Abstract
We characterized sequences of a novel SSS139 RsaI satellite DNA family in Drosophila gouveai and Drosophila seriema, two members of the Drosophila buzzatii cluster (D. repleta group). The sequences were AT-rich (69%) with a monomer unit length of about 139 bp and contained two direct subrepeats of 14 bp and 16 bp, suggesting that it might have originated by the duplication of smaller sequences. Southern and dot-blot hybridization analyses also detected SSS139 in other Drosophila buzzatii cluster species (D. koepferae, D. antonietae, D. borborema and D. serido) but not in D. buzzatii. These results agree with the marginal phylogenetic position of D. buzzatii within the D. buzzatii cluster.
Drosophila buzzatii cluster; molecular evolution; repetitive DNA; satellite DNA; SSS139 satellite DNA
EVOLUTIONARY GENETICS
SHORT COMMUNICATION
Molecular characterization of SSS139, a new satellite DNA family in sibling species of the Drosophila buzzatii cluster
Fernando F. FrancoI; Fabio M. SeneI; Maura H. ManfrinII
IDepartamento de Genética, Faculdade de Medicina de Ribeirão Preto,Universidade de São Paulo, Ribeirão Preto, SP, Brazil
IIDepartamento de Biologia, Faculdade de Filosofia Ciências e Letras de Ribeirão Preto, Universidade de São Paulo, Ribeirão Preto, SP, Brazil
Send correspondence to Send correspondence to: Fernando F. Franco Departamento de Genética, Faculdade de Medicina de Ribeirão Preto Universidade de São Paulo Av. dos Bandeirantes, Bloco A 14049-900 Ribeirão Preto, SP, Brazil E-mail: fffranco@rge.fmrp.usp.br
ABSTRACT
We characterized sequences of a novel SSS139 RsaI satellite DNA family in Drosophila gouveai and Drosophila seriema, two members of the Drosophila buzzatii cluster (D. repleta group). The sequences were AT-rich (69%) with a monomer unit length of about 139 bp and contained two direct subrepeats of 14 bp and 16 bp, suggesting that it might have originated by the duplication of smaller sequences. Southern and dot-blot hybridization analyses also detected SSS139 in other Drosophila buzzatii cluster species (D. koepferae, D. antonietae, D. borborema and D. serido) but not in D. buzzatii. These results agree with the marginal phylogenetic position of D. buzzatii within the D. buzzatii cluster.
Key words: Drosophila buzzatii cluster, molecular evolution, repetitive DNA, satellite DNA, SSS139 satellite DNA.
Satellite DNA consists of highly repetitive and tandemly arranged DNA sequences (Charlesworth et al., 1994) which are considered the main components of constitutive heterochromatin and are usually located in the centromeric regions of chromosomes and, less frequently, in telomeres (Charlesworth et al., 1994; Ugarkovic and Plohl, 2002). Satellite DNAs are heterogeneous and no general function has been attributed to this DNA class. However, despite the terminology "junk DNA" frequently associated with these sequences (Orgel and Crick, 1980), several biological roles have been suggested for some satellite DNA families, such as regulation of both heterochromatin condensation and genetic expression (reviewed by Ugarkovic, 2005). Moreover, satellite DNAs are involved in the maintenance of functional centromeres in mammals (Willard, 1990) and might also be related to the late replication of centromeres (Csink and Henikoff, 1998).
The satellite DNA sequences evolve in a concerted manner (Dover, 1982) and the main molecular mechanisms involved in its evolution are slippage replication, unequal crossing-over, gene conversion and rolling circle replication, which can, in general, induce a strong intra-specific homogenization of satellite DNA sequences and inter-specific divergence (Dover, 1982; Charlesworth et al., 1994).
The monomers of a satellite DNA can be species-specific (Bachmann et al., 1994; Abadon et al., 1998) or shared among phylogenetically related species (Watabe et al., 1997; Lopez-Flores et al., 2004; Kuhn and Sene, 2005). Though there are examples of extremely conserved satellite DNA sequences among species that diverged for long evolutionary periods (de la Herrán et al., 2001; Mravinac et al. 2002), most satellite DNA shared among species presents high evolutionary rates, acquiring diagnostic mutations for each species.
