WO1983004051A1

WO1983004051A1 - Expression of preprothaumatin-like proteins in kluyveromyces yeasts

Info

Publication number: WO1983004051A1
Application number: PCT/EP1983/000129
Authority: WO
Inventors: Luppo Edens; Adrianus Marinus Ledeboer; Cornelis Theodorus Verrips; Johannes Abel Van Den Berg
Original assignee: Unilever N.V.
Priority date: 1982-05-19
Filing date: 1983-05-19
Publication date: 1983-11-24
Also published as: AR241796A1; NO840133L; GR78852B; HU204097B; DK173699B1; ATE42338T1; EP0096430B2; AU571181B2; IL68733A; EP0096910A1; AU1553983A; JPS61275227A; PT76727A; CA1224735A; PT76727B; ES522556A0; EP0096430B1; JPS59501572A; FI840149A; IE831185L

Abstract

Yeasts of the genus $i(Kluyveromyces), in particular $i(K. lactis), acting as hosts for the expression of preprothaumatin or its various allelic and modified forms or their maturation forms, which yeasts contain an rDNA plasmid comprising a structural gene encoding for a thaumatin-like protein, an autonomous replicating sequence derived from $i(K. lactis) (KARS), a yeast regulon derived from the GAPDH-genes of $i(S. cerevisiae), and a selection marker, e.g. the trp-1 or the lac-4 gene from $i(S. cerevisiae) and $i(K. lactis), respectively. Optionally the plasmid also contains a transcription terminator from a yeast. Further the preparation of such yeasts and the preparation of thaumatin-like proteins with such yeasts and the proteins so obtained are claimed. The yeast described give a better expression than obatined with $i(E. coli).

Description

EXPRESSION OF PREPROTHAUMATIN-LIKE PROTEINS INKLUYVEROMYCES YEASTS

The present invention relates to the microbiological preparation of preprothaumatin and related compounds, which preparation has been made possible by recombinant DNA techniques. In European patent applications (A2) 0 054 330 and 0 054 331, both published on 23 June 1982, DNA sequences encoding various allelic forms of preprothaumatin, their maturation forms such as pre thaumatin, prothaumatin and thaumatin, and modified forms thereof, as well as cloning vehicles comprising said DNA sequences, their use in transforming microorganisms, in particular E . coli, and the preparation of thaumatin like proteins are described.

For the production to be commercially attractive, the yields obtained with E . coli are not high enough, so that a need exists for microbiological systems which are capable of producing the thaumatin-like proteins in far higher amounts. By thaumatin-like proteins are meant preprothaumatin, its various allelic or modified forms, and their maturation forms such as prethaumatin, prothaumatin and thaumatin.

It has now been found that the structural genes described in the above-mentioned European patent applica tions can be combined with autonomously replicating sequences originating from Kluyveromyces lactis (so-called KARS), with a selection marker and with a yeast regulon into a plasmid, which plasmid can be brought into yeast cells of the Kluyveromyces genus, which then become capable of producing the thaumatin-like proteins. In this way expression of the thaumatin-like proteins in yeast cells succeeded.

Therefore, the present invention provides a yeast of the genus Kluyveromyces containing a recombinant DNA plasmid comprising :

(i) a structural gene encoding for preprothaumatin or its various allelic or modified forms or their maturation forms,

(ii) an autonomously replicating sequence originating from Kluyveromyces lactis (so-called KARS), (iii) a yeast regulon derived from the glyceraldehyde-3-phosphate dehydrogenase (GAPDH) genes,of Saccharomyces cerevisiae, and

(iv) a selection marker, such as the trp-1 or the lac-4 gene.

In this way a much improved expression of the desired proteins could be obtained, so that commercial application comes more within reach.

Preferably the plasmid also contains a transcription terminator derived from a yeast, and/or a centromer and/or a replicating region derived from a yeast.

Good results have been obtained with a Kluyveromyces lactis yeast, but it is very probable that other Kluyveromyces species will be effective as well. The structural genes are preferably selected from the group consisting of the structural genes disclosed in the above-mentioned European patent applications.

Successful KARS-sequences were isolated from the wild strain K. lactis CBS 2360, as will be described below.

For transformation purposes in K. lactis it is desirable to use selectable markers on the vectors, for example the tryptophan gene (trp-1) and the lactase gene (lac-4) which originate from S. cerevisiae and K. lactis, respectively. These DNA-sequences are effective not only as selective markers, but also in enabling a selective pressure to be exerted on the system during further propagation.

