Molecular taxonomy of cupped oysters (Crassostrea, Saccostrea, and Striostrea) in Thailand based on COI, 16S, and 18S rDNA polymorphism.

Genetic diversity of oysters Crassostrea belcheri (Sowerby, 1871), C. iredalei (Faustino, 1932), Saccostrea cucullata (Born, 1778), S. forskali (Gmelin, 1791), and Striostrea (Parastriostrea) mytiloides (Lamarck, 1819) (Ostreoida, Mollusca) was analyzed by polymerase chain reaction - restriction fragment length polymorphism (PCR-RFLP) of 16S ribosomal DNA with AcsI, AluI, DdeI, DraI, RsaI, and TaqI, 18S ribosomal DNA with HinfI, and cytochrome oxidase subunit I with AcsI, DdeI and MboI. A total of 54 composite haplotypes were observed. Species-diagnostic markers were specifically found in C. belcheri, C. iredalei, and S. cucullata, but not in S. forskali and Striostrea mytiloides, which shared common composite haplotypes. Neighbor-joining trees constructed from genetic distances between pairs of composite haplotypes and species indicated large genetic differences between Crassostrea and Saccostrea (including Striostrea mytiloides), but closer relationships were observed within each genus. Four groups of unidentified oysters (Crassostrea sp. and Saccostrea sp. groups 1, 2, and 3) were also genetically analyzed. Fixed RFLP markers were found in Crassostrea sp. and Saccostrea sp. group 2, but not in Saccostrea sp. groups 1 and 3. Phylogenetic and genetic heterogeneity analyses indicated that Crassostrea sp. and Saccostrea sp. group 2 should be considered as newly unidentified oyster species in Thailand.

Molecular genetic identification tools for three commercially cultured oysters (Crassostrea belcheri, Crassostrea iredalei, and Saccostrea cucullata) in Thailand.

Molecular genetic keys for identification of 3 commercially cultured oysters (Crassostrea belcheri, Crassostrea iredalei, and Saccostrea cucullata) in Thailand were developed based on restriction analysis of 18S ribosomal DNA and cytochrome oxidase subunit I (COI). Digestion of the amplified 18S rDNA with Hinf I unambiguously differentiated Crassostrea oysters from Saccostrea oysters and Striostrea (Parastriostrea) mytiloides. In addition, species-specific restriction fragment length polymorphism patterns of C. belcheri, C. iredalei, and S. cucullata were consistently observed when the gel-eluted COI was digested with Mbo I and Dde I. Thirty composite haplotypes were observed across all individuals. Species-specific composite haplotypes were found in C. belcheri (AAAA and AAAB), C. iredalei (AABC and AABU), and S. cucullata (BBCD and BBCE), respectively. The most common composite haplotype of COI in C. belcheri (AAAA), C. iredalei (AABC), and S. cucullata (BBCD) was amplified, cloned, and sequenced. Detection of C. belcheri and C. iredalei based on polymerase chain reaction was further developed using more specific primers (HCO2198 and R372) followed by digestion of a 372-bp product with Mbo I.

Genetic diversity and molecular markers of cupped oysters (genera Crassostrea, Caccostrea, and Striostrea) in Thailand revealed by randomly amplified polymorphic DNA analysis.

Genetic diversity and species-diagnostic markers of 5 oysters in Thailand, Crassostrea belcheri (Sowerby, 1871), Crassostrea iredalei (Faustino, 1932), Saccostrea cucullata (Born, 1778), Saccostrea forskali (Gmelin, 1791), and Striostrea Parastriostrea) mytiloides (Lamarck, 1819), were investigated by randomly amplified polymorphic DNA (RAPD) analysis. In a total, 135, 127, and 108 genotypes were observed from primers OPA09, OPB01, and OPB08 (Operon Technologies Inc., kits A and B), and 131 and 122 genotypes from primers UBC210 and UBC220 (University of British Columbia), respectively. Two hundred fifty-four reproducible and polymorphic fragments (200-2500 bp in length) were generated across the 5 investigated species. The average number of bands per primer varied between 12.4 and 32.2. The percentage of polymorphic bands within Crassostrea (53.23%-77.67%) was lower than that within Saccostrea and Striostrea oysters (86.21%-99.36%). Nine, species-specific markers were found in C. belcheri, 4 in C. iredalei, and 2 in S. cucullata. The mean of a ratio between the number of genotypes generated by each primer and the number of investigated specimens of C. belcheri (0.58) was lower than that of the remaining species (0.90-1.00). Genetic distances between pairs of oyster samples were between 0.105 and 0.811. A neighbor-joining tree indicated distant relationships between Crassostrea and Saccostrea oysters, but closer relationships were observed between the latter and Striostrea mytiloides.

Development of Species-Specific Markers of the Tropical Oyster (Crassostrea belcheri) in Thailand.

Randomly amplified polymorphic DNA (RAPD) analysis was used to identify species-specific markers of 5 oyster species in Thailand: Crassostrea belcheri, Crassostrea iredalei, Saccostrea cucullata, Saccostrea forskali, and Striostrea (Parastriostrea) mytiloides. Species-specific markers were found in C. belcheri, C. iredalei, and S. cucullata but not in S. forskali and S. mytiloides. Three C. belcheri-specific RAPD fragments were cloned and sequenced. A primer set was designed from each of the recombinant clones (pPACB1, pPACB2, and pPACB3). The polymerase chain reaction products showed expected sizes of 536, 600, and 500 bp, respectively, with the sensitivity of detection approximately 30 pg of C. belcheri total DNA template. The specificity of pPACB1 was examined against 135 individuals of indigenous oyster species in Thailand and against outgroup references S. commercialis (N = 12) and Perna viridis (N = 12). Results indicated the species-specific nature of primers developed from pPACB1. This primer set can be used for broodstock selection and determination of C. belcheri larvae to assist the selective breeding program for this commercially important species.