The Drosophila buzzatii cluster (D. repleta group, D. buzzatii complex) is a monophyletic group composed by cactophilic and sibling species that are naturally endemic to South America (Manfrin and Sene, 2006). Currently, the D. buzzatii cluster is composed of seven nominal Drosophila species (D. antonietae, D. borborema, D. buzzatii, D. gouveai, D. koepferae, D. serido and D. seriema). According to aedeagus and wing morphology, the D. buzzatii cluster can be divided into two species groups (Tidon-Sklorz and Sene, 2001; Moraes et al., 2004). One of them is composed by D. buzzatii populations, and another group, called the D. serido sibling set, is composed by the remaining D. buzzatii cluster species.
The species of the D. buzzatii cluster share pBuM satellite DNA, an AT-rich family which can be divided into two subfamilies, pBuM-1, consisting of tandemly arranged repetition units of approximately 190 bp, and pBuM-2 made up of 370 bp units in the same arrangement (Kuhn et al., 1999; Kuhn and Sene, 2005). The sequences of the pBuM satellite DNA family have diagnostic nucleotide substitutions for the species of the D. buzzatii cluster as well as quantitative differences among them (Kuhn and Sene, 2005). At the intraspecific level, a strong interpopulational similarity was found in the pBuM sequences in D. buzzatii, D. seriema and D. gouveai (Kuhn et al., 2003; Kuhn and Sene, 2004; Franco et al., 2006). All species of the D. buzzatii cluster also contain the CG-rich DBC-150 satellite DNA composed of 150 bp monomers and restricted to dot chromosomes (Kuhn et al., 2007). An interesting characteristic of DBC-150 is the low rates of homogenization presented in relation the pBuM family, which might be related to its exclusive location in the dot chromosomes, a region with presumed suppressed meiotic recombination.
In the present paper we describe how we characterized a RsaI satellite DNA family in D. gouveai and D. seriema (D. buzzatii cluster; D. serido sibling set) and used Southern and dot blot analyses to detected its presence in other members of the D. serido sibling set. We also discuss the origin of this satellite DNA and its presence/absence pattern in the D. buzzatii cluster in relation to the phylogenetic hypothesis available of this group.
Seven strains representing all species of the Drosophila buzzatii cluster, were studied: D. antonietae H84P4 (Sertãozinho, SP, Brazil); D. borborema 1281.0 (Cafarnaum, BA, Brazil); D. buzzatii J79H41 (Ibotirama, BA, Brazil); D. gouveai H74M2 (Altinópolis-SP, Brazil); D. koepferae B20D2 (Tapia, Argentina); D. serido 1431.4 (Cafarnaum, BA, Brazil) and D. seriema D71C1B (Morro do Chapéu-BA, Brazil). These species are maintained in the Genetic Evolution Laboratory (Laboratório de Genética Evolutiva) at the University of São Paulo, Ribeirão Preto, Brazil.
The genomic DNA of adult flies was extracted according to Preiss et al. (1988) and that of D. gouveai (H74M2) and D. seriema (D71C1B) digested with the RsaI restriction enzyme (Invitrogen) and electrophoresed on 5% polyacrylamide gel using a 100 base-pair ladder marker (Fermentas) as standard. Prominent bands of approximately 150 bp were eluted from the gel by overnight incubation at 37 °C in an elution solution containing 500 mM sodium acetate plus 1 mM ethylenediaminetetraacetic acid (EDTA) and the recovered fragments ligated to a pUC18 plasmid vector (Amersham) and transformed in competent E. coli DH5-a (Amersham), recombinant clones being identified using the b-galactosidase blue-white selection system (Sambrook et al., 1989). Plasmid DNA was prepared according the methodology described in Sambrook et al. (1989) and the DNA template reaction for sequencing was prepared according to the BigDye Terminator Cycle Sequencing Ready Reaction Kit manual (Perkin-Elmer). Automatic DNA sequencing was performed on an ABI Prism 377 sequencer (Perkin-Elmer).
