Highly active alkaline phosphatase

Abstract

The invention concerns a DNA coding a eukaryotic highly active alkaline phosphatase with a specific activity of more than 3000 U/mg. The invention also concerns a process for the production of a DNA according to the invention, a vector containing the DNA according to the invention and a cell line containing this vector. Furthermore the invention concerns a recombinant highly active alkaline phosphatase with a specific activity of more than 3000 U/mg which is coded by the DNA according to the invention.

Description

The invention concerns a DNA coding a eukaryotic highly active alkaline phosphatase with a specific activity of more than 3000 U/mg. Furthermore the invention concerns a process for the production of the DNA according to the invention as well as a vector containing the DNA according to the invention as well as a cell line containing this vector. The invention additionally concerns a recombinant highly active alkaline phosphatase with a specific activity of more than 3000 U/mg which is coded by the DNA according to the invention.

Alkaline phosphatases (AP) are dimeric, zinc-containing, non-specific phosphomonoesterases which are found in all organisms from E. coli to mammals (McComb et al., 1979). Comparison of the primary structure of different alkaline phosphatases showed a high degree of homology (25-30% homology between E. coli and mammalian AP) (Millán, 1988; Harris, 1989).

In humans and higher animals the AP family consists of four members which are coded on different gene loci (Millán, 1988; Harris, 1989). The alkaline phosphatase family includes the tissue-specific APs (placental AP (PLAP), germ cell AP (GCAP) and intestinal AP (IAP)) and the non-tissue-specific APs (TNAP) which are mainly located in the liver, kidney and bones.

A decisive property of the previously known APs is the large variability of the catalytic activity of the mammalian APs which have a 10-100-fold higher specific activity than E. coli AP. Among the mammalian APs the AP from the bovine intestine (bIAP) exhibits the highest specific activity. This property makes the bIAP attractive for biotechnological applications such as enzyme conjugates for a diagnostic reagent or dephosphorylation of DNA. In 1985 Besman and Coleman proved the existence of two IAP isoenzymes in the bovine intestine, the IAP from the calf intestine and the IAP from the intestine of a mature cow (bIAPs), by amino-terminal sequencing of chromatographically purified AP fractions. A clear difference at the amino terminus was described between the bIAP of the mature cow (LVPVEEED) and the bIAP from calf intestine (LIPAEEEN). In 1993 Weissig et al. achieved an accurate biochemical characterization by cloning a recombinant bIAP (bIAP I) with a specific activity of ca. 3000 U/mg and the N-terminus LVPVEEED. However, bIAPs from calf intestine with specific activities of up to 8000 U/mg are also commercially available (Boehringer Mannheim, Biozyme, Oriental Yeast) which, however, have previously not been further characterized. All attempts at cloning these highly active alkaline phosphatases were unsuccessful. It was therefore not possible to produce a recombinant highly active alkaline phosphatase. However, the possibility of recombinant production is absolutely essential for an economic production of highly active alkaline phosphatase.

Consequently the object of the present invention was to provide highly active alkaline phosphatases by recombinant means which can also be cloned. Highly active within the sense of the present invention means that the alkaline phosphatase according to the invention has an at least 10% increased activity compared to previously known alkaline phosphatases.

The object was achieved according to the invention by the provision of a DNA coding a eukaryotic highly active alkaline phosphatase with a specific activity of more than 3000 U/mg, preferably of at least 3500 U/mg in which the amino acid residue at position 322 is smaller than aspartate. A eukaryotic DNA is preferred within the sense of the present invention. Eukaryotic cDNA is particularly preferred which means a DNA that no longer contains introns. The term “amino acid residue smaller than aspartate” is understood as any amino acid, preferably natural amino acids or amino acids derived therefrom, which has a smaller spatial dimension than the structure of the amino acid aspartate. A DNA according to the invention is preferred in which the amino acid residue 322 is glycine, alanine, threonine, valine or serine. A DNA according to the invention is particularly preferred in which the amino acid residue 322 is glycine or serine. It is quite especially preferred that the amino acid residue 322 is glycine. A DNA according to SEQ ID NO.: 1, 3 and 5 (FIGS. 1 , 3 , 5 ) and the associated amino acid sequence according to SEQ ID NO.: 2, 4 and 6 (FIGS. 2 , 4 , 6 ) are part of the present invention. The present invention also concerns those cDNAs which differ from the afore-mentioned only in that the N-terminus is longer or shorter in comparison to the cDNAs according to SEQ ID NO.: 2, 4 and 6. In such cases the name for position 322 according to SEQ ID NO.: 2, 4 and 6 changes correspondingly. If for example the N-terminus is x amino acids longer or shorter than SEQ ID NO.: 2, 4 and 6, the relevant position 322 is also shifted by x amino acids. SEQ ID NO.: 1 contains the DNA code for the sequence of the highly active bIAPII isoenzyme. The native enzyme was known but not characterized and not possible to clone. Hence the determination of the amino acid sequence of the highly active bIAP II isoenzyme is a subject matter of the present invention. A highly purified fraction with high specific activity from the calf intestine (Boehringer Mannheim) was used to determine the sequence. Peptide maps of the highly active AP were produced by cleavage with the endoproteinases LysC, AspN, GluC, trypsin and chemical cleavage by bromocyanogen. The peptides produced in this manner were separated and isolated by means of reversed phase HPLC. Each peptide was analysed by electrospray mass spectroscopy and sequenced by means of Edman degradation. The sequences obtained in this way were compared with the published sequence of bIAP I (Weissig et al., 1993). As expected the amino terminus of bIAP II has the start sequence LIPAEEEN as described by Besman and Coleman ( J. Biol. Chem . 260, 11190-11193 (1985)). The complete amino acid sequence of bIAP II is shown in SEQ ID NO.: 2 (FIG. 2 ). According to this the bIAP II has a total of 24 amino acid substitutions compared to bIAP I. The number of amino acids in the isolated highly active bIAP II isoenzyme is 480 amino acids. The nucleotide sequence of 1798 bp ( FIG. 1 ) includes a coding region of 514 amino acids. The amino acids that are possible from position 481 to 514 inclusive can vary within wide limits.

In the following the present invention describes the cloning and complete characterization of two new previously unknown bIAPs (bIAP III and bIAP IV). Northern blot analyses were carried out on RNA samples from different sections of the bovine intestine. A cDNA bank of the probes with the strongest hybridization signal was set up with an oligo dT primer (Stratagene, San Diego, Calif., USA) in the vector IZAP II (Stratagene, San Diego, Calif, USA). The complete bank (1.0×10 6 recombinant clones) was screened with the 1075 bp HindIII fragment of bIAP I which covers a region from exon I to VIII of the bIAP I gene. 65 Clones were isolated and sequenced. In this process two new bIAPs were identified (bIAP III and bIAP IV) whose characterization is described further below and were neither completely homologous to bIAP I nor to bIAP II. The nucleotide sequences of bIAP III and IV are shown in FIGS. 3 and 5 . The sequence differences of bIAPs I IV are shown in FIG. 7 . However, none of the new bIAPs has the expected N-terminus LIPAEEEN but rather new previously not described N-termini (see FIG. 7 ). The cDNA of the two new bIAP isoenzymes was recleaved with appropriate restriction enzymes and inserted by ligation into the CHO expression vector pcDNA-3 (e.g. from the Invitrogen Co. San Diego, Calif., USA). The clones which contained the new bIAP isoenzymes were brought to expression according to the method described by Invitrogen and the isoenzymes were characterized. The expression of a bIAP gene in various hosts is described in WO 93/18139 (CHO cells, E. coli , baculovirus system). The methods, vectors and expression systems described in this document are part of the disclosure of the present application. The present invention in addition concerns the native and recombinant highly active alkaline phosphatases bIAP III and bIAP IV. The alkaline phosphatases according to SEQ ID NO.: 4 and 6 are particularly preferred. CHO cell lines containing the bIAP III and bIAP IV gene were deposited at the DSMZ, “Deutsche Sammlung von Mikroorganismen und Zellkulturen GmbH”, Mascheroder Weg 1b, D-38124 Braunschweig (DSM ACC 2349, DSM ACC 2350).

In the following the invention describes the construction of the bIAP II sequence by ligation of mutated and wild-type fragments of bIAP I, III and IV. A series of intermediary intermediate products (L1N8, INT 1, INT 2 and INT 3) was generated by this process which code for functional isoenzymes. In order to construct these intermediary intermediate products a section of the bIAP-cDNA to be modified was cleaved out in each case with appropriate restriction enzymes and replaced by a segment of another bIAP-cDNA containing the desired mutations which possesses compatible ends by digestion with restriction enzymes. Mutations which cannot be introduced by ligation of segments of different bIAP-cDNAs were introduced by site-directed mutagenesis. The mutated fragment was subsequently recleaved with appropriate restriction enzymes and ligated into a like-wise cleaved bIAP-cDNA segment with compatible ends (FIG. 8 ). The mutations introduced in this manner were subsequently checked by restriction analysis and sequencing.

