Coagulation factor IXa: the relaxed conformation of Tyr99 blocks substrate binding.

BACKGROUND: Among the S1 family of serine proteinases, the blood coagulation factor IXa (fIXa) is uniquely inefficient against synthetic peptide substrates. Mutagenesis studies show that a loop of residues at the S2-S4 substrate-binding cleft (the 99-loop) contributes to the low efficiency. The crystal structure of porcine fIXa in complex with the inhibitor D-Phe-Pro-Arg-chloromethylketone (PPACK) was unable to directly clarify the role of the 99-loop, as the doubly covalent inhibitor induced an active conformation of fIXa. RESULTS: The crystal structure of a recombinant two-domain construct of human fIXa in complex with p-aminobenzamidine shows that the Tyr99 sidechain adopts an atypical conformation in the absence of substrate interactions. In this conformation, the hydroxyl group occupies the volume corresponding to the mainchain of a canonically bound substrate P2 residue. To accommodate substrate binding, Tyr99 must adopt a higher energy conformation that creates the S2 pocket and restricts the S4 pocket, as in fIXa-PPACK. The energy cost may contribute significantly to the poor K(M) values of fIXa for chromogenic substrates. In homologs, such as factor Xa and tissue plasminogen activator, the different conformation of the 99-loop leaves Tyr99 in low-energy conformations in both bound and unbound states. CONCLUSIONS: Molecular recognition of substrates by fIXa seems to be determined by the action of the 99-loop on Tyr99. This is in contrast to other coagulation enzymes where, in general, the chemical nature of residue 99 determines molecular recognition in S2 and S3-S4. This dominant role on substrate interaction suggests that the 99-loop may be rearranged in the physiological fX activation complex of fIXa, fVIIIa, and fX.

New enzyme lineages by subdomain shuffling.

Protein functions have evolved in part via domain recombination events. Such events, for example, recombine structurally independent functional domains and shuffle targeting, regulatory, and/or catalytic functions. Domain recombination, however, can generate new functions, as implied by the observation of catalytic sites at interfaces of distinct folding domains. If useful to an evolving organism, such initially rudimentary functions would likely acquire greater efficiency and diversity, whereas the initially distinct folding domains would likely develop into single functional domains. This represents the probable evolution of the S1 serine protease family, whose two homologous beta-barrel subdomains assemble to form the binding sites and the catalytic machinery. Among S1 family members, the contact interface and catalytic residues are highly conserved whereas surrounding surfaces are highly variable. This observation suggests a new strategy to engineer viable proteins with novel properties, by swapping folding subdomains chosen from among protein family members. Such hybrid proteins would retain properties conserved throughout the family, including folding stability as single domain proteins, while providing new surfaces amenable to directed evolution or engineering of specific new properties. We show here that recombining the N-terminal subdomain from coagulation factor X with the C-terminal subdomain from trypsin creates a potent enzyme (fXYa) with novel properties, in particular a broad substrate specificity. As shown by the 2.15-A crystal structure, plasticity at the hydrophobic subdomain interface maintains activity, while surface loops are displaced compared with the parent subdomains. fXYa thus represents a new serine proteinase lineage with hybrid fX, trypsin, and novel properties.

Dramatic enhancement of the catalytic activity of coagulation factor IXa by alcohols.

The coagulation factor IXa (FIXa) exhibits a very weak proteolytic activity towards natural or synthetic substrates. Upon complex formation with its cofactor FVIIIa and Ca2+-mediated binding to phospholipid membranes, FIXa becomes a very potent activator of FX. The presence of FVIIIa has no effect on the cleavage of peptide substrates by FIXa, however. We found that several alcohols dramatically enhance the catalytic activity of human FIXa towards synthetic substrates. Substrates with the tripeptidyl moiety R-D-Xxx-Gly-Arg are especially susceptible to the enhanced FIXa catalysis. Maximal increase up to 20-fold has been measured in the presence of ethylene glycol. We suggest that alcohols modify the conformation of FIXa rendering the active-site cleft more easily accessible to tripeptide substrates with a hydrophobic residue in the P3-position.

Converting blood coagulation factor IXa into factor Xa: dramatic increase in amidolytic activity identifies important active site determinants.

