Periplasmically-exported lupanine hydroxylase undergoes transition from soluble to functional inclusion bodies in Escherichia coli.

Pseudomonas lupanine hydroxylase is a periplasmic-localised, two domain quinocytochrome c enzyme. It requires numerous post-translocation modifications involving signal peptide processing, disulphide bridge formation and, heme linkage in the carboxy-terminal cytochrome c domain to eventually generate a Ca(2+)-bound quino-c hemoprotein that hydroxylates the plant alkaloid, lupanine. An exported, functional recombinant enzyme was generated in Escherichia coli by co-expression with cytochrome c maturation factors. Increased growth temperatures ranging from 18 to 30 degrees C gradually raised the enzyme production to a peak together with its concomitant aggregation as red solid particles, readily activatable in a fully functional form by mild chaotropic treatment. Here, we demonstrate that the exported lupanine hydroxylase undergoes a cascade transition from a soluble to "non-classical" inclusion body form when build-up in the periplasm exceeded a basal threshold concentration. These periplasmic aggregates were distinct from the non-secreted, signal-sequenceless counterpart that occurred as misfolded, non-functional concatamers in the form of classical inclusion bodies. We discuss our findings in the light of current models of how aggregation of lupanine hydroxylase arises in the periplasmic space.

Signal peptidase I-mediated processing of an engineered mammalian cytochrome b(5) precursor is an exocytoplasmic post-translocational event in Escherichia coli.

Proteins destined for translocation across the prokaryotic cytoplasmic membrane are synthesized as precursors carrying transient N-terminal extensions known as signal sequences. They facilitate initial engagement of precursor proteins with the sec-dependent translocase to initiate active threading of the polypeptide across the membrane. The translocated precursor is then processed by a transcytoplasmic signal peptidase anchored to the inner membrane. The temporal nature of cleavage of the signal sequence during pre-protein translocation has remained elusive. Using an engineered mammalian cytochrome b(5) precursor we demonstrate that the signal peptide processing in Escherichia coli is an event that can occur after almost complete exocytoplasmic translocation of the preprotein is accomplished. We discuss implications of the findings in light of the known working model of sec-dependent pre-protein translocon.

The quinohaemoprotein lupanine hydroxylase from Pseudomonas putida.

Lupanine hydroxylase catalyses the first reaction in the catabolism of the alkaloid lupanine by Pseudomonas putida. It dehydrogenates the substrate, which can then be hydrated. It is a monomeric protein of M(r) 72,000 and contains a covalently bound haem and a molecule of PQQ. The gene for this enzyme has been cloned and sequenced and the derived protein sequence has a 26 amino acid signal sequence at the N-terminal for translocation of the protein to the periplasm. Many of the features seen in the sequence of lupanine hydroxylase are common with other quinoproteins including the W-motifs that are characteristic of the eight-bladed propeller structure of methanol dehydrogenase. However, the unusual disulfide bridge between adjacent cysteines that is present in some PQQ-containing enzymes is absent in lupanine hydroxylase. The C-terminal domain contains characteristics of a cytochrome c and overall the sequence shows similarities with that of the quinohaemoprotein, alcohol dehydrogenase from Comamonas testosteroni. The gene coding for lupanine hydroxylase has been successfully expressed in Escherichia coli and a procedure has been developed to renature and reactivate the enzyme, which was found to be associated with the inclusion bodies. Reactivation required addition of PQQ and was dependent on calcium ions.

A directed evolution strategy for optimized export of recombinant proteins reveals critical determinants for preprotein discharge.

A directed evolutionary approach is described that searches short, random peptide sequences for appendage at the secretory signal peptide-mature protein junction to seek ideal algorithms for both efficient and hyper export of recombinant proteins to the periplasm of Escherichia coli. The strategy employs simple, visual detection of positive clones using a PINK expression system that faithfully reports on export status of a mammalian hemoprotein in E. coli. With-in "sequence spaces" ranging from 1 to 13 residues, a significant but highly variable secretory fitness was scored such that the rate of secretion reciprocally correlated with the membrane-associated precursor pool of the evolved exportable hemoproteins. Three clusters of hyper, median, and hypo exporters were isolated. These had corresponding net charges of -1, 0, and +1 within the evolved sequence space, which in turn clearly correlated with the prevailing magnitude and polarity of the membrane energization states. The findings suggest that both the nature of the charged residue and the proximal sequence in the early mature region are the crucial determinants of the protonophore-dependent electrophoretic discharge of the precursor across the inner membrane of E. coli. We conclude that the directed evolutionary approach will find ready application in engineering recombinant proteins for their efficient secretion via the sec export pathway in E. coli.