Southern hybridization of all D. buzzatii cluster species was carried out using 5 mg of genomic DNA from each of the strains tested. The DNA was digested with RsaI and the fragments separated in 1% agarose gel and blotted onto nylon membranes (Amersham) according to Sambrook et al. (1989). Labeling of probe DNA (clone D71C1B-150/10) was done using the Random Primers DNA Labeling System (Gibco BRL) and membranes were hybridized at 60 °C overnight in a hybridization solution containing 7% sodium dodecyl sulfate (SDS) and 0.5 M Na2HPO4 and washed twice at about 25 °C for 15 min in a solution containing 5% SDS, 40 mM Na2HPO4 and 1 mM EDTA. For dot-blot analyses 50 ng, 100 ng and 250 ng of genomic DNA from each of the D. buzzatii cluster species tested were placed on nylon membranes (GE Healthcare) and denatured with a solution containing 0.5M NaOH and 1.5 M NaCl, neutralized with a solution containing 1 M Tris-Base and 1.5 M NaCl (pH 7.4) and then rinsed with 2x saline-sodium citrate (SSC) buffer. The membranes were then dried and UV crosslinked. The labeling of the probe and hybridization used the conditions described above for Southern hybridization. Genomic DNA from Drosophila coroica (D. repleta group, D. fasciola subgroup) was used as negative control and the sequence of the clone D71C1B-150/10 as the positive control.
The alignment of the sequences was carried out using the CLUSTAL W program v1.8 (Thompson et al., 1994) and sequences homology searches were performed on the NCBI GenBank using BLASTn (Altschul et al., 1990). Detection of direct repeats in the satellite DNA monomers was performed on the consensus sequence using the online search program OligoRep.
We obtained six sequences, four from D. seriema (GenBank EF035014 to EF035017) and two from D. gouveai (GenBank EF035018 and EF035019). The high similarity found in all sequences indicating that they belonged to the same DNA family (Figure 1). All of the sequences obtained were AT-rich (~69% on average) and their sizes range from 138 bp (D71C1B-150/14) to 145 bp (H74M2-150/3).
Southern hybridization revealed a ladder pattern, characteristic of highly repetitive sequences (Plohl et al. 2004). The presence of additional and larger than expected bands (~140 bp) of decreasing intensity is explainable by the variability presented at the restriction enzyme recognition site in some copies in the tandem array (Figure 2a).
No homolog sequence obtained in this research was found in the NCBI GenBank (searched on May 15, 2007). These results indicate that the sequences described here constitute an uncharacterized satellite DNA family, which we called SSS139 (the letters are a reference for serido sibling set and the numbers representing the average monomer size). This satellite DNA is unrelated to the other two satellite families (pBuM and DBC-150) described for the D. buzzatii cluster species (Kuhn and Sene, 2005; Kuhn et al., 2007).
Despite the high nucleotide similarity (~95% on average), the SSS139 copies of D. gouveai and D. seriema have different nucleotides at positions 35, 50 and 72, suggesting that these sites might be species-specific. Moreover, the CATA sequence in positions 37 to 41 of the consensus sequence also might be specific for D. gouveai (Figure 1), suggesting that this satellite DNA evolved independently in D. gouveai and D. seriema. Indeed, concerted evolution can lead to fast divergence of satellite sequences in reproductively isolated species through independent horizontal spreading of variant monomers in a tandem array in each lineage (Dover, 1982; Charlesworth et al., 1994).
One of the hypotheses for the origin of satellite DNA monomers suggests the amplification, rearrangement and subsequent differentiation of small motifs (Ugarkovic and Plohl, 2002). Lee et al. (1997) proposed that satellite DNA I, shared among deer and cattle, emerged from a 31 bp motif that was initially amplified 25 times to form a complex monomer. It has also been proposed that HindIII satellite DNA family sequences (shared among species of sturgeons from the Ancipenser genus) with repetition units of from 169 bp to 172 bp evolved from various duplications of shorter sequences (de la Herrán et al., 2001). We found the direct subrepetitions 1a/1b (78.6% similarity) and 2a/2b (81.25% similarity) in the consensus sequence of SSS139 satellite DNA (Figure 1). This suggests that the SSS139 monomers may have evolved by duplication of smaller sequences and the later accumulated mutations, giving rise to a longer sequence that may have been amplified by the molecular mechanisms such as unequal crossing over or rolling circle replication which are often responsible for the increase of copy number in tandemly arranged sequences (Charlesworth et al., 1994). An alternative hypothesis is that the 1a/1b and 2a/2b subrepetitions emerged from a pre-existing SSS139 monomer and this repetition unit duplication carrier was spread horizontally by concerted evolution events.
