Identification and Molecular Biology of Variant D Blood Group of RHD*95A Genotype

Abstract

To explore the molecular biology of D variant blood group with RHD*95A genotype and the genetic mechanism of its generation. A total of 6 samples from 3 generations of a family were analyzed. RHD blood group was identified by saline test tube and microcolumn gel card method. 10 exons of RHD gene were amplified by Polymerase Chain Reaction-Sequence Specific Primer (PCR-SSP) and analyzed by direct sequencing. Homology modeling was used to compare the structural differences between mutant RHD protein and wild-type RHD protein. The proband was identified as D variant by serological identification, RHD gene sequencing directly detected a c. 95 c > A mutation in exon 1 that leads to encoding the 32-bit amino acids by threonine Thr (T) into aspartic acid Asn (N), the rest of the exon sequences were normal compared with the normal RHD*01 gene. In the family, the proband's father, grandmather and uncle were all carried the same RHD*95A allele. Protein modeling results suggested that the hydrogen chain connected to the 32nd amino acid residue was changed after p.T32N mutation, which affected the structural stability of RHD protein. The first genetic lineage of the RHD*95A gene was identified in a Chinese population. The c.95C>A mutation in RHD gene was found in the family, which resulted in reduced expression of RHD antigen and showed D variant, the mutation could be stably inheritable. Gene identification and protein structure analysis of D variant population is helpful to explore the molecular mechanism of its formation and ensure the safety of blood transfusion.