Preferably the transcription terminator, if used, is selected from the group consisting of a terminator sequence originating from the Hind III-Eco RI fragment of the 2 micron DNA vector of S. cerevisiae and a terminator sequence derived from the GAPDH genes of S. cerevisiae.

The presence of a centromer or replicating region derived from a yeast chromosome, e.g. from S. cerevisiae or from K. lactis improves the stability of the plasmids according to the invention.

The invention further provides a process for preparing a yeast of the genus Kluyveromyces as described above, which process comprises the preparation of a recombinant DNA plasmid by combining a structural gene as indicated above with a KARS-sequence and upstream of the structural gene with a yeast GAPDH regulon and with a selection marker, and optionally with a centromer or replicating region derived from a yeast chromosome and optionally downstream of the structural gene with a transcription terminator derived from a yeast, followed by introducing the plasmid so prepared into a yeast of the Kluyveromyces genus. Finally the invention provides a process for the microbiological preparation of preprothaumatin or its various allelic or modified forms or their maturation forms disclosed in the above-mentioned European patent applications as well as the proteins so prepared, which process comprises cultivating a yeast of the Kluyveromyces genus as described above, followed by harvesting the thaumatin or thaumatin-like protein thus produced by the yeast.

The invention will be illustrated below in more detail.

Yeasts of the genus Kluyveromyces were chosen, because these micro-organisms comprise many harmless rnicro-organisms which can be used in foods and drugs manufacture. For example, the species Kluyveromyces lactis and Kluyveromyces fragilis are safe organisms which are mentioned in the GRAS-list of the Food and Drugs Administration of the USA (GRAS = Generally Recognized As Safe). The behaviour of K. lactis in fermentation processes is known to be better than that of E. coli and quite controllable; the separation of yeasts from the fermentation fluid is preferable to that of e.g. E. coli and often yeasts produce larger quantities of (extra-cellular or periplasmic) proteins than E. coli. Therefore yeasts of the genus Kluyveromyces lend themselves better to industrial production than E. coli.

Up to now vectors for Kluyveromyces were not known at all. As a result of extensive research and experimentation new vectors were found which are capable of transforming the host organism Kluyveromyces lactis and which, moreover, are able to replicate autonomously in the transformed cell.

The new K. lactis vectors control the function of replication and maintenance in K. lactis. These replication sequences are the autonomously replicating sequences originating from Kluyveromyces lactis (KARS).

Vectors of the KARS type are used because of their high transformation frequency.

The most suitable representative is pKARS-2, a hybrid plasmid composed of a K. lactis DNA fragment containing the KARS-2 sequence which is inserted into the known S. cerevisiae plasmid YRp7 (Struhl et al , Proc. Natl. Acad. Sci, USA, 76, 1035-1039).

On the vectors there are suitable restriction sites which allow further gene cloning.

Also Escherichia coli is a suitable host. In that case the ampicillin resistance gene (Amp^R) is also a suitable selectable marker on the vector. The plasmids are preferably multiplied and stored within E. coli cells. The transformed strains are selectively grown on L-broth containing ampicillin (100 micrograms/ml). One transformed strain, viz E. coli JA 221 (pKARS 12) was deposited with the Centraal Bureau voor Schimrnelcultures, Oosterstraat 1, 3742 SK Baarn, The Netherlands, under number CBS 353.82 (= LMD 82.20) on 19 May 1982. The plasmids can be isolated from the cells by e.g. the method of Katz, L. et al, J. Bacterol. 114 (1973) 577. The protoplasts of the yeast host are transformed by the aforementioned vectors in a usual incubation medium containing Tris, calcium chloride and polyethylene glycol having a molecular weight ranging from 2,000 to 6,000, but preferably of 4,000.

In using KARS-type plasmids one has the possibility of selecting for the presence of tryptophan prototrophy in the transformants.

The autonomous existence of the KARS-containing plasmids in transformed cells was demonstrated with the aid of DNA analysis. Undigested minilysates of transformants were analyzed according to the Southern procedure, by hybridization with labelled pBR322, the bacterial part of the pKARS plasmids.

Comparative electrophoresis of a minilysate of an untransformed Kluyveromyces lactis lac-4 mutant and of purified plasmid preparations shows that only in the transformants hybridizing bands are present with electrophoretic mobilities corresponding to supercoiled and open circular forms of the plasmid used for transformation.

Presence of the plasmid in transformed cells was further confirmed by transforming E. coli with the DNA preparation from the yeast transformants and isolating the same plasmids from the E. coli transformants formed.

