Linker insertion mutagenesis based on IS21 transposition: isolation of an AMP-insensitive variant of catabolic ornithine carbamoyltransferase from Pseudomonas aeruginosa

Thomas Seitz1, Bernard Berger1, Van Thanh Nguyen1,2, Catherine Tricot2, Vincent Villeret2, Sergio Schmid3, Victor Stalon2,4 and Dieter Haas1,5

1 Laboratoire de Biologie Microbienne, Université de Lausanne, CH-1015 Lausanne, Switzerland, 2 Institut de Recherches Microbiologiques Jean-Marie Wiame, B-1070 Brussels, Belgium, 3 Ecole d'Ingénieurs du Valais, CH-1950 Sion, Switzerland and 4 Laboratoire de Microbiologie, Université Libre de Bruxelles, B-1070 Brussels, Belgium


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The bacterial insertion sequence IS21 when repeated in tandem efficiently promotes non-replicative cointegrate formation in Escherichia coli. An IS21–IS21 junction region which had been engineered to contain unique SalI and BglII sites close to the IS21 termini was not affected in the ability to form cointegrates with target plasmids. Based on this finding, a novel procedure of random linker insertion mutagenesis was devised. Suicide plasmids containing the engineered junction region (pME5 and pME6) formed cointegrates with target plasmids in an E.coli host strain expressing the IS21 transposition proteins in trans. Cointegrates were resolved in vitro by restriction with SalI or BglII and ligation; thus, insertions of four or 11 codons, respectively, were created in the target DNA, practically at random. The cloned Pseudomonas aeruginosa arcB gene encoding catabolic ornithine carbamoyltransferase was used as a target. Of 20 different four-codon insertions in arcB, 11 inactivated the enzyme. Among the remaining nine insertion mutants which retained enzyme activity, three enzyme variants had reduced affinity for the substrate ornithine and one had lost recognition of the allosteric activator AMP. The linker insertions obtained illustrate the usefulness of the method in the analysis of structure–function relationships of proteins.

Keywords: catabolic ornithine carbamoyltransferase/IS21/linker insertion mutagenesis/transposition/Pseudomonas aeruginosa


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Insertion of oligopeptides into proteins at various sites provides a convenient means to investigate structure–function relationships. Some insertions made at `permissive' sites may not affect the function of a protein, whereas insertions at other sites may abolish protein function altogether. However, the most interesting insertions may be those that change protein properties by modifying substrate or effector recognition (Shortle and Sondek, 1995Go; Hayes et al., 1997Go; Manoil and Bailey, 1997Go).

Short, in-frame linker insertions can be generated by different mutagenesis methods. In vitro, target genes can be opened at specific sites with restriction endonucleases or at random sites by limited digestion with DNase I. Short oligonucleotides of 2–4 codons are then inserted (Barany, 1985Go; Goff and Prasad, 1991Go; Kegler-Ebo et al., 1994Go). Drawbacks of these methods are that, on the one hand, restriction sites are not distributed randomly and, on the other, DNase I rarely produces flush double-stranded breaks without adjacent deletions (Graf and Schachman, 1996Go), although improvements of the method using DNase I have alleviated the deletion problem to some extent (Dykxhoorn et al., 1997Go). Another type of approach uses transposable elements containing artificially introduced restriction sites close to both ends. After insertion in vivo, the bulk of the transposable element lying between the introduced restriction sites is cut out in vitro and ligation then creates a residual small insertion, which is formed by the ends of the transposable element and the target duplication. This principle has been used with derivatives of Tn3 (Hoekstra et al., 1991Go), Tn5 (Manoil and Bailey, 1997Go; Nelson et al., 1997Go), Tn4430 (Hallet et al., 1997Go; Hayes et al., 1997Go) and Moloney leukemia virus (MoLV) (Singh et al., 1997Go).