The coagulation factors IXa (fIXa) and Xa (fXa) share extensive structural and functional homology; both cleave natural substrates effectively only with a cofactor at a phospholipid surface. However, the amidolytic activity of fIXa is 10(4)-fold lower than that of fXa. To identify determinants of this poor reactivity, we expressed variants of truncated fIXa (rf9a) and fXa (rf10a) in Escherichia coli. The crystal structures of fIXa and fXa revealed four characteristic active site components which were subsequently exchanged between rf9a and rf10a. Exchanging Glu219 by Gly or exchanging the 148 loop did not increase activity of rf9a, whereas corresponding mutations abolished reactivity of rf10a. Exchanging Ile213 by Val only moderately increased reactivity of rf9a. Exchanging the 99 loop, however, dramatically increased reactivity. Furthermore, combining all four mutations essentially introduced fXa properties into rf9a: the amidolytic activity was increased 130-fold with fXa substrate selectivity. The results suggest a 2-fold origin of fIXa's poor reactivity. A narrowed S3/S4 subsite disfavours interaction with substrate P3/P4 residues, while a distorted S1 subsite disfavours effective cleavage of the scissile bond. Both defects could be repaired by introducing fXa residues. Such engineered coagulation enzymes will be useful in diagnostics and in the development of therapeutics.

A fusion protein designed for noncovalent immobilization: stability, enzymatic activity, and use in an enzyme reactor.

We have designed a new method for enzyme immobilization using a fusion protein of yeast alpha-glucosidase containing at its C-terminus a polycationic hexa-arginine fusion peptide. This fusion protein can be directly adsorbed from crude cell extracts on polyanionic matrices in a specific, oriented fashion. Upon noncovalent immobilization by polyionic interactions, the stability of the fusion protein is not affected by pH-, urea-, or thermal-denaturation. Furthermore, the enzymatic properties (specific activity at increasing enzyme concentration, Michaelis constant, or activation energy of the enzymatic reaction) are not influenced by this noncovalent coupling. The operational stability of the coupled enzyme under conditions of continuous substrate conversion is, however, increased significantly compared to the soluble form. Fusion proteins containing polyionic peptide sequences are proposed as versatile tools for the production of immobilized enzyme catalysts.

Isolation and characterisation of antibodies which specifically recognise the peptide encoded by exon 7 (v2) of the human CD44 gene.

Aims-Exon 7 of the human CD44 gene is overexpressed in many commonly occurring carcinomas. The aim of the study was to explore the diagnostic and therapeutic potential of this frequent abnormality.Methods-A new monoclonal antibody (mAb, M-23.6.1) and a polyclonal antibody (pAb,S-6127) to the corresponding antigen were raised by immunising mice and sheep, respectively, with a specially constructed fusion protein HIV2 (gp32)-CD44 exon 7.Results-Characterisation of mAb, M-23.6.1 by ELISA, western blotting, immunocytochemistry, and FACS analysis confirmed that it specifically recognises an epitope in the region between amino acids 19 and 33 of the peptide encoded by this exon. Western blotting experiments with two cell lines, RT112 and ZR75-1, known from RT-PCR data to be overtranscribing the exon, yielded a monospecific band of approximately 220 kDa, and immunocytochemistry showed discrete membrane staining on the same cell lines. Fluorescent antibody cell sorting (FACS) revealed binding to greater than 90% of the cells of each of these lines. Specificity of recognition of the antigen was shown by inhibition of the precise immunoreactivity typically seen in ELISA and Western blots, by pre-incubation with synthetic exon 7 peptide or fragments of it.Conclusions-The new antibodies will be useful tools for the further analysis of abnormal CD44 isoforms and their clinical implications.

Glycoprotein biosynthesis in Saccharomyces cerevisiae: ngd29, an N-glycosylation mutant allelic to och1 having a defect in the initiation of outer chain formation.

Outer chain glycosylation in Saccharomyces cerevisiae leads to heterogeneous and immunogenic asparagine-linked saccharide chains containing more than 50 mannose residues on secreted glycoproteins. Using a [3H]mannose suicide selection procedure a collection of N-glycosylation defective mutants (designated ngd) was isolated. One mutant, ngd29, was found to have a defect in the initiation of the outer chain and displayed a temperature growth sensitivity at 37 degrees C allowing the isolation of the corresponding gene by complementation. Cloning, sequencing and disruption of NGD29 showed that it is a non lethal gene and identical to OCH1. It complemented both the glycosylation and growth defect. Membranes isolated from an ngd29 disruptant or an ngd29mnn1 double mutant were no longer able, in contrast to membranes from wild type cells, to transfer mannose from GDPmannose to Man8GlcNAc2, the in vivo acceptor for building up the outer chain. Heterologous expression of glucose oxidase from Aspergillus niger in an ngd29mnn1 double mutant produced a secreted uniform glycoprotein with exclusively Man8GlcNAc2 structure that in wild type yeast is heavily hyperglycosylated. The data indicate that this mutant strain is a suitable host for the expression of recombinant glycoproteins from different origin in S. cerevisiae to obtain mammalian oligomannosidic type N-linked carbohydrate chains.

