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Converting transaldolase into aldolase through swapping of the multifunctional acid-base catalyst COMMON AND DIVERGENT CATALYTIC PRINCIPLES IN F6P ALDOLASE AND TRANSALDOLASE Viktor Sautner, Mascha Miriam Friedrich, Anja Lehwess-Litzmann, and Kai Tittmann Biochemistry, Just Accepted Manuscript • DOI: 10.1021/acs.biochem.5b00283 • Publication Date (Web): 01 Jul 2015 Downloaded from http://pubs.acs.org on July 8, 2015

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Biochemistry

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Converting transaldolase into aldolase through swapping of the multifunctional acid-base catalyst COMMON AND DIVERGENT CATALYTIC PRINCIPLES IN F6P ALDOLASE AND

4

TRANSALDOLASE

1 2

5 Viktor Sautner, Mascha Miriam Friedrich, Anja Lehwess-Litzmann & Kai Tittmann * 6 7 8 9 10 11 12

Göttingen Center for Molecular Biosciences, Department of Molecular Enzymology, Georg-August University Göttingen, Germany, Ernst-Caspari-Haus, Justus-von-Liebig-Weg 11, D-37077 Göttingen, Germany Running title: Origins of reaction specificities in F6P aldolase and transaldolase * Correspondence to: Kai Tittmann,

13 E-mail: [email protected], 14 phone: +49-551-3914430, 15 fax: +49-551-395749 16 17 18 19 20 21 22

Keywords: enzyme mechanism, enzyme catalysis, crystallography, kinetics, carbohydrate metabolism

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ABBREVIATIONS

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TAL, transaldolase; TacTAL, TAL from Thermoplasma acidophilum; EcTAL, TAL from Escherichia

25

coli; HsTAL, TAL from Homo sapiens; FSA, fructose-6-phosphate aldolase; F6P, D-fructose 6-

26

phosphate; G3P; D-glyceraldehyde 3-phosphate; E4P, D-erythrose 4-phosphate; S7P, D-sedoheptulose 7-

27

phosphate; DHA, dihydroxyacetone

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ABSTRACT

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Transaldolase (TAL) and fructose-6-phosphate aldolase (FSA) both belong to the class I aldolase

41

family, and share a high degree of structural similarity and sequence identity. The molecular

42

basis of the different reaction specificities (transferase versus aldolase) has remained enigmatic

43

so far. A notable difference between the active sites is the presence of either a TAL-specific Glu

44

(Gln in FSA) or a FSA-specific Tyr (Phe in TAL). Both residues seem to have analoguous

45

multifunctional catalytic roles but are positioned at different faces of the substrate locale. We

46

have engineered a TAL double variant (Glu-to-Gln and Phe-to-Tyr) with an active site

47

resembling that of FSA. This variant indeed exhibits aldolase activity as main activity with a

48

catalytic efficiency even larger than that of authentic FSA, while TAL activity is greatly

49

impaired. Structural analysis of this variant in complex with the dihydroxyacetone Schiff base

50

formed upon substrate cleavage identifies the introduced Tyr (genuine in FSA) to catalyze

51

protonation of the central carbanion-enamine as a key determinant of the aldolase reaction. Our

52

studies pinpoint that the Glu in TAL and the Tyr in FSA, although located at different positions

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at the active site, similarly act as bona fide acid-base catalysts in numerous catalytic steps

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including substrate binding, dehydration of the carbinolamine and substrate cleavage. We

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propose that the different spatial positions of the multifunctional Glu in TAL and of the

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corresponding multifunctional Tyr in FSA relative to the substrate locale are critically

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controlling reaction specificity through either unfavorable (TAL) or favorable (FSA) geometry

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of proton transfer onto the common carbanion-enamine intermediate. The presence of both

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potential acid-base residues, Glu and Tyr, in the active site of TAL has deleterious effects on

60

substrate binding and cleavage, most likely resulting from a differently organized H-bonding

61

network. Large-scale motions of the protein associated with opening and closing of the active

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site are observed that seem to bear relevance for catalysis as covalent intermediates are

63

exclusively observed in the ‘closed’ conformation of the active site. Pre-steady-state kinetics are

64

used to monitor catalytic processes and structural transitions, and to refine the kinetic framework

65

of TAL catalysis.