Here we describe the development and application of a novel insertion mutagenesis procedure that produces insertions of four or 11 codons with little or no target specificity. The method is based on replicon fusion mediated by the tandemly repeated insertion sequence IS21, in Escherichia coli as the host. Plasmids carrying an IS21 tandem readily form cointegrates with other replicons in a non-replicative reaction that resembles integration of retroviruses (Reimmann and Haas, 1990Go). IS21-dependent cointegrate formation requires two IS21-encoded proteins, cointegrase (the 45 kDa istA gene product) and the IstB accessory protein (Schmid et al., 1998Go). The cointegrates formed in vivo can then be freed of the donor plasmid and the major part of both flanking IS21 elements (engineered to contain unique restriction sites at their ends), by restriction and ligation in vitro. In this way, small in-frame insertions can be generated. We have chosen catabolic ornithine carbamoyltransferase (cOTC) of Pseudomonas aeruginosa as the target of our linker insertion mutagenesis method. This dodecameric enzyme catalyzes the reaction citrulline + Pi -> ornithine + carbamoylphosphate, the second step of the arginine deiminase pathway (Baur et al., 1987Go; Marcq et al., 1991Go; Villeret et al., 1995Go). The deiminase pathway provides the cells with ATP in the absence of respiration (Vander Wauven et al., 1984Go). AMP, a signal of low energy, allosterically activates cOTC (Tricot et al., 1993Go, 1998Go; Sainz et al., 1998Go). A linker insertion has now allowed us to obtain for the first time an AMP-insensitive cOTC. Some preliminary results have been included in a previous review (Haas et al., 1996Go).


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Growth conditions, bacterial strains and plasmids

Media, selective antibiotic concentrations and conditions of incubation have been described before (Jeenes et al., 1986Go; Reimmann and Haas, 1990Go). E.coli strains and plasmids are listed in Table IGo.


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Table I. Bacterial strains and plasmids
 
Assay of cointegrate formation in a three-plasmid system

The detailed procedure has been described by Schmid et al. (1998). Cointegration frequencies are calculated as cointegrates (R751::pME3915, R751::pME3923 or R751::pME3924) transferred per target plasmid (R751) transferred, in conjugation with E.coli HB101 as the recipient.

Recombinant DNA methods and plasmid construction

Standard DNA methods were utilized (Sambrook et al., 1989Go) with some refinements quoted by Schmid et al. (1998). To introduce the istA(P45) and istB genes into the E.coli chromosome, the delivery system described by Diederich et al. (1992) was used, pLDR10 being the vehicle. The lacIQ gene, the tac promoter, the istA(P45) and istB genes and the rrnB terminator were recruited, on a 4.5 kb NruI–ScaI fragment, from pME3913, extended with linkers containing BglII and NotI sites and inserted into the 2.7 kb backbone of pLDR10 cut with BamHI and NotI (partially). The resulting 7.2 kb plasmid was cut partially with EcoRI such that the 2.0 kb EcoRI Sp/Sm fragment (Prentki and Krisch, 1984Go) could be inserted next to the attP site. Thus, pME3920 (Figure 1aGo) was obtained. Its NotI fragments were circularized by ligation and introduced by transformation into E.coli RR28/pLDR8, with selection for streptomycin (20 µg/ml) and spectinomycin (20 µg/ml) resistance. The temperature-sensitive helper plasmid pLDR8 carries the {lambda} int gene (Diederich et al., 1992Go). Of 80 transformants obtained, 70 were Cm-sensitive and presumably had integrated the 7.1 kb NotI fragment (Figure 1aGo) into the chromosome, via int-driven recombination between the attP site on the 7.1 kb NotI fragment and the attB site in the chromosome. The correct integration of the 7.1 kb fragment was verified in four isolates by Southern hybridization, using an IS21 probe (the 2.0 kb SalI–HindIII fragment of pME3913). All four isolates gave the expected pattern (data not shown) and one representative isolate designated ECOLIST was kept.



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Fig. 1. (a) Construction of pME3920. The istA(P45) and istB genes of IS21 are expressed from the tac promoter (Ptac) and controlled by the lacIQ repressor gene. The 7.1 kb NotI fragment was circularized by ligation and integrated into the E.coli chromosome by recombination between the attP site of pME3920 and the chromosomal attB site. {Delta}, deletion; oriV, origin of replication. (b) Construction of pME3659. This is a pBluescript derivative carrying the arcB gene of P.aeruginosa.

