Wieger Hemrika

Identification of anti-repressor elements that confer high and stable protein production in mammalian cells

The expression of transgenic proteins is often low and unstable over time, a problem that may be due to integration of the transgene in repressed chromatin. We developed a screening technology to identify genetic elements that efficiently counteract chromatin-associated repression. When these elements were used to flank a transgene, we observed a substantial increase in the number of mammalian cell colonies that expressed the transgenic protein. Expression of the shielded transgene was, in a copy number–dependent fashion, substantially higher than the expression of unprotected transgenes. Also, protein production remained stable over an extended time period. The DNA elements are small, not exceeding 2,100 base pairs (bp), and they are highly conserved between human and mouse, at both the functional and sequence levels. Our results demonstrate the existence of a class of genetic elements that can readily be applied to more efficient transgenic protein production in mammalian cells.

X-ray crystal structures of active site mutants of the vanadium-containing chloroperoxidase from the fungus Curvularia inaequalis.

Abstract The X-ray structures of the chloroperoxidase from Curvularia inaequalis, heterologously expressed in Saccharomyces cerevisiae, have been determined both in its apo and in its holo forms at 1.66 and 2.11 Å resolution, respectively. The crystal structures reveal that the overall structure of this enzyme remains nearly unaltered, particularly at the metal binding site. At the active site of the apo-chloroperoxidase structure a clearly defined sulfate ion was found, partially stabilised through electrostatic interactions and hydrogen bonds with positively charged residues involved in the interactions with the vanadate in the native protein. The vanadate binding pocket seems to form a very rigid frame stabilising oxyanion binding. The rigidity of this active site matrix is the result of a large number of hydrogen bonding interactions involving side chains and the main chain of residues lining the active site. The structures of single site mutants to alanine of the catalytic residue His404 and the vanadium protein ligand His496 have also been analysed. Additionally we determined the structural effects of mutations to alanine of residue Arg360, directly involved in the compensation of the negative charge of the vanadate group, and of residue Asp292 involved in forming a salt bridge with Arg490 which also interacts with the vanadate. The enzymatic chlorinating activity is drastically reduced to approximately 1% in mutants D292A, H404A and H496A. The structures of the mutants confirm the view of the active site of this chloroperoxidase as a rigid matrix providing an oxyanion binding site. No large changes are observed at the active site for any of the analysed mutants. The empty space left by replacement of large side chains by alanines is usually occupied by a new solvent molecule which partially replaces the hydrogen bonding interactions to the vanadate. The new solvent molecules additionally replace part of the interactions the mutated side chains were making to other residues lining the active site frame. When this is not possible, another side chain in the proximity of the mutated residue moves in order to satisfy the hydrogen bonding potential of the residues located at the active site frame.

Heterologous expression of the vanadium-containing chloroperoxidase from Curvularia inaequalis in Saccharomyces cerevisiae and site-directed mutagenesis of the active site residues His496, Lys353, Arg360 and Arg490

The vanadium-containing chloroperoxidase from the fungus Curvularia inaequalis is heterologously expressed to high levels in the yeast Saccharomyces cerevisiae. Characterization of the recombinant enzyme reveals that this behaves very similar to the native chloroperoxidase. Site-directed mutagenesis is performed on four highly conserved active site residues to examine their role in catalysis. When the vanadate-binding residue His496 is changed into an alanine, the mutant enzyme loses the ability to bind vanadate covalently resulting in an inactive enzyme. The negative charges on the vanadate oxygens are compensated by hydrogen bonds with the residues Arg360, Arg490, and Lys353. When these residues are changed into alanines the mutant enzymes lose the ability to effectively oxidize chloride but can still function as bromoperoxidases. A general mechanism for haloperoxidase catalysis is proposed that also correlates the kinetic properties of the mutants with the charge and the hydrogen-bonding network in the vanadate-binding site.

Isolation, Characterization, and Primary Structure of the Vanadium Chloroperoxidase from the Fungus Embellisia didymospora

Here we describe the isolation, purification, and basic kinetic parameters of a vanadium type chloroperoxidase from the hyphomycete fungus Embellisia didymospora. The enzyme proved to possess similar high substrate affinities, aK m of 5 μm for a bromide, 1.2 mm for a chloride, and 60 μm for a hydrogen peroxide, as those of the vanadium chloroperoxidase fromCurvularia inaequalis, although with lower turnover rates for both Cl− and Br−. Substrate bromide was also found to inhibit the enzyme, a feature subsequently also noted for the chloroperoxidase from C. inaequalis. The gene encoding this enzyme was identified using DNA Southern blotting techniques and subsequently isolated and sequenced. A comparison is made between this vanadium chloroperoxidase and that of the fungus C. inaequalis both kinetically and at the sequence level. At the primary structural level the two chloroperoxidases share 68% identity, with conservation of all active site residues.

A new model for the membrane topology of glucose-6-phosphatase: the enzyme involved in von Gierke disease.