Particularly useful hosts are the mutants Kluyveromyces lactis SD11 lac-4 trp-1 and SD69 lac-4, which are derived from the wild type CBS 2360 and deposited with Centraal Bureau voor Schimmelcultures, Oosterstraat 1,

3742 SK Baarn, Netherlands, under numbers SBS 8092 and nr CBS 8093, respectively, on 19 May 1982. Usually, transforming plasmids remain within the host cell as separate entities capable of autonomous replication and expression. It is pointed out here, however, that genes, located on plasmids (with or without repli cation sequences) can subsequently also be integrated in the chromosomal DNA of the cell.

The invention is exemplified by a detailed description for the production of preprothaumatin. But the invented process is also applicable for the cloning and expression of other genes encoding for thaumatin-like proteins.

When the invented strains are further adapted for large scale production, it is desirable to remove all bacterial DNA sequences from the vector plasmids.

Genes can remain on autonomously replicating plasmids after having been introduced into the cell or may be integrated in the chromosomal DNA of the host cell.

Isolation of KARS-sequences, their incorporation in recombinant DNA plasmids, and their introduction into cells of K. lactis

A. Preparation of recombinant pKARS plasmids

5 micrograms of plasmid YRp7 (Struhl et al., Proc. Natl. Acad. Sci., USA 76, 1035-39 (1979) were digested with restriction-enzyme Sal I. 14 micrograms of DNA from the wild strain K. lactis CBS 2360 were digested with enzyme Xho I. The fragments of the plasmid and the K. lactis DNA were mixed in a molar ratio of 1:3, forming a DNA fragments mixture.

After inactivation of the restriction-enzymes the solution was brought to a DNA concentration of 25 micrograms/ml and incubated with T4-ligase under standard conditions (Boehringer).

Transformation of E. coli DG75 with the ligated mixture under usual conditions yielded a mixture of 4.5x10⁵

Amp ^R transformants, 9x10³ of which contained K. lactis inserts, as could be deduced from their sensitivity to tetracycline.

The proportion of tetracycline-sensitive cells could be increased to 85% by cycloserine treatment (Bolivar F. and Backman K. (Methods in Enzymology, 68 (1979) 245-267). According to the method of Katz et al. (see Ex. 1) 14 different plasmids were isolated, which were referred to as pKARS 1-14. All were capable of transforming the K. lactis SD11 lac-4 trp-1 strain to Trp⁺ phenotype with a frequency of 10 -10⁴ per microgram of DNA. Plasmid pKARS-12 showed the highest transformation frequency of 3x10⁴ per microgram of DNA, but plasmid pKARS-2 appeared to be more convenient in further processing. The recombinant plasmids obtained could also be transferred to E. coli JA221 ( trp E5, leu B6, lac y, rec A, hsdM⁺, hsdR-).

B. Kluyveromyces lactis SD11 lac-4 trp-1 transformed to Trp+ with plasmid pKARS-12

Cells of the strain K. lactis SD11 lac4 trp-1 were suspended in a growth medium (pH 6.8) containing 1% of yeast extract, 2% of peptone and 2% of glucose. The growth was continued until the exponential phase (3- 5.10⁷ cells per ml) had been reached.

The yeast cells were collected by centrifugation, wash ed with water and resuspended in a solution (pH 8.0) containing 1.2 mol/l sorbitol, 25 mmol/l EDTA and 0.2 mol/l fresh mercaptoethanol.

After incubation for 10 min. at 30°C the cells were centrifuged, washed two times with an 1.2 mol/l sor sorbitol solution and suspended in 20 ml of a solution (pH 5.8) containing 1.2 mol/l sorbitol, 10 mmol/l EDTA, 0.1 mol/l sodium citrate and 10 mg helicase.

Protoplasts were formed and after 15-20 min. these were centrifuged, washed three times with 1.2 mol/l sorbitol and resuspended to a concentration of about 5.10¹⁰ cells per ml in 0.1 ml of a solution containing 10 mmol/l CaCl₂ and 1.2 mol/l sorbitol.

10 micrograms of pKARS-12 DNA were added and the mixture was incubated for 15 min. at 25°C. Thereafter 0.5 ml of a solution (pH 7.5) containing 10 mmol/l Tris, 10 mmol/l CaCl₂ and 20% (w/v) polyethylene glycol 4000 was added, followed by 20 min. incubation. Protoplasts were precipitated by centrifugation and then resuspended to a concentration of about 5.10 protoplasts per ml in a solution (pH 6.8) containing 7 mmol/l CaCl₂, 1.2 mol/l sorbitol, 0.5 mg/ml yeast extract, 1 mg/ml peptone and 2 mg/ml glucose.