 
The arcB gene was subcloned from pME183-7 (Nguyen et al., 1994Go) on a minimal 1.1 kb XhoI–EcoRI fragment into pBluescript KS(+) such that the vector's lac promoter transcribed arcB (Figure 1bGo).

For the construction of pME3923 (Figure 2aGo), a synthetic 123 bp linker was constructed from seven overlapping phosphorylated oligonucleotides. The 123 bp region contains 76 bp of IS21R, a TA spacer and 45 bp of IS21L. This region is identical with the wild-type IS21 sequence, except for four base changes introducing two BglII restriction sites (Figure 2aGo). The assembled linker was inserted into the EcoRV site of pBluescript KS(+), checked by nucleotide sequencing and inserted, as a BamHI–HindIII fragment, into pACYC184 cut with BamHI and HindIII, producing pME3923. The additional three point mutations giving two SalI restriction sites in pME3924 (Figure 2aGo) were introduced on a 31 bp phosphorylated oligonucleotide containing BglII-compatible ends. This oligonucleotide replaced the corresponding fragment in pME3923.




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Fig. 2. (a) Modification of the IS21–IS21 junction region by introduction of restriction sites: effect on non-replicative cointegrate formation in a three-plasmid system. Plasmid pME3915, a pACYC184 derivative containing wild-type IS21 termini, has been described (Schmid et al., 1998Go). Plasmids pME3923 and pME3924 were constructed sequentially by insertion of synthetic oligonucleotides into pACYC184 (Materials and methods). The three IS21–IS21 junction constructs formed cointegrates with R751 in the presence of the helper pME3913; cointegration frequencies are calculated as previously described (Schmid et al., 1998Go). (b) Construction of R6K-derived suicide plasmids containing the modified IS21–IS21 junction region from pME3924. See Materials and methods for details. mob, Site required for conjugal mobilization by IncP plasmids.

 
Plasmid pME5 was constructed by subcloning the 0.14 kb EcoRI–HindIII fragment of pME3924, which carries the IS21–IS21 junction region including SalI and BglII sites (Figure 2aGo), into pJP5603, cut with HindIII (partially) and EcoRI. Plasmid pME6 is based on the 3.0 kb fragment of pGP704, obtained by digestion with HindIII (partial) and PstI. This fragment was combined with a 2.9 kb PstI–HindIII Cm resistance cassette from Tn1725 (Ubben and Schmitt, 1986Go) and the 0.14 kb IS21–IS21 junction region of pME3924 (delimited by EcoRI and HindIII sites). Both pME5 and pME6 (Figure 2bGo) were replicated in E.coli CC118/{lambda}pir and prepared from this strain by Qiagen column purification (Qiagen Inc.).

Linker insertion mutagenesis protocol

E.coli ECOLIST containing pME3659 was grown with shaking in nutrient yeast broth (NYB) containing ampicillin (Ap) (100 µg/ml). An overnight culture was diluted 1:100 in the same medium and isopropyl-ß-D-thiogalactoside (IPTG) was added to a final concentration of 1 mM, to induce the istA(P45) and istB genes. When cells had reached an optical density corresponding to about 4x108 cells/ml, they were harvested by centrifugation and made competent by treatment with 100 mM CaCl2 (Sambrook et al., 1989Go). Competent cells were transformed in 100 µl with about 0.2 µg of pME5 or pME6 DNA. Several transformation experiments were conducted in parallel, to ensure formation of a sufficient number of independent transformants. After incubation on ice for 30 min and a 2 min heat shock (42°C), cells were incubated in NYB for 90 min, concentrated 20-fold and plated on nutrient agar (NA) containing 50 µg/ml kanamycin (Km) (for pME5) or 50 µg/ml chloramphenicol (Cm) (for pME6). This procedure typically resulted in >=20 Km- or Cm-resistant colonies, respectively. From each individual transformation tube one clone was picked and grown in selective NYB. Plasmid mini-preparations (Del Sal et al., 1988Go) were analyzed for the presence of pME3659::pME5 or pME3659::pME6 cointegrates among unreacted pME3659. Digestion with KpnI plus XbaI (enzymes cutting the polylinker flanking the arcB gene, but not cutting the suicide plasmids) was used to map the pME5 or pME6 insertions to the target gene or the vector moiety (Figure 3Go). Cointegrates containing an insertion in the arcB gene were separated from pME3659 by transformation of E.coli RR28 with 100–1000-fold diluted mini-preps. The insertion sites were sequenced by the method of Tsang and Bentley (1988) using two IS21-specific primers: 5'-TGTTGGGTGGAGCGG-3', positions 60–46 at the 5' end of IS21, and 5'-GGGCATGAAAATGGC-3', positions 2087–2101 at the 3' end of IS21 (Reimmann et al., 1989Go). These primers read from the IS21 termini into the target gene.