66

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Introduction

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Transaldolase (TAL) and fructose-6-phosphate aldolase (FSA) both belong to the class I aldolase

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family, which operate via Schiff base chemistry using an active center lysine to reversibly cleave

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phosphoketose D-fructose-6-phosphate (F6P) in an aldol-type reaction 1-3. Transaldolase shuttles

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a three-carbon dihydroxyacetone unit derived from F6P to aldose acceptor D-erythrose-4-

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phosphate (E4P) affording ketose D-sedoheptulose-7-phosphate (S7P) and aldose D-

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glyceraldehyde-3-phosphate (G3P) (eq 1) 1. FSA reversibly cleaves substrate F6P into G3P and

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dihydroxyacetone (DHA) (eq 2)2. While F6P aldolase activity of FSA could be clearly

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demonstrated in vitro, its physiological function is still unclear.

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TAL:

F6P + E4P ⇔ S7P + G3P

(eq 1)

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FSA:

F6P ⇔ G3P + DHA

(eq 2)

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The catalytic cycles of both enzymes are highly analogous and proceed through a series of

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identical covalent reaction intermediates including the dipolar and neutral carbinolamine, the

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F6P Schiff base, and the carbanion-enamine with multiple critical proton transfers (Scheme 1) 3.

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Key to the different reaction specificities of the two enzymes is the stability of the carbanion-

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enamine intermediate formed upon cleavage of the common F6P Schiff base. While TAL retains

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the covalent C3-lysine carbanion-enamine conjugate bound in stable form for eventual transfer to

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aldose acceptor E4P (aldol addition), this intermediate undergoes facile hydrolysis in FSA

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liberating DHA as product. Aldolytic cleavage requires stereospecific protonation at C3 of the

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carbanion-enamine by a suitably placed acid-base catalyst followed by hydrolysis of the formed

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DHA Schiff base (Scheme 1) 3. The different reaction specificities of the two enzymes is very

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remarkable, because the overall structures as well as the active site architectures are highly

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equivalent (Figure 1). FSA from E. coli has a similar overall structure (doughnut-shaped

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homodecamer of (β/α)8 barrels, Z-score = 30, r.m.s.d. for Cα atoms = 1.5 Å for monomer), and

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shows 31.1 % sequence identity and 60.9 % sequence similarity to TAL from T. acidophilum

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(TacTAL), of which recently several structures were determined at different stages of the

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catalytic cycle

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substrate binding and catalysis are conserved in FSA (e.g.: Asp6, Asn28, Lys86, Arg135and

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Thr110), some active site residues are replaced in FSA by either hydrophobic

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(Ser130TAL→AlaFSA,

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(Glu60TAL→GlnFSA, Phe132TAL→TyrFSA, Arg169TAL→LysFSA). The absence of Glu60 in the

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active site of E. coli FSA (Gln59) along with the presence of Tyr131 (Phe132 in TacTAL) is of

4, 5

. While most of the active site residues of TacTAL with putative roles in

Asn108TAL→LeuFSA,

Ser58TAL→PheFSA)

or

homologous

residues

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particular interest. Glu60 has been suggested to have a key catalytic role in multiple proton

100

transfers in TacTAL including dehydration of the carbinolamine and substrate cleavage at the

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F6P Schiff base state by protonation of the 2-OH of the neutral carbinolamine and subsequent

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deprotonation of 4-OH of the F6P Schiff base (see Scheme 1) 5. This mechanism seems to be

103

conserved in the different TAL subfamilies 6. The X-ray structures with bound substrate Schiff