After incubation for 60 min. at 30°C the protoplasts were centrifuged, washed with 0.6 mol/l KCl solution and resuspended in 0.6 mol/l KCl solution.

In order to be able to select the Trp+ tranformants, 1.10⁹ protoplasts were brought on 2% agar minimal plates (with 3% agar overlay) containing 2% of glucose and 0.6 mol/l KCl.

Colonies appeared within 4-5 days. On 0.6 mol/l KCl plates with glucose as carbon source protoplast regeneration is usually 0.5-1.5%. Per microgram of pKARS12 DNA 3.4x10⁴ Trp+ transformants were obtained.

DNA preparations were made according to Struhl et al. (Proc. Natl. Acad. Sci., USA 76, 1035-1039, (1979).

C. Kluyveromyces lactis SD69 lac-4 transformed to Trp+ with KARS-type plasmids

Analogously to the method described in B transformation experiments could be carried out with other KARS type plasmids. The results of the experiments are summarized in the following Table.

The molecular weights of pKARS plasmids were determined after digestion with Eco RI and Hind III endonucleases, using 0.8% of agarose gel and the usual molecular weight markers.

The following detailed description will illustrate the isolation of the GAPDH regulon and its introduction into preprothaumatin encoding plasmids. Isolation of clones containing the glyceraldehyde-3-phosphate dehydrogenase (GAPDH) operon of S. cerevisiae.

Unless stated otherwise, all enzyme incubations were carried out under conditions described by the supplier. Enzymes were obtained from Amersham, Boehringer, BRL or Biolabs.

A DNA pool of the yeast S. cerevisiae vras prepared in the hybrid E. coli-yeast plasmid pFl 1 (M.R.Chevallier et al. Gene 11, 11-19 (1980)) by a method similar to the one described by M.Carlson and D.Botstein, Cell 28, 145-154 (1982). Purified yeast DNA was partially digested digested with restriction endcnuclease Sau 3A and the resulting DNA fragments (with an average length of 5 kb) were ligated by T4 DNA ligase in the dephosphorylated Bam HI site of pFl 1. After transformation of CaCI₂-treated E. coli cells with the ligated material a pool of about 30.000 ampicillin resistant clones was obtained. These clones were screened by a colony hybridization procedure (R.E. Thayer, Anal. Biochem., 98, 60-63 (1979)) with a chemically synthesized and ³²P-labelled oligcmer with the sequence 5'TACCAGGAGACCAACTT3'.

According to data published by J.P. Holland and M.J. Eblland (J. Biol. Chen., 255, 2596-2605, 1980) this oligcmer is complementary with the DNA sequence encoding aminoacids 306-310 (the wobble base of the last amino acid was emitted frcm the oligcmer) of the GAPDH gene. Using hybridization conditions decribed by R.B. Wallace et al., Micleic Acid Res., 9, 879-894 (1981), six positive transformants could be identified. One of these harboured plasmid pFl 1-33. The latter plasmid contained titie GAPDH gene including its promoter/regulation region and its transcription termination/ polyadenylation region. The approximately 9 kb long insert of pFl 1-33 has been characterized by restriction enzyme analysis (Fig. 1) and partial nucleotide sequence analysis (Figs. 2 and 3). E. Isolation of the GAPDH promoter/regulation region and its introduction into a preprothaumatin encoding plasmid (Fig 4)