Hence a subject matter of the present invention is a process for the production of the DNA according to the invention characterized in that mutated and wild-type fragments of the DNA of one or several alkaline phosphatases were ligated. Moreover the present invention concerns a cDNA which codes functional isoenzymes and which is formed as intermediate products during the aforementioned process according to the invention. Additionally the present invention concerns a vector containing the cDNA according to the invention.

A further subject matter of the present invention is a cell line containing the vector according to the invention. Suitable cells are for example eukaryotic cells such as CHO, pichia, hansenula or saccharomyces cerevisiae and aspergillus or prokaryotic cells such as E. coli. E. coli , yeast and CHO cells are particularly preferred. Suitable starting vectors for E. coli strains are for example pTE, pTaq, bPL, pBluescript. Suitable E. coli strains are for example XL1-Blue, HB101, RR1 Δ M15, BL21(DE), MC 1000 etc. Suitable pichia vectors are for example pGAPZα and pPICZα (Invitrogen, San Diego, Calif., USA). A suitable vector for CHO cell lines is for example pcDNA-3 (Invitrogen, San Diego, Calif., USA). A CHO cell line containing the bIAP II gene was deposited at the DSMZ, “Deutsche Sammlung von Mikroorganismen und Zellkulturen GmbH”, Mascheroder Weg 1b, D-38124 Braunschweig (DSM ACC 2348).

The kinetic characterization of the recombinant bIAP I, II, III and IV isoenzymes showed considerable differences with regard to the catalytic properties (FIG. 9 ). For example bIAP II has a more than 300% increased i.e. more than three-fold higher specific activity (ca. 8600 U/mg) than bIAP I (ca. 2700 U/mg). But also bIAP III and bIAP IV exhibit an approximately 1.8-fold (ca. 4700 U/mg) and about 2.6-fold (>6700 U/mg) higher activity respectively than bIAP I ( FIG. 9 ) which corresponds to a percentage increase of ca. 170% and 250% respectively. Furthermore there was a considerable measurable difference in the heat stability of the isoenzymes. bIAP I is the most heat stable isoenzyme, the T m value of bIAP II and III is 7° C. lower and the T m value of bIAP IV is 13° C. lower than bIAP I (FIG. 9 ). The T m value is understood as the temperature at which a 50% residual activity is measured after an incubation period of 10 minutes.

In the following the invention describes the identification of amino acid residues which influence the specific activity of the bIAPs. This was aided by the intermediary intermediate products. The expression of the intermediary chimers L1N8, INT 1, INT2 and INT3 enabled 11 of the 24 amino acids to be excluded as an effector for the increase in activity (FIG. 7 ).

The L1N8 mutant enzyme had a comparable specific activity to bIAP I; consequently the mutations V2I, V4A and D8N introduced in this case are not relevant for the increase in the specific activity. The notation V2I means that at position 2 the amino acid valine is replaced by isoleucine.

The INT 1 mutant has a comparable specific activity to bIAP II and consequently this region is important.

The INT 2 mutant has a comparable specific activity to INT 1 and bIAP II and consequently the mutations S380G, D411G, D416E, Q420R, Q427L, E453Q and T480A from INT 2 can also be excluded.

In generating the INT 3 mutants no change in the high specific activity was found thus excluding an effect of the mutation N192Y.

In order to identify which of the 13 remaining residues are crucial for the high specific activity, the bIAP II cDNA was used in the present invention as a template for single mutations against the corresponding amino acid of bIAP I. The single mutants N122K, I133M, A142S, K180M, M205K, E210V, E236A, G322D and I332G as well as a combined A289Q-A294V-Q297R-L299V bIAP II mutant were constructed (FIG. 9 ).

Surprisingly it was found that mainly the mutation G322D is able to decrease the high specific activity of bIAP II (ca. 8600 U/mg) by more than a factor of 3 (2817 U/mg) and thus to convert it into the comparably low specific activity of bIAP I.

In order to verify this result the reverse mutation D322G was introduced into bIAP I in the present invention. Surprisingly in this case the reverse effect namely an increase of the specific activity of more than 3-fold to 10148 U/mg was measured and hence a comparable value to bIAP II was achieved (FIG. 9 ). A comparison of the amino acid sequences of the relatively more highly active bIAP III (ca. 4700 U/mg) and the more highly active bIAP IV (>6700 U/mg) again confirm this result. bIAP III has a serine at position in 322 and bIAP IV has a glycine.

In addition in the present invention the generated mutants were in turn examined for heat stability. Consequently the difference in the heat stability between bIAP I and bIAP II is due to a combined effect of more than one substitution. The [G 322 ]bIAP I as well as the [D 322 ]bIAP II mutants exhibit stability values which lie between those of the bIAP I and bIAP II isoenzymes (FIG. 9 ). The D322G mutation has a slight destabilizing effect (almost 4° C. in T 50 ) on the bIAP I isoenzyme whereas the substitution G322D in bIAP II results in a corresponding increase in the stability of this mutant enzyme. However, the heat stability of the wild-type bIAP I is not achieved.

Hence the subject matter of the present invention is in particular to provide a highly active recombinant alkaline phosphatase with an activity of more than 3000 U/mg which is coded by a eukaryotic cDNA. A highly active recombinant alkaline phosphatase according to the invention is particularly preferred in which a glycine, alanine, threonine, valine or serine is at position 322. An alkaline phosphatase according to the invention is particularly preferred in which a glycine is at position 322.

The highly active recombinant alkaline phosphatase according to the invention can preferably additionally have a mutation at one or several of the following positions:

Amino acid residues at position 1, 108, 125, 149, 181, 188, 219, 221, 222, 223, 224, 231, 252, 258, 260, 282, 304, 321, 330, 331, 354, 383, 385, 400, 405, 413, 428, 431 and 461 in which the mutation causes an increase in activity. Furthermore the present invention concerns a process for the production of the highly active alkaline phosphatase according to the invention. The alkaline phosphatases according to the invention can also be further improved by specific mutagenesis e.g. with regard to their thermostability.

The activity of the highly active alkaline phosphatase according to the invention was determined according to E. Mössner et al., Z. Physiol. Chem. 361 (1980), 543-549; with the difference that the test was carried out at 37° C. rather than at 25° C. as described in the publication. The determination at 37° C. is the world-wide usual temperature at which the activity is measured in diethanol buffer (BM test method 5426).

The protein determination of the APs according to the invention and of the known APs is carried out by measuring the absorbance of the protein solution at 280 nm against water. The absorbance of a low and highly active AP solution at a concentration of 1 mg/ml is 1.0 at 280 nm (A 280 nm (1 mg/ml) equals 1).

The specific activity is determined by forming a quotient of activity relative to the accompanying amount of protein.

FIGURE LEGENDS

FIG. 1 :

SEQ ID NO.: 1 nucleotide sequence of bIAP II (1798 bp) Start of the coding region for mature bIAP II at pos. 108, end at pos. 1649

FIG. 2 :

SEQ ID NO.: 2 amino acid sequence of bIAP II (480 amino acids) with cleavage sites

FIG. 3 :

SEQ ID NO.: 3 nucleotide sequence of bIAP III (2460 bp) Start of the coding region for mature bIAP III at pos. 123, end at pos. 1655

FIG. 4 :

SEQ ID NO.: 4 amino acid sequence of bIAP III (511-amino acids)

FIG. 5 :

SEQ ID NO.: 5 nucleotide sequence of bIAP IV (2542 bp) Start of the coding region for mature bIAP IV at pos. 122, end at pos. 1654

FIG. 6 :

SEQ ID NO.: 6 amino acid sequence of bIAP IV (511 amino acids)

FIG. 7 :

Amino acid differences between bIAP I, bIAP II, bIAP III and bIAP IV isoenzymes. Only the residues that are different are shown. The asterisk identifies those positions that were selected for individual mutagenesis in order to identify residues that are responsible for an increased catalytic activity of bIAP II.

FIG. 8 :

Ligation strategy for bIAP II DNA

FIG. 9 :

Kinetic parameters and heat stability of recombinant wild-type and chimeric bIAP enzymes and mutants of the bIAP enzymes changed by site-directed mutagenesis. *[QVRV]bIAP II is the abbreviation for the [Q 289 , V 294 , R 297 , V 299 ]bIAP II mutant.

