- Short Report
- Open Access
Microsatellite loci characterized in the leaf-cutter ant Atta laevigata
© Kakazu et al.; licensee BioMed Central Ltd. 2013
Received: 23 January 2013
Accepted: 12 August 2013
Published: 17 August 2013
The leaf-cutter ant Atta laevigata (Formicidae: Attini) is an agricultural pest largely distributed in the Neotropics and a model organism for studies of evolution, speciation and population genetics. Microsatellites are a very powerful tool for these kind of studies, but such markers are not available for studies on A. laevigata. In the present report, we describe the isolation and characterization of nine microsatellite loci in A. laevigata and the testing of these markers across other species of leaf-cutter ants.
Nine microsatellite loci, consisting of six dinucloeotide, one trinucleotide, one tetranucleotide, and one di/trinucleotide repeat motifs, were isolated and characterized. Primers and protocols were successfully designed to selectively amplify these markers. To test effectiveness of these markers for detailed population genetic studies, we genotyped female workers collected from 36 monogynic nests of A. laevigata and found that eight loci were within Hardy–Weinberg expectations, while the remaining locus had a deficiency of heterozygotes. Micro-Checker analysis of individuals from 55 monogynic nests indicated that loci Alae11, Alae24, Alae18 showed signs of null alleles. For the remaining six loci, the number of alleles per locus ranged between 2 and 11, with expected heterozygosity ranging between 0.07 and 0.88. All of these loci cross-amplified in other species of Atta.
These six polymorphic microsatellite loci should prove useful for future genetic investigations of the pest species Atta laevigata, as well as studies of other species of leaf-cutter ants in the genus Atta.
Atta laevigata (Smith 1858) belongs to a group of ants called leaf-cutter ants, representing 15 described species in the genus Atta and 24 species in the genus Acromyrmex. The broad distribution of A. laevigata throughout the Neotropics makes this species a model organism for detailed phylogeographic studies. Based on variation in morphology, previous authors proposed that A. laevigata should be divided in two different species. However, morphological differences supporting this division are currently attributed to caste and biogeographic variations within a single species. More recently, two sympatric and distinct morphotypes of this ant have been characterized (Bezerra et al., pers. com). Therefore, it seems that a very recent and perhaps still ongoing process of speciation is taking place in A. laevigata. Thus, this ant is a promising model organism for studies of speciation. One means of testing for incipient speciation is to evaluate patterns of gene flow between these two sympatric forms.
Microsatellite markers proved to be very effective for estimating gene flow between recently isolated species. Unfortunately, no nuclear microsatellite markers have been described for A. laevigata. This paper presents a characterization of nine nuclear microsatellite loci derived from A. laevigata.
In order to isolate microsatellite loci, we constructed an enriched library for tetranucleotide loci following the methodology of Hamilton et al.. Total genomic DNA was extracted from a single specimen of A. laevigata as per the protocol of Martins et al. and digested with two restriction endonucleases, BstUI and XmnI. DNA fragments (400–1000 bp) were eluted from an agarose gel using the GFX PCR DNA and Gel Band Purification Kit (Ge HealthCare, Buckinghamshire, UK). The enrichment protocol consisted of attaching SuperSNX adapters to fragment ends of eight biotinylated oligonucleotides [(AAAC)6, (AAAG)6, (AATC)6, (AATG)6, (ACCT)6, (ACAG)6, (ACTC)6, (ACTG)6)] and isolation on streptavidin-coated magnetic beads (Promega, Madison, WI). The recovered DNA was enriched by polymerase chain reaction using the SuperSNX primers, linked into a vector using the CloneJET PCR Cloning Kit (Fermentas, Glen Burnie, MD), and transformed into competent DH10B E. coli cells.
A total of 384 clones were sequenced in an ABI 3500 automated sequencer (Applied Biosystems, Foster City, CA) using the BigDye Terminator v3.1 Cycle Sequencing Kit (Applied Biosystems, Foster City, CA). Products containing repetitive sequences were identified using the software CID (Clipping Vectors, Identifying SSR, Designing Primers). Selected sequences were manually inspected for repeats and flanking regions. Primers were designed using Generunner 3.01 (Hastings Software Inc., Hastings on Hudson, NY). In order to characterize and optimize the nine microsatellite loci identified from the initial screening, 36 A. laevigata female workers in a population in São Paulo state (southwest Brazil) were examined. Each worker was collected from a different monogynic nest.
Polymerase chain reactions were performed using a three primer labeling system in a final volume of 15 μl containing 2 pmol of a specific forward primer, 8 pmol of a specific reverse primer, 8 pmol of M13(−21) universal primer labeled with 6-FAM or NED, 0.125 mM dNTPs, 1× PCR buffer, 1.5 mM MgCl2, 1 U Taq DNA Polymerase (Fermentas, Glen Burnie, MD) and ~25 ng template DNA. The amplification protocol was: 95°C (4 min), 35 cycles at 94°C (30 s), 44–56°C (30 s) and 72°C (30 s), followed by 12 cycles at 94°C (30 s), 53°C (45 s), 72°C (45 s) and a final extension at 72°C for 20 min. Amplicons were analyzed with an ABI 3500 (Applied Biosystems, Foster City, CA) automated sequencer and the alleles were scored against the internal GeneScan-600 (LIZ) size standard kit (Applied Biosystems, Foster City, CA).
Tests for Hardy-Weinberg and linkage disequilibrium were performed using Genepop[11, 12] and significance values were obtained by the Markov chain method (10,000 dememorization number; 1,000 batches; 10,000 iterations per batch). Bonferroni correction was used to adjust for multiple comparisons and the presence of null alleles for each locus was verified with the Micro-Checker software.
Characterization of nine microsatellite loci isolated from Atta laevigata
Primer sequence (5'-3', forward / reverse)
HW p- value
AGTTTCTGCAATATTCGC / TCTGTGAGAGAGCAAGTGAG
(TC) 1(TCC) 2(TC) 9tt(TC) 4
GCAAAGACATCGTAAAGTG / TGCAACCGTCTTGTATG
TCTTGTAAGTAACTGTCGAGC / CGTCATATCCGAATGTCAG
CGCTACATCCCATCTCAC / GACAGCAATATTTCGATAGC
CACGATAGTTTTCGATATCC / TGGGTGTATCAAAGAAAGAC
ACTATGTCCATGTTATGCG / GACTACAAGTAAGAATAGTGAGC
ACATGTCCACTCCGTCAG / CGATAGCGTGATATTTGC
GACGTGGAGCTGCAATAC / AAGTGAGTACAAAACATACAGG
GCAATAAATTCAGATGGC / CTGCAAAATCACAGTTGC
Loci Alae2, 5, 9, 10, and 16 were polymorphic for 10 individuals of Atta robusta, a species belonging to a different subgenus (Neoatta) from that of A. laevigata (subgenus Epiatta). This suggests that the five selected loci should work for most of the Atta species occurring in Brazil.
This panel of microsatellite loci will be useful DNA markers for genetic studies of A. laevigata, providing important data for the understanding of biology, evolution, and genetic diversity of this species. They will be also useful for studies on other leaf-cutter ants in the Atta genus.
Availability of supporting data
The microsatellite sequences are available through the National Center for Biotechnology Information (http://ncbi.nlm.nih.gov) under the accession numbers KC571624 to KC571632.
We thank Cintia Bezerra for providing the worker ants used to test microsatellite loci. This work was funded by CNPq and FAPESP.
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