104

bases indicated that the proton transfers between Glu60 and the intermediates are shuttled

105

through an adjacent catalytic water molecule (Figure 1). The absence of an equivalent Glu

106

residue in the active site of FSA is therefore surprising, since the acid-base chemistry required

107

for the aldol-cleavage of substrate F6P is also part of the reaction pathway of this enzyme. With

108

the exception of the conserved Asp6, only Tyr131 could potentially act as an acid-base catalyst

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in the active site of FSA. Since the structural studies of intermediates in transaldolase were

110

suggesting a role of Asp6 for substrate binding and correct intermediate positioning with no

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direct role in proton transfers (it H-bonds to 3-OH and 5-OH of the substrate), we hypothesized

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that Tyr131 in FSA is a key acid-base catalyst of aldol-cleavage akin to Glu60 in the reaction

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mechanism of TAL 5. Tyr residues are already known to play crucial roles in proton-transfer

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reactions in other class I aldolases, most prominently as in case of mammalian fructose-1,6-

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bisphosphate (FBP) aldolase 7, 8. In e.g. rabbit muscle fructose-1,6-bisphosphate aldolase, the C-

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terminal tyrosine (Tyr363), which is located on a highly flexible segment, acts in concert with

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Lys146 and Glu187 as acid-base catalyst during the hydrolytic cleavage of fructose 1,6-

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bisphosphate into dihydroxyacetone phosphate and G3P 9. The deletion of this Tyr by treatment

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of the protein with carboxypeptidase resulted in a decrease of aldolase activity and in an increase

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of transaldolase activity

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multifunctional role akin to the conserved Glu in transaldolases and FBP aldolases from

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eukaryotes 11, 12. Recent studies demonstrated that an exchange of the aforementioned active site

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Phe in TAL of E. coli and of human origin (Phe132 in TacTAL) by a Tyr greatly stimulated

124

aldolase activity, while at the same time TAL activity was impaired

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TAL activity in these variants was still 30-40-fold higher than aldolase activity. The exact role of

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this Tyr in substrate binding and catalysis of the Phe→Tyr TAL variants and in FSA remained,

127

however, unclear. Modeling of the reaction intermediates trapped in TacTAL into the active site

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of FSA suggested a potential role of the introduced Tyr as acid-base catalyst in multiple proton

129

transfers (dehydration, substrate cleavage, protonation of carbanion-enamine)

130

hypothesis were correct, the absence of an additional acid-base catalyst such as the TAL-specific

131

Glu would likely be catalytically advantageous as two neighboring acid-base catalysts (a Glu and

10

. In archaeal aldolases, Tyr residues were shown to possess a

13

. Nonetheless, residual

3

. If this

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Biochemistry

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a Tyr) might obscure the required order and directionality of the numerous proton transfers due

133

to a differently organized hydrogen-bonding network at the active site.

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Here, we have examined the catalytic role of this Tyr residue in the FSA mechanism while using

135

a transaldolase-derived ‘pseudo-FSA’ enzyme, in which the TAL-specific key catalytic residues

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Glu60 and Phe132 in TacTAL were both changed to Gln60 and Tyr132 in order to restore an

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active site that closely resembles that of FSA. Our study underscores the role of this Tyr as a key

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acid-base catalyst in the FSA reaction using TacTAL as model by measurements of steady-state

139

and transient kinetics, and high-resolution structural analysis of the central DHA Schiff-base

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intermediate for the first time in this enzyme family. Remarkably, introduction of both mutations

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affords an enzyme variant (Glu60Gln/Phe132Tyr) with even higher catalytic efficiency for F6P

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aldolase activity than authentic FSA from E. coli and any TAL Phe-to-Tyr single variant tested

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so far. In broader context, our studies delineate the governing principles of how the relative

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orientation of the multifunctional general acid-base catalyst to the reactive intermediate

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determines the different reaction specificities in aldolases and transaldolases.