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Fig. 3. Linker insertion mutagenesis procedure. (A) E.coli ECOLIST containing the target plasmid pME3659 is transformed with pME6, with selection for Cm resistance. After cointegrate formation, plasmid minipreparations are digested with KpnI and XbaI, to map the pME3659::pME6 cointegrates. (B) Uncut mini-preparations of cointegrates containing pME6 in the arcB gene are diluted 100–1000-fold and introduced into E.coli RR28 by transformation, with selection for Cm resistance. (C) Purified cointegrates are cut with SalI or BglII, ligated and introduced into E.coli RR28 by transformation, with selection for Ap resistance. An aliquot of the cointegrate preparation is used for sequencing the IS21arcB borders. Instead of pME6, pME5 can be used, with Km selection. The 12 bp insertions obtained with SalI, which consist of an 8 bp invariant core and a 4 bp target duplication, are shown in Figure 5Go. The 33 bp linker insertion sequence obtained with BglII (bold face) is TGT CGA CGC CAA GAT CTC TGG CGT CGA CAN NNN; the four variable nucleotides forming the target duplication are designated by N.

 
Cointegrates of interest were restricted with SalI, ligated and introduced into E.coli, with Ap selection. Alternatively, BglII was used for resolution of cointegrates. Loss of Km or Cm resistance confirmed that the bulk of the suicide plasmid had been excised. Expression of mutated cOTCs was tested in the OTC-negative argF argI mutant CM236 of E.coli.

Assay of cOTC

The assay conditions have been detailed by Nguyen et al. (1996).


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Some point mutations in the inverted repeats of IS21 do not affect cointegrate formation

The method of IS21-based linker insertion mutagenesis described below relies on the observation that two IS21 termini, joined together by a short junction sequence (typically two nucleotides), are an excellent substrate for the IS21 transposition proteins IstA(P45) and IstB (Schmid et al., 1998Go). The reactive IS21–IS21 junction region is relatively small – 123 bp are sufficient (Figure 2aGo) – and can be genetically modified to contain unique restriction sites which are essential features of the mutagenesis method. However, the newly introduced restriction sites must not obstruct the transposition machinery. Therefore, it was important to measure the formation of cointegrates by an in vivo mating-out assay previously described (Schmid et al., 1998Go). An E.coli host strain was used that contains three plasmids: (i) pME3913, a helper plasmid expressing the istA(P45) cointegrase and istB genes of IS21 but not containing the inverted repeats of IS21; (ii) pME3915, a plasmid containing a wild-type IS21–IS21 junction in which the inverted repeats are connected by a 2 bp (TA) sequence (Figure 2aGo); and (iii) R751, a conjugative plasmid serving as the target for pME3915. Cointegrase and the IstB protein, supplied in trans by pME3913, connect the IS21–IS21 junction to the target. The R751::pME3915 cointegrates thus formed are recovered, after conjugation, in an E.coli recipient strain (Schmid et al., 1998Go). In order to introduce point mutations into the inverted repeats, we reconstructed the IS21–IS21 junction region using synthetic oligonucleotides. In this way, two artificial BglII sites were created flanking the inverted repeats in pME3923 (Figure 2aGo). Additionally, two SalI sites were introduced into the inverted repeats in pME3924 (Figure 2aGo). Although pME3923 and pME3924 contained four and seven point mutations, respectively, in comparison with the original IS21–IS21 junction region in pME3915, the two mutant plasmids formed cointegrates with R751 at the same frequencies (about 5x10–2) as did pME3915 (Figure 2aGo). Thus, the IS21–IS21 junction region of pME3924 could be exploited to develop a system of transpositional linker insertion mutagenesis.