On the basis of the restriction enzyme analysis and the nucleotide sequence data of the insert of plasmid pFl 1-33, the RNA initiation/ regulation region of the GAPDH gene was isolated as an 800 nucleotides long Cde I fragment. To identify this prαroter fragment, plasmid pFl 1-33 was digested with Sal I and the three resulting DNA fragments were subjected to a Southern hybridization test with the chemically synthesized oligcmer [E.M. Southern, J.Mol.Eiol. 98, 503-517 (1975)]. A positively hybridizing 4.3 kb long restriction fragment was isolated on a preparative scale by electroelution from a 0.7% agarose gel and was then cleaved with Dde I. Of the resulting Dde I fragments only the largest one had a recognition site fbr Pvu II, a cleavage site located within the GAPDH regulon region (Fig. 1). The largest Dde I fragment was isolated and incubated with Klencw DNA polymerase and four dNTP's (A.R. Davis et al., Gene 10, 205-218 (1980)) to generate a blunt-ended DNA molecule. After extraction of the reaction mixture with phenol/chloroform (50/50 v/v), passage of the aquous layer through a Sephadex G50 column and ethanol precipitation of the iraterial present in the void volune, the DNA fragment was equipped with the ³²P- labelled Eco RI linker 5'GGAATTCCS' by incubation with T4 ENA ligase. Owing to the Klenow DNA polymerase reaction and the subsequent ligation of the Eco RI linker, the original Dde I sites were reconstructed at the ends of the regulon fragment. Tb inactivate the. ligase the reaction mixture was heated to 65°C for 10 minutes, then sodium chloride was added (final concentration 50 mol/l) and the whole mix was incubated with Eco RI. Incubation was terminated by extraction with phenol/ chloroform, the DNA was precipitated twice with ethanol, resuspended and then ligated into a suitable vector molecule. Since the Dde I regulon fragment was equipped with Eco RI sites, it can easily be introduced into the Eco RI site of pUR 528 (EP-PA 54331) to create a plasmid in which the yeast regulon is adjacent to the structural gene encoding preprothaunatin. The latter plasmid was obtained by cleavage of pUR 528 with Eco RI, treatment of the linearized plasmid molecule with (calf intestinal) alkaline phosphatase to prevent self-ligation and incubation of each of these vector molecules, as well as the purified Dde I promoter fragment, with T4 ENA ligase. Transformation of the various ligation mixes in CaCl₂-treated E. coli HB101 cells yielded several ampicillin resistant, colonies. From seme of these colonies plasmid DNA was isolated (H.C. Birnboiin and J. Doly, Nucleic Acids Res. 7, 1513-1523 (1979)), and incubated with PvuII to test the orientation of the insert.

In the nomenclature plasmids containing the Eco RI (Dde I) GAFCB regulon fragment in the correct orientation (i.e. transcription from the GAPDH regulon occurs in the direction of a downstream located structural gene) are indicated by the addendum-01 to the original code of the plasmid (for example pUR 528 is changed in pUR 528-01; see Fig. 4).

Tb facilitate manipulation of plasnids containing the Eco RI regulon fragment, one of the two Eco RI sites was destroyed. Two /ug of plasmid DNA (e.g. pUR 528-01) was partially digested with Eco RI and then incubated with 5 units Mung bean nuclease (obtained from P.L. Biochetnicals Inc.) in a total volume of 200 /ul in the presence of 0.05 moles/l sodium acetate (pH 5.0), 0.05 moles/l sodium chloride and 0.001 moles/l zinc chloride for 30 minutes at rocm temperature to remove sticky ends. The nuclease was inactivated by addition of SDS to a final concentration of 0.1% (D. Kbwalski et al., Biochemistry 15, 4457-4463 (1976) ) and the DNA was precipitated by the addition of 2 volumes of ethanol (in this case the addition of 0.1 volume of 3 moles/1 sodium acetate was emitted). Linearized DNA molecules were then religated by incubation with T4 ENA ligase and used to transform CaCl₂-treated E. coli cells. Plasmid DNA isolated from ampicillin resistant colonies was tested by cleavage with EcoRI and Mlu I for the presence of a single Eco RI site adjacent to the preprothaumatin gene (cf. Fig. 4).

Plasmids containing the GAPDH prcmoter fragment but having only a single Eco RI recognition site adjacent to the ATG initiation codon of a downstream located structural gene, are referred to as -02 type plas mids (for example: pUR 528-01 is changed in pUR 528-02; see Fig. 4). F. Reconstitution of the original GAPDH promoter/regulation region in plasmids encoding preprothaumatin by introduction of a synthetic DNA fragment (Fig. 5, 6)

As shown by the nucleotide sequence depicted in Fig. 2, the Eco RI Dde I) GAPDH promoter fragment contains the nucleotides -850 to -39 of the original GAPDH promoter/regulation region. Not contained in this promoter fragment are the 38 nucleotides preceding the ATG initiation codon of the GAPDH encoding gene. The latter 38-nucleotides long fragment contains the PuCACACA sequence, which, is found in several yeast genes. Said PuCACACA sequence, situated about 20 bp upstream of the translation start site (M.J. Dobson et al. , Nucleic Acid Res. , 10, 2625-2637 (1982) ) , provides the nuσleotide sequence upstream of the ATG codon which is opti mal for protein initiation. (M. Kbzak, Nucleic Acids

