity (He) than CL in the parental generation Gn (Table 1; Figure 1A,B), with marginally significant differences for AR between lines (Z = 1,72; P = 0.08, Wilcoxon Matched Pairs Test).

Table 1 Genetic variability estimates in the laboratory established line (CL) and the adapting line (TW) of Anastrepha fraterculus for generations n, n+3 and n+6 under laboratory rearing conditions.
Figure 1
figure 1

Mean allelic richness, AR (A), and mean expected heterozygosity, He (B), at generations n, n+3 and n+6 under laboratory conditions of rearing for the four populations of A. fraterculus.

The genetic diversity in CL seemed to be more stable through generations than that in TW, specifically in terms of AR (Table 1; Figure 1A). He for CL showed the same pattern as AR but with some inter-replicate variation (Figure 1B). In contrast, in TW, both variability parameters tended to decline during early laboratory adaptation (Figure 1A,B). Despite the high inter-replica variation detected within TW, marginally significant differences were detected in genetic variability across generations (Table 2). Particularly, one replicate of this line (TW R1) showed a stronger decline in genetic variability across generations than the other replicate (TW R2) (Figure 1A,B). The Friedman ANOVA demonstrated significant differences in both Na and AR among generations for the R1 replicate (Q = 6.35 P = 0.04 for Na; Q = 7.74, P = 0.02, for AR). Although these parameters showed a similar trend to decline through generations in R2, no significant differences were detected for this replicate. For CL, no significant differences were detected in genetic diversity indexes among generations (P > 0.05 in all cases).

Table 2 Results of the hierarchical analysis of molecular variance (AMOVA) for the CL and TW lines of A. fraterculus

AMOVA results (Table 2) support the pattern observed in the genetic diversity parameters analyzed, with low but marginally significant differences among generations. The differences between replicates within lines explained 2.65% and 2.64% of the total variance for TW and CL, respectively (P<0.05, Table 2). Most of the variation was found within replicates, with 96.20% (TW) and 94.20% (CL) of the total variance explained by this source (Table 2).

Figure 2 shows the results obtained for the Ln RH test applied to detect deviations from neutrality in our microsatellite data set. No microsatellite locus exhibited any consistent indication of positive selection, except for locus A112 in R1 TW, whose Ln RH value fell slightly outside the 95% limits of the normal distribution. This locus showed a decrease in variability through generations in this TW replicate (Figure 2).

Figure 2
figure 2

Heterozygosity ratios (Ln RH) between generations n and n+6 for CL (A) and TW (B) populations. Dashed lines represent the 95% confidence interval of the normal distribution. Positive and negative Ln RH values denote an increase or a decrease in variability through time, respectively.

Discussion

We presented here the first exploratory analysis of the dynamics of change in genetic variability for a wild A. fraterculus sp.1 population during early adaptation. We discuss our data in the frame of recent studies on other Tephritid species and explored the relative impact of evolutionary forces during laboratory adaptation. Our results indicate that during introduction to laboratory conditions A. fraterculus suffers a clear genetic differentiation, even in the very early steps of the adaptation process. Genetic drift appeared to be the main evolutionary force impacting on the genetic variability of the A. fraterculus during the introduction to laboratory rearing conditions.

The genotypic differences exhibited in the parental generation between CL and TW reflect the occurrence of genotypic variation between the long-established population and the wild population that gave origin to it. In line with previous studies, the wild population showed higher values in genetic diversity parameters. Our lab-adapted line also showed an overall high genetic variability in the 10 microsatellite loci, as described for laboratory strains of Bactrocera dorsalis Hendel [52], and a stable pattern of genetic variability across generations. These results evidence that the more than 56 generations in laboratory culture would have relatively low impact in the genetic diversity of this A. fraterculus experimental line. Moreover, the expected heterozygosity values were comparable between our CL line and the IGEAF established strain that gave origin (results obtained for 14 microsatellites markers) [35], suggesting the existence of an intrinsic mechanism that contributes to maintaining the variability in A. fraterculus even under laboratory conditions.