Elements of IS21-based linker insertion mutagenesis

First, the modified IS21–IS21 junction of pME3924 was introduced into two suicide plasmids derived from plasmid R6K, producing pME5 (equipped with a Km resistance) and pME6 (carrying a Cm resistance) (Figure 2bGo). These plasmids replicate in E.coli strains that express the R6K {pi} protein, the product of the pir replication control gene (Miller and Mekalanos, 1988Go). In the absence of pir, pME5 and pME6 fail to replicate, unless they have formed a cointegrate with another replicon. Second, the istA(P45) and istB transposition genes of IS21 were fused to the tac promoter and inserted, together with the lacIQ gene, into the chromosomal {lambda} attachment site attB of E.coli RR28, producing strain ECOLIST (see Materials and methods for details). Thus, expression of the istA(P45) and istB genes could be induced by addition of IPTG. Third, the insertion target, the P.aeruginosa arcB gene encoding cOTC (Baur et al., 1987Go), was cloned into a high-copy-number plasmid (pBluescript) which gave pME3659 (Figure 1bGo). This plasmid was introduced into E.coli ECOLIST by transformation (Figure 3Go). Note that the arcB gene and the vector do not contain any SalI or BglII sites. This fact facilitates the resolution of cointegrates (see below).

Procedure of IS21-based linker insertion mutagenesis

E.coli ECOLIST/pME3659 was grown with IPTG and transformed with pME6; selection was made for the Cm resistance marker of pME6. (Details of the experimental protocol are described in Materials and methods.) Cm-resistant colonies arose at a frequency of 10–6–10–7 per E.coli cell (Figure 3Go, A). An analogous procedure was used with pME5, except that selection was made for Km resistance. Although the suicide plasmids can insert into the chromosome, a majority of the antibiotic-resistant transformants revealed an insertion in the multi-copy plasmid: 38 out of a total of 44 pME5 insertions and 71 out of 75 pME6 insertions were found in pME3659. It may be that the recovery of plasmid cointegrates was favored by the selective antibiotic concentrations used, which were relatively high (50 µg/ml).

The pME3659::pME6 or pME3659::pME5 cointegrates were separated from the co-existing unchanged target plasmid pME3659 by a second transformation step (Figure 3Go, B) and analyzed for the site of insertion. The arcB gene (1.1 kb) was the target for an insertion of pME5 or pME6 in 35% of the cointegrates analyzed, whereas the vector moiety being larger (2.9 kb) carried an insertion in the remaining 65% of the cointegrates. The pME6 inserts in the arcB gene were mapped by sequencing using IS21-specific primers and found to be located throughout arcB (Figure 4aGo). Although some clustering of insertions was observed in arcB, no target sequence specificity could be detected (data not shown). Insertions were flanked by 4 bp target duplications, as expected from previous work (Reimmann et al., 1989Go; Schmid et al., 1998Go), except for two insertions, which were surrounded by 5 and 6 bp direct repeats, respectively.



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Fig. 4. Insertions of pME6 in the arcB gene of pME3659. (a) Sites of insertion in arcB are indicated by flags whose orientation is defined below; numbers refer to arcB nucleotides downstream of the unique XhoI site (Baur et al., 1987Go); {circ}, translation start; •, translation stop of arcB; open flags, 4 bp target duplication; shaded flags, 5 or 6 bp target duplication. The orientation of pME6 insertions is defined below. (b) Translated arcB sequence with {alpha}-helices H1 to H12 and ß-sheets B1–B10 (Villeret et al., 1995Go). Amino acid residues which are conserved in 25 OTCs are indicated by bold face; – in triangle, insertion causing an cOTC-negative phenotype; + in triangle, insertion causing reduced cOTC activity because of low affinity for ornithine; ++ in triangle, insertion not affecting cOTC activity. Tetramer peptides below triangles specify the sequence of the insertions.