Res. 9, 5233-5252 (1981) ) . Moreover, as shown in Fig. 7, these 38 nucleotides allow the formation of a loop structure which might be involved in the regulation of expression of the GAPDH gene. On the basis of the above-mentioned arguments, introduction of the 38 nucleotides between the Dde I prcmoter-fragment and the ATG codon of a downstream located structural gene was considered necessary to improve promoter activity as well as translation initiation. As outlined in Fig. 5 the missing DNA fragment was obtained by the chemical synthesis of two partially overlapping oligcmers. The Sac I site present in the overlapping part of the two oligonucleotides was introduced for two reasons: (i) to enable manipulation of the nucleotide sequence immediately upstream of the ATG codon including the construction of poly A-tailed yeast expression vectors. (ii) to give a cleavage site for an enzyme generating 3'-protruding ends that can easily and reproducibly be removed by incubation with T4 DNA polymerase in the presence of the four dNTP's. Equimolar amounts of the two purified oligomers were phosphσrylated at their 5'-termini, hybridized (J.J. Rossi et al., 1982, J. Biol. Chan. 257, 9226-9229) and converted into a double-stranded DNA molecule by incubation with Klenow DNA polymerase and the four dNTP's under conditions which have been described for double-stranded DNA synthesis (A.R. Davis et al., Gene 10, 205-218 (1980)). Analysis of the reaction products by electrophoresis through a 13% acrylamide gel followed by autoradiography showed that more than 80% of the starting single-stranded oligonucleotides were converted into double-stranded material. The DNA was isolated by passage of the reaction mix ewer a Sephadex G50 column and ethanol precipitation of the material present in the void volume. The DNA was then phosphorylated by incubation with polynucleotide kinase and digested with Dde I. To ranσve the nucleotides cleaved off in the latter reaction, the reacton mix was subjected to two precipitations with ethanol.

As shown in Fig. 6 cloning of the resulting synthetic DNA fragment was carried out by by the simultaneous ligation of this fragment and a Bgl II-Dde I GAPDH promoter regulation fragment in a vector molecule from which the Eco RI site preceding the ATG initiation codon was removed by Mung bean nuclease digestion (cf. E. ) . The Bgl II-Dde I promoter/regulation fragment was obtained by digestion of plasmid pUR 528-02 with Dde I and Bgl II. Separation of the resulting restriction fragments by electrophoresis through a 2% agarose gel and subsequent isolation of the fragment from the gel yielded the purified 793 nucleotides long promoter/regulation fragment. In the plasmid pUR 528- 02 the nucleotide sequence preceding the ATG codon is 5'-GAATTC(T)ATG 3' (EP-PA 54330 and EP-PA 54331), which is different frσn the favourable nucleotide sequence given by M. Kozak (Nucleic Acids Res. 9, 5233- 5252 (1981)). Since our aim was to reconstitute the original GAPDH promoter/regulation/protein initiation region as accurately as possible, the Eco RI site was removed in order to ligate the synthetic DNA fragment to the resulting blunt-end. Removal of the Eco RI site was accomplished by Mung bean nuclease digestion of Eco Rl-cleaved pUR528- 02 ENA (see E.).

Subsequently the plasmid DNA was digested with Bgl II and incubated with phosphatase. After separation of the two DNA fragments by electrophoresis through a 0.7% agarose gel, the largest fragment was isolated and used as the vector in which the Bgl II-Dde I promoter fragment as well as the - Dde I-treated- synthetic DNA fragment were ligated.

Plasmids in which the Dde I promoter/regulation fragment together with the Sac I recognition site containing synthetic DNA fragment are introduced are indicated by the addendum -03 (for example: pUR 528-02 is changed into pUR 528-03).

G. Introduction of 2 μrn DNA replication origin and the yeast leu-2 gene in preprothautmatin encoding plasmids

To test the functionality of the GAPDH regulon in S. cerevisiae, plasmids pUR528-02 and pUR528-03 were equipped with a replication origin obtained frcm the yeast 2 μm DNA and a selectable marker. Both functions were excised frcm plasnid ptMP81 and introduced into the two preprothaumatin encoding plasnids. The E. coli-yeast shuttle vector pM81 (Fig. 8; C.P.Holleriberg, Current Tbpics in Microbiol. and Immun., 96, 119-144, 1982)) consists of plasmid pCRI (C.Covey et al., MGG, 145, 155-158 (1976)) and a double Eco RI fragment of pJDB 219 (J.D.Beggs, Nature, 275, 104-109 (1978)) carrying both the leu-2 gene and the yeast 2 μm DNA replication origin. The last mentioned two functions were excised from pMP81 by a digestion with Hind III and Sal I. The resulting 4.4 kb long restriction fragment was combined with pUR 528-02 or pUR 528-03 derivatives oontaining preprothaumatin gene and with a GAPDH promoter/regulation region of S. cerevisiae to form plasmids. This was accomplished by cleavage of said plasmids with Hind III and Sal I (cf. Fig. 6, 9) and a subsequent treatment of the resulting fragments with phosphatase. After separation of the fragments by electrophoresis through a 1% agarose gel, the largest fragment was isolated, mixed with the purified Hind Ill-Sal I fragment obtained from pMP81, ligated with T4 DNA ligase and transformed to CaC^-treated E. coli cells. From some of the ampicillin-resistant transformants plasmid DNA was isolated and subjected to restriction enzyme analysis. Plasmids containing the correct insert (pURY 528-02 or pURY 528-03) were purified by CsCl-ethidium bromide density gradient centrifugation and used to transform S. cerevisiae (A.Hinnen et al., Proc. Natl. Acad. Sci. USA 75, 1929-1033 (1978)) according to the procedure of J.D.Beggs, Nature 275, 104-109 (1978).

