Existence of multiple isoforms of HS1-associated protein X-1 in murine and human tissues.

To date, the literature concerning the HS1 (haematopoietic cell-specific protein 1)-associated protein X-1 (HAX1) protein has reported considerable variation regarding its function in mammalian cells, subcellular localisation and binding partners. We show here that HAX1 comprises a family of proteins. Murine tissues express three mRNA variants, encoded by two genes on chromosomes 2 and 3. The chromosome 2 gene is intronless and would encode a protein 100% identical with that encoded by chromosome 3. In humans, alternative splice variants, encoded by the chromosome 1 gene, produce a family of transcripts composed of up to eight members. Based on the sequences published in GenBank and Ensembl, we designed specific primers and detected by PCR three mRNA species in murine tissues and eight variants in human cells. We screened a panel of 19 human cell lines as well as primary fibroblasts, oral keratinocytes and freshly isolated peripheral blood mononuclear cells. All human cells studied expressed at least six of the possible HAX1 mRNA variants. In silico analysis of the variants revealed an open reading frame in all of them, suggesting that murine and human tissues can express two and eight HAX1 proteins, respectively. Analysis of human protein lysates by Western blotting with the use of a monoclonal anti-HAX1 antibody revealed multiple bands. These bands were decreased after treatment of cells with a single small interfering RNA duplex targeting a region common to six of the variants, confirming their identity as HAX1 proteins. Comparison of the human variants with the six HAX1 homologues described to date in the chimpanzee (Pan troglodytes) and the four homologues described in macaque (Macaca mulatta) revealed very high conservation with only one amino acid substitution between human and chimpanzee homologues. Moreover, a number of additional products were amplified and sequenced, which indicated that further human isoforms are likely to exist. These findings are likely to explain the current confusion concerning putative HAX1 function.