Enzymes in diagnostics: achievements and possibilities of recombinant DNA technology.

We discuss, from an industrial point of view, the scope and possibilities of recombinant DNA technology for "diagnostic enzyme" production and application. We describe the construction of enzyme-overproducing strains and show how to simplify downstream processing, increase product quality and process profitability, improve diagnostic enzyme properties, and adjust enzymes to harsh assay conditions. We also consider some safety and environmental aspects of enzyme production. Other aspects of diagnostic enzymes that we cover are the facilitation of enzyme purification by attachment of short amino acid tails, the introduction of tails or tags for site-specific conjugation or oriented immobilization, the construction of bi- or multifunctional enzymes, and the production of enzyme-based diagnostic tests as demonstrated by the homogeneous immunoassay system of CEDIA tests. We use as examples of diagnostic enzymes glucose-6-phosphate dehydrogenase (EC 1.1.1.49), glucose oxidase (EC 1.1.3.4), alkaline phosphatase (EC 3.1.3.1), alpha-glucosidase (EC 3.2.1.20), pyruvate oxidase (EC 1.2.3.3), creatinase (EC 3.5.3.3), and beta-galactosidase (EC 3.2.1.23).

Control of formation of active soluble or inactive insoluble baker's yeast alpha-glucosidase PI in Escherichia coli by induction and growth conditions.

Using standard growth conditions (LB medium, 37 degrees C, induction with 5 mM IPTG) yeast alpha-glucosidase PI expressed under the control of the regulated tac-hybrid promoter results in the synthesis of insoluble aggregated alpha-glucosidase granules in Escherichia coli. Under these conditions active soluble alpha-glucosidase amounts to less than 1% of the heterologously produced protein. However, the amount of soluble active alpha-glucosidase was dramatically increased when the strong tac-hybrid promoter was to a limited extent induced. This was achieved at concentrations of 0.01 mM IPTG or of 1% lactose or lower in a lactose-permease deficient host strain containing the lacIq repressor gene on an R-plasmid. The formation of active soluble alpha-glucosidase was almost 100% when E. coli cells induced in this manner were cultivated under conditions that reduced growth rate, i.e. at decreased temperature, extreme pH values or in minimal and complete media supplemented with different carbon sources.

Cloning and characterization of baker's yeast alpha-glucosidase: over-expression in a yeast strain devoid of vacuolar proteinases.

Two alpha-glucosidase (maltase) genes, designated GLUCPI and GLUCPII, have been cloned from an industrial strain of baker's yeast (Saccharomyces cerevisiae) by complementation of a maltase-negative mutant strain. The different genes were identified according to their alternatively expressed isoenzymes PI and PII in transformants after isoelectric focusing and activity staining in separated cell lysates. The gene encoding alpha-glucosidase PI (GLUCPI), which was not present in laboratory strains of S. carlsbergensis with a defined MAL1, 2, 3, 4 or 6 locus, was sequenced and compared with the recently published MAL6S gene. This comparison revealed single amino acid deviations at three positions in the predicted polypeptide sequence. In addition, the divergent promoter region of GLUCPI differed from MAL6S by a triple repeated 147-bp DNA segment. Maltose induction and glucose repression of alpha-glucosidase PI were not affected by the deletion of the repeated DNA segment. However, the absolute expression of alpha-glucosidase PI increased two- to four-fold. In addition, a two-fold increase in the maltase synthesis occurred when the cloned positive regulator gene MAL2-8ep was on the same plasmid. Furthermore, stability of the alpha-glucosidase in cultures in the stationary growth phase was greatly enhanced using a host strain lacking the proteinases A and B and the carboxypeptidases Y and S. Promoter trimming, MAL2-8cp stimulation and the use of a host strain deficient in four vacuolar proteinases resulted in alpha-glucosidase PI expression of about 13% of the soluble protein.

Purification procedure and N-terminal amino acid sequence of yeast malate dehydrogenase isoenzymes.