146 147

Materials and Methods

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Mutagenesis, expression, purification and crystallization

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Mutant strains producing TacTAL variants Phe132Tyr and Glu60Gln/Phe132Tyr were generated

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by introduction of appropriate mutations using the QuikChange site-directed mutagenesis

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protocol (Stratagene, La Jolla, CA). Expression and purification of TacTAL wt and of both

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variants was carried out as described before

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exhibits greatly increased aldolase activity, was crystallized according to the hanging-drop

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vapor-diffusion method using a reservoir solution of 200 mM ammonium acetate pH 4.4, 10%

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(w/v) PEG 6000 and 25% (v/v) glycerol. In order to obtain crystal structures with reaction

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intermediates bound to the active site, TacTAL double variant Glu60Gln/Phe132Tyr (16 mg/mL

157

in 6 mM Tris-HCl/14 mM glycylglycine pH 7.5) was supplemented with 34 mM F6P prior to

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crystallization; 3 µL of this solution were mixed with 3 µL of reservoir solution at room

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temperature, and equilibrated against 250 µL of reservoir solution.

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TacTAL crystallizes in two different space groups (P21 and C2221)

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sufficiently large single crystals of TacTAL in the desired space group C2221, the crystallization

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solution was micro-seeded with previously obtained TacTAL crystals of this space group, and

5, 14

. Double variant Glu60Gln/Phe132Tyr, which

14

. In order to grow

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incubated at 30 °C for 10 min in a thermostatted incubator. Transaldolase crystals were then

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further grown for 7 – 15 days at 20 °C.

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X-ray data collection, processing and model building

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Diffraction data of a single TacTAL crystal (Glu60Gln/Phe132Tyr variant) were collected using

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synchrotron radiation at ESRF Grenoble (beamline ID23-1, wavelength 0.91 Å), France at

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cryogenic temperatures at 100 K. Diffraction images were indexed, integrated, and scaled using

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the XDS-package 15.

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Model-building and refinement were performed using COOT and the PHENIX.REFINE

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crystallographic package using the previously solved structure of TacTAL wild-type as a starting

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model

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MOLPROBITY-server 19 was used to verify the geometry of the final model, of which 97.93% are

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in the favored region of the Ramachandran plot, 1.99% in the allowed region along with 0.09%

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outliers. The representation of structures was performed with PyMOL (Schrödinger, LLC).

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The structural alignment of monomers of TacTAL and FSA, and the calculation of Z-score and

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r.m.s.d. were performed using the DALILITE-server 20 and T-COFFEE-server 21.

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Database accession number

179

The final refined model and the corresponding structure factor amplitudes have been deposited in

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the Research Collaboratory for Structural Biology (http://www.rcsb.org) under accession

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numbers 4XZ9.

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Steady-State Activity Assay

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The steady-state kinetics for aldolase activity of TacTAL wt and variants (conversion of donor

184

F6P into G3P and DHA) were measured in a coupled spectrophotometric assay using the

185

auxiliary enzymes triosephosphate isomerase (TIM) and sn-glycerol-3-phosphate : NAD+ 2-

186

oxidoreductase (G3PDH) to detect formation of G3P formed by aldolytic cleavage of F6P 22. The

187

concomitant oxidation of NADH was monitored spectrophotometrically in a UV-Vis

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spectrometer (V-650, Jasco GmbH, Gros-Umstadt) at 340 nm at 30 °C. The reaction mixture

189

contained 20 mM glycyl-glycine, pH 7.5, 3 U/mL TIM/G3PDH (8 mM (NH4)2SO4), 0.22 mM

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NADH and varying concentrations of F6P (0.1 - 100 mM). The enzyme concentrations were 1

191

mg/mL (TacTAL wt), 0.17 mg/mL (TacTAL Phe132Tyr) and 0.035 mg/mL (TacTAL

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Glu60Gln/Phe132Tyr), respectively.