The invention is further elucidated by the following examples:

Example 1

Cloning

A λgt 11 cDNA bank prepared from the intestine of mature cows (Clontech Laboratories, Palo Alto, Calif., USA) was screened using a 1075 bp Hind III fragment from the 5′ end of the bIAP I cDNA as a probe (Weissig et al., 1993). Clones from this cDNA bank were used to screen an EMBL-3 SP6/T7 genomic cDNA bank which was prepared from the liver of mature cows (Clontech Laboratories, Palo Alto, Calif., USA). A non-amplified λZAP II c-DNA bank was set up by means of an oligo dT primer (Stratagene, San Diego, Calif., USA) from mRNA which was isolated from the small intestine of a mature cow using the Trisolv™ reagent and was screened with the 1075 bp HindIII fragment of the bIAP I cDNA as a probe. The probes were radio-labelled using a random primed DNA labeling kit (Boehringer Mannheim). Phage DNA was prepared as described for λgt 11 and EMBL-3 SP6/T7 clones (Tsonis & Manes, 1988). The in vivo cleavage of the λZAP II clones was carried out according to the manufacturer's instructions (Stratagene, San Diego, Calif.). Genomic clones were characterized by Southern blot analysis as described (Sambrook et al., 1989). EcoRI cDNA fragments of λgt 11 clones and different restriction fragments from clones of other banks were subcloned into the KS+vector (Stratagene, San Diego, Calif., USA). Plasmid DNA was prepared by alkaline lysis (Sambrook et al., 1989). The sequencing was carried out using Sequenase according to the manufacturer's protocol (Amersham). The oligo-nucleotides used to sequence the bIAPs III and IV are described in the following: 1s: SEQ ID NO.7: GCC AAG AAT GTC ATC CTC; 1a: SEQ ID NO.8: GAG GAT GAC ATT CTT GGC; 2s: SEQ ID NO.9: GGT GTA AGT GCA GCC GC; 2a: SEQ ID NO.10: GCG GCT GCA CTT AGA CC; 3s: SEQ ID NO. 11: AAT GTA CAT GTT TCC TG; 3a: SEQ ID NO.12: CAG GAA ACA TGT ACA TT; 4s: SEQ ID NO.13: CCA GGG CTT CTA CCT CTT; 4a: SEQ ID NO.14: AAG AGG TAG AAG CCC TGG; 5s: SEQ ID NO.15: ACC AGA GCT ACC ACC TCG; 5a: SEQ ID NO.16: AAG CAG GAA ACC CCA AGA; 6s: SEQ ID NO.17: CTT CAG TGG CTT GGG ATT; 6a: SEQ ID NO.18: AAT CCC AAG CCA CTG AAG. The nucleic acid sequences were analysed with the MacVector sequence analysis program (International Biotechnologies, Inc. New Haven, Conn., USA).

Example 2

Determination of the amino acid sequence of bIAP II

Approximately 500 μg of a purified highly active (ca. 6000 U/mg) bovine intestinal AP was dissolved in 450 μl 6M guanidine hydrochloride, 0.25 M Tris, 1 mM EDTA, pH 8.5 and subsequently 30 μl mercaptoethanol was added. After reduction for 30 minutes at 100° C., the cysteines were alkylated by addition of 35 μl vinylpyridine and this mixture was incubated in the dark for 45 minutes at room temperature. The reaction mixture was then immediately desalted over a short reversed phase HPLC Aquapore RP300 column (30×2.1 mm, Applied Biosystems, Weiterstadt). A step gradient of acetonitrile in 0.1% trifluoroacetic acid was used to elute bound enzymes. Fractions containing protein were evaporated to dryness. In order to deglycosylate the enzyme 125 μg AP was dissolved in 15 μl distilled water and 6 μl incubation buffer (250 mM Na 2 HPO 4 , 50 mM EDTA, pH 7.2) and 15 U EndoF/PNGase (Boehringer Mannheim, Penzberg). The mixture was kept overnight at 37° C. and subsequently used for cleavage. Reduced and alkylated AP was enzymatically cleaved with various enzymes according to the instructions on the data sheets of the individual enzymes (endoproteinase LysC, endoproteinase AspN, endoproteinase GluC and trypsin (Boehringer Mannheim, Penzberg). Cyanogen bromide cleavage was carried out for 8 hours using 10% (w/w) CNBr in 70% (v/v) formic-acid. After dissolving with water, the volume of the solution was reduced using a SpeedVac concentrator (Savant) and used for a reversed phase HPLC. The C-terminal tryptic peptide was digested for 4 minutes with carboxypeptidase Y (8 ng/μl) and the released peptides were analysed according to the manufacturer's instructions with matrix-supported laser desorption/ionisation mass spectrometry using a Bruker Reflex III instrument. 2,5 Dihydroxybenzoic acid (10 mg/ml) in acetonitrile/water (50/50, v/v) was used as the matrix. Peptides from enzymatic or chemical cleavages were separated by reversed phase HPLC on a LiChrospher C18 selB column 125×2 mm (Merck, Darmstadt) using a 0.1% trifluoroacetic acid/acetonitrile solvent system. The flow rate was 300 μl/min. The eluant was detected by UV monitoring at 206 nm and the fractions were collected manually. The mass determination of the peptides was carried out with an API III electrospray mass spectrometer (PE-Sciex, Langen) according to the manufacturer's instructions. The amino acid sequence was determined with a 492 A protein sequencer (Applied Biosystems, Weiterstadt) according to the manufacturer's instructions.