The occurrence of SSS139 in other species of the D. buzzatii cluster was detected with the Southern blot (data not shown) and dot-blot analyses and there were signs of hybridization with the SSS139 probe for all the D. buzzatii cluster species forming the D. serido sibling set, but not for D. buzzatii strains (Figure 2b). However, although our data suggests the absence of SSS139 in D. buzzatii species, the hypothesis that SSS139 is highly divergent or is present in a residual quantity in D. buzzatii cannot be discarded because the Southern and dot blot analyses were performed under high stringency conditions.
According to phylogenies based on mitochondrial (Manfrin et al., 2001) and nuclear genes (Rodriguez-Trelles et al., 2000), D. buzzatii belongs to the most basal lineage of the D. buzzatii cluster. Furthermore, among the species of the cluster, D. buzzatii has a primitive pattern of chromosome inversions (Ruiz and Wasserman, 1993) and is the most reproductively isolated species (Marin et al., 1993; Madi-Ravazzi et al., 1997; Machado et al., 2006). Morphologically, the aedeagus and wing morphometry of this species is different from that of the other species of the cluster (Tidon-Sklorz and Sene 2001; Moraes et al., 2004; Manfrin and Sene, 2006). In this context, it is not surprising that other species in the D. buzzatii cluster share characteristics not found in D. buzzatii.
With regard to the satellite DNA, the pBuM (Kuhn et al., 1999; Kuhn and Sene, 2005) and the SSS139 families have yielded some insights into the evolutionary relationships of the species from the D. buzzatii cluster. Regarding the pBuM family, D. buzzatii presents the most divergent sequences and shows several species-specific substitutions. Nevertheless, sequences of this satellite DNA from other species from the D. buzzatii cluster present relatively fewer diagnostic mutations (Kuhn et al., 1999; Kuhn and Sene, 2005). The presence or absence pattern of the SSS139 satellite DNA family also subdivides D. buzzatii cluster species into the D. buzzatii group (absence of SSS139) and the D. serido sibling set (presence of SSS139) (Figure 2b). The main conclusion from these data is that D. buzzatii is the most differentiated species of the D. buzzatii cluster, in agreement with its marginal phylogenetic position within the cluster (Manfrin et al. 2001; Rodriguez-Trelles et al., 2000).
As suggested by morphological characters, the D. serido sibling set species form a monophyletic group in a phylogeny based on the xanthine dehydrogenase nuclear gene (Rodriguez-Trelles et al., 2000). On the other hand, according to phylogeny based on mitochondrial DNA data the D. serido sibling set is polyphyletic due the phylogenetic position of D. koepferae as a sister group of D. buzzatii in the basal lineage (Manfrin et al., 2001). The pBuM and SSS139 satellite DNA data suggest that D. koepferae could be more closely related to the remaining D. serido sibling set species than to D. buzzatii species, thus supporting morphological (Tidon-Sklorz and Sene 2001; Moraes et al., 2004) and nuclear gene data (Rodriguez-Trelles et al., 2000) and in disagreement with mitochondrial DNA data (Manfrin et al., 2001). In this context, we suggest that the phylogenetic position of D. koepferae must be reconsidered by further studies using more molecular markers.
Acknowledgments
We thank Professor Nilce M. Martinez-Rossi for the use of her lababoratory for some of the experiments. We also are grateful to Paulo R. Epifanio and Roseli A.P. Ferreira for technical assistance, Gustavo C.S. Kuhn for reading the first draft of the manuscript and to anonymous referees for useful and critical comments. This work was supported by several grants from the Brazilian agencies Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES), Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq), Fundação de Amparo a Pesquisa do Estado de São Paulo (FAPESP, grant number 03/05031-0), Financiadora de Estudos e Projetos (FINEP) and Universidade de São Paulo (USP) to MHM. FAPESP made personal fellowships to FMS (grant number 04/08565-8) and FFF (grant number 05/51780-0).
Internet Resource
Received: January 25, 2007; Accepted: June 26, 2007.
Associate Editor: Louis Bernard Klaczko
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Publication Dates
-
Publication in this collection
28 Feb 2008 -
Date of issue
2008
History
-
Received
25 Jan 2007 -
Accepted
26 June 2007