16-18

. TLS grouping for each monomer was implemented as recently described 5. The

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Transaldolase activity was analyzed under the same conditions except that acceptor E4P was

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added to the assay in concentrations up to 2 mM.

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In order to determine the macroscopic kinetic constants (kcat, KM), the initial rates were plotted

196

against substrate concentration and analyzed using the Michaelis-Menten equation.

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Pre-steady state kinetics

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The pre-steady state of the donor-half reaction (cleavage of donor F6P) was analyzed by

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stopped-flow kinetics using a coupled spectrophotometric assay as described before. The enzyme

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solution (0.44 mg/mL TacTAL, 200 U/mL TIM/G3PDH, 0.44 mM NADH in 20 mM glycyl-

201

glycine, pH 7.5) and substrate solution (0.1-100 mM F6P in 20 mM glycylglycine, pH 7.5) were

202

rapidly mixed using a stopped-flow spectrometer (SX20, Applied Photophysics, UK) in a 1+1

203

mixing ratio at 30 °C. Progress curves were fitted with appropriate equations consisting of either

204

one or two single exponential terms (pre-steady state phase) and a linear term (steady-state

205

consumption of F6P) (vide infra).

206

The estimated rate constants kobs of the pre-steady-state phase were plotted versus the applied

207

F6P concentration, and data were fitted to either a hyperbolic equation (eq 3) for F6P

208

concentrations up to 12 mM or a hyperbolic equation taking into account substrate access

209

inhibition (eq 4).

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obs =

211


obs =

max obs ∙[F6P] 

S

(eq 3)

[F6P]

max obs 



S  [F6P] 

(eq 4)

[F6P] I

212

where kobsmax denotes the rate constant at infinitely high F6P concentrations, KSapp the

213

equilibrium constant of the fast substrate binding (pre-)equilibrium, and KI the inhibition

214

equilibrium constant of a putative substrate access inhibition.

215 216

Results and Discussion

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Steady-state kinetic analysis of aldolase and transaldolase activity

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TacTAL wt and TacTAL variants Phe132Tyr and Glu60Gln/Phe132Tyr could be recombinantly

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expressed in E. coli and purified to homogeneity. The expression yields of the two variants were 7 ACS Paragon Plus Environment

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not as high as in case of the wt enzyme (~2 mg enzyme/g cell pellet), and amounted to 0.8 mg enzyme/g cell

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pellet

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We first assessed the steady-state kinetic properties of all three proteins for F6P aldolase activity

223

(F6P as sole substrate) and TAL activity (F6P and E4P as substrates) using a spectrophotometric

224

assay that detects liberated product G3P. TacTAL wt exhibits a very small, yet detectable F6P

225

aldolase activity that corresponds to a kcat of ~2.2·10-3 s-1 on a per active site basis (Table 1).

226

However, since very high concentrations of enzyme were required in the assay, true steady-state

227

(multiple turnover) conditions cannot be established at small F6P concentrations precluding a

228

reliable estimation of the KM F6P value. Notably, the aldolase activity of TacTAL wt is three to

229

four orders of magnitude smaller than its genuine TAL activity (kcat ~14 s-1). Single variant

230

Phe132Tyr exhibits a 102-fold stimulated F6P aldolase activity (kcat = 0.24 ± 0.01), and a KM

231

value for F6P (12.3 ± 1.5 mM) that is comparable to that of FSA (Table1, Figure 2). The

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catalytic efficiency kcat/KM of TacTAL Phe132Tyr is approximately 5% of that of FSA. TAL

233

activity of this variant is greatly impaired, addition of acceptor E4P (tested up to 2 mM at

234

different F6P concentrations) to the F6P-containing assay did not lead to a measurable change of

235

the reaction rate suggesting that the TAL activity is smaller than (or equal to) FSA activity. This

236

translates into a reduction of TAL activity by a factor of at least ~60 in this variant. Introduction

237

of the second mutation in the Glu60Gln/Phe132Tyr double variant increases F6P aldolase