The declining patterns in genetic variability through early adaptation to laboratory conditions observed for TW are consistent with the results obtained by Gilchrist et al. [10] and Zigouridis et al. [11] in Bactrocera spp. In larger-scale studies, these authors followed the fluctuation of genotypic frequencies of microsatellite markers during the colonization of replicated lines of Bactrocera tryoni Froggat (Diptera: Tephritidae) and a wild population of B. oleae Rossi (Diptera: Tephritidae) in laboratory conditions, respectively. Substantial changes in the genetic variability during the initial period of adaptation were observed for these species, particularly between generations 4 and 10 for B. tryoni [10] and generations 1 and 5 for B. oleae [11].

The high inter-replicate differences observed particularly for our TW line suggest the occurrence of genetic drift with detectable impact on the genetic variability of the replicates, as described by Gilchrist et al. [10] for B. tryoni and Simões et al. [8, 51, 53] for Drosophila subobscura Collin (Diptera: Drosophilidae) populations. In agreement with the study by Hopper with small population sizes [54], genetic drift appears to be the main evolutionary process involved in the genetic differentiation of our TW populations.

We found no strong evidence of selection with the Ln RH test applied to the microsatellite data. Only one locus (A112) showed slight deviations from neutral expectations at one TW replicate (R1) between Gn and Gn+6. Our results point out the relative importance of genetic drift, particularly, through the smaller effective population sizes at early stages of adaptation, molding genetic molecular diversity in our recently introduced TW line, although certain genome region (A112 locus) could reflect selection during laboratory adaptation. In this context, we suggest that the implementation of strategies like the cross of replicates, as proposed by Gilchrist et al. [10, 55], could maintain variability in regular A. fraterculus experimental and mass-rearing programs. The approach proposed by these authors relates to the fragmentation of a population to diminish the genetic adaptation to captivity [7], which may reduce the genetic variability at a replicate level but maintain it at a population level. Keeping isolated replicates and pooling them every certain number of generations would help to reduce inbreeding to an acceptable level [56]. Additionally, results presented by Zygouridis et al. [11] indicate that refreshments with wild material performed every five to eight generations could be adequate to maintain a wild profile in terms of genetic variability in a B. oleae mass-reared colony and would represent a good strategy to maintain variability in this species. In the case of our A. fraterculus line, the adequate number of generations between replicate crosses or refreshments with wild material and the evolutionary forces driving genetic changes in the adaptation process of A. fraterculus deserve further evaluation including a larger number of generations and a larger number of replicates. The possible combination of these studies with other management strategies for A. fraterculus remains as a challenge for future research and will provide useful information to establish improved and efficient experimental and mass-rearing colonies for the development of SIT for this pest.

The present study represents a first insight into the dynamics of change in the genetic variability of A. fraterculus populations during adaptation to laboratory conditions. Our results indicate the relative importance of genetic drift as a principal driving evolutionary force in early laboratory adaptation that must be further analyzed. Given our findings of the dissimilarities between replicates, we suggest that the fragmentation and crosses among replicates after several generations may be a suitable procedure to maintain the genetic diversity of the population in captivity. Future challenges should include analyzing further generations and establishing the association between long-term dynamics of change in the genetic variability and in biological or behavioral parameters of relevance to the quality assessment of mass-reared colonies (as fecundity, mating performance, etc) across generations for SIT implementation against this pest.

Conclusion

Studies about changes in genetic variability during adaptation to artificial rearing are of fundamental importance to the monitoring of biological and genetic parameters applicable to mass-reared strains in the frame of SIT control strategies. These studies bring useful information about genetic aspects of foundation and management strategies for A. fraterculus experimental rearing. We introduced here a first approach to the genetic changes of a wild population of A. fraterculus during the first generations under artificial rearing. Based on recent studies on other Tephritidae species, we discuss the possible evolutionary forces driving the genetic changes observed here. Although our investigations are based on an experimentally reared strain, the results provide useful information about the genetic aspects of this species that could be useful in the development of larger-scale rearing to maximize its potential in the field when specific control strategies are applied.