Example 3

Preparation of the bIAP II cDNA and bIAP II mutagenesis

In order to prepare a cDNA which codes for bIAP II, wild-type restriction fragments and site-directed mutagenized PCR fragments of the cDNAs bIAP I, III and IV were ligated with one another and the L1N8 (3 fragments) and INT 1 (9 fragments) cDNA intermediate constructs were created. INT 1 and bIAP III then served as a template for the site-directed mutagenesis and fragments from this were assembled to form the complete INT 2 (8 fragments) cDNA. Restriction fragments of INT 2 and site-directed mutagenized fragments of INT 2 were then assembled to form the INT 3 (5 fragments) cDNA and finally to form the bIAP II (4 fragments) cDNA. The site-directed mutagenesis was carried out according to the method of Tomic et al. (1990) using Bsa I (type II s) as the restriction enzyme which cleaves at a distance from its recognition sequence (GGTCTCN1/N5). All PCR products were sequenced in order to verify the absence of secondary mutations. All constructs were confirmed by sequencing and restriction digestion. The sequence of the oligonucleotide primers used to amplify the site-directed mutagenized fragments are as follows: the name of the primer is mentioned first followed by the sequence (positions that indicate the mutations are underlined: KS:SEQ ID NO.19: CGA GGT CGA CGG TAT CG; 1L:SEQ ID NO.20: GCA GGT CTC TCA GCT GGG ATG A G G GTG AGG; 8N:SEQ ID NO.21: GCA GGT CTC AGC TGA GGA GGA A AA CCC CGC; 122:SEQ ID NO.22: GCA GGT CTC TGT TGT GTC GCA CTG GTT; 1s:SEQ ID NO.7: GCC AAG AAT GTC ATC CTC; M133I:SEQ ID NO.23: GGT CTC TTT CTT GGC CCG GTT G AT CAC; S142A:SEQ ID NO.24: GGT CTC AAG AAA GCA GGG AAG G CC GTC; 180:SEQ ID NO.25: GGT CTC GTG CAT CAG CAG GCA GGT CGG C; M180K:SEQ ID NO.26: GGT CTC ATG CAC AGA A GA ATG GCT GCC AG; K205M:SEQ ID NO.27: GGT CTC AAA CAT GTA CAT TCG GCC TCC ACC; V210E:SEQ ID NO.28: GT CTC CAT GTT TCC TGA GGG GAC CCC A; A236E:SEQ ID NO.29: GGT CTC CTG CCA T T C C TG CAC CAG GTT; 236:SEQ ID NO.30: GGT CTC TGG CAG GCC AAG CAC CAG GGA; 289:SEQ ID NO.31: GGT CTC CAG GGT CGG GTC CTT GGT GTG; E289A:SEQ ID NO.32: GGT CTC GAC CCT GG C GGA GAT GAC G; 330:SEQ ID NO.33: GGT CTC CTC AGT CAG TGC CAT ATA; 330E,V332I:SEQ ID NO:34: GGT CTC ACT GA G GCG A TC ATG TTT GAC; XIa:SEQ ID NO.35: TG CAC CAG GTG CGC CTG CGG GCC; N192Y:SEQ ID NO.36: GCC GCA CAG CTG GTC T AC AAC ATG GAT; S380G:SEQ ID NO.37: GCT GTC TAA GGC CTT GC C GGG GGC; N192Y:SEQ ID NO.38: GCC GCA CAG CTG GTC T AC AAC ATG GAT; D411G:SEQ ID NO.39: GGG GGT CTC GCT TGC TG C CAT TAA C: D416E:SEQ ID NO.40: GTT AAT GGT CTC ACA AGC GAG GA A CCC TCG; S428A:SEQ ID NO.41: CCC GTG GGT CTC GCT AG C C CAG GGG CAC; D416E:SEQ ID NO:42: GTT AAT GGT CTC ACA AGC GAG GA A CCC TCG; T480S:SEQ ID NO.43: GAT GCT GGT CTC GGT GG A GGG GGC TGG CAG; 480:SEQ ID NO.44: CTG CCA GGT CTC ACC ACC GCC ACC AGC ATC; SP6:SEQ ID NO.45: CAT ACG ATT TAG GTG ACA CTA TAG; 236:SEQ ID NO.46: GGT CTC TGG CAG GCC AAG CAC CAG GGA; Q304R-:SEQ ID NO.47: GTA GAA GCC CC G GGG GTT CCT GCT; Q304+:SEQ ID NO.48:AGC AGG AAC C CC CGG GGC TTC TAC; E321D:SEQ ID NO.49: TGC CAT ATA AGC TTT GCC G TC ATG GTG. The various PCR reactions are numbered 1-16, the templates are either wild-type cDNAs bIAP I, III or IV or the chimeric constructs INT 1 or INT 2. The oligonucleotide primers (1L in parantheses) are stated above. 1. bIAP IV (KS, 1L); 2. bIAP IV (8N, 122); 3. bIAP III (1S, M133I); 4.bIAP I (S142A, 180); 5. bIAP I (M180K, K205M); 6. bIAP I(V210E, A236E); 7. bIAP I (236, 289); 8. bIAP IV (E289A, 330); 9. bIAP III (330E, V332I, XIa); 10. INT1 (N192Y, S380G); 11. INT1 (N192Y, D411G); 12. bIAP III (D416E, S428A); 13. INT1 (D416E, T480S); 14. INT1 (480, SP6); 15. INT2 (236, Q304R−); 16. INT2 (Q304R+, E321D). The following ligation reactions were carried out in all cases using the pcDNA- 3 (Invitrogen, San Diego, Calif.) expression vector. The fragments are numbered according to the aforementioned PCR reaction numbers or named with the name of the wild-type or the chimeric cDNA followed by the restriction enzymes which were used to form the cohesive terminus of this fragment. L1N8 =pcDNA-3/EcoRI-XbaI+1/EcoRI-BsaI+2/BsaI-BamHI+bIAP I/BamHI-XbaI. INT 1=pcDNA-3/EcoRI-XbaI+L1N8/EcoRI-NcoI+3/NcoI-BsaI+4/BsaI+5/BsaI+6/BsaI+7/BsaI+8/BsaI+9/BsaI-StuI+bIAP I/StuI-XbaI. INT 2 =pcDNA-3/EcoRI-NotI+INT1/EcoRI-PstI+10/PstI-StuI+11/StuI-BsaI+12/BsaI+13/BsaI+14/BsaI+bIAP I/BsaI-NotI. INT 3 =pcDNA-3/EcoRI-XbaI+INT2/EcoRI-NcoI+INT2/NcoI-PvuII+10/PvuII-EagI+INT2/EagI-HindIII+INT2/HindIII-XbaI. bIAP II=pcDNA-3/EcoRI-XbaI+INT3/EcoRI-EagI+15/EagI-SmaI+16/SmaI-HindIII+INT3/HindIII-XbaI.

10 Additional constructs were prepared in order to identify the residue (the residues) which are responsible for the various kinetic properties of bIAP I and II. All constructs were subcloned in pcDNA-3/EcoRI-XbaI. 5 Constructs were prepared by exchange of restriction fragments between L1N8 or bIAP I (I) and bIAP II (II). L1N8 EcoRI-Pm1I and (II) Pm1I-XbaI were ligated in order to prepare the [N122K]bIAP II mutant cDNA. (II) EcoRI-BstEII, (I) BstEII-PvuII, (II) PvuII XbaI were combined for the [K180M]bIAP II mutant cDNA. (II) EcoRI-EagI, (I) EagI-BstEII, (II) BstEII-XbaI were ligated for the [A289Q, A294V, Q297R, L299V]bIAP II mutant. (II) EcoRI-EagI, (II) EagI-BstEII, (I) BstEII-HindIII, (II) HindIII-XbaI for the [G322D]bIAP II mutant. (II) EcoRI-HindIII, (I) HindIII-SacI, (II) SacI-XbaI for the [I332G]bIAP II mutant. 5 other positions required new site-directed mutagenesis. The following oligonucleotides were used for this: I133M-:SEQ ID NO.50: GGT CTC TTT CTT GGC CCG GTT CAT CAC; A142S-:SEQ ID NO.51: TGG TCA CCA CTC CCA CGG ACT TCC CTG; M205K-:SEQ ID NO.52: GGT CTC AAA CAT GTA TTT TCG GCC TCC ACC; E210V+:SEQ ID NO.53: GGT CTC ATG TTT CCT GTG GGG ACC CCA GAC; E236A:SEQ ID NO.54: GGT CTC CTG CCA TGC CTG CAC CAG GTT. The following 8 PCR reactions (a-h) with bIAP II as the template were carried out using these and the previously listed oligonucleotides: a. 1s, I133M−; b. S142A+, M205K−; c. 1s, A142S−; d. V210E+, 330−; e. E210V+, 330−; f. M180K+, E236A−; g. 236+, 330−; h. S142A, K205M−. The products which were formed from this were subcloned and sequenced and then the fragments were isolated for the following ligations: (II) EcoRI-NcoI, (a) NcoI-BsaI, (b) BsaI, PvuII, (II) PvuII-XbaI for I133M. (II) EcoRI-NcoI, (c) NcoI-BstEII, (II) BstEII-PvuII, (II) PvuII-XbaI for A142S. (II) EcoRI-BstEII, (b) BstEII-BsaI, (d) BsaI-HindIII, (II) HindIII-XbaI for M205K. (II) EcoRI-BstEII, (h) BstEII-BsaI, (e) BsaI-HindIII, (II) HindIII-XbaI for E210V. (II) EcoRI-NcoI, (II) NcoI-PvuII, (f) PvuII-BsaI, (g) BsaI-HindIII, (II) HindIII-XbaI for E236A.

Example 4

Production and characterization of recombinant enzymes

All cDNAs (bIAP I, bIAP II, bIAP III, bIAP IV and corresponding mutants) were cloned into the pcDNA-3 expression vector (Invitrogen, San Diego, Calif., USA), transferred into ovarial cells of a chinese hamster (CHO cells) and stable transfectants were selected by growing the cells in the presence of 500 μg/ml geneticin (Gibco, BRL). Recombinant APs were extracted as described from stably transferred CHO cells (Hoylaerts et al., 1997). Microtitre plates that were coated with 0.1 μg/ml high affinity anti-bovine AP monoclonal antibody (Scottish Antibody Production Unit, Lanarkshire, Scotland) were incubated with increasing enzyme concentrations in order to measure the k cat . The activity of the bound enzyme was measured as the change in absorbance with time at 405 nm and 20° C. after addition of 30 mM p-nitrophenyl phosphate (pNPP) as the substrate in 1.0 M diethanolamine buffer (pH 9.8), 1 mM MgCl 2 and 20 μM ZnCl 2 . The concentration of the p-nitrophenol that formed was calculated with an extinction coefficient of 10,080 litre mole −1 cm −1 . Commercial preparations with known specific activities (Biozyme Laboratories, 7822 U/mg and Boehringer Mannheim, 3073 U/mg) and also purified bIAP II (8600 U/mg) were used as standards. The enzyme concentration in these solutions which saturated the antibody (E°) was calculated from a standard curve of activity against known enzyme concentrations under identical test conditions. The maximum substrate conversion (V max ) was then divided by E° in order to calculate k cat . In order to calculate K m the substrate concentration was changed between 0.25-2.0 mM p-nitrophenyl phosphate (pNPP) and the initial reaction rate at 20° C. was measured over a period of 10 minutes. Regression curves of [pNPP]/v versus [pNPP] (Hanes curves) as the X axis yielded −K m . Division of the standard deviation of the calculated y value for each x value in the regression by the slope of regression yielded the standard deviation of K m . V max ±standard deviation was calculated using the appropriate equations by dividing K m ± standard deviation by the y intercept±standard deviation. The specific activities were calculated in comparison to Biozyme on the basis of antibody-saturated activity. Heat stability curves were established by incubation of extracts at 45-75° C. with an increase in 5° C. steps every 10 minutes as described previously (Weissig et al., 1993). The activity of each sample was then determined as described above and the residual activity was calculated as the residual percentage compared to the non-heated sample. The temperature at which 50% residual activity remains (T 50 ) was calculated from the residual activity against temperature curves.