Presence and role of a second disulphide bond in recombinant lupanine hydroxylase using site-directed mutagenesis with 143Cys→Ser and 124,143Cys→Ser mutations in Escherichia coli.

Lupanine hydroxylase (LH), a quinohaemoprotein, catabolizes lupanine and possesses four cysteine (Cys) residues; two associated with a cytochrome c motif ((586)Cys and (589)Cys), while the role of the remaining two residues ((124)Cys and (143)Cys) is unclear. Structural graphic simulation using homology modelling suggested a potential second -S-S- bond, a common feature between adjacent Cys residues in other quinohaemoproteins; however, in LH, these residues are located 18 amino acids apart. Formation of the second disulphide bond was initially chemically confirmed by iodomethane alkylation with 91% loss of enzymic activity, and no significant change was observed with unreduced alkylated protein. Dithiothreitol-induced reduction of LH followed by Cd(2+) treatment also resulted in significant loss of activity in a dose-dependent manner. Subsequent investigation into the role of disulphide bond in LH was performed using engineered (143)Cys→Ser and (124,143)Cys→Ser mutants and exhibited 25% and zero activity, respectively, of wild type in the periplasm. Homology structure prediction showed three changes in α-helices and four in ß-pleated sheets in (143)Cys→Ser mutant, and (124,143)Cys→Ser mutant had six changes in α-helices and nine in ß-pleated sheets. These mutations resulted in the enlargement of the molecule and affect the enzyme activity because of structural changes in the cytochrome c domain.

Export of a hyperexpressed mammalian globular cytochrome b5 precursor in Escherichia coli is dramatically affected by the nature of the amino acid flanking the secretory signal sequence cleavage bond.

A chimeric mammalian globular cytochrome b(5) fused to Escherichia coli alkaline phosphatase signal sequence (SS) was used as a model probe to investigate the influence of substituting each one of the standard 20 amino acids at its N-terminus on the Sec-dependent export of the precursor to the periplasmic space of E. coli. Substituting the native Met(+1) of the passenger protein flanking the SS with any one of the remaining 19 amino acids introduced significant changes in the export of cytochrome b(5) without jamming the Sec-dependent translocon. Acidic and hydrophilic residues proved to be the most efficient promoters of export. Small, nonbulky and basic residues yielded intermediate levels of the hemoprotein export. Replacement with a Cys(+1) residue generated significant quantities of both monomeric and disulfide-linked dimeric forms. However, bulky, aromatic and hydrophobic residues caused a significant decline in the rates of secretion. In expectation with their absences in the natural periplasmically secreted proteins, Pro and Ile-tagged cytochrome b(5) precursors failed to generate any detectable secreted recombinant products. Although Ala, amongst the native E. coli periplasmic proteins, is the preferred X(+1) residue with an occurrence of 50% frequency, it proved half as effective in promoting export when inserted proximally to the SS of cytochrome b(5). The mechanisms involved for these export variations are discussed. The findings will prove beneficial for high-level generation of recombinant proteins by secretory means for pharmaceutical and related biotechnological applications.

The membrane-interactive tail of cytochrome b(5) can function as a stop-transfer sequence in concert with a signal sequence to give inversion of protein topology in the endoplasmic reticulum.

Sequence analyses of the C-terminal membrane intercalative region of the rat cytochrome b(5) indicated that this domain has, in addition to a signal sequence, a combined element of the classic stop-transfer sequence typically found in a variety of transmembrane proteins. Such bitopic protein arrangements arise by tandem but topogenically displaced activities of cleavable/noncleavable signal and stop-transfer sequences. A fusion precursor comprising an N-terminally linked prokaryotic signal sequence and the full-length of mammalian cytochrome b(5), including its C-terminal membrane insertion sequence, was engineered to investigate the outcome of this combination of signals on the targeting and topology of the cytochrome b(5) in the endoplasmic reticulum membrane. Precytochrome b(5) was cotranslationally translocated across the endoplasmic reticulum membrane. The signal-processed cytochrome b(5) was integrally anchored in the membrane with the globular domain facing the lumen. Thus, the topology of the signal sequence-directed cytochrome b(5) in the microsomal vesicle was reversed with respect to that of the native form. Posttranslational incubation of the precytochrome b(5) with microsomes resulted in a "loose" incorporation of the unprocessed form onto the surface of the vesicle. Our findings suggest that the membrane-insertion sequence of cytochrome b(5) has a functional stop-transfer sequence. We discuss the implications of these findings with respect to selective targeting of cytochrome b(5) to the endoplasmic reticulum membrane in the view that signal and stop-transfer sequences are often interchangeable or combined for topogenic functions.

