Variability of the major histocompatibility complex is very suitable for investigating a wide range of open questions in evolutionary ecology and conservation because it reflects evolutionarily relevant and adaptive processes within and between populations. First, the 1st full-length expressed DQB and DRB gene products in the order Cetacea from 2 species of bottlenose dolphins (genus Tursiops, family Delphinidae) of the western Pacific, which differ in their diet, microflora, and habitat, was presented. These species might represent a natural model through which we can examine the immunogenetic consequences of different pathogenic and environmental influences on the MHC of mammals. Blood samples from 2 T. aduncus (from Taiwan and Indonesia) and 2 T. truncatus (from Taiwan and Japan) were used for RACE-PCR. The presence of 1 DQB locus and 2 DRB loci in this genus was revealed. The presence of Tutr-DQB, Tuad-DRB, and Tutr-DRB suggests a functional role for these molecules in pathogen-specific immune responses. However, several features do not support a traditional role for Tuad-DQB molecules in peptide binding, and further study is needed. The phylogenetic analysis revealed that the sequence divergence of these 2 species might reflect different selective pressures between pathogens in oceanic (T. truncatus) and coastal (T. aduncus) waters. This study provides an essential foundation for analyzing variations in MHC genes and studying infectious disease ecology in bottlenose dolphins. For a better understanding of the immunologic diversity in bottlenose dolphins, the sequence variation of the exon 2 region of MHC DQB locus was analyzed in 62 bottlenose dolphins (42 T. truncatus and 20 T. aduncus), collected from strandings and fishery bycatch in Taiwanese waters. The 172 bp sequences amplified showed no more than two alleles in each individual. The high proportion of nonsynonymous nucleotide substitutions and the moderate amount of variation suggest positive selection pressure on this locus, arguing against a reduction in the marine environment selection pressure. The phylogenetic relationship among DQB exon 2 sequences of bottlenose dolphins and other delphinids did not coincide with taxonomic relationship, indicating a trans-species evolutionary pattern. Moreover, there is no mixture but a clear division between T. truncatus and T. aduncus, indicating that different selective pressures from pathogens exist in oceanic and coastal waters because shallow waters along the coast may influence by the terrestrial runoff and the pathogen diversity and abundance in the coastal waters may be different from that in the oceanic area. The habitat-specific alleles may have adaptive value for certain species and can be discriminately selected. Lastly, the evolutionary relationship and estimates of divergence time of cetartiodactyls by using MHC class II genes was reported. The results suggest that cetaceans (T. truncatus and T. aduncus) diverged from artiodactyls (pig, hippo, and ruminants) about 60 Mya or slightly earlier and the pathogen-driven directional selection is very likely the driving force of the sequence divergence of MHC genes of the cetaceans and the terrestrial relatives. Furthermore, the results show that T. truncatus and T. aduncus diverged about 24 Mya, which predates the emergence of oldest dolphin (approximately 11 Mya) quite much. It implies that these allelic lineages were maintained for a long evolutionary period through speciation events by balancing selection and the long persistence time could allow the accumulation of multiple substitutions between allelic lineages. This research provides new insights into the dynamics of MHC-pathogen coevolution and is the first study on the evolutionary history of cetartiodactyls using the MHC class II genes.