Abstract
Secretory human prostatic acid phosphatase (hPAP) is glycosylated at three asparagine residues (N62, N188, N301) and has potent antinociceptive effects when administered to mice. Currently, it is unknown if these N-linked residues are required for hPAP protein stability and activity in vitro or in animal models of chronic pain. Here, we expressed wild-type hPAP and a series of Asn to Gln point mutations in the yeast Pichia pastoris X33 then analyzed protein levels and enzyme activity in cell lysates and in conditioned media. Pichia secreted wild-type recombinant (r)-hPAP into the media (6–7 mg protein/L). This protein was as active as native hPAP in biochemical assays and in mouse models of inflammatory pain and neuropathic pain. In contrast, the N62Q and N188Q single mutants and the N62Q, N188Q double mutant were expressed at lower levels and were less active than wild-type r-hPAP. The purified N62Q, N188Q double mutant protein was also 1.9 fold less active in vivo. The N301Q mutant was not expressed, suggesting a critical role for this residue in protein stability. To explicitly test the importance of secretion, a construct lacking the signal peptide of hPAP was expressed in Pichia and assayed. This “cellular” construct was not expressed at levels detectable by western blotting. Taken together, these data indicate that secretion and post-translational carbohydrate modifications are required for PAP protein stability and catalytic activity. Moreover, our findings indicate that recombinant hPAP can be produced in Pichia—a yeast strain that is used to generate biologics for therapeutic purposes.
Highlights
Prostatic acid phosphatase (Pap, known as Acpp) is a single gene that encodes two extracellularly active enzymes: 1. secretory (S-) and 2. transmembrane (TM-) PAP [1]
We observed a single 50 kDa immunoreactive band in conditioned media from r-human prostatic acid phosphatase (hPAP) transformants but not in media from untransformed P. pastoris X33 controls (Figure 1A). This 50 kDa band corresponded to the known molecular weight of native S-PAP [21], and indicated that recombinant human S-PAP (r-hPAP) was secreted into the medium by Pichia. r-hPAP was detected in the lysate at the 48 hour time point (Figure 1A), reflective of full-length protein within secretory organelles
Three of these mutants [r-hPAP (N62Q), r-hPAP (N188Q) and r-hPAP (N62Q, N188Q)] were expressed and active in the cellular fraction and secreted fraction, suggesting key elements of the tertiary and quaternary r-hPAP structure were conserved in these mutants
Summary
Prostatic acid phosphatase (Pap, known as Acpp) is a single gene that encodes two extracellularly active enzymes: 1. secretory (S-) and 2. transmembrane (TM-) PAP [1]. Transmembrane (TM-) PAP [1]. S-PAP is expressed in prostate epithelial cells and has long been used as a prostate cancer biomarker [2]. S-PAP was thought to be prostate specific; recent studies revealed that the splice variant (TMPAP) was expressed in additional tissues, including salivary gland, lung, kidney, skeletal muscle and nociceptive (pain-sensing) dorsal root ganglia neurons [1,3]. Deletion of PAP reduces extracellular AMP hydrolysis in nociceptive neurons and in the dorsal spinal cord [5]. S-PAP (injected intrathecally) has long-lasting (three-day) antinociceptive effects in mouse models of inflammatory pain and neuropathic pain and these antinociceptive effects are entirely adenosine A1 receptor (A1R) dependent [3,6].
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