Tài liệu Báo cáo khoa học: Crystal structure of thiamindiphosphate-dependent indolepyruvate decarboxylase from Enterobacter cloacae, an enzyme involved in the biosynthesis of the plant hormone indole-3-acetic acid doc

The substrate binding site in indolepyruvate decarboxylase contains a large hydrophobic pocket which can accommo-date the bulky indole moiety of the substrate.. Fax: +46 8327626, Tel.: +

Crystal structure of thiamindiphosphate-dependent indolepyruvate

in the biosynthesis of the plant hormone indole-3-acetic acid

Anja Schu¨tz1, Tatyana Sandalova2, Stefano Ricagno2, Gerhard Hu¨bner1, Stephan Ko¨nig1

and Gunter Schneider2

1

Institute of Biochemistry, Department of Biochemistry and Biotechnology, Martin-Luther-University Halle-Wittenberg,

Germany;2Division of Molecular Structural Biology, Department of Medical Biochemistry and Biophysics,

Karolinska Institutet, Stockholm, Sweden

The thiamin diphosphate-dependent enzyme indolepyruvate

decarboxylase catalyses the formation of indoleacetaldehyde

from indolepyruvate, one step in the indolepyruvate

path-way of biosynthesis of the plant hormone indole-3-acetic

acid The crystal structure of this enzyme from Enterobacter

cloacaehas been determined at 2.65 A˚ resolution and refined

to a crystallographic R-factor of 20.5% (Rfree23.6%) The

subunit of indolepyruvate decarboxylase contains three

domains of open a/b topology, which are similar in structure

to that of pyruvate decarboxylase The tetramer has pseudo

222 symmetry and can be described as a dimer of dimers

It resembles the tetramer of pyruvate decarboxylase from

Zymomonas mobilis, but with a relative difference of 20
in

the angle between the two dimers Active site residues are

highly conserved in indolepyruvate/pyruvate decarboxylase,

suggesting that the interactions with the cofactor thiamin diphosphate and the catalytic mechanisms are very similar The substrate binding site in indolepyruvate decarboxylase contains a large hydrophobic pocket which can accommo-date the bulky indole moiety of the substrate In pyruvate decarboxylases this pocket is smaller in size and allows dis-crimination of larger vs smaller substrates In most pyruvate decarboxylases, restriction of cavity size is due to replace-ment of residues at three positions by large, hydrophobic amino acids such as tyrosine or tryptophan

Keywords: crystal structure; protein crystallography; pyru-vate decarboxylase; substrate specificity; thiamin diphos-phate

Plant hormones play central roles in the regulation of plant

growth and development The first plant hormone to be

described was indole-3-acetic acid (IAA), which is

synthe-sized by plants [1,2] and plant-associated bacteria [3,4]

Several pathways for the synthesis of IAA in these

organisms have been described, and most of them start

fromL-tryptophan as precursor One of the

tryptophan-dependent biosynthetic routes to IAA is the indolepyruvic

acid (IPA) pathway This pathway starts from L

-trypto-phan, and consists of three steps: (a) the conversion of

tryptophan to indole-3-pyruvic acid; (b) the formation of indole-3-acetaldehyde; and (c) the production of IAA (Fig 1) The first step of the pathway is catalysed by

L-tryptophan aminotransferase, a pyridoxal-5-phosphate-dependent enzyme [5] The intermediate, IPA, is decarboxy-lated by the action of indolepyruvate decarboxylase (IPDC) [6] and the resulting indole-3-acetaldehyde is oxidized by

an aldehyde oxidase to IAA [7]

Genes encoding IPDC from several microorganisms have been cloned and characterized These organisms include Enterobacter cloacae [8], Pantoea agglomerans [9], Klebsiella aerogenes[10], Azospirillum brasilense [11,12] and Azospirillum lipoferum [13] The IPDC genes code for polypeptides of about 550 amino acids in length, corres-ponding to a molecular mass of
60 kDa per subunit The enzyme from E cloacae, which has been characterized biochemically to some extent, has a molecular mass of

240 kDa, suggesting a tetrameric structure in solution [6] The enzyme is dependent on Mg2+and thiamin diphos-phate as cofactors and has a high affinity for the substrate, indolepyruvate (KM¼ 20 lM;

sequences of IPDC show homology to pyruvate decarb-oxylases (PDC) with, for instance, 40% identity between IPDC from E cloacae and PDC from Klyveromyces lactis, 38% identity to PDC from Saccharomyces cerevisiae (ScPDC) and 32% identity to PDC from Zymomonas mobilis(ZmPDC) [8]

Correspondence to G Schneider, Department of Medical Biochemistry

and Biophysics, Tomtebodava¨gen 6, Karolinska Institutet,

S-171 77 Stockholm, Sweden.