Cloning, sequencing and heterologous expression of the gene for lupanine hydroxylase, a quinocytochrome c from a Pseudomonas sp.

The gene encoding the enzyme lupanine hydroxylase was isolated by PCR using chromosomal DNA from a lupanine-utilizing Pseudomonas sp. as template and primers based on the sequences of the N- and C-termini of the purified protein. The derived sequence for the mature gene product gave a protein with an M (r) of 72256, in good agreement with the value found by SDS/PAGE of the pure enzyme, and contained the sequences of several peptides obtained after endoproteinase Lys-C digestion of the pure enzyme. The gene, under the transcriptional control of a phoA promotor and with the Escherichia coli alkaline phosphatase signal sequence, was expressed in E. coli containing a plasmid expressing the genes for cytochrome c maturation proteins constitutively. Haem-containing inactive protein in inclusion bodies was renatured and reactivated with pyrroloquinoline quinone (PQQ) and Ca(2+) to give active enzyme. The lupanine hydroxylase (luh) gene coded for a protein with a cleavable 26-residue signal sequence at its N-terminus, required for the transport of the enzyme to its periplasmic location. Analysis of the protein sequence showed that it contains two domains, a large PQQ-binding N-terminal domain and a smaller cytochrome c C-terminal domain. Comparison of the derived sequence with those of other proteins showed considerable similarity with other quino(haemo)proteins, including alcohol dehydrogenases from a variety of bacteria. The PQQ-binding domain sequence contains W motifs, characteristic of the eight-bladed "propeller" structure of methanol dehydrogenase, but lacks the unusual disulphide ring structure formed from two adjacent cysteines seen in this enzyme. The C-terminus shares some similarity with bacterial cytochrome c and includes the haem-binding consensus sequence CXXCH.

Export of a heterologous cytochrome P450 (CYP105D1) in Escherichia coli is associated with periplasmic accumulation of uroporphyrin.

This report suggests an important physiological role of a CYP in the accumulation of uroporphyrin I arising from catalytic oxidative conversion of uroporphyrinogen I to uroporphyrin I in the periplasm of Escherichia coli cultured in the presence of 5-aminolevulinic acid. A structurally competent Streptomyces griseus CYP105D1 was expressed as an engineered, exportable form in aerobically grown E. coli. Its progressive induction in the presence of 5-aminolevulinic acid-supplemented medium was accompanied by an accumulation of a greater than 100-fold higher amount of uroporphyrin I in the periplasm relative to cells lacking CYP105D1. Expression of a cytoplasm-resident engineered CYP105D1 at a comparative level to the secreted form was far less effective in promoting porphyrin accumulation in the periplasm. Expression at a 10-fold molar excess over the exported CYP105D1 of another periplasmically exported hemoprotein, the globular core of cytochrome b5, did not substitute the role of the periplasmically localized CYP105D1 in promoting porphyrin production. This, therefore, eliminated the possibility that uroporphyrin accumulation is merely a result of increased hemoprotein synthesis. Moreover, in the strain that secreted CYP105D1, uroporphyrin production was considerably reduced by azole-based P450 inhibitors. Production of both holo-CYP105D1 and uroporphyrin was dependent upon 5-aminolevulinic acid, except that at higher concentrations this resulted in a decrease in uroporphyrin. This study suggests that the exported CYP105D1 oxidatively catalyzes periplasmic conversion of uroporphyrinogen I to uroporphyrin I in E. coli. The findings have significant implications in the ontogenesis of human uroporphyria-related diseases.

A cytochrome c from a lupanine-transforming Pseudomonas putida strain is expressed in Escherichia coli during aerobic cultivation and efficiently exported and assembled in the periplasm.

We have cloned, sequenced, and heterologously expressed a periplasmic cytochrome c from a lupanine-utilizing Pseudomonas putida strain. Aerobic batch cultivation of Escherichia coli TB1 harboring the cytochrome c gene placed downstream of the lac promoter in pUC9 vector resulted in significant production of the holo-cytochrome c in the periplasm ( approximately 4 mg of hemoprotein/liter of culture). The recombinant cytochrome c was purified to homogeneity and was found to be functional in accepting electrons from lupanine hydroxylase while catalyzing hydroxylation of lupanine. Comparison of the N-terminal amino acid sequence of the isolated cytochrome c with that deduced from the DNA sequence indicated that the signal sequence was processed at the bond position predicted by the SigPep program. The molecular size of the cytochrome c determined by electrospray mass spectrometry (9,595) was in precise agreement with that predicted from the nucleotide sequence.