H. Introduction of KARS-2 and the trp-1 gene in preprothaumatin encoding plasmids

The E. coli yeast shuttle vector pEK 2-7 consists of plasmid YEp7 (D.T. Stinchbomb et al., Nature 282, 39-43 (1979)) containing the 1,2 kb KARS-2 fragment. Owing to the presence of the yeast trp-1 gene, plasmid pEK 2-7 can be maintained in K. lactis SD11 lac-4, trp-1; (the preparation of pEK 2-7 is described in European/PCT application no. , claiming priority of Netherlands patent application 8202091).

To demonstrate the functionality of the promoter/regulation region of the GAPDH encoding gene in K. lactis, plasmid pUR 528-03 (Fig. 9) has been equipped with both the KARS-2 fragment and the trp-1 gene. The last- mentioned two functions were excised from pEK 2-7 by a digestion with Bgl II, followed by isolation from a 0.7% agarose gel of the smallest fragment generated. This purified fragment was then inserted in the dephosphorylated Bgl II cleavage site of pUR 528-03 by incubation with T4 DNA ligase. Transformation of the ligation mix in CaCl₂-treated E. coli cells yielded plasmid pURK 528-03 (Fig. 10). Transformants generated by the introduction of the latter plasmid into K . lactis SD 11 cells by the procedure described in Netherlands patent application No. 8202091 could be shown to synthesize thaumatin-like protein (Fig. 11).

By techniques similar to those mentioned above, plasmid pURY 528-03 (see G) was also equipped with the KARS-2 fragment and the yeast trp-1 gene and introduced into K. lactis SD 11 (Fig. 10).

I Expression in K. lactis of the preprothaumatin encoding genes under control of the promoter/regulation region of the glyceraldehyde-3-phosphate dehydrogenase operon of S. cerevisiae

Using the same detection procedure, K. lactis cells carrying pURK 528-33 could also be shown to synthesize a thaumatin-like protein (Fig.11). The production of thaumatin-like proteins in cells containing pURK 528-33 was, however, about 3 times higher than in cells containing pURK 528-03. Since similar observations have been made by C.Gerbaud et al. Gene 5, 233-253 (1979) in the expression of the yeast ura-3 gene upon insertion of this gene within the coding region "Able" of the 2 Aim DNA, it is very likely that the enhanced expression of thaumatin-like protein by pURK 528-33 is due to efficient transcription termination events in the transcription/polyadenylation of the "Able" operon. This observation indicates that the presence of an efficient transcription termination/polydenylation region downstream of a an efficient transcription of a structural gene transcribed by the GAPDH promoter/ regulation region is an important factor in optimizing gene expression. It is to be expected that substitution of the "Able-terminator" by the GAPDH termination polyadenylation region (Fig. 3) will give at least a similar improvement in the expression.

Legends to the figures

Fig. 1 Restriction endonuclease cleavage map of a region of plasmid pFl 1-33 containing a yeast glyceraldehyde-3-phosphate dehydrogenase operon.

Fig. 2 Nucleotide sequence of the promoter/regulation region of the glyceraldehyde-3-phosphate dehydrogenase operon cloned in pFl 1-33. TATA and TATAAA sequences are indicated by solid underlining. Presumptive transcription termination signals are underlined with dots. Nucleotide sequences between brackets indicate inverted repeats. The nucleotide sequence encoding the 38 amino acids long peptide is enclosed in a box.

Fig. 3 Nucleotide sequence of the transcripton termination/ polyadenylation region of the glyceraldehyde-3-phosphate dehydrogenase operon cloned in pFl 1-33. AATAA. sequences are indicated by solid underlining. Presumptive transcription termination signals are underlined with dots.

Fig. 4 Schematic representation of the insertion of the Eco RI (Dde I) GAPDH promoter/regulation fragment in the preprothaumatin encoding plasmid and removal of an Eco RI cleavage site from the resulting plasmid.