Fax: +46 8327626, Tel.: +46 87287675,

E-mail: gunter@alfa.mbb.ki.se

Abbreviations: IPDC, indolepyruvate decarboxylase; PDC, pyruvate

decarboxylase; EcIPDC, indole-pyruvate decarboxylase from

Ente-robacter cloacae; ZmPDC, PDC from Zymomonas mobilis; ScPDC,

PDC from Saccharomyces cerevisiae; IA A , indole-3-acetic acid;

IPA, indolepyruvic acid; ThDP, thiamin diphosphate.

Note: To facilitate comparison, we are using the nomenclature defined

by Muller et al (1993) [48] to identify the various domains

in ThDP-dependent enzymes.

(Received 19 January 2003, revised 28 March 2003,

accepted 2 April 2003)

This study reports the three-dimensional structure of

IPDC from E cloacae, determined to 2.65 A˚ resolution by

protein crystallography The fold of the subunit is similar to

that of ScPDC [14] and ZmPDC [15] However, the packing

of the two dimers in the tetramer is different from that of the

PDCs of known structure, best described as a 20
rotation

of one dimer towards the other when compared to the

Z mobilis enzyme The active site shows a substantially

larger substrate binding pocket in IPDC in order to

accommodate the bulky indole moiety of the substrate

Materials and methods

Protein production and purification

The Escherichia coli strain JM109 harbouring the plasmid

pIP362 (kindly provided by J Koga, Meiji Seika Kaisha

Ltd, Japan) was used for expression The plasmid contains

the IPDC gene from E cloacae inserted into the high

production vector pUC19 A6-L culture of Escherichia coli

strain JM109 was grown in a medium containing 2% (w/v)

bactotryptone, 1% (w/v) yeast extract, 0.5% (w/v) sodium

were suspended in 40 mL 0.1M potassium phosphate

pH 6.5, containing 10 mM thiamin diphosphate (ThDP),

10 mM magnesium sulphate, 1 mM EDTA, 5 mM dithio-threitol

2 , and disrupted in a French Press at 1200 bar (Gaulin, APV Homogeniser GmbH, Lu¨beck, Germany) The mixture was centrifuged at 70 000 g for 10 min and the pellet was discarded Nucleic acids were precipitated by incubation with 0.1% (w/v) streptomycin sulphate for

45 min at 8
C A15–30% (w/v) ammonium sulphate fractionation was performed at a protein concentration of

20 mgÆmL)1 After centrifugation at 30 000 g for 5 min, the precipitate was dissolved in 10 mL 50 mM Mes/NaOH

pH 6.5, containing 10 mM magnesium sulphate, 0.15M ammonium sulphate and 1 mMdithiothreitol The solution was applied to a Sephacryl S200 H column (5· 95 cm; Amersham Biosciences) and eluted with the same buffer at

1 mLÆmin)1 The IPDC-containing fractions were pooled and concentrated by precipitation with ammonium sulphate (0.5 mgÆmL)1) After centrifugation the precipitate was dissolved in 20 mMMes/NaOH pH 6.5, 1 mM dithiothrei-tol and this solution was desalted on a Hiprep column (2.6· 10 cm; Amersham Biosciences) and applied to a Source 15Q column (2.6· 7 cm; Amersham Biosciences) Elution was performed using a linear gradient of 120 mL 0–25% of 20 mMMes/NaOH pH 6.5, 1 mMdithiothreitol, 0.25Mammonium sulphate The fractions with the highest catalytic activity and homogeneity were pooled, and after addition of 0.2M ammonium sulphate quickly frozen in liquid nitrogen, and stored at)80
C

