The high-prevalence blood group antigen, Sd a , had been puzzling blood bankers and transfusionists for at least a decade when it was reported in 1967. The characteristic mix of agglutinates and free red blood cells (RBCs), caused by anti-Sd a , is seen with the RBCs from 90 percent of individuals of European descent. However, only 2-4 percent of individuals are truly Sd(a-) and may produce anti-Sd a . The antibodies, generally considered insignificant, may cause hemolytic transfusion reactions with high-expressing Sd(a+) RBCs (e.g., the unusual Cad phenotype, which can also be polyagglutinable). The Sd a glycan, GalNAcβ1-4(NeuAcα2-3)Gal-R, is produced in the gastrointestinal and urinary systems, while its origin on RBCs is more controversial. According to current theory, Sd a is likely to be passively adsorbed in low amounts, except in Cad individuals, where it has been found on erythroid proteins and at higher levels. The long-standing hypothesis that B4GALNT2 encodes the Sd a synthase was confirmed in 2019, since homozygosity for a variant allele with rs7224888:C produces a non-functional enzyme associated with most cases of the Sd(a-) phenotype. Thereby, the SID blood group system was acknowledged as number 038 by the International Society of Blood Transfusion. Although the genetic background of Sd(a-) was settled, questions remain. The genetic background of the Cad phenotype has not yet been determined, and the source of the RBC-carried Sd a is unknown. Furthermore, the interest of Sd a stretches beyond transfusion medicine. Some tantalizing examples are lowered antigen levels in malignant tissue compared with normal tissue and interference with infectious agents like Escherichia coli , influenza virus, and malaria parasites.