54 1798 base pairs nucleotide single strand linear genomic DNA 1GAATTCGGCA CGAGCCAGGT CCCATCCTGA CCCTCCGCCA TCACACAGCT ATGCAGTGGG 60CCTGTGTGCT GCTGCTGCTG GGCCTGTGGC TACAGCTCTC CCTCACCCTC ATCCCAGCTG 120AGGAGGAAAA CCCCGCCTTC TGGAACCGCC AGGCAGCCCA GGCCCTTGAT GTAGCCAAGA 180AGTTGCAGCC GATCCAGACA GCTGCCAAGA ATGTCATCCT CTTCTTGGGG GATGGGATGG 240GGGTGCCTAC GGTGACAGCC ACTCGGATCC TAAAGGGGCA GATGAATGGC AAACTGGGAC 300CTGAGACACC CCTGGCCATG GACCAGTTCC CATACGTGGC TCTGTCCAAG ACATACAACG 360TGGACAGACA GGTGCCAGAC AGCGCAGGCA CTGCCACTGC CTACCTGTGT GGGGTCAAGG 420GCAACTACAG AACCATCGGT GTAAGTGCAG CCGCCCGCTA CAATCAGTGC AACACGACAC 480GTGGGAATGA GGTCACGTCT GTGATCAACC GGGCCAAGAA AGCAGGGAAG GCCGTGGGAG 540TGGTGACCAC CACCAGGGTG CAGCATGCCT CCCCAGCCGG GGCCTACGCG CACACGGTGA 600ACCGAAACTG GTACTCAGAC GCCGACCTGC CTGCTGATGC ACAGAAGAAT GGCTGCCAGG 660ACATCGCCGC ACAGCTGGTC TACAACATGG ATATTGACGT GATCCTGGGT GGAGGCCGAA 720TGTACATGTT TCCTGAGGGG ACCCCAGACC CTGAATACCC AGATGATGCC AGTGTGAATG 780GAGTCCGGAA GGACAAGCAG AACCTGGTGC AGGAATGGCA GGCCAAGCAC CAGGGAGCCC 840AGTATGTGTG GAACCGCACT GCGCTCCTTC AGGCGGCCGA TGACTCCAGT GTAACACACC 900TCATGGGCCT CTTTGAGCCG GCAGACATGA AGTATAATGT TCAGCAAGAC CACACCAAGG 960ACCCGACCCT GGCGGAGATG ACGGAGGCGG CCCTGCAAGT GCTGAGCAGG AACCCCCGGG 1020GCTTCTACCT CTTCGTGGAG GGAGGCCGCA TTGACCACGG TCACCATGAC GGCAAAGCTT 1080ATATGGCACT GACTGAGGCG ATCATGTTTG ACAATGCCAT CGCCAAGGCT AACGAGCTCA 1140CTAGCGAACT GGACACGCTG ATCCTTGTCA CTGCAGACCA CTCCCATGTC TTCTCTTTTG 1200GTGGCTACAC ACTGCGTGGG ACCTCCATTT TCGGTCTGGC CCCCGGCAAG GCCTTAGACA 1260GCAAGTCCTA CACCTCCATC CTCTATGGCA ATGGCCCAGG CTATGCGCTT GGCGGGGGCT 1320CGAGGCCCGA TGTTAATGGC AGCACAAGCG AGGAACCCTC ATACCGGCAG CAGGCGGCCG 1380TGCCCCTGGC TAGCGAGACC CACGGGGGCG AAGACGTGGC GGTGTTCGCG CGAGGCCCGC 1440AGGCGCACCT GGTGCACGGC GTGCAGGAGG AGACCTTCGT GGCGCACATC ATGGCCTTTG 1500CGGGCTGCGT GGAGCCCTAC ACCGACTGCA ATCTGCCAGC CCCCGCCACC GCCACCAGCA 1560TCCCCGACGC CGCGCACCTG GCGGCCAGCC CGCCTCCACT GGCGCTGCTG GCTGGGGCGA 1620TGCTGCTGCT GCTGGCGCCC ACCTTGTACT AACCCCCACC AGTTCCAGGT CTCGGGATTT 1680CCCGCTCTCC TGCCCAAAAC CTCCCAGCTC AGGCCCTACC GGAGCTACCA CCTCAGAGTC 1740CCCACCCCGA AGTGCTATCC TAGCTGCCAC TCCTGCAGAC CCGACCCAGC CGGAATTC 1798 480 amino acids amino acid single strand linear protein 2Leu Ile Pro Ala Glu Glu Glu Asn Pro Ala Phe Trp Asn Arg Gln Ala1 5 10 15Ala Gln Ala Leu Asp Val Ala Lys Lys Leu Gln Pro Ile Gln Thr Ala 20 25 30Ala Lys Asn Val Ile Leu Phe Leu Gly Asp Gly Met Gly Val Pro Thr 35 40 45Val Thr Ala Thr Arg Ile Leu Lys Gly Gln Met Asn Gly Lys Leu Gly 50 55 60Pro Glu Thr Pro Leu Ala Met Asp Gln Phe Pro Tyr Val Ala Leu Ser65 70 75 80Lys Thr Tyr Asn Val Asp Arg Gln Val Pro Asp Ser Ala Gly Thr Ala 85 90 95Thr Ala Tyr Leu Cys Gly Val Lys Gly Asn Tyr Arg Thr Ile Gly Val 100 105 110Ser Ala Ala Ala Arg Tyr Asn Gln Cys Asn Thr Thr Arg Gly Asn Glu 115 120 125Val Thr Ser Val Ile Asn Arg Ala Lys Lys Ala Gly Lys Ala Val Gly 130 135 140Val Val Thr Thr Thr Arg Val Gln His Ala Ser Pro Ala Gly Ala Tyr145 150 155 160Ala His Thr Val Asn Arg Asn Trp Tyr Ser Asp Ala Asp Leu Pro Ala 165 170 175Asp Ala Gln Lys Asn Gly Cys Gln Asp Ile Ala Ala Gln Leu Val Tyr 180 185 190Asn Met Asp Ile Asp Val Ile Leu Gly Gly Gly Arg Met Tyr Met Phe 195 200 205Pro Glu Gly Thr Pro Asp Pro Glu Tyr Pro Asp Asp Ala Ser Val Asn 210 215 220Gly Val Arg Lys Asp Lys Gln Asn Leu Val Gln Glu Trp Gln Ala Lys225 230 235 240His Gln Gly Ala Gln Tyr Val Trp Asn Arg Thr Ala Leu Leu Gln Ala 245 250 255Ala Asp Asp Ser Ser Val Thr His Leu Met Gly Leu Phe Glu Pro Ala 260 265 270Asp Met Lys Tyr Asn Val Gln Gln Asp His Thr Lys Asp Pro Thr Leu 275 280 285Ala Glu Met Thr Glu Ala Ala Leu Gln Val Leu Ser Arg Asn Pro Arg 290 295 300Gly Phe Tyr Leu Phe Val Glu Gly Gly Arg Ile Asp His Gly His His305 310 315 320Asp Gly Lys Ala Tyr Met Ala Leu Thr Glu Ala Ile Met Phe Asp Asn 325 330 335Ala Ile Ala Lys Ala Asn Glu Leu Thr Ser Glu Leu Asp Thr Leu Ile 340 345 350Leu Val Thr Ala Asp His Ser His Val Phe Ser Phe Gly Gly Tyr Thr 355 360 365Leu Arg Gly Thr Ser Ile Phe Gly Leu Ala Pro Gly Lys Ala Leu Asp 370 375 380Ser Lys Ser Tyr Thr Ser Ile Leu Tyr Gly Asn Gly Pro Gly Tyr Ala385 390 395 400Leu Gly Gly Gly Ser Arg Pro Asp Val Asn Gly Ser Thr Ser Glu Glu 405 410 415Pro Ser Tyr Arg Gln Gln Ala Ala Val Pro Leu Ala Ser Glu Thr His 420 425 430Gly Gly Glu Asp Val Ala Val Phe Ala Arg Gly Pro Gln Ala His Leu 435 440 445Val His Gly Val Gln Glu Glu Thr Phe Val Ala His Ile Met Ala Phe 450 455 460Ala Gly Cys Val Glu Pro Tyr Thr Asp Cys Asn Leu Pro Ala Pro Ala465 470 475 480 2460 base pairs nucleotide single strand linear genomic DNA 3GAATTCGGCA CGAGCGAGAC CCAGACTCCC CAGGTCCCAT CCTGACCCTC CGCCATCACA 60CAGCTATGCA GGGGGCCTGC GTGCTGCTGC TGCTGGGCCT GTGGCTACAG CTCTCCCTCG 120CCTTCATCCC AGTTGAGGAG GAAGACCCCG CCTTCTGGAA CCGCCAGGCA GCCCAGGCCC 180TTGATGTGGC TAAGAAGCTG CAGCCCATCC AGAAAGCCGC CAAGAATGTC ATCCTCTTCT 240TGGGAGATGG GATGGGGGTG CCTACGGTGA CAGCCACTCG GATACTGAAG GGGCAGATGA 300ATGACAAGCT GGGACCTGAG ACACCCCTGG CCATGGACCA GTTCCCATAC GTGGCTCTGT 360CCAAGACATA CAACGTGGAC AGACAGGTGC CAGACAGCGC AGGCACTGCC ACTGCCTACC 420TGTGTGGGGT CAAGGGCAAC TACAGAACCA TCGGTGTAAG TGCAGCCGCC CGCTACAATC 480AGTGCAACAC GACACGTGGG AATGAGGTCA CGTCTGTGAT GAACCGGGCC AAGAAAGCAG 540GGAAGTCAGT GGGAGTGGTG ACCACCACCA GGGTGCAGCA CGCCTCCCCA GCCGGTGCTT 600ATGCACACAC GGTGAACCGT GACTGGTACT CAGACGCCGA CCTGCCTGCC GATGCACAGA 660CGTATGGCTG CCAGGACATC GCCACACAAC TGGTCAACAA CATGGATATT GACGTGATCC 720TGGGTGGAGG CCGAAAGTAC ATGTTTCCTG AGGGGACCCC AGACCCTGAA TACCCACACG 780ATGCCAGTGT GAATGGAGTC CGGAAGGACA AGCGGAATCT GGTGCAGGAG TGGCAGGCCA 840AGCACCAGGG AGCCCAGTAT GTGTGGAACC GCACGGAGCT CCTTCAGGCA GCCAATGACT 900CCAGTGTTAC ACATCTCATG GGCCTCTTTG AGCCGGCAGA CATGAAGTAT AATGTTCAGC 960AAGACCCCAC CAAGGACCCG ACCCTGGAGG AGATGACGGA GGCGGCCCTG CAAGTGCTGA 1020GCAGGAACCC CCAGGGCTTC TACCTCTTCG TGGAGGGAGG CCGCATTGAC CACGGTCACC 1080ATGATAGCAA AGCTTATATG GCGCTGACTG AGGCGGTCAT GTTTGACAAT GCCATCGCCA 1140AGGCTAACGA GCTCACTAGC GAACTGGACA CGCTGATCCT TGTCACTGCA GACCACTCCC 1200ATGTCTTCTC TTTTGGTGGC TACACACTGC GTGGGACCTC CATTTTCGGT CTGGCCCCCA 1260GCAAGGCCTC AGACAAGAAG TCCTACACCT CCATCCTCTA TGGCAATGGC CCTGGCTACG 1320TGCTTGGTGG GGGCTCAAGG CCCGATGTTA ATGACAGCAT AAGCGAGGAC CCCTCATACC 1380GGCAGCAGGC GGCCGTGCCC CTGTCTAGCG AGACCCACGG GGGCGAAGAC GTGGCGGTGT 1440TCGCGCGAGG CCCGCAGGCG CACCTGGTGC ACGGCGTGCA GGAGGAGACC TTCGTGGCGC 1500ACGTCATGGC CTTTGCGGGC TGCGTGGAGC CCTACACCGA CTGCAATCTG CCGGCCCCCT 1560CTGGCCTCTC CGACGCCGCG CACCTGGCGG CCAGCGCGCC TTCGCTAGCG CTGCTGGCCG 1620GGGCGATGCT GCTGCTGCTG GCGCCCGCCT TGTACTGACC CCCACCAACT CCAGGTCTTG 1680GGGTTTCCCG CTTTCTTGCC CCAAAATCTC CCAGCGCAGG CCCCATCTGA GCTACCACCT 1740CAGAGTCCCC