Crystallization The purified enzyme was concentrated to
4 mgÆmL)1 Simultaneously, the buffer was changed to 20 mM Mes/ NaOH pH 6.5 and 1 mMdithiothreitol IPDC was crystal-lized by the hanging drop vapour diffusion method Crystals were grown at 20
C using poly(ethylene glycol) 2000 monomethylether as precipitating agent Drops contained equal volumes (2 lL) of reservoir solution [0.1Msodium citrate pH 5.0, 8–12% (w/v) poly(ethylene glycol)] and IPDC (4 mgÆmL)1 in 20 mM Mes/NaOH pH 6.5, 1 mM dithiothreitol, 5 mM ThDP, 5 mM magnesium sulphate) Before setting the drops, IPDC was incubated with the cofactors at room temperature for 30 min The best crystals were obtained at 9–10% (w/v) poly(ethylene glycol) Within 3–4 days bundles of needles appeared Streak seeding was then used to improve the crystal size After transfer of seeds

to fresh drops, single crystals appeared within 1 day and grew to a maximum size of 0.6· 0.4 · 0.2 mm in 3 days Data collection

X-ray data were collected at cryo-conditions with a ADSC Quantum-4 CCD detector on beam line ID29 (ESRF, Grenoble, France) The crystals were soaked in crystallization buffer supplemented with 20% glycerol

Fig 1 The indole-3-pyruvic acid pathway for the biosynthesis of

the plant hormone indole-3-acetic acid in Enterobacter cloacae 1,

L -tryptophan aminotransferase, 2, indolepyruvate decarboxylase, 3,

indoleacetaldehyde oxidase.

before flash freezing directly in the nitrogen stream The

diffraction data was collected at wavelength 0.979 A˚ and

processed withMOSFLM

[17] was used for scaling and reduction of the data The

space group and cell dimensions were determined using the

auto-indexing option of MOSFLM and by the analysis of

pseudo-precession images [18]

Structure determination

The structure was solved by molecular replacement using the

program packageAMORE[19] The self-rotation function and

the estimated solvent content [20] indicate that the

asym-metric unit contains four subunits, arranged as a tetramer

The structure of a dimer of ZmPDC was used as a search

model, as calculation of low resolution models of E cloacae

PDC (EcPDC) from small angle X-ray solution scattering

data [21] had indicated that the quaternary structure of

IPDC is more similar to that of ZmPDC than ScPDC A

poly serine model of ZmPDC without cofactors and solvent

atoms was used as search model The best solution had a

correlation coefficient of 0.235 after rigid body refinement

This solution was fixed, and the search for the second dimer

gave a solution with a correlation coefficient of 0.32 and an

R-factor of 50.1% after rigid body refinement

Model building and crystallographic refinement

Refinement of the model was performed withCNS

monitor progress 5% of each data set was set aside for

calculation of Rfree[23] Initial improvement of the model

was achieved by rigid body refinement, first with the

dimers, and subsequently with the subunits as independent

rigid bodies As the asymmetric unit contains one

tetramer, tight noncrystallographic symmetry restraints

(Wa¼ 300 kcalÆmol)1ÆA˚)2)

crystal-lographically independent monomers throughout the

refinement procedure Bulk solvent correction was used

with default CNS parameters Manual rebuilding of the

model was performed using the program O [24] based on

sigma-weighted 2Fo) Fc and Fo) Fc electron density

maps The parts of the polypeptide chain which differ

most from the search model due to insertions/deletions in

the amino acid sequence were modelled based on omit

electron density maps [22]

The coenzyme ThDP was excluded from the search model and the correctness of the solution was confirmed by electron density for ThDP and Mg2+ appearing at the expected positions (Fig 2) The model was further refined

by simulated annealing and isotropic B-factor refinement Water molecules were modelled using the automatic water picking option in CNS All water molecules were checked for hydrogen bonds with protein atoms The final R-values and other refinement statistics are given in Table 1 The X-ray data and the atomic coordinates have been deposited

at the Protein Data Bank, accession number 1ovm Structure analysis

Structure comparisons were carried out using the pro-grams TOP [25] and O [24] using default parameters Sequence alignments were performed with MULTALIN

Fig 2 Stereoview of the ThDP binding site in IPDC The initial, unrefined 2Fo-Fc map, showing the electron density for the bound magnesium ion and ThDP is contoured at

1 r The refined protein model is superposed The magnesium ion is shown by a green sphere and red spheres represent bound solvent molecules.

Table 1 Data collection and refinement statistics.

