Phylogenetic and experimental characterization of an acyl-ACP thioesterase family reveals significant diversity in enzymatic specificity and activity

Background

The inorganic (P_i) phosphate transporter (PiT) family comprises known and putative Na⁺- or H⁺-dependent P_i-transporting proteins with representatives from all kingdoms. The mammalian members are placed in the outer cell membranes and suggested to supply cells with P_i to maintain house-keeping functions. Alignment of protein sequences representing PiT family members from all kingdoms reveals the presence of conserved amino acids and that bacterial phosphate permeases and putative phosphate permeases from archaea lack substantial parts of the protein sequence when compared to the mammalian PiT family members. Besides being Na⁺-dependent P_i (NaP_i) transporters, the mammalian PiT paralogs, PiT1 and PiT2, also are receptors for gamma-retroviruses. We have here exploited the dual-function of PiT1 and PiT2 to study the structure-function relationship of PiT proteins.

Results

We show that the human PiT2 histidine, H₅₀₂, and the human PiT1 glutamate, E₇₀, - both conserved in eukaryotic PiT family members - are critical for P_i transport function. Noticeably, human PiT2 H₅₀₂ is located in the C-terminal PiT family signature sequence, and human PiT1 E₇₀ is located in ProDom domains characteristic for all PiT family members. A human PiT2 truncation mutant, which consists of the predicted 10 transmembrane (TM) domain backbone without a large intracellular domain (human PiT2ΔR₂₅₄-V₄₈₃), was found to be a fully functional P_i transporter. Further truncation of the human PiT2 protein by additional removal of two predicted TM domains together with the large intracellular domain created a mutant that resembles a bacterial phosphate permease and an archaeal putative phosphate permease. This human PiT2 truncation mutant (human PiT2ΔL₁₈₃-V₄₈₃) did also support P_i transport albeit at very low levels.

Conclusions

The results suggest that the overall structure of the P_i-transporting unit of the PiT family proteins has remained unchanged during evolution. Moreover, in combination, our studies of the gene structure of the human PiT1 and PiT2 genes (SLC20A1 and SLC20A2, respectively) and alignment of protein sequences of PiT family members from all kingdoms, along with the studies of the dual functions of the human PiT paralogs show that these proteins are excellent as models for studying the evolution of a protein's structure-function relationship.