As SIT has not yet been developed for A. fraterculus, all the investigations focused on this direction, as are biological and genetic studies performed in natural and lab strains, will be of paramount importance to help governmental decisions to solve the important economic problem posed by this fruit pest in South America.

References

  1. Lacy RC: Clarification of genetic terms and their use in the management of captive populations. Zoo Biol. 1995, 14: 565-578. 10.1002/zoo.1430140609.

    Article  Google Scholar 

  2. Carey JR: Host-specific demographic studies of the Mediterranean fruit fly Ceratitis capitata. Ecol Entomol. 1984, 9: 261-270. 10.1111/j.1365-2311.1984.tb00850.x.

    Article  Google Scholar 

  3. Joachim-Bravo IS, Zucoloto FS: Performance and feeding behavior of Ceratitis capitata: comparison of a wild population and laboratory population. Entomol Exp Appl. 1998, 87: 67-72. 10.1046/j.1570-7458.1998.00305.x.

    Article  Google Scholar 

  4. Economopoulos AP: Adaptation of the Mediterranean Fruit Fly (Diptera: Tephritidae) to Artificial Rearing. J Econ Entomol. 1992, 85 (Suppl 3): 753-758.

    Article  Google Scholar 

  5. Dupont-Nivet M, Mallard J, Bonnet J, Blanc J: Evolution of the genetic variability in a population of the edible snail, Helix aspersa Muller, undergoing domestication and short-term selection. Heredity. 2001, 87: 129-135. 10.1046/j.1365-2540.2001.00836.x.

    Article  CAS  PubMed  Google Scholar 

  6. Ekesi S, Nderitu PW, Chang CL: Adaptation to and Small-Scale Rearing of Invasive Fruit Fly Bactrocera invadens (Diptera: Tephritidae) on Artificial Diet. Ann Entomol Soc Am. 2007, 100 (Suppl 4): 562-567.

    Article  Google Scholar 

  7. Frankham R: Genetic adaptation to captivity in species conservation programs. Mol Ecol. 2008, 17: 325-333. 10.1111/j.1365-294X.2007.03399.x.

    Article  PubMed  Google Scholar 

  8. Simões P, Pascual M, Coelho M, Matos M: Divergent evolution of molecular markers during laboratory adaptation in Drosophila subobscura. Genetica. 2010, 138: 999-1009. 10.1007/s10709-010-9486-4.

    Article  PubMed  CAS  Google Scholar 

  9. Goncalves EC, Ferrari SF, Bastos HB, Wajntal A, Aleixo A, Schneider MP: Comparative genetic diversity of wild and captive populations of the bare-faced curassow (Craxfa sciolata) based on cross-species microsatellite markers: implications for conservation and management. Biochem Genet. 2010, 48 (Suppl 5-6): 472-479.

    Article  CAS  PubMed  Google Scholar 

  10. Gilchrist AS, Cameron EC, Sved JA, Meats AW: Genetic consequences of domestication and mass rearing of pest fruit fly Bactrocera tryoni (Diptera: Tephritidae). J Econ Entomol. 2012, 105 (Suppl 3): 1051-1056.

    Article  CAS  PubMed  Google Scholar 

  11. Zygouridis NE, Argov Y, Nemny-Lavy E, Augustinos AA, Nestel D, Mathiopoulos KD: Genetic changes during laboratory domestication of an olive fly SIT strain. J Appl Entomol. 2014, 138 (Suppl 6): 423-432. Published online: 27 FEB 2013

    Article  Google Scholar 

  12. Nei M, Maruyama T, Chakraborty R: The bottleneck effect and genetic variability in populations. Evolution. 1975, 29: 1-10. 10.2307/2407137.