Space group P2 1 2 1 2 Cell dimensions (A˚) 132.2, 151.6, 107.6 Resolution (A˚) 2.65

Completeness (%) 99.9 (99.9) a

Total number of reflections 315 465 Unique reflections 63 426

R sym (%) 8.7 (36.9)

Number of protein atoms 16404 Number of solvent molecules 347 Root mean square bond lengths 0.007 Root mean square bond angles 1.388 B-factors (A˚2)

Ramachandran plot Percentage of nonglycine residues in:

Favourable regions 87.9 Additionally allowed regions 12.1

a Numbers in parentheses are for the highest resolution shell.

Purification of IPDC

The procedure comprises four steps: streptomycin sulphate

treatment, ammonium sulphate precipitation, gel filtration,

and anion exchange chromatography The resulting enzyme

is the homogenous apo enzyme, free of cofactors A

molecular mass of 60 000 Da per subunit resulted from

SDS/PAGE, which corresponded to the value calculated

from the nucleotide sequence of the structural gene The

identity of the purified enzyme was confirmed by N-terminal

amino acid sequence analysis

(Met-Arg-Thr-Pro-Tyr-Cys-Val-Ala)

Structure determination

The crystals of holo-IPDC belong to the space group P21212

with unit cell dimensions a¼ 132.2 A˚, b ¼ 151.6 A˚, c ¼

107.6 A˚ and one tetramer in the asymmetric unit,

corres-ponding to a solvent content of 45% The structure of IPDC

was solved by molecular replacement using a dimer of

ZmPDC as an initial search model and refined to final Rfree/

R-values of 23.6%/20.5% The stereochemistry of the

model is as expected for this resolution (Table 1) In

general, the electron density for the polypeptide chain is well

defined However, there is no continuous electron density

for the long loop connecting the middle and the C-terminal

domains (residues 342–355) and these residues were not

included in the model (Fig 4,

the model during refinement showed that almost all residues

obey noncrystallographic symmetry, except the C termini

and the side chains of residues His227, Asp278, Arg367,

Ile379, and Arg394 After superposition of the subunits the

rmsd between all corresponding Caatoms is 0.13 A˚ for two

monomers in the dimer, and 0.17 A˚ for two dimers The

final model includes residues 3–341, and 356–551 of the

protein, four magnesium ions, four molecules of ThDP and

citrate, and 347 water molecules The crystallographic

refinement statistics are presented in Table 1

Overall structure of IPDC

IPDC is a homo-tetramer with overall dimensions of

92· 94 · 116 A˚ Each monomer consists of three domains

with an open a/b class topology: the N-terminal PYR1

domain (residues 3–180), which binds the pyrimidine part of

ThDP; the middle domain (residues 181–340); and the

C-terminal PP domain (residues 356–551), which binds the

diphosphate moiety of the cofactor (Fig 3) The PYR and

PP domains contain a six-stranded parallel b-sheet flanked

by a number of helices, whereas the middle domain contains

a six-stranded mixed b-sheet (four strands are parallel, two

antiparallel), with several helices packing against the sheet

The secondary structure elements of IPDC are shown in

Fig 4, together with the aligned amino acid sequences of

IPDC and ZmPDC The topology of the IPDC monomer is similar to that of ScPDC and ZmPDC with some variations

in the length and orientation of helices The superposition of the IPDC monomer on the subunit of ScPDC and ZmPDC results in rmsd of 1.24 A˚ for 470 out of 563 Ca atoms and 1.48 A˚ for 496 out of 568 Ca atoms, respectively All insertion/deletions are short, they occur in the loop regions and do not effect the overall structure The loop connecting the middle and PP domain is five residues longer in ZmPDC and most residues of this loop are invisible in the structure

of IPDC None of the insertions/deletions occur near the active site, however, some of them are at the dimerization/ tetramerization interfaces (Fig 4)

Two monomers interact tightly to form the dimer The accessible surface area buried in the monomor–monomer interface is 3590 A˚2 (17% of the whole accessible surface area) The interface is mostly nonpolar (65% of residues), but it also contains 26 hydrogen bonds and two salt bridges All three domains of the monomer participate in the dimer interactions (Fig 4, residues marked d), with most residues

at the interface coming from the PYR and PP domains This

is in agreement with the average mobility of the domains in the crystal; the PYR domain has the lowest average B-factor,

23 A˚2 (comparable to the B-factor of bound ThDP), whereas the middle domain has the highest overall B-factor,

37 A˚2 One-hundred and two residues make up the mono-mer–monomer interface; 57 of these residues are conserved between IPDC and ZmPDC, and 15 residues are invariant in all IPDC/PDC sequences (Fig 4)