ACCCTGAAGT CCTATCTAGC GCACTCCAGA CCGCGACTCA GCCCCACCAC 1800CAGAGCTTCA CCTCCCAGCA ACGAAGGAGC CTTAGCTCAC AGCCTTTCAT GGCCCAGACC 1860ATTCTGGAGA CTGAGGCCCT GATTTTCCCG ACCCAACTTC AGTGGCTTGA GATTTTGTGT 1920TCTGCCACCC CGGATCCCTG TAAGGGGGCT CGGACCATCC AGACTCCCCC CACTGCCCAC 1980AGCCGAACCT GAGGACCAGG CTGGCACGGT CCCAGGGGTC CCAGGCCCGG CTGGAACCCA 2040CATCTTTGCC TTTCAGGAGA CCCTGGGACT GTGGGGTTTC CAGGAGGCGT GGCTTCTTGG 2100AGGCGTGGCT TCGGAGGGGT GGCTTCCGAG AAGGCGTGGC TCCCTGTCCT GGAACCACCC 2160TGTGGGNATC TGGGGCCCAA GGAGATGTCT GGGGCAAAGA GTGCCGGGGG ACCCTGGACA 2220CAGAATCTTC AGCGGCCCCT CCTAGGAACC CAGCAGTACC ATTATAGAGA GGGGACACCG 2280ACACAGAGGA GAGGAGACTT GTCCCAGGTC CCTCAGCTGC TGTGAGGGGT GACCCTTGGT 2340TCCCGTTACC AGGCTGGGGG ATCCCAGGAG CAGCGGGGGA CCTGGGGGTG GGGACACAGG 2400CCCCACACTC CTGGGAGGGA GGAAGCAGCC CTNAAATAAA CTGTTCCTCG TGCCGAATTC 2460 511 amino acids amino acid single strand linear protein 4Phe Ile Pro Val Glu Glu Glu Asp Pro Ala Phe Trp Asn Arg Gln Ala1 5 10 15Ala Gln Ala Leu Asp Val Ala Lys Lys Leu Gln Pro Ile Gln Lys Ala 20 25 30Ala Lys Asn Val Ile Leu Phe Leu Gly Asp Gly Met Gly Val Pro Thr 35 40 45Val Thr Ala Thr Arg Ile Leu Lys Gly Gln Met Asn Asp Lys Leu Gly 50 55 60Pro Glu Thr Pro Leu Ala Met Asp Gln Phe Pro Tyr Val Ala Leu Ser65 70 75 80Lys Thr Tyr Asn Val Asp Arg Gln Val Pro Asp Ser Ala Gly Thr Ala 85 90 95Thr Ala Tyr Leu Cys Gly Val Lys Gly Asn Tyr Arg Thr Ile Gly Val 100 105 110Ser Ala Ala Ala Arg Tyr Asn Gln Cys Asn Thr Thr Arg Gly Asn Glu 115 120 125Val Thr Ser Val Met Asn Arg Ala Lys Lys Ala Gly Lys Ser Val Gly 130 135 140Val Val Thr Thr Thr Arg Val Gln His Ala Ser Pro Ala Gly Ala Tyr145 150 155 160Ala His Thr Val Asn Arg Asp Trp Tyr Ser Asp Ala Asp Leu Pro Ala 165 170 175Asp Ala Gln Thr Tyr Gly Cys Gln Asp Ile Ala Thr Gln Leu Val Asn 180 185 190Asn Met Asp Ile Asp Val Ile Leu Gly Gly Gly Arg Lys Tyr Met Phe 195 200 205Pro Glu Gly Thr Pro Asp Pro Glu Tyr Pro His Asp Ala Ser Val Asn 210 215 220Gly Val Arg Lys Asp Lys Arg Asn Leu Val Gln Glu Trp Gln Ala Lys225 230 235 240His Gln Gly Ala Gln Tyr Val Trp Asn Arg Thr Glu Leu Leu Gln Ala 245 250 255Ala Asn Asp Ser Ser Val Thr His Leu Met Gly Leu Phe Glu Pro Ala 260 265 270Asp Met Lys Tyr Asn Val Gln Gln Asp Pro Thr Lys Asp Pro Thr Leu 275 280 285Glu Glu Met Thr Glu Ala Ala Leu Gln Val Leu Ser Arg Asn Pro Gln 290 295 300Gly Phe Tyr Leu Phe Val Glu Gly Gly Arg Ile Asp His Gly His His305 310 315 320Asp Ser Lys Ala Tyr Met Ala Leu Thr Glu Ala Val Met Phe Asp Asn 325 330 335Ala Ile Ala Lys Ala Asn Glu Leu Thr Ser Glu Leu Asp Thr Leu Ile 340 345 350Leu Val Thr Ala Asp His Ser His Val Phe Ser Phe Gly Gly Tyr Thr 355 360 365Leu Arg Gly Thr Ser Ile Phe Gly Leu Ala Pro Ser Lys Ala Ser Asp 370 375 380Lys Lys Ser Tyr Thr Ser Ile Leu Tyr Gly Asn Gly Pro Gly Tyr Val385 390 395 400Leu Gly Gly Gly Ser Arg Pro Asp Val Asn Asp Ser Ile Ser Glu Asp 405 410 415Pro Ser Tyr Arg Gln Gln Ala Ala Val Pro Leu Ser Ser Glu Thr His 420 425 430Gly Gly Glu Asp Val Ala Val Phe Ala Arg Gly Pro Gln Ala His Leu 435 440 445Val His Gly Val Gln Glu Glu Thr Phe Val Ala His Val Met Ala Phe 450 455 460Ala Gly Cys Val Glu Pro Tyr Thr Asp Cys Asn Leu Pro Ala Pro Ser465 470 475 480Gly Leu Ser Asp Ala Ala His Leu Ala Ala Ser Ala Pro Ser Leu Ala 485 490 495Leu Leu Ala Gly Ala Met Leu Leu Leu Leu Ala Pro Ala Leu Tyr 500 505 510 2542 base pairs nucleotide single strand linear genomic DNA 5GAATTCGGCA CGAGGAGACC CGGCCTCCCC AGGTCCCATC CTGACCCTCC GCCATCACAC 60AGCCATGCAG TGGGCCTGTG TGCTGCTGCT GCTGGGCCTG TGGCTACAGC TCTCCCTCAC 120CTTCATCCCA GCTGAGGAGG AAGACCCCGC CTTCTGGAAC CGCCAGGCAG CCCAGGCCCT 180TGATGTAGCC AAGAAGTTGC AGCCGATCCA GACAGCTGCC AAGAATGTCA TCCTCTTCTT 240GGGGGATGGG ATGGGGGTGC CTACGGTGAC AGCCACTCGG ATCCTAAAGG GGCAGATGAA 300TGGTAAGCTG GGACCTGAGA CACCCCTGGC CATGGACCAG TTCCCATACG TGGCTCTGTC 360CAAGACATAC AACGTGGACA GACAGGTGCC AGACAGCGCA GGCACTGCCA CTGCCTACCT 420GTGTGGGGTC AAGGGCAACT ACAAAACCAT TGGTGTAAGT GCAGCCGCCC GCTACAACCA 480GTGCAACACA ACAAGTGGCA ATGAGGTCAC GTCTGTGATG AACCGGGCCA AGAAAGCAGG 540AAAGTCAGTG GGAGTGGTGA CCACCTCCAG GGTGCAGCAT GCCTCCCCAG CCGGTGCTTA 600TGCACACACG GTGAACCGAA ACTGGTACTC AGATGCCGAC CTGCCTGCCG ATGCACAGAC 660GTATGGCTGC CAGGACATCG CCACACAACT GGTCAACAAC ATGGATATTG ACGTGATCCT 720GGGTGGAGGC CGAATGTACA TGTTTCCTGA GGGGACCCCG GATCCTGAAT ACCCATACGA 780TGTCAATCAG ACTGGAGTCC GGAAGGACAA GCGGAATCTG GTGCAGGAGT GGCAGGCCAA 840GCACCAGGGA GCCCAGTATG TGTGGAACCG CACGGAGCTC CTTCAGGCAG CCAATGACCC 900CAGTGTAACA CACCTCATGG GCCTCTTTGA GCCGGCAGAC ATGAAGTATA ATGTTCAGCA 960AGACCCCACC AAGGACCCGA CCCTGGAGGA GATGACGGAG GCGGCCCTGC AAGTGCTGAG 1020CAGGAACCCC CAGGGCTTCT ACCTCTTCGT GGAGGGAGGC CGCATTGACC ACGGTCACCA 1080TGAAGGCAAA GCTTATATGG CACTGACTGA TACAGTCATG TTTGACAATG CCATCGCCAA 1140GGCTAACGAG CTCACTAGCG AACTGGACAC GCTGATCCTT GCCACTGCAG ACCACTCCCA 1200TGTCTTCTCT TTTGGTGGCT ACACACTGCG TGGGACCTCC ATTTTCGGTC TGGCCCCCAG 1260CAAGGCCTCA GACAACAAGT CCTACACCTC CATCCTCTAT GGCAATGGCC CTGGCTACGT 1320GCTTGGTGGG GGCTTAAGGC CCGATGTTAA TGACAGCATA AGCGAGGACC CCTCGTACCG 1380GCAGCAGGCG GCCGTGCCCC TGTCTAGTGA GTCCCACGGG GGCGAGGACG TGGCGGTGTT 1440CGCGCGAGGC CCGCAGGCGC ACCTGGTGCA CGGCGTGCAG GAGGAGACCT TCGTGGCGCA 1500CGTCATGGCC TTTGCGGGCT GCGTGGAGCC CTACACCGAC TGCAATCTGC CGGCCCCCTC 1560TGGCCTCTCC GACGCCGCGC ACCTGGCGGC CAGCCCGCCT TCGCTGGCGC TGCTGGCCGG 1620GGCGATGCTG CTGCTGCTGG CGCCTGCCTT GTACTGACCC CCACCAACTC CAGGTCTTGG 1680GGTTTCCTGC TTTCCTGCCA AAAATCTCCC AGCGCAGACC CCACCAGAGC TACCACCTCG 1740GAGTCTCCAC CCTGAAGTCC TATCTTAGCG GCCACTCCCG GATCCCCGAC CAGGCCCCAC 1800TAGCAGAGCT TCACCTCCCA GAAATGAAGG ATTCACCTTC CAGCAACGAA GAAGCCTCAG 1860CTCACAGCCC TTCATGGCCC AGCCCATCCA GAGGCTGAGG CCCTGATTTC CCTGTGACAC 1920CCGTAGACCT ACTGCCCGAC CCCAACTTCA GTGGCTTGGG ATTTTGTGTT CTGCCACCCC 1980TAACCCCAGT AAGGGGGCTC GGACCATCCA GACTCTCCCC ACTGCCCACA ACCCCACCTG 2040AGAACCAGGC TAGCACGGTC CCAAGGTTCC CAGGCCCGGC TAGAACCCAC ACCATGCCTT 2100TCAGGAGACC CTGGGGCTCC GGGGTTTCCG GGAGGCGTGG CTTTCTTAGG AGGCGTGGAA 2160ACTGAGGAGG CACGGTTTCT GAGGAGGCGT GCGTCCTGGG GAGCTGTGGC TTCCGGTCCT 2220CCCCATGCCC TGTGGGCTCC TCCCTAACCA AGGAGACGGC CAAGGAGACG TCTGGAACCA 2280GGAGCGGCGG GGGAACCTTG CAGAGCCCTC AGCAACCCCT CCTAGGAACC CAGGGTACCG 2340TTAGAGAGAG GAGACAGCGA CACAGAGGAG AGGAGACTTG TCCCAGGTCT CTCAGCTGCT 2400ATGAAGGTGG CCCCGGTGCC CCTTCCAGGC TGGGAGATCC CAGGAGCAGC GGGGGAGCTG 2460GTGGGTGGGG ACACAGCCCC GCCTTCATGG GAGGGAGGAA GCAGCCCTCA AATAAACTGT 2520TCTAAGTGTG AAAAAATCTA GA 2542 511 amino acids amino acid single strand linear protein 6Phe Ile Pro Ala Glu Glu Glu Asp Pro Ala Phe Trp Asn Arg Gln Ala1 5 10 15Ala Gln Ala Leu Asp Val Ala Lys Lys Leu Gln Pro Ile Gln Thr Ala 20 25 30Ala Lys Asn Val Ile Leu Phe Leu Gly