Nearly 300 blood group specificities on red cells are known, many of which are polymorphic. The molecular mechanisms responsible for these polymorphisms are diverse, though the majority represent single nucleotide polymorphisms (SNPs) encoding amino acid substitutions. Other mechanisms include the following: gene deletion; single nucleotide deletion and sequence duplication, which introduce reading-frame shifts; nonsense mutation; intergenic recombination between closely-linked genes, giving rise to hybrid genes and hybrid proteins; and a SNP in the promoter region of a blood group gene. Examples of these genetic mechanisms are taken from the ABO, Rh, Kell, and Duffy blood group systems. Null phenotypes, in which no antigens of a blood group system are expressed, are not generally polymorphic, but provide good examples of the effect of inactivating mutations on blood group expression. As natural human 'knock-outs' they provide useful clues to the functions of blood group antigens. Knowledge of the molecular bases to blood group polymorphisms provides a means to predict blood group phenotype from genomic DNA with a high degree of accuracy. This currently has two main applications in transfusion medicine: for determining fetal blood groups to assess whether the fetus is at risk from haemolytic disease; and to determine blood group phenotypes in multiply transfused, transfusion-dependent patients, where serological tests are precluded by the presence of donor red cells. Other applications are being developed for the future.