Identifying common sequence variations known as single nucleotide polymorphisms (SNPs) in human populations is one of the current objectives of the human genome project. Nearly 3 million SNPs have been identified. Analysis of the relative allele frequency of these markers in human populations and the genetic associations between these markers, known as linkage disequilibrium, is now underway to generate a high-density genetic map. Because of the central role T cells play in immune reactivity, the T-cell receptor (TCR) loci have long been considered important candidates for common disease susceptibility within the immune system (e.g., asthma, atopy and autoimmunity). Over the past two decades, hundreds of SNPs in the TCR loci have been identified. Most studies have focused on defining SNPs in the variable gene segments which are involved in antigenic recognition. On average, the coding sequence of each TCR variable gene segment contains two SNPs, with many more found in the 5', 3' and intronic sequences of these segments. Therefore, a potentially large repertoire of functional variants exists in these loci. Association between SNPs (linkage disequilibrium) extends approximately 30 kb in the TCR loci, although a few larger regions of disequilibrium have been identified. Therefore, the SNPs found in one variable gene segment may or may not be associated with SNPs in other surrounding variable gene segments. This suggests that meaningful association studies in the TCR loci will require the analysis and typing of large marker sets to fully evaluate the role of TCR loci in common disease susceptibility in human populations.