Asp Gly Met Gly Val Pro Thr 35 40 45Val Thr Ala Thr Arg Ile Leu Lys Gly Gln Met Asn Gly Lys Leu Gly 50 55 60Pro Glu Thr Pro Leu Ala Met Asp Gln Phe Pro Tyr Val Ala Leu Ser65 70 75 80Lys Thr Tyr Asn Val Asp Arg Gln Val Pro Asp Ser Ala Gly Thr Ala 85 90 95Thr Ala Tyr Leu Cys Gly Val Lys Gly Asn Tyr Lys Thr Ile Gly Val 100 105 110Ser Ala Ala Ala Arg Tyr Asn Gln Cys Asn Thr Thr Ser Gly Asn Glu 115 120 125Val Thr Ser Val Met Asn Arg Ala Lys Lys Ala Gly Lys Ser Val Gly 130 135 140Val Val Thr Thr Ser Arg Val Gln His Ala Ser Pro Ala Gly Ala Tyr145 150 155 160Ala His Thr Val Asn Arg Asn Trp Tyr Ser Asp Ala Asp Leu Pro Ala 165 170 175Asp Ala Gln Thr Tyr Gly Cys Gln Asp Ile Ala Thr Gln Leu Val Asn 180 185 190Asn Met Asp Ile Asp Val Ile Leu Gly Gly Gly Arg Met Tyr Met Phe 195 200 205Pro Glu Gly Thr Pro Asp Pro Glu Tyr Pro Tyr Asp Val Asn Gln Thr 210 215 220Gly Val Arg Lys Asp Lys Arg Asn Leu Val Gln Glu Trp Gln Ala Lys225 230 235 240His Gln Gly Ala Gln Tyr Val Trp Asn Arg Thr Glu Leu Leu Gln Ala 245 250 255Ala Asn Asp Pro Ser Val Thr His Leu Met Gly Leu Phe Glu Pro Ala 260 265 270Asp Met Lys Tyr Asn Val Gln Gln Asp Pro Thr Lys Asp Pro Thr Leu 275 280 285Glu Glu Met Thr Glu Ala Ala Leu Gln Val Leu Ser Arg Asn Pro Gln 290 295 300Gly Phe Tyr Leu Phe Val Glu Gly Gly Arg Ile Asp His Gly His His305 310 315 320Glu Gly Lys Ala Tyr Met Ala Leu Thr Asp Thr Val Met Phe Asp Asn 325 330 335Ala Ile Ala Lys Ala Asn Glu Leu Thr Ser Glu Leu Asp Thr Leu Ile 340 345 350Leu Ala Thr Ala Asp His Ser His Val Phe Ser Phe Gly Gly Tyr Thr 355 360 365Leu Arg Gly Thr Ser Ile Phe Gly Leu Ala Pro Ser Lys Ala Ser Asp 370 375 380Asn Lys Ser Tyr Thr Ser Ile Leu Tyr Gly Asn Gly Pro Gly Tyr Val385 390 395 400Leu Gly Gly Gly Leu Arg Pro Asp Val Asn Asp Ser Ile Ser Glu Asp 405 410 415Pro Ser Tyr Arg Gln Gln Ala Ala Val Pro Leu Ser Ser Glu Ser His 420 425 430Gly Gly Glu Asp Val Ala Val Phe Ala Arg Gly Pro Gln Ala His Leu 435 440 445Val His Gly Val Gln Glu Glu Thr Phe Val Ala His Val Met Ala Phe 450 455 460Ala Gly Cys Val Glu Pro Tyr Thr Asp Cys Asn Leu Pro Ala Pro Ser465 470 475 480Gly Leu Ser Asp Ala Ala His Leu Ala Ala Ser Pro Pro Ser Leu Ala 485 490 495Leu Leu Ala Gly Ala Met Leu Leu Leu Leu Ala Pro Ala Leu Tyr 500 505 510 18 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 7GCCAAGAATG TCATCCTC 18 18 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 8GAGGATGACA TTCTTGGC 18 17 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 9GGTGTAAGTG CAGCCGC 17 17 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 10GCGGCTGCAC TTAGACC 17 17 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 11AATGTACATG TTTCCTG 17 17 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 12CAGGAAACAT GTACATT 17 18 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 13CCAGGGCTTC TACCTCTT 18 18 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 14AAGAGGTAGA AGCCCTGG 18 18 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 15ACCAGAGCTA CCACCTCG 18 18 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 16AAGCAGGAAA CCCCAAGA 18 18 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 17CTTCAGTGGC TTGGGATT 18 18 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 18AATCCCAAGC CACTGAAG 18 17 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 19CGAGGTCGAC GGTATCG 17 30 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 20GCAGGTCTCT CAGCTGGGAT GAGGGTGAGG 30 30 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 21GCAGGTCTCA GCTGAGGAGG AAAACCCCGC 30 27 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 22GCAGGTCTCT GTTGTGTCGC ACTGGTT 27 27 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 23GGTCTCTTTC TTGGCCCGGT TGATCAC 27 27 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 24GGTCTCAAGA AAGCAGGGAA GGCCGTC 27 28 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 25GGTCTCGTGC ATCAGCAGGC AGGTCGGC 28 29 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 26GGTCTCATGC ACAGAAGAAT GGCTGCCAG 29 30 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 27GGTCTCAAAC ATGTACATTC GGCCTCCACC 30 27 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 28GTCTCCATGT TTCCTGAGGG GACCCCA 27 27 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 29GGTCTCCTGC CATTCCTGCA CCAGGTT 27 27 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 30GGTCTCTGGC AGGCCAAGCA CCAGGGA 27 27 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 31GGTCTCCAGG GTCGGGTCCT TGGTGTG 27 25 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 32GGTCTCGACC CTGGCGGAGA TGACG 25 24 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 33GGTCTCCTCA GTCAGTGCCA TATA 24 27 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 34GGTCTCACTG AGGCGATCAT GTTTGAC 27 23 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 35TGCACCAGGT GCGCCTGCGG GCC 23 27 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 36GCCGCACAGC TGGTCTACAA CATGGAT 27 24 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 37GCTGTCTAAG GCCTTGCCGG GGGC 24 27 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 38GCCGCACAGC TGGTCTACAA CATGGAT 27 25 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 39GGGGGTCTCG CTTGCTGCCA TTAAC 25 30 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 40GTTAATGGTC TCACAAGCGA GGAACCCTCG 30 27 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 41CCCGTGGGTC TCGCTAGCCA GGGGCAC 27 30 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 42GTTAATGGTC TCACAAGCGA GGAACCCTCG 30 30 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 43GATGCTGGTC TCGGTGGAGG GGGCTGGCAG 30 30 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 44CTGCCAGGTC TCACCACCGC CACCAGCATC 30 24 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 45CATACGATTT AGGTGACACT ATAG 24 27 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 46GGTCTCTGGC AGGCCAAGCA CCAGGGA 27 24 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 47GTAGAAGCCC CGGGGGTTCC TGCT 24 24 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 48AGCAGGAACC CCCGGGGCTT CTAC 24 27 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 49TGCCATATAA GCTTTGCCGT CATGGTG 27 27 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 50GGTCTCTTTC TTGGCCCGGT TCATCAC 27 27 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 51TGGTCACCAC TCCCACGGAC TTCCCTG 27 30 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 52GGTCTCAAAC ATGTATTTTC GGCCTCCACC 30 30 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 53GGTCTCATGT TTCCTGTGGG GACCCCAGAC 30 27 base pairs nucleotide single strand linear other nucleic acid /desc = “oligonucleotide” 54GGTCTCCTGC CATGCCTGCA CCAGGTT 27