The IPDC dimer interface is with 3414 A˚2comparable to that of pyruvamide-activated ScPDC [29] In ZmPDC, the interaction area is larger (4387 A˚2), whereas it is smaller in

Fig 3 Fold of the subunit of IPDC from Enterobacter cloacae The PYR domain is shown in blue, the middle domain in green and the PP domain in red The secondary structure elements are labelled as defined

in Fig 4 The cofactor ThDP and the magnesium ion are included as ball-and-stick models The broken line indicates the disordered loop comprising residues 342–355.

nonactivated ScPDC (2892 A˚2) [14] The number of

hydrogen bonds is also far fewer than in ZmPDC (26 vs

66) In part, this is due to the shorter C-terminal region

in IPDC, because the last five residues of ZmPDC are

responsible for a dimer interface area of 400 A˚2 Another

difference of about 400 A˚2 in the dimer interface can be

accounted for by a deletion of five residues in the IPDC

amino acid sequence after helix a21 (Fig 4) In ZmPDC, residues 496–504, which are inserted at this position, participate in the monomer–monomer interface In addition

to these two deletions in the IPDC sequence, there are several amino acid substitutions resulting in a reduced number of hydrogen bonds in the IPDC dimer interface, for instance Ser74fi Gly, Asn102 fi Gly, Asn104 fi Ala,

Fig 4 Structural alignment of EcIPDC and ZmPDC sequences Sequences were denoted as IPDC if biochemical and/or genetic data support such

an activity of the enzyme Residues conserved in six known/putative IPDCs (Enterobacter cloacae, Pseudomonas putida, Pantoea agglomerans, Azospirillum brasiliense, Azospirillum lipoferum and Klebsiella aerogenes) are shown in red in the EcIPDC sequence (DCIP_ENTCL) Residues conserved in 12 PDC sequences (DCP1_MAIZE, DCP1_ORYSA, DCP1_PEA, DCP2_TOBAC, DCP2_ORYSA, DCPY_ZYMMO, DCP1_YEAST, DCP2_YEAST, DCP3_YEAST, DCPY_KLULA, DCPY_KLUMA, DCPY_HANUV) are also shown in red in the ZmPDC sequence (DCPY_ZYMMO) Conservative amino acid replacements are shown in blue Residues common to ZmPDC and IPDC are shown in bold a-Helices are displayed as rectangles, b-strands as arrows d indicates residues in the dimer interface and t residues in tetramer interface Residues lining the active site cavity are underlined Residues binding ThDP are highlighted with a blue background, and those involved in substrate binding by yellow Amino acids of EcIPDC invisible in the electron density map are shown in lowercase.

Gln411fi Leu, Lys485 fi Ala, Asn486 fi Leu (first

resi-due is that of ZmPDC) (Fig 4)

Two dimers form a tetramer (Fig 5), as seen in many

other ThDP-dependent enzymes However, the dimer–

dimer interface is smaller than the monomer–monomer

interface within the dimer Only 2030 A˚2 (9.5%) of the

dimer accessible surface area is buried in IPDC upon

tetramer formation That corresponds to 44 interacting

residues, which are marked by t in Fig 4 Ten of them are

conserved between IPDC and ZmPDC, but none are

invariant in the whole IPDC/PDC family The majority of

residues contributing to these interfaces is located in

the PYR and middle domains The interface contains 10

hydrogen bonds in IPDC The dimer–dimer interface

in IPDC is smaller than the corresponding interface in

ZmPDC (4400 A˚2) It is significantly larger than in

non-activated ScPDC (1344 A˚2), and comparable to

pyruv-amide-activated ScPDC (1920 A˚2) [15]

The tetramer of IPDC differs significantly from other

tetrameric ThDP in the packing of the dimers within the

tetramer The pseudo 222 symmetry is preserved, and

the molecule can be best described as a dimer of dimers

The closest relative is ZmPDC, where the second dimer is

rotated by about 20
when tetramers of IPDC and ZmPDC are compared (Fig 5) It is noteworthy that the relative orientation of the dimers in the tetramer is different in all of the tetrameric PDCs of known three-dimensional structure Binding of the cofactors ThDP and Mg2+