 
Twenty pME3659::pME6 cointegrates having a 4 bp target duplication were restricted in vitro with SalI, ligated and established in E.coli RR28 by transformation. This created tetrapeptide insertions in cOTC (Figure 3Go, C). Had BglII been used for resolution, inserts of 11 amino acids would have been formed (Figure 3Go, C).

Three important properties of the IS21-based linker insertion mutagenesis deserve to be pointed out. First, stop codons are not created (Figure 5Go), hence truncated proteins will not arise. Second, owing to the 4 bp direct repeats, no amino acid residue of the target protein is altered or deleted by an insertion. Third, the procedure carried out with SalI restriction can give rise to 205 different tetrapeptide insertions (Figure 5Go). The 8 bp core sequence, which is derived from the IS21 termini and carries the SalI site, is palindromic. Hence the orientation of the suicide plasmid pME6 or pME5 in the cointegrate will not influence the amino acid composition of the insertion. Depending on the reading frame, three different patterns of invariant dipeptides (Cys–Arg, Ser–Thr, Val–Asp) are produced within the tetrapeptide insertions (Figure 5Go). An illustration of this variation is given by the insertions 2S (nucleotide position 802 in the arcB gene) and 6S (nucleotide position 803 in the arcB gene); both insertions follow Ile247 but differ in amino acid composition (Figure 4bGo). When cointegrates are resolved with BglII, the number of different undecapeptides is 2x205 = 410. The reason for this is the non-symmetrical sequence of the 29 bp core element (Figure 3Go), implying that the amino acid sequence of the insertion depends on the orientation of the core element.



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Fig. 5. Possible linker insertions after digestion with SalI. DR, direct repeat, i.e. target duplication; aa, amino acid; * Phe, Ser, Tyr, Cys, Leu, Pro, His, Arg, Ile, Thr, Asn, Val, Ala, Asp or Gly; {dagger} Ile, Met, Thr, Asn, Lys, Ser or Arg.

 
Characterization of mutant cOTCs

The mutant arcB genes on pME3659 were transcribed from the vector's lac promoter and expressed in the OTC-negative E.coli mutant CM236 (argF argI). The recombinant cOTCs, which represented about 5% of the total soluble proteins and could all be detected by Western blotting (data not shown), were assayed for enzymatic activity. The enzymes were tested in the thermodynamically favored reverse reaction (citrulline formation from ornithine and carbamoylphosphate). The allosteric activator AMP has a similar effect on both the forward (citrulline cleavage) and the reverse reaction (Sainz et al., 1998Go). Eleven tetrapeptide insertions in cOTC resulted in loss of activity (Figure 4bGo). In general, these insertions were located either close to amino acid residues which are highly conserved in OTCs (Lys31, Glu88, Asp92, Asn167, Gly180, Arg320) or in a sequence involved in the binding of the substrate carbamoylphosphate (Lys54 to Arg60) (Villeret et al., 1995Go; Valentini et al., 1996Go; Ha et al., 1997Go).

Nine tetrapeptide insertions in cOTC did not abolish enzyme activity. Of these, three lying in helix H9 (designated 2S, 4S and 6S; Figure 4bGo) strongly reduced the affinity for ornithine in that the Km for ornithine was increased 22–65-fold (Table IIGo). One insertion (designated 24S), which was at the end of helix H5 (Figure 4bGo), was of particular interest to this study because the mutant enzyme was insensitive to the allosteric activator AMP at 10 mM. In contrast, the wild-type enzyme showed increased affinity for carbamoylphosphate in the presence of 10 mM AMP (Figure 6Go; Table IIGo). In the absence of effectors, the 24S mutant enzyme had a lower affinity for carbamoylphosphate, in comparison with the wild-type cOTC (Table IIGo). However, the mutant enzyme retained its sensitivity towards the activator Pi, although the Pi concentration required to bring about 50% of maximal activation was increased 4-fold, from 0.5 to 2 mM. These properties suggest that amino acid residues in the vicinity of the insertion site 24S may be involved in AMP recognition.