    Article  PubMed  Google Scholar 

  13. Bartlett AC: Genetic changes during insect domestication. Advances and Challenges in Insect Rearing. Edited by: King EG and Leppla NC. 1984, New Orleans, 2-8.

    Google Scholar 

  14. Hernandez ED, Toledo J, Artiaga-Lopez T, Flores S: Demographic changes in Anastrepha oblique (Diptera: Tephritidae) throughout the laboratory colonization process. J Econ Entomol. 2009, 102 (Suppl 2): 542-551.

    Article  PubMed  Google Scholar 

  15. Knipling EF: The basic principles of insect population suppression and management. 1979, Agriculture Handbook Number 512, SEA, USDA, Washington DC, USA

    Google Scholar 

  16. Enkerlin WR: Impact of fruit fly control programmes using the Sterile Insect Technique. Principles and Practice in Area-Wide Integrated Pest Management. Edited by: Dyck VA, Hendrichs J, Robinson AS, Dordrecht. 2005, The Netherlands: Springer, 651-676.

    Google Scholar 

  17. Hendrichs MA, Wornoayporn V, Katsoyannos B, Hendrichs J: Quality control methods to measure predator evasion in wild and mass-reared Mediterranean fruit flies (Diptera: Tephritidae). Fla Entomol. 2007, 90 (Suppl 1): 64-70.

    Article  Google Scholar 

  18. Aluja MR: Bionomics and management of Anastrepha. Annu Rev Entomol. 1994, 39: 155-178. 10.1146/annurev.en.39.010194.001103.

    Article  Google Scholar 

  19. Hernandez E, Orozco D, Breceda SF, Dominguez J: Dispersal and longevity of wild and mass reared Anastrepha ludens and Anastrepha oblique (Diptera: Tephritidae). Fla Entomol. 2007, 90: 123-135. 10.1653/0015-4040(2007)90[123:DALOWA]2.0.CO;2.

    Article  Google Scholar 

  20. Zepeda-Cisneros C, Meza Hernández J, Ibañez Palacios J, García Martínez V, León Crisóstomo A: Development and evaluation of genetic sexing strain of Anastrepha ludens for sterile insect technique. Report of the International Congress of Entomology: 20-24 August. 2012, Daegu, Korea

    Google Scholar 

  21. Guillen D, Sanchez R: Expansion of the national fruit control programme in Argentina. Area-wide control of insect pests from research to field implementation. Edited by: Vreysen M.B, Robinson AS, Hendrichs J. 2007, IAEA, 653-660.

    Chapter  Google Scholar 

  22. Aruani R, Ceresa A, Granados J, Taret G, Peruzzoti P, Ortiz G: Advances in the national fruit fly control and eradication program in Argentine. Fruit Fly Pests: A World Assessment of their Biology and Management. Edited by: McPheron B, Steck G. 1996, 521-530.

    Google Scholar 

  23. Sugayama R, Kovaleski A, Liedo P, Malavasi A: Colonization of a new fruit crop by Anastrepha fraterculus (Diptera: Tephritidae) in Brazil: a demographic analysis. Environ Entomol. 1998, 27: 642-648. 10.1093/ee/27.3.642.

    Article  Google Scholar 

  24. Cosenzo E: Programa nacional de control y erradicación de mosca de los frutos (PROCEM). Resúmenes del Taller de Mosca de los Frutos 2003. 2003, Buenos Aires. SENASA

    Google Scholar 

  25. Steck G: Taxonomic status of Anastrepha fraterculus. Proceedings of the Workshop on the South American fruit fly, Anastrepha fraterculus (Wied.); advances in artificial rearing, taxonomic status and biological studies: 1-2 Nov 1996. 1999, Viña del Mar, Chile, 13-20.

    Google Scholar 

  26. Goday C, Selivon D, Perondini ALP, Greciano PG, Ruiz MF: Cytological characterization of sex chromosomes and ribosomal DNA location in Anastrepha species (Diptera, Tephritidae). Cytogenet Genome Res. 2006, 114: 70-76. 10.1159/000091931.