Fig. 5 Representation of the various steps involved in the preparation of the synthetic DNA fragment used to reconstitute the original GAPDH promoter/regulation region upstream of preprothaumatin encoding nucleotide sequences.

Fig. 6 Schematic representation of the introduction of the synthetic DNA fragment in preprothaumatin encoding plasmids. Fig. 7 Schematic representation of the structure of the GAPDH promoter/regulation region including potential stem and loop structures. Presumptive transcription termination signals are indicated by slashes. The position of the coding sequence for the 38 amino acids long peptide on the fragment is shown by ATG and TAA codons.

Fig. 8 Schematic representation of plasmid pMP8i.

Fig. 9 Schematic representation of the introduction of the 2 micron DNA origin of replication and the leu 2 gene obtained from pMP81 by digestion with Hind III an Sal I into preprothaumatin encoding piasmids.

Fig. 10 Schematic representation of the introduction of the KARS-2 and trp 1 gene obtained from pEK 2-7 by digestion with Bgl II into prepro-thaumatin encoding plasmids. .

Fig. 11 Fluorogram of (³⁵S) labelled thaumatin-like proteins synthesized by K. lactis SD11 cells containing plasmid pEK 2-7 (lane a), plasmid pURK 528-03 (lane b) and plasmid pURK 528-33 (lane c) Yeast transformants were grown for 3 hours on a minimal medium containing ³⁵S-cysteine. Cells were collected by centrifugation, resuspended in 1 ml 2.0 mol/l sorbitol, 0.025 mol/l NaPO₄ pH 7.5, 1 mmol/l EDTA, 1 mmol/l MgCL₂, 2.5% β-mercaptoethanol, 1 mg/ml zymolyase 60.000 and incubated for 30 minutes at 30°C. Spheroplasts were then centrifuged and lysed by the addition of 270 μl H₂O, 4 μl 100 mmol/l PMSF, 8μl 250 mmol/l EDTA, 40 μl 9% NaCl and 80 μl 5x PBSTDS (50 mmol/l NaPO₄ pH 7.2, 5% Triton X 100, 2.5% deoxycholate, 2,5 % SDS). Immunoprecipitation of thaumatin-like proteins and analysis of precipitated proteins was carried out as described by L. Edens et al, Gene 18, 1-12 (1982).

Claims

1. Yeast of the genus Kluyveromyces containing a recombinant DNA plasmid comprising (i) a structural gene encoding for preprothaumatin or its various allelic or modified forms or their maturation forms,

(ii) an autonomously replicating sequence originating from Kluyveromyces lactis (so-called KARS), and (iii) a yeast regulon derived from the glyceralde - hyde-3-phosρhate dehydrogenase (GAPDH) genes of Saccharomyces cerevisiae, and optionally

(iv) a selection marker, such as the trp-1 or the lac-4 gene, and optionally

(v) a transcription terminator derived from a yeast,

(vi) a centromer derived from a yeast, and (vii) a replication region derived from a yeast.

2. Yeast according to Claim 1, characterized in that it is a Kluyveromyces lactis yeast.

3. Yeast according to Claim 1, characterized in that the structural gene is selected from the group consisting of structural genes disclosed in European patent applications (A2) 0 054 330 and 0 054 331.

4. Yeast according to Claim 1, characterized in that the KARS-sequence originates from the wild strain K. lactis CBS 2360.

5. Yeast according to Claim 1, characterized in that the transcription terminator is selected from the group consisting of a termination sequence originating from the Hind III-Eco RI fragment of the 2 micron DNA vector of S. cerevisiae and a termination sequence

6. A process for preparing a yeast as claimed in any one of Claims 1-5, characterized in that a recombinant DNA plasmid is prepared by combining a structural gene as mentioned in Claim 1 with a KARS-sequence and upstream of the structural gene with a yeast GAPDH regulon and with a selection marker, and optionally with a centromer derived from a yeast and optionally with a replication region derived from a yeast and optionally downstream of the structural gene with a transcription terminator derived from a yeast, whereafter the plasmid so prepared is introduced into a yeast of the Kluyveromyces genus.

7. A process for the microbiological preparation of preprothaumatin or its various allelic or modified forms or their maturation forms disclosed in European patent applications (A2) 0 054 330 and 0 054 331, characterized in that a yeast of the Kluyveromyces genus as claimed in any one of Claims 1 -5 is cultivated, after which the thaumatin or thaumatin-like protein produced by the yeast is harvested.

8. Preprothaumatin or its various allelic or modified forms or their maturation forms, preferably as disclosed in European patent applications (A2) 0 054 330 and 0 054 331, prepared according to a process as claimed in Claim 7.