238

activity by an additional factor of three (kcat = 0.62 ± 0.01s-1), and at the same time decreased the

239

apparent Michaelis constant of F6P (KM = 1.5 ± 0.1 mM) compared to the Phe132Tyr single

240

variant (Table 1, Figure 2). Addition of acceptor E4P (tested up to 2 mM) to the assay containing

241

F6P resulted in a decrease of the reaction rate by up to 10% showcasing that i) TAL activity is

242

smaller than FSA activity and ii) that bound E4P slightly impairs protonation of the carbanion-

243

enamine and/or hydrolysis of the C3 Schiff base (see Scheme 1). Notably, the catalytic

244

efficiency of F6P aldolytic cleavage for TacTAL double variant Glu60Gln/Phe132Tyr (413 M-1

245

s-1) is the highest ever reported value, it is higher than these of authentic FSA and of Phe→Tyr

246

single variants from E. coli and human TAL (Table 1)

247

variants exhibited markedly elevated FSA activity, their residual TAL activity was still 30-40-

248

fold higher than FSA activity. In case of TacTAL double variant Glu60Gln/Phe132Tyr, FSA

249

activity is clearly higher than the residual TAL activity as indicated by the observed inhibitory

250

effect of E4P on F6P consumption.

for Phe132Tyr or even 0.3 mg enzyme/g cell pellet in case of Glu60Gln/Phe132Tyr.

13

. Although these previously studied

251 252

Pre-steady-state kinetic analysis of F6P conversion

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Biochemistry

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In order to gather more insights into the kinetics of TacTAL-catalyzed F6P cleavage, we

254

conducted stopped-flow experiments, in which TacTAL was mixed with substrate F6P. In a

255

minimal reaction scheme (Scheme 2), aldolytic cleavage of F6P into products G3P and DHA can

256

be subdivided into two half-reactions: i) F6P binding and cleavage (all steps until liberation of

257

G3P), and ii) protonation and hydrolysis of the C3 carbanion-enamine with concomitant release

258

of DHA. Since midway formed product G3P is detected in the spectrophotometric assay, the

259

potential occurrence or absence of a pre-steady-state phase is diagnostic for which of the two

260

half-reactions is rate-determining for overall catalysis akin to the classic kinetic analysis of

261

protease-catalyzed turnover of p-nitrophenyl-ester substrates 23, 24.

262

When TacTAL wt was mixed with substrate F6P in the stopped-flow instrument, an initial pre-

263

steady-state burst phase was observed in the first 100 ms followed by a linear decrease in

264

absorbance in the steady state (Figure 3). This observation indicates that the second half-reaction

265

(protonation of the carbanion-enamine, hydrolysis of DHA Schiff base and DHA release) is rate-

266

determining for the overall reaction, whereas the first half-reaction that is binding and cleavage

267

of F6P proceeds considerably faster. The fitted first-order rate constants kobs of the burst phase

268

display a hyperbolic dependence on the substrate concentration up to 10 mM with a KSapp of 0.49

269

± 0.06 mM, at higher F6P concentrations, however, rate constants are getting smaller. The reason

270

for the slowed substrate binding/cleavage at high F6P concentrations is unclear, this observation

271

could reflect substrate access inhibition or, alternatively, a negative cooperativity between the

272

different monomers (TacTAL forms homopentamers assembling into decamers) as suggested by

273

previous structural studies

274

intermonomer negative cooperativity is the finding that the maximal amplitude of the burst phase

275

corresponds to turnover of only 60% of the active sites indicating that at max only 3 out of 5

276

monomers of the pentamer are acting on F6P. Alternatively, a switch between an induced fit and

277

a conformational selection mechanism at higher F6P concentrations might account for the

278

observed dependence of kobs from the F6P concentration 25. The maximal rate constant kobs of the

279

burst phase amounts to ~50-55 s-1 (at cF6P 5-15 mM), which is greater then the turnover number