    Article  CAS  PubMed  Google Scholar 

  27. Hernández-Ortiz V, Bartolucci A, Morales-Valles P, Frías D, Selivon D: Cryptic Species of the Anastrepha fraterculus Complex (Diptera: Tephritidae): A Multivariate Approach for the Recognition of South American Morphotypes. Ann Entomol Soc Am. 2012, 105 (Suppl 2): 135-376.

    Google Scholar 

  28. Rull J, Abraham S, Kovaleski A, Segura DF, Islam A, Wornoayporn V, Dammalage T, Tomas US, Vera MT: Random mating and reproductive compatibility among Argentinean and southern Brazilian populations of Anastrepha fraterculus (Diptera: Tephritidae). Bull Entomol Res. 2012, 102: 435-443. 10.1017/S0007485312000016.

    Article  CAS  PubMed  Google Scholar 

  29. Jaldo H, Gramajo C, Willink E: Mass rearing of A. fraterculus: A preliminary Strategy. Fla Entomol. 2001, 84: 716-718. 10.2307/3496407.

    Article  Google Scholar 

  30. Vera MT, Wood RJ, Cladera J, Gilburn AS: Factors affecting female remating frequency in the Mediterranean fruit fly (Diptera: Tephritidae). Fla Entomol. 2002, 85: 156-164. 10.1653/0015-4040(2002)085[0156:FAFRFI]2.0.CO;2.

    Article  Google Scholar 

  31. Gomez Cendra P, Segura D, Allinghi A, Cladera J, Vilardi J: Comparison of longevity between a laboratory strain and a natural population of Anastrepha fraterculus (Diptera: Tephritidae) under field cage conditions. Fla Entomol. 2007, 90: 147-153. 10.1653/0015-4040(2007)90[147:COLBAL]2.0.CO;2.

    Article  Google Scholar 

  32. Vera MT, Abraham S, Oviedo A, Willink E: Demographic and quality control parameters of Anastrepha fraterculus (Diptera: Tephritidae) maintained under artificial rearing. Fla Entomol. 2007, 90: 53-57. 10.1653/0015-4040(2007)90[53:DAQCPO]2.0.CO;2.

    Article  Google Scholar 

  33. Viscarret M, Carabajal-Paladino LZ, Lanzavecchia SB, Milla FH, Cladera JL: Evaluación de parámetros biológicos de Anastrepha fraterculus (Diptera: Tephritidae) durante el proceso de adaptación a la cría artificial. Proceedings of the VII Congreso Argentino de Entomología: 21-24 Oct. 2008, Córdoba, Argentina

    Google Scholar 

  34. Lanzavecchia SBL, Juri M, Bonomi A, Gomulski L, Scannapieco AC, Segura DF, Malacrida A, Cladera J, Gasperi G: Microsatellite markers from the 'South American fruit fly' Anastrepha fraterculus: a valuable tool for population genetic analysis and SIT applications. BMC Genetic. 2014, 15 ((Suppl 2)): S13-

    Article  Google Scholar 

  35. Bruford MW, Wayne RK: Microsatellites and their application to population genetic studies. Curr Opin Genet Dev. 1993, 3: 939-943. 10.1016/0959-437X(93)90017-J.

    Article  CAS  PubMed  Google Scholar 

  36. Schlötterer C, Pemberton J: The use of microsatellites for genetic analysis of natural populations. EXS. 1994, 69: 203-214.

    PubMed  Google Scholar 

  37. Jaldo HE, Willink E, Liedo P: Demographic analysis of mass-reared Anastrepha fraterculus (Diptera: Tephritidae) in Tucumán, Argentina. Revista Industrial y Agrícola de Tucumán. 2007, 84: 15-20.

