Summary In this study, we describe the first set of SNP markers for the South African abalone, Haliotismidae. A cDNA library was constructed from which ESTs were selected for the screening ofSNPs. The observed frequency of SNPs in this species was estimated at one every 185 bp.When characterized in wild-caught abalone, the minor allele frequencies and F ST estimatesfor every SNP indicated that these markers may potentially be useful for populationanalysis, parentage assignment and linkage mapping in Haliotis midae. No linkagedisequilibrium was observed between SNPs originating from different EST sequences. TheseSNPs, together with additional SNPs currently being developed, will provide a usefulcomplementary set of markers to the currently available genetic markers in abalone.Keywords expressed sequence tag, Haliotis midae, single nucleotide polymorphism.A commercially valuable species of abalone, Haliotis midae,inhabits the rocky shores of South Africa and is one of over50 Haliotis species found worldwide. The increasing demandand overexploitation of this marine mollusc necessitated thedevelopment and implementation of genetic managementpractices in natural as well as commercial stocks. Thepopulation genetic status of H. midae has so far beeninvestigated using allozymes, mtDNA sequence data andnon-species-specific microsatellite markers (Evans et al.2004). Although the isolation of species-specific micro-satellites (Bester et al. 2004; Slabbert et al. 2008) promises afiner-scale inference of H. midae stock structure, SNPs arealso considered for population genetic analysis in view ofthe potential limitations of microsatellite loci. Morin et al.(2004) reviews a number of advantages of SNPs over othermarker types for the inference of population structure.Unlike microsatellite loci, SNPs occur more frequently in thegenome, are extremely stable due to low mutation rates(Sachidanandam et al. 2001) and most importantly, SNPalleles are almost exclusively identical-by-decent (IBD),preventing scoring errors associated with homoplasy. Froma technical perspective, the identification of SNPs can bemade simple and inexpensive using high-throughputgenotyping technology.Given the relative paucity of functional sequence datafromH.midae,theneedarosetocreateandsequenceacDNAlibrary for this species. SNPs identified within thesesequences can potentially be used as type I markers inpopulationgeneticanalysisandlinkagemappingofH.midae.Inthisstudy,wedescribethedetectionof20SNPlociandthefurther characterization of 12 of them using a targeted geneapproach.Acollaborativeefforttoimprovethegeneticstatusof H. midae, while conserving natural stocks, is expected tobenefit greatly from this marker information.For the construction of a cDNA library, material wasobtained from farmed abalone and was snap-frozen in liquidnitrogen. Total RNA was extracted from 200 mg gill tissueby homogenization with one-step RNA Reagent (Bio BasicInc.). Approximately 150 lg of RNA was purified using apolyA Spin mRNA isolation kit (New England Biolabs) and2 lg mRNA was used in cDNA library construction (Pro-mega Universal Riboclone cDNA Synthesis System). cDNAinserts were cloned into a pGEM 4Z vector (Promega), andthis was followed by plasmid miniprep DNA isolation(QIAprep Spin Miniprep kit; QIAGEN) and sequencing in atleast one direction using vector-specific primers (M13).Vector and adaptor sequences were removed using