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Table II. Kinetic parameters of mutant enzymes
 



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Fig. 6. Carbamoylphosphate saturation curves of (a) wild-type cOTC and (b) the AMP-insensitive mutant 24S; v/Vm, relative velocity of reaction; {circ}, no effector added; •, + 10 mM AMP.

 

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The fact that the IS21–IS21 junction region, in a stretch of 35 nucleotides, tolerated seven point mutations without any effect on the frequency of cointegrate formation (Figure 2aGo) was surprising at first. This tolerance allowed us to devise a versatile system of linker insertion mutagenesis, by introducing into the IS21–IS21 junction region two strategically placed restriction sites for each SalI and BglII. Owing to these restriction sites, the bulk of the transposable element can be excised from the cointegrate, leaving behind an insertion of four codons (resolution with SalI) or 11 codons (resolution with BglII). Two conceptually similar systems, which depend on MoLV and Tn4430, respectively, (Singh et al., 1997Go; Hallet et al., 1997Go), give 12- and five-codon insertions, respectively. Insertions of this length have the potential to alter functional activities of a protein such as substrate specificity (Shortle and Sondek, 1995Go; Hayes et al., 1997Go). As we have shown here for cOTC, a four-codon insertion can completely abrogate an effector binding site, without compromising the catalytic activity of the enzyme. Linker insertions generated by the Tn3- and Tn5-mediated systems (Hoekstra et al., 1991Go; Manoil and Bailey, 1997Go) are larger (45 and 31 codons, respectively) and potentially more disruptive.

We have previously shown that the cointegration reaction usually leads to 4 bp direct repeats, with the occasional exception of 5 bp direct repeats (Reimmann et al., 1989Go; Schmid et al., 1998Go). During this study, 30 insertions of pME5 and pME6 in the arcB gene were sequenced, including the 20 pME6 insertions analyzed in detail (Figure 4Go). Twenty-eight insertions were flanked by 4 bp direct repeats. One pME6 insertion had 5 bp direct repeats and one pME6 insertion 6 bp direct repeats, reflecting the fact that IS21, like other IS elements (Galas and Chandler, 1989Go), has some flexibility when interacting with a target sequence. Linker insertions flanked by atypical direct repeats change the reading frame. It is possible to avoid this complication either by filling in or by chewing back the protruding ends of the SalI site. The resulting core elements of 12 or 4 bp, respectively, in combination with direct repeats of 6 or 5 bp, respectively, will give in-frame insertions.

The DNA recognition specificity of the IS21 transposition–cointegration machinery is only partially understood. In the IS21–IS21 junction donor, the terminal nucleotides 5'-CA-3' of IS21 are crucial for cointegrate formation (our unpublished results), whereas the mutational changes producing the SalI and BglII sites (Figure 2aGo) do not affect the activity of cointegrase. This specificity is reminiscent of that displayed by retroviral integrases. These enzymes and IS21 cointegrase promote mechanistically similar reactions (Andrake and Skalka, 1996Go; Haas et al., 1996Go). We have investigated the target specificity of the IS21 cointegrase reaction with a number of targets, including the pBR325 tet gene (Reimmann et al., 1989Go), the P.aeruginosa arcB gene (this study) and several other prokaryotic and eukaryotic genes (our unpublished data). No target sequence specificity has become obvious. However, some clustering of insertions in a few regions and repeated insertions into identical sites have been observed, as illustrated by Figure 4Go. The reasons for this behavior are not clear. Secondary structures in target DNA may play a role (Hallet et al., 1994Go). However, most insertions appear to occur at random sites and hence are suited for linker insertion mutagenesis.

