Recombinant Yarrowia lipolytica strains for the heterologous expression of multi-component enzyme systems: Expression of mammalian steroidogenic proteins.

New Yarrowia lipolytica strains for the co-expression of steroidogenic mammalian proteins were obtained in this study. For this purpose, a two-step approach for constructing recombinant strains that permits the simple introduction of several expression cassettes encoding heterologous proteins into the yeast genome was successfully applied. This study tested two series of integrative multi-copy expression vectors containing cDNAs for the mature forms of P450scc system components (cytochrome P450scc (CYP11A1), adrenodoxin reductase, adrenodoxin, or fused adrenodoxin-P450scc) or for P45017α (CYP17A1) under the control of the isocitrate lyase promoter pICL1, which were constructed using the basic plasmids p64PT or p67PT (rDNA or the long terminal repeat (LTR) zeta of Ylt1 as integration targeting sequences and ura3d4 as a multi-copy selection marker). This study demonstrated the integration of up to three expression vectors containing different heterologous cDNA via their simultaneous transformation into haploid recipient strains. Additionally, further combinations of the different expression cassettes in one strain were obtained by subsequent diploidisation using selected haploid multi-copy transformants. Thus, recombinant strains containing three to five different expression cassettes were obtained, as demonstrated by Southern blotting. Expression of P450scc system proteins was identified by western blotting. The presented method for recombinant strain construction is a useful tool for the heterologous expression of multi-component enzyme systems in Y. lipolytica.

Formation and functioning of fused cholesterol side-chain cleavage enzymes.

We studied the properties of various fused combinations of the components of the mitochondrial cholesterol side-chain cleavage system including cytochrome P450scc, adrenodoxin (Adx), and adrenodoxin reductase (AdR). When recombinant DNAs encoding these constructs were expressed in Escherichia coli, both cholesterol side-chain cleavage activity and sensitivity to intracellular proteolysis of the three-component fusions depended on the species of origin and the arrangement of the constituents. To understand the assembly of the catalytic domains in the fused molecules, we analyzed the catalytic properties of three two-component fusions: P450scc-Adx, Adx-P450scc, and AdR-Adx. We examined the ability of each fusion to carry out the side-chain cleavage reaction in the presence of the corresponding missing component of the whole system and examined the dependence of this reaction on the presence of exogenously added individual components of the double fusions. This analysis indicated that the active centers in the double fusions are either unable to interact or are misfolded; in some cases they were inaccessible to exogenous partners. Our data suggest that when fusion proteins containing P450scc, Adx, and AdR undergo protein folding, the corresponding catalytic domains are not formed independently of each other. Thus, the correct folding and catalytic activity of each domain is determined interactively and not independently.

Effects of various N-terminal addressing signals on sorting and folding of mammalian CYP11A1 in yeast mitochondria.

Topogenesis of cytochrome p450scc, a resident protein of the inner membrane of adrenocortical mitochondria, is still obscure. In particular, little is known about the cause of its tissue specificity. In an attempt to clarify this point, we examined the process in Saccharomyces cerevisiae cells synthesizing cytochrome p450scc as its native precursor (pCYP11A1) or versions in which its N-terminal addressing presequence had been replaced with those of yeast mitochondrial proteins: CoxIV(1-25) and Su9(1-112). We found the pCYP11A1 and CoxIV(1-25)-mCYP11A1 versions to be effectively imported into yeast mitochondria and subjected to proteolytic processing. However, only minor portions of the imported proteins were incorporated into mitochondrial membranes, whereas their bulk accumulated as aggregates insoluble in 1% Triton X-100. Along with previously published data, this suggests that a distinguishing feature of the import of the CYP11A1 precursors into yeast mitochondria is their easy translocation into the matrix where the foreign proteins mainly undergo proteolysis or aggregation. The fraction of CYP11A1 that happens to be inserted into the inner mitochondrial membrane is effectively converted into the catalytically active holoenzyme. Experiments with the Su9(1-112)-mCYP11A1 construct bearing a re-export signal revealed that, after translocation of the fused protein into the matrix and its processing, the Su9(67-112) segment ensures association of the mCYP11A1 body with the inner membrane, but proper folding of the latter does not take place. Thus it can be said that the most specific stage of CYP11A1 topogenesis in adrenocortical mitochondria is its confinement and folding in the inner mitochondrial membrane. In yeast mitochondria, only an insignificant portion of the imported CYP11A1 follows this mechanism.