Claims

1. A highly active recombinant alkaline phosphatase with a specific activity of more than 3000 U/mg which is coded by a DNA in which the triplet which codes for the amino acid residue corresponding to the amino acid residue at position 322 of SEQ ID NO 2, 4 or 6 codes for an amino acid residue that is smaller than aspartate.

2. The alkaline phosphatase of claim 1, wherein said amino acid residue 322 is selected from the group consisting of glycine, alanine, threonine, valine and serine.

3. The alkaline phosphatase of claim 1, wherein said amino acid residue 322 is selected from the group consisting of glycine and serine.

4. The alkaline phosphatase of claim 1, wherein said amino acid residue 322 is glycine.

5. The alkaline phosphatase of claim 1, wherein said DNA has a nucleotide sequence as shown in FIG. 1 (SEQ ID NO.: 1).

6. The alkaline phosphatase of claim 1, wherein said DNA has a nucleotide sequence as shown in FIG. 3 (SEQ ID NO.: 3).

7. The alkaline phosphatase of claim 1, wherein said DNA has a nucleotide sequence as shown in FIG. 5 (SEQ ID NO.: 5).

8. The highly active recombinant alkaline phosphatase of claim 1, wherein said DNA has an additional mutation at an amino acid position selected from the group consisting of 1, 108, 125, 149, 181, 188, 219, 221, 222, 223, 224, 231, 252, 258, 260, 282, 304, 321, 330, 331, 354, 383, 385, 400, 405, 413, 428, 431 and 461.

9. An isolated highly active alkaline phosphatase comprising the amino acid sequence shown in SEQ ID NO.: 4.

10. An isolated highly active alkaline phosphatase comprising the amino acid sequence shown in SEQ ID NO.: 6.