280

for the overall TAL reaction (kcat ~14 s-1). This pinpoints that all reaction steps until formation

281

of the carbanion-enamine are not rate-determining for the TAL reaction. This in turn suggests

282

that aldol addition of the carbanion-enamine with acceptor E4P and subsequent liberation of

283

product S7P must be (at least partially) rate-determining for the overall TAL reaction. As

284

expected, off-pathway protonation of the carbanion-enamine and subsequent DHA liberation

285

proceed extremely slow in TacTAL wild-type, and are rate-determining for conversion of F6P

286

into G3P and DHA (k’ = 2.25·10-3 s-1).

5

. In support of this mechanistic proposition invoking an

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In TacTAL single variant Phe132Tyr, no burst phase can be observed in the stopped-flow kinetic

288

analysis of F6P conversion (Figure 3). As it could be established that a burst is not occuring in

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the dead time of the stopped-flow experiment (t ~1.5 ms), this observation indicates that the

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single site Phe132→Tyr substitution in TacTAL greatly impairs one or more step(s) of the first

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half-reaction comprising all steps until formation of the carbanion-enamine and concomitant

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G3P release. Owing to this kinetic behaviour, the first half-reaction that is binding and cleavage

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of F6P has become rate determining in the variant (kobs ≤ 0.24 s-1), and thus proceeds at least

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200-fold slower than in the wild-type enzyme (kobsmax = 55 s-1). This drastic effect implies that

295

the Phe→Tyr single site mutation has a large impact on the active site structure and/or reactivity.

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TacTAL double variant Glu60Gln/Phe132Tyr exhibits a pre-steady-state phase that is similar to

297

that of TacTAL wt as a pre-steady-state burst phase preceding a linear decrease in the steady

298

state can be observed (Figure 3). However, in addition, a lag phase can be monitored in the very

299

first 50 ms of the reaction. Notably, the duration of this lag phase is not dependent on the applied

300

substrate concentration suggesting that this kinetic phase reflects an intrinsic process of the

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enzyme. There is precedent in the literature for substrate-independent lag phases as e.g. in case

302

of glucanase 26. Since the previous structural analysis of TacTAL showed the enzyme to adopt an

303

open (presumably inactive) and closed (presumably active) conformation with an equilibrium

304

position close to unity in the resting state 5, one might speculate that the observed lag phase

305

corresponds to the equilibrium shift between the two states upon substrate binding according to a

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conformational selection mechanism (Scheme 2) 27, 28. The fitted first-order rate constants of the

307

burst phase show a similar dependence on the F6P concentration as described above for the wild-

308

type enzyme with a kobsmax of ~50 s-1 (e.g. at 10 mM F6P kobs = 46.9 ± 1.4 s-1, see Figure 3). The

309

preceding lag phase can be reasonably fitted at F6P concentrations > 5 mM with a single

310

exponential function and amounts to 50-70 s-1 for the individual progress curves (e.g.

311

kobslag = 67.2 ± 3.7 s-1 at 10 mM F6P, see Figure 3). Admittedly, at lower F6P concentrations, kobs

312

of the lag phase cannot be reliably estimated because of the very small amplitude of this phase

313

such that a precise value cannot be determined with this type of experiments. In sum,

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introduction of the second mutation (Glu60→Gln) in the TacTAL double variant

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Glu60Gln/Phe132Tyr restored the active site in a way that F6P binding and cleavage are as

316

efficient as in the wild-type enzyme, whereas the single variant Phe132Tyr with both potential

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acid-base catalysts at the active site (Glu60, Tyr132) is greatly impaired in that regard. The 2nd

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half-reaction of aldolytic F6P cleavage (see Scheme 2) in TacTAL Glu60Gln/Phe132Tyr is rate

319

determining for the overall reaction (kcat = 0.62 s-1, see Table 1) pinpointing that either

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protonation of the carbanion-enamine, hydrolysis of the C3 (DHA) Schiff base