Native-state stability determines the extent of degradation relative to secretion of protein variants from Pichia pastoris.

We have investigated the relationship between the stability and secreted yield of a series of mutational variants of human lysozyme (HuL) in Pichia pastoris. We show that genes directly involved in the unfolded protein response (UPR), ER-associated degradation (ERAD) and ER-phagy are transcriptionally up-regulated more quickly and to higher levels in response to expression of more highly-destabilised HuL variants and those variants are secreted to lower yield. We also show that the less stable variants are retained within the cell and may also be targeted for degradation. To explore the relationship between stability and secretion further, two different single-chain-variable-fragment (scFv) antibodies were also expressed in P. pastoris, but only one of the scFvs gave rise to secreted protein. The non-secreted scFv was detected within the cell and the UPR indicators were pronounced, as they were for the poorly-secreted HuL variants. The non-secreted scFv was modified by changing either the framework regions or the linker to improve the predicted stability of the scFv and secretion was then achieved and the levels of UPR indicators were lowered Our data support the hypothesis that less stable proteins are targeted for degradation over secretion and that this accounts for the decrease in the yields observed. We discuss the secretion of proteins in relation to lysozyme amyloidosis, in particular, and optimised protein secretion, in general.

Activation of the unfolded protein response in Pichia pastoris requires splicing of a HAC1 mRNA intron and retention of the C-terminal tail of Hac1p.

We have shown that the unfolded protein response (UPR) in Pichia pastoris requires splicing of a non-conventional intron in the HAC1(u) mRNA in common with other eukaryotes. P. pastoris is a favoured yeast expression host for secreted production of heterologous proteins and the regulation of the UPR in P. pastoris may hold the key to its effective folding and secretion of proteins. We have also shown that the C-terminal region of the Hac1p from P. pastoris is required for functionality. Although the C-terminal regions of Hac1p from both S. cerevisiae and P. pastoris are rich in phenylalanine residues, the P. pastoris Hac1p lacks a C-terminal serine that is known to be important in the efficient functionality of Hac1p from S. cerevisiae.

Concanamycin and indolyl pentadieneamide inhibitors of the vacuolar H+-ATPase bind with high affinity to the purified proteolipid subunit of the membrane domain.

The macrolide antibiotic concanamycin is a potent and specific inhibitor of the vacuolar H(+)-ATPase (V-ATPase), binding to the V(0) membrane domain of this eukaryotic acid pump. Although binding is known to involve the 16 kDa proteolipid subunit, contributions from other V(0) subunits are possible that could account for the apparently different inhibitor sensitivities of pump isoforms in vertebrate cells. In this study, we used a fluorescence quenching assay to directly examine the roles of V(0) subunits in inhibitor binding. Pyrene-labeled V(0) domains were affinity purified from Saccharomyces vacuolar membranes, and the 16 kDa proteolipid was subsequently extracted into chloroform and methanol and purified by size exclusion chromatography. Fluorescence from the isolated proteins was strongly quenched by nanomolar concentrations of both concanamycin and an indolyl pentadieneamide compound, indicating high-affinity binding of both natural macrolide and synthetic inhibitors. Competition studies showed that these inhibitors bind to overlapping sites on the proteolipid. Significantly, the 16 kDa proteolipid in isolation was able to bind inhibitors as strongly as V(0) did. In contrast, proteolipids carrying mutations that confer resistance to both inhibitors showed no binding. We conclude that the extracted 16 kDa proteolipid retains sufficient fold to form a high-affinity inhibitor binding site for both natural and synthetic V-ATPase inhibitors and that the proteolipid contains the major proportion of the structural determinants for inhibitor binding. The role of membrane domain subunit a in concanamycin binding and therefore in defining the inhibitor binding properties of tissue-specific V-ATPases is critically re-assessed in light of these data.

Assembly of the yeast vacuolar H+-ATPase and ATP hydrolysis occurs in the absence of subunit c''.

The V-ATPases are ubiquitous enzymes of eukaryotes. They are involved in many cellular processes via their ability to pump protons across biological membranes. They are two domain enzymes comprising an ATP hydrolysing sector and a proton translocating sector. Both sectors are functionally coupled. The proton tanslocating sector, V0, is comprised of five polypeptides in an as yet undetermined stoichiometry. In V0 three homologous proteins, subunit c, c' and c'' have previously been reported to be essential for assembly of the enzyme. However, we report that subunit c'' is not essential for assembly but is for functional coupling of the enzyme.

Interaction of inhibitors of the vacuolar H(+)-ATPase with the transmembrane Vo-sector.

The macrolide antibiotic concanamycin A and a designed derivative of 5-(2-indolyl)-2,4-pentadienamide (INDOL0) are potent inhibitors of vacuolar H(+)-ATPases, with IC(50) values in the low and medium nanomolar range, respectively. Interaction of these V-ATPase inhibitors with spin-labeled subunit c in the transmembrane V(o)-sector of the ATPase was studied by using the transport-active 16-kDa proteolipid analogue of subunit c from the hepatopancreas of Nephrops norvegicus. Analogous experiments were also performed with vacuolar membranes from Saccharomyces cerevisiae. Membranous preparations of the Nephrops 16-kDa proteolipid were spin-labeled either on the unique cysteine C54, with a nitroxyl maleimide, or on the functionally essential glutamate E140, with a nitroxyl analogue of dicyclohexylcarbodiimide (DCCD). These residues were previously demonstrated to be accessible to lipid. Interaction of the inhibitors with these lipid-exposed residues was studied by using both conventional and saturation transfer EPR spectroscopy. Immobilization of the spin-labeled residues by the inhibitors was observed on both the nanosecond and microsecond time scales. The perturbation by INDOL0 was mostly greater than that by concanamycin A. Qualitatively similar but quantitatively greater effects were obtained with the same spin-label reagents and vacuolar membranes in which the Nephrops 16-kDa proteolipid was expressed in place of the native vma3p proteolipid of yeast. The spin-label immobilization corresponds to a direct interaction of the inhibitors with these intramembranous sites on the protein. A mutational analysis on transmembrane segment 4 known to give resistance to concanamycin A also gave partial resistance to INDOL0. The results are consistent with transmembrane segments 2 and 4 of the 16-kDa putative four-helix bundle, and particularly the functionally essential protonation locus, being involved in the inhibitor binding sites. Inhibition of proton transport may also involve immobilization of the overall rotation of the proteolipid subunit assembly.