    Google Scholar 

  38. Salles L: Rearing of Anastrepha fraterculus (Wiedemann). In The South American fruit fly, Anastrepha fraterculus (Wied.); advances in artificial rearing, taxonomic status and biological studies. Proceedings of a workshop organized by the Joint FAO/IAEA Division of Nuclear Techniques in Food and Agronomy: 1-2 November. 1996, Vina del Mar, Chile

    Google Scholar 

  39. Baruffi L, Damiani G, Guglielmino C, Bandi C, Malacrida A, Gasperi G: Polymorphism within and between populations of Ceratitis capitata: comparison between RAPD and multi locus enzyme electrophoresis data. Heredity. 1995, 74: 425-437. 10.1038/hdy.1995.60.

    Article  CAS  PubMed  Google Scholar 

  40. Sambrook J, Fritschi EF, Maniatis T: Molecular cloning: a laboratory manual. 1989, New York: Cold Spring Harbor Laboratory Press, 2

    Google Scholar 

  41. SoftGenetics LLC, GeneMarker version 2.4.0. [http://www.softgenetics.com/GeneMarker.html]

  42. Goudet J: FSTAT (Version 1.2): A Computer Program to Calculate F-Statistics. J Hered. 1995, 86 (Suppl 6): 485-486.

    Article  Google Scholar 

  43. Excoffier L, Laval G, Scheneider S: Arlequin (version 3.0): An integrated software package for population genetics data analysis. Evol Bioinfor. 2005, 1: 47-50.

    Article  CAS  Google Scholar 

  44. Rice W: Analyzing Tables of Statistical Tests. Evolution. 1989, 43 (Suppl 1): 223-225.

    Article  PubMed  Google Scholar 

  45. Van Oosterhout C, Hutchinson W, Wills P, Shirpley P: Program Note Micro Checker: Software for identifying and correcting genotyping errors in microsatellite data. Mol Ecol. 2004, 4: 535-538. 10.1111/j.1471-8286.2004.00684.x.

    Article  CAS  Google Scholar 

  46. Raymond M, Rousset F: GENEPOP (version 1.2): population genetics software for exact tests and ecumenicism. Heredity. 1995, 86: 248-249.

    Article  Google Scholar 

  47. Rousset F: Genepop'007: a complete reimplementation of the Genepop software for Windows and Linux. Mol Ecol Resources. 2008, 8: 103-106. 10.1111/j.1471-8286.2007.01931.x.

    Article  Google Scholar 

  48. Statistica v 5.1 Statsoft, Tulsa, OK, USA. 1996

  49. Schlötterer C: A microsatellite-based multilocus screen for the identification of local selective sweeps. Genetics. 2002, 160: 753-763.

    Article  PubMed  PubMed Central  Google Scholar 

  50. Kauer MO, Dieringer D, Schlötterer C: A microsatellite variability screen for positive selection associated with the 'Out of Africa' habitat expansion of Drosophila melanogaster. Genetics. 2008, 165: 1137-1148.

    Article  Google Scholar 

  51. Simões P, Pascual M, Santos J, Fragata I, Rose M, Matos M: Evolutionay dynamics of molecular markers during local adaptation: a case study in Drosophila subobscura. BMC Evolutionary Biology. 2008, 8: 66-10.1186/1471-2148-8-66.

    Article  PubMed  PubMed Central  CAS  Google Scholar 

  52. Aketarawong N, Chinvinijkul S, Orankanok W, Guglielmino C, Franz G, Malacrida A, Thanaphum S: The utility of microsatellite DNA markers for the evaluation of area-wide integrated pest management using SIT for the fruit fly, Bactrocera dorsalis (Hendel), control programs in Thailand. Genetica. 2011, 139 (Suppl 1): 129-40.

    Article  PubMed  Google Scholar 

  53. Simões P, Santos J, Fragata I, Mueller L, Rose M, Matos M: How repeatable is adaptive evolution? The role of geographical origin and founder effects in laboratory adaptation. Evolution. 2008, 62: 1817-1829. 10.1111/j.1558-5646.2008.00423.x.