The homo-tetrameric IPDC binds four molecules of the cofactors ThDP and Mg2+ The ThDP binding sites are located in narrow clefts at the interfaces formed by the PYR domains from one subunit and the PP domains of the other subunit within the dimer ThDP adopts the V-conformation [30,31] and is completely buried in the cofactor binding cleft Several hydrogen bonds that are responsible for binding and proper orientation of the aminopyrimidine ring, are conserved in all ThDP-dependent enzymes One of these, the hydrogen bond between the N1¢ atom of the pyrimidine ring of ThDP and the side chain of an invariant glutamate residue of the neighbouring subunit (Glu52), is essential for catalysis [32–35] The C2 carbon atom of the thiazolium ring points into the active site cavity and is accessible for external ligands The diphosphate moiety of ThDP is bound exclusively to the PP domain of the subunit through

Fig 5 Quaternary structure of IPDC Upper panel: stereo view of the quaternary structure of IPDC from Enterobacter cloacae The four subunits

of the tetramer are shown in different colours The cofactor molecules are included as ball-and-stick models Lower panel: different packing of the dimers in the tetramer of EcIPDC and ZmPDC After superposition of one dimer in the tetramer of EcIPDC and ZmPDC (green), the difference in the orientation of the second dimer (IDPC, blue, ZmPDC, red) in the two enzymes is clearly evident.

10

hydrogen bonds and a bridging magnesium ion The

magnesium ion is octahedrally coordinated to oxygen

atoms from the diphosphate group of ThDP, the side

chains of Asp435 and Asn462, the main chain oxygen atom

of Gly464, and a water molecule All these interactions are

highly conserved among ThDP-dependent enzymes

Substrate binding site and catalytic residues

The active site cavity in IPDC extends from the thiazolium

ring of the cofactor to the surface of the protein The

entrance of the active site cleft is covered by the C-terminal

helix and this part of the polypeptide chain must move in

order to allow entry of the substrate This structural feature

was also found in ZmPDC [15], and it could be shown that

the kinetic properties of ZmPDC variants, truncated at the

C-terminal helix, are consistent with a role of this helix in

closure of the active site [36]

Amodel of the a-carbanion/enamine intermediate of the

substrate indole-3-pyruvate with ThDP in the active site of

IPDC was built based on the three-dimensional structure of

the corresponding intermediate in transketolase [37] and the

model derived for ScPDC [38] (Fig 6) In the immediate

vicinity of the modelled a-carbanion/enamine, there are a

number of invariant amino acids, Asp29, His115, His116,

and Glu468, which are conserved in all PDCs Site-directed

mutagenesis has confirmed the essentiality of these residues

for catalysis in ScPDC [39,40] and ZmPDC [41–43],

8

respectively These studies, together with structural data

from crystallography [14,15,29] and modelling [38] have

provided considerable insights into the role of these residues

in PDC As all amino acids, which were suggested to

participate in catalytic steps of PDC are conserved in IPDC,

the enzymatic mechanism seems to be very similar, if not

identical, in the two enzymes

Asignificant difference in the active site between PDC

and IPDC appears to be Gln383, which is replaced by Thr

in most PDCs (Fig 4) In the structure of holo-IPDC the

side chain of Gln383 points away from the active site cavity

and cannot interact with bound substrate and/or reaction

intermediates However, only side chain movement would

be sufficient to allow interactions of this residue with bound

substrate, suggesting that Gln383 might be involved in

substrate binding and, possibly, specific recognition of

indole-3-pyruvate

Substrate recognition The indole moiety of the modelled intermediate is bound in

a large hydrophobic pocket, lined by residues from three helices, Ala387, Phe388 (helix a16), Val467, Ile471 (helix a20), Leu538, Leu542, and Leu546 (a23), and is completely buried in the protein Three of these residues (Phe388, Val467 and Ile471) are either invariant or have conservative substitutions in all PDC/IPDC sequences (Fig 4) The assignment of this hydrophobic pocket as part of the substrate binding site is further supported by mutational studies of ZmPDC, because residue substitutions at the positions corresponding to 467 and 471 in IPDC influence substrate binding and specificity [43]