Very recently we have proposed [Hemrika et al. (1997) Proc. Natl. Acad. Sci. USA 94, 2145–2149] that the active site of the vanadate‐containing chloroperoxidase from the fungus Curvularia inaequalis, of which the tertiary structure is known, is structurally very similar to that of the membrane‐bound mammalian glucose‐6‐phosphatases for which no structural data are available. The proposed active site of glucose‐6‐phosphatase, however, is incompatible with the six transmembrane–helix topology model that is currently used. Here we present a new topology model for glucose‐6‐phosphatase which is in agreement with all available data.

The effect of deletion of the genes encoding the 40 kDa subunit II or the 17 kDa subunit VI on the steady-state kinetics of yeast ubiquinol-cytochrome-c oxidoreductase.

Yeast ubiquinol-cytochrome c oxidoreductase is still active after inactivation of the genes encoding the 40 kDa Core II protein or the 17 kDa subunit VI (Oudshoorn et al. (1987) Eur. J. Biochem. 163, 97-103 and Schoppink et al. (1988) Eur. J. Biochem. 173, 115-122). The steady-state levels of several other subunits of Complex III are severely reduced in the 40 kDa0 mutant. The level of spectrally detectable Complex III cytochrome b in the mutant submitochondrial particles is about 5% of that of the wild type. However, when the steady-state activity of Complex III with respect to the cytochrome c reduction was examined, similar maximal turnover numbers and Km values were found for the mutated and the wild-type complexes, both when yeast cytochrome c and when horse-heart cytochrome c was used as electron acceptor. We therefore conclude that the Core II subunit of yeast Complex III plays no role in the binding of cytochrome c and that it has no major influence of the overall electron transport and on the binding of ubiquinol by the enzyme. Absence of the 17 kDa subunit VI of yeast Complex III, the homologous counterpart of the hinge protein of the bovine heart enzyme, resulted in a decrease in the rate of reduction of both horse-heart cytochrome c and yeast cytochrome c by Complex III under conditions of relatively high ionic strength. However, under conditions of optimal ionic strength, no difference could be seen in the maximal turnover numbers and Km values, neither with horse-heart cytochrome c nor with yeast cytochrome c between Complex III deficient in the 17 kDa protein and the wild-type complex. Binding of ATP to ferricytochrome c inhibits its reduction by Complex III under conditions of relatively high ionic strength. But when the 17 kDa protein is absent, this inhibition is also observed under optimal ionic-strength conditions. These results can be explained by assuming a stimulating role for the acidic 17 kDa protein in the association of basic cytochrome c with Complex III. This association is (part of) the rate-limiting step in the reduction of cytochrome c by Complex III under conditions of relatively high ionic strength or when this association is hindered, for instance, by binding of ATP.(ABSTRACT TRUNCATED AT 400 WORDS)

The regulation of the vanadium chloroperoxidase from Curvularia inaequalis

The effects of carbon and nitrogen source on the regulation of the vanadium chloroperoxidase secreted by the fungus Curnularia inaequalis were investigated. The addition of glucose showed a repressing effect on both the observed messenger RNA level and the measured enzyme activities, whereas the addition of glutamate as nitrogen source and the addition of both glutamate and glycerol had no effect. Addition of vanadate had no effect on the level of mRNA. Eight hundred base pairs of the upstream promoter region of vCPO were sequenced and various features of interest are highlighted. Closer inspection of the mycelium revealed that once secreted, vCPO probably remains tightly associated with the hyphae in two forms, one of which may be a proform of the enzyme. A possible cleavage event at the C-terminus may lower its potential for hyphal association and permit its disassociation into the growth medium. A putative role for the vanadium chloroperoxidase is put forward.

The aromatic nature of residue 66 of the 11-kDa subunit of ubiquinol-cytochrome c oxidoreductase of the yeast Saccharomyces cerevisiae is important for the assembly of a functional enzyme

Transformation of multi‐ and single‐copy plasmids carrying a mutated version (LTN2, region 66‐YWYWW‐70 replaced by SASAA) of QCR8, the gene encoding the 11‐kDa subunit of ubiquinol‐cytochrome c oxidoreductase of Saccharomyces cerevisiae, to a QCR80 strain indicated the importance of this aromatic region for the assembly of a functional enzyme. Sequencing of plasmids giving spontaneous restoration of growth to some colonies among the single‐copy LTN2 transformants showed that changing the sequence SASAA into the sequence FASAA could, to a large extent, overcome the observed assembly defect, indicating the importance of the aromatic nature of residue 66.

Features of Assembly and Mechanism of Yeast Mitochondrial Ubiquinol:Cytochrome C Oxidoreductase

Several deletion mutants of S. cerevisiae, deficient in one of the subunits of the yeast mitochondrial ubiquinol: cytochrome c oxidoreductase, contain subnormal amounts of various subunits, due to proteolytic breakdown as consequence of improper assembly. Only deletion of the 17 kDa subunit or the Fe-S protein does not have any significant effect on assembly. It is concluded that the complex is assembled from various subcomplexes of which the subcomplex consisting of cytochrome b, the 11 kDa subunit and the 14 kDa subunit is sensitive to proteolytic breakdown in the absence of any of the two core proteins. The Fe-S protein has to be integrated into this subcomplex to become proteinase-resistent. Cytochrome b is absent in the 11 and 14 kDa0 mutants, and present at very low amounts in the 40 and 44 kDa0 mutants.