    Article  PubMed  Google Scholar 

  54. Hopper K, Roush R, Powell W: Management of genetics of biological-control introductions. Annu Rev Entomol. 1993, 38: 27-51. 10.1146/annurev.en.38.010193.000331.

    Article  Google Scholar 

  55. Gilchrist A, Meats A: The genetic structure of populations of an invading pest fruit fly, Bactrocera tryoni, at the species climatic range limit. Heredity. 2010, 105: 165-172. 10.1038/hdy.2009.163.

    Article  CAS  PubMed  Google Scholar 

  56. Frankham R, Ballou J, Briscoe D: Introduction to conservation genetics. 2002, Cambridge. UK: Cambridge University Press

    Chapter  Google Scholar 

Download references

Acknowledgements

We would like to thank the anonymous reviewers for the suggestions and the valuable comments that helped us to improve the manuscript. This work was partially supported by the National Institute of Agriculture Technology (INTA) through the project AEBIO-242411 (module pests) to SBL, and by the International Atomic Energy Agency (IAEA) through the Research Contract N°15745 to SBL. We wish to thank Juan Vilardi and Laura Paulin for their valuable help and suggestions with respect to statistical analysis. We also are indebted to Fabian Milla, Clara Liendo and Claudia Conte for their technical assistance.

This article has been published as part of BMC Genetics Volume 15 Supplement 2, 2014: Development and evaluation of improved strains of insect pests for SIT. The full contents of the supplement are available online at http://www.biomedcentral.com/bmcgenet/supplements/15/S2.

Publication of this supplement was funded by the International Atomic Energy Agency. The peer review process for articles published in this supplement was overseen by the Supplement Editors in accordance with BioMed Central's peer review guidelines for supplements. The Supplement Editors declare that they have no competing interests.

Author information

Authors and Affiliations

Authors

Corresponding author

Correspondence to Silvia B Lanzavecchia.

Additional information

Competing interests

The authors declare that they have no competing interests.

Authors' contributions

MAP performed the experimental procedures, molecular genetic studies and participated in the drafting of the manuscript. ACS performed the genetic and statistical analysis and drafted the manuscript. MIR performed the statistical analysis and helped to draft the manuscript. MJ participated in the characterization of the microsatellite markers and molecular genetic studies. MTV and DFS participated in the experimental design and coordinated the management of insect strains. JLC participated in the design of the study and helped to draft the manuscript. SBL participated in the design of the study, genetic analysis and drafting of the manuscript. All authors read and approved the final version of the manuscript.

María A Parreño, Alejandra C Scannapieco contributed equally to this work.

Electronic supplementary material

12863_2014_1324_MOESM1_ESM.xlsx

Additional file 1: Table S1 (Additional_file1_Table1_Parreño et al. 2014.xls). Table S1. Fixation index FIS and null allele frequency at each locus for all populations (CL R1, CL R2, TW R1, TW R2) and generations (n, n+3, n+6). Bold values represent significant frequencies of null alleles after Bonferroni correction (P < 0.05). FIS values with asterisk represent significant deviations from HWE, *P < 0.05. (XLSX 13 KB)

Rights and permissions

Open Access  This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made.

The images or other third party material in this article are included in the article’s Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder.

To view a copy of this licence, visit https://creativecommons.org/licenses/by/4.0/.

The Creative Commons Public Domain Dedication waiver (https://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated in a credit line to the data.

Reprints and permissions

About this article

Check for updates. Verify currency and authenticity via CrossMark

Cite this article

Parreño, M.A., Scannapieco, A.C., Remis, M.I. et al. Dynamics of genetic variability in Anastrepha fraterculus(Diptera: Tephritidae) during adaptation to laboratory rearing conditions. BMC Genet 15 (Suppl 2), S14 (2014). https://doi.org/10.1186/1471-2156-15-S2-S14

Download citation

  • Published:

  • DOI: https://doi.org/10.1186/1471-2156-15-S2-S14

Keywords