The volume of the active site cavity is larger in IPDC (130 A˚3) than in ZmPDC (85 A˚3), where it is partially filled with bulky amino acids, Tyr290, Trp387, and Trp542 (IPDC sequence numbering) These large aromatic side chains effectively restrict the size of the pocket and prevent binding of larger substrates (Fig 6) The structural model is thus consistent with the finding that ZmPDC does not recognize indolepyruvate as a substrate [13a]

sequence comparisons of residues lining this substrate recognition pocket reveal identical residues at these posi-tions also in all plant PDCs Achange in substrate specificity from pyruvate to indolepyruvate thus involves

at least substitution of three residues in the substrate binding pocket In all IPDC sequences, residue 290 is replaced by threonine, position 387 by alanine or leucine, and position

542 by residues which are smaller than tryptophan, resulting

in a larger cavity size Restriction of the cavity size thus seems to be a major cause of discrimination against large substrates in PDCs

Yeast PDCs do not follow this substitution pattern as the basis of discrimination towards large aromatic substrates Consequently, ScPDC is, in contrast with ZmPDC, able to decarboxylate indole-pyruvate (Schu¨tz et al unpublished data) While yeast PDCs show a similar substitution at position 290 (Thrfi Phe) as ZmPDC, there are no replacements at position 387 by amino acids with a large hydrophobic side chain Furthermore, there are significant structural differences between ZmPDC and IPDC on the one hand, and ScPDC on the other hand involving the C-terminal part of the polypeptide chain (Fig 7) In the latter, differences in the conformation of the loop between

Fig 6 Stereo picture of the model of the a-carbanion/enamine intermediate (light grey)

in the active site of EcIPDC The three resi-dues, which restrict the size of the substrate binding cavity in ZmPDC (Tyr290, Trp387 and Trp542), are shown in red.

strands b11 and b12 prevent the C-terminal helix from

approaching the other subunit in the dimer sufficiently to

shield the active site, as it does in ZmPDC and IPDC There

is therefore no residue in ScPDC which is structurally

equivalent to 542 in ZmPDC and IPDC These differences

result in a larger volume of the active site cavity in ScPDC,

allowing accommodation of larger substrates such as

indole-3-pyruvate

Substrate activation

IPDC follows Michaelis–Menten kinetics (Schu¨tz et al

unpublished data) In this regard, the enzyme is similar to

ZmPDC that in contrast with all other PDCs investigated

so far is not subject to substrate activation [44] Several

models to account for substrate activation in ScPDC have

been proposed [45–47], involving Cys221 as the site where

the substrate activation cascade is triggered More recently,

an additional pathway for signal transduction between

active sites in ScPDC has been suggested, based on a

detailed kinetic study [40] An alternative model is based on

the structure of ScPDC with bound activator pyruvamide,

which revealed a disorder–order transition of two active

site loops (residues 104–113 and 290–304), and which

appears to be a key event in the activation process [29]

These conformational transitions are accompanied by

large-scale changes in the relative orientation of the dimers

in the tetramer In the three-dimensional structure of

ZmPDC, the active site loops are well ordered and

observed in a conformation suitable for catalysis to occur

[15] The much tighter packing of the subunits in the

ZmPDC tetramer, leading to more extensive interactions in

the dimer–dimer interface compared to ScPDC most likely

excludes such large-scale conformational changes during

catalysis, and these structural features explain the lack of

substrate activation in ZmPDC In IPDC, the assembly of

the subunits in the tetramer resembles that of ZmPDC

rather than ScPDC As in ZmPDC, the active site loops

are folded in a conformation poised for catalysis even in

the absence of substrate or other activators The structure

of IPDC supports the conclusion that the substrate

activation observed in most PDC species may be linked

to the packing of the subunits in the tetramer Enzyme

species with a rather loose packing such as ScPDC

maintain the possibility of conformational changes during

catalysis, and thus allow for cooperativity, whereas in ZmPDC and IPDC with tighter and more extensive dimer– dimer interfaces large-scale conformational changes would

be energetically too costly and are not used for control of enzyme activity

Acknowledgements

We thank J Koga for providing a plasmid producing Enterobacter cloacae indolepyruvate decarboxylase, and K.-P Ru¨cknagel (Max-Planck-Society, Research Unit Enzymology of protein folding, Halle/ Saale, Germany) for the amino acid sequence analysis We acknow-ledge access to synchrotron radiation at beamline ID29, ESRF, Grenoble A.S acknowledges travel support by the Deutscher Akademischer Austauschdienst (DAAD) This work was supported

by the Science Research Council, Sweden and the Graduiertenkolleg of Sachsen-Anhalt.

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