Three linker insertions in helix H9 (Figure 4bGo) strongly reduced the affinity of cOTC for ornithine (Table IIGo). This effect is comparable to that seen for mutant forms of human anabolic OTC causing `late onset' hyperammonemia. In some of these mutants, Arg277 (a conserved residue corresponding to Arg246 in cOTC) is replaced by Trp or Gln (Tuchman et al., 1995Go; Morizono et al., 1997Go). In both cOTC of P.aeruginosa and human OTC an ionic interaction between Arg246 and Asp163 (whose conserved counterpart in human OTC is Asp196) is vital to the function of the ornithine binding domain and mutational disruption of this interaction causes reduced ornithine binding, probably because Asp163 may be involved in binding the {alpha}-amino group of ornithine (Figure 7Go). All three tetrapeptide insertions obtained between Gly244 and Lys248 in cOTC (Figure 4bGo) are expected to disrupt the normal interaction between Arg246 and Asp163 and hence the elevated Km values for ornithine can be understood.



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Fig. 7. Model of the cOTC monomer (Villeret et al., 1995Go). CP, carbamoylphosphate; C-ter and N-ter, C-terminal and N-terminal residues; HH1–HH12, {alpha}-helices; <2S>, <4S>, <6S> and <24S>, sites of four-codon insertions (Figure 4bGo; Table IIGo) whose properties are discussed specifically in the text; D163 and R246, amino acid residues forming an ionic interaction in the ornithine binding domain.

 
The tetrapeptide insertion 24S giving an AMP-insensitive phenotype was mapped to the end of helix H5, near Arg146 (Figure 4bGo). This arginine residue, in concert with Arg32 and Arg28 of the same cOTC monomer, is located at an interface formed by three monomers belonging to different trimers (Villeret et al., 1995Go). The nine arginine residues at this interface appear to constitute a sulfate binding site (Figure 8Go) and they might also interact with negatively charged activators such as inorganic phosphate or AMP (Villeret et al., 1995Go, 1998Go; Tricot et al., 1998Go). Among some 25 OTCs sequenced to date, only the cOTCs of P.aeruginosa and Rhizobium etli have these characteristic nine arginine residues; both enzymes are activated by AMP (Tricot et al., 1993Go; D'Hooghe et al., 1997Go). The crystal structure of the cOTC E105G mutant (Villeret et al., 1995Go, 1998Go) reveals that the loops formed by amino acid residues 150–157 between helix H5 and ß-sheet B6 (Figures 4b and 8GoGo) partially cover the arginine rings, potentially limiting the access of the allosteric activators. Although the structural changes taking place during the allosteric transition are unknown, the trimer–trimer interface area is likely to be involved in modulating the activity of the catalytic trimers. The insertion of the 24S linker Cys–Arg–His–Ser may indeed lower the accessibility to the arginine rings and thereby interfere with AMP binding in either the allosteric T or R state. These data can now serve as a guide to devise experiments defining more precisely the residues involved in AMP binding.



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Fig. 8. Sulfate binding site at the interface between three cOTC monomers. Sulfate (tetrahedral molecule in 3-fold axis) is bound by ionic interactions with Arg32, Arg28 and Arg146. Insertion <24S> may affect these interactions, in particular with Arg146.

 
The AMP-insensitive mutant and the mutants exhibing low ornithine affinity clearly illustrate the potential of the IS21-based linker insertion mutagenesis. Random insertion and variable composition of linkers give rise to a multitude of protein variants. Moreover, it is pertinent to point out that the SalI site in the linker insertions can be exploited to introduce new genetic information, e.g. specifying a protease cleavage site or an epitope.


    Notes
 
5 To whom correspondence should be addressed. E-mail: dieter.haas{at}lbm.unil.ch Back


    Acknowledgments
 
We thank our colleagues who provided plasmids and strains and C.Reimmann and V.Krishnapillai for valuable discussions. This work was supported by the Swiss National Foundation for Scientific Research (project 31-45896.95), the Roche Research Foundation, the Internationale Brachet Stiftung and the Belgian Fund for Joint Basic Research.


    References
 Top
 Abstract
 Introduction
 Materials and methods
 Results
 Discussion
 References
 
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Received August 31, 1999; revised December 20, 1999; accepted January 6, 2000.