Genotyping of DRB1 and DRB3/4/5 is performed in our lab using generic DRB PCR primers, followed by sequencing on the 454 GS FLX and use of Conexio Genomics software. During genotyping homozygous cell lines, we detected additional sequences at about 7% of the read depth of the reported true allele. These artifacts appeared to be PCR crossovers between the DRB1 and DRB3/4/5 sequences. The crossovers usually had one or more mismatches with the IMGT database but occasionally matched a very rare allele (e.g. DRB1 ∗ 03:42). We performed a study to determine if these sequences were in vitro artifacts and to determine if some rare DRB alleles in the IMGT database might, in fact, be in vitro artifacts that had been submitted.To test for in vitro artifact formation during late cycles of genomic PCR, we amplified the DRB loci from 21 homozygous cells lines under both our standard PCR conditions (35 cycles) and a reduced number of cycles (28), followed by 454 sequencing. Using the same PCR conditions, we also sequenced the DRB loci of four samples, each of which had previously been identified as having a novel DRB allele that was subsequently submitted to the IMGT database.For all homozygous 21 cell lines, amplification for 35 cycles gave low abundance sequences as possible “second alleles.” In 36% of the cases, these artifactual sequences corresponded to named alleles. Such sequences were not detected with amplification for 28 cycles. In the case of 4 samples with rare alleles previously submitted to the IMGT, we found that 3 were true alleles. The fourth, while not a crossover product, contained a sequencing error which was revealed by our 454 HLA genotyping assay.Formation of in vitro crossover products of the DRB loci can occur in late cycles of PCR. PCR conditions have been identified that minimize generation of these in vitro artifacts. Clonal sequencing on the 454 GS FLX is a valuable method for revealing both these artifacts and traditional sequencing errors.