A method has been devised for the rapid isolation of malate dehydrogenase isoenzymes. First, anionic proteins were precipitated with polyethyleneimine, whilst hydrophobic malate dehydrogenase remained in the supernatant fluid. Secondly, the supernatant was 30% saturated with ammonium sulfate and the two isoenzymes were separated by hydrophobic phenyl-Sepharose CL-4B chromatography. For further purification the enzymes were chromatofocused, and polybuffer was removed by hydrophobic chromatography. Affinity chromatography with blue Sepharose CL-6B [1] was used as final purification step. The purified isoenzymes were homogeneous as shown by isoelectric focusing and could be used for N-terminal sequencing. 34 amino acid residues could be identified for the cytoplasmic isoenzyme and 56 amino acid residues for the mitochondrial isoenzyme. Although there are regions of strong homology between both isoenzymes, the sequence differences clearly showed support that both isoenzymes are coded by different genes. Sequence comparison clearly indicated that the N-terminus of the cytoplasmic enzyme extended that of the mitochondrial enzyme by 12 amino acid residues. The amino acid sequence of the extending sequence resembled that of leading sequences known for enzymes which are transported into the mitochondria. The assumed leading sequence is discussed with respect to its possible role in glucose inactivation.

Glucose repression and hexokinase isoenzymes in yeast. Isolation and characterization of a modified hexokinase PII isoenzyme.

Hexokinase PII, but not isoenzyme PI, has a unique role in glucose repression in yeasts [Entian, K.-D. (1980) Mol. Gen. Genet. 178, 633-637; Entian, K.-D. and Mecke, D. (1982) J. Biol. Chem. 257, 870-874; Entian, K.-D. and Fröhlich, K.-U. (1984) J. Bacteriol. 158, 29-35]. The number of hexokinase isoenzymes in crude extracts was re-examined by chromatofocusing. In addition to the known isoenzymes PI and PII, a third isoenzyme, PIIM, was detected. The activity of this enzyme was only about 5-10% of that of hexokinase PII and was independent of growth conditions. Experiments with hexokinase transformants and purified hexokinase isoenzymes clearly indicated that the PIIM form is also present in vivo. Fingerprint mapping of purified hexokinases showed that hexokinase PIIM is closely related to PII. Hybridization experiments between totally restricted yeast DNA and the previously isolated PII gene clearly indicated that PIIM is also coded by one of the two known hexokinase genes. No mRNA specific for hexokinase PIIM was detected after hybridization experiments with the previously cloned hexokinase PII gene [Fröhlich et al. (1984) Mol. Gen. Genet. 194, 144-148]. Hexokinase PIIM appears to be derived from hexokinase PII by a posttranslational event. The Km values of each of the purified isoenzymes, PII and PIIM, were identical for glucose, fructose and ATP. Both isoenzymes were strongly inhibited by high physiological concentrations for ATP; such inhibition has not been described previously. The possible role of hexokinase PIIM in glucose repression is discussed.

Complete nucleotide sequence of the hexokinase PI gene (HXK1) of Saccharomyces cerevisiae.

The nucleotide sequence of the yeast glycolytic hexokinase isoenzyme PI-gene, HXK1, has been determined by sequencing the yeast DNA insert of the previously isolated plasmid HXK1 clone [Entian et al., Mol. Gen. Genet. 198 (1984) 50-54]. The structural gene sequence included 1452 bp coding for 484 amino acid (aa) residues corresponding to the Mr of 153 605 for the HXK1 monomer. Several initiation regions and termination points were located using nuclease S1 mapping. The HXK1 sequence was 76% homologous with that of HXK2, which is responsible for triggering glucose repression in yeasts. Since HXK1 is not involved in this regulatory system, the regulatory function of HXK2 must correspond to one or more of the differences between both isoenzymes. Most changes in the amino acid sequence were statistically distributed; however, four clustered regions with more than five altered aa residues were identified.

Cloning of hexokinase isoenzyme PI from Saccharomyces cerevisiae: PI transformants confirm the unique role of hexokinase isoenzyme PII for glucose repression in yeasts.

Hexokinase isoenzyme PI was cloned using a gene pool obtained from a yeast strain having only one functional hexokinase, isoenzyme PI. The gene was characterized using 20 restriction enzymes and located within a region of 2.0 kbp. The PI plasmid strongly hybridized with the PII plasmids isolated previously (Fröhlich et al. 1984). Hence there was a close relationship between the two genes, one of which must have been derived from the other by gene duplication. In contrast, glucose repression was restored only in hexokinase PII transformants; PI transformants remained non-repressible. This observation provided additional evidence for the hypothesis of Entian (1980) that only hexokinase PII is necessary for glucose repression. Furthermore, glucose phosphorylating activity in PI transformants exceeded that of wild-type cells, giving clear evidence that the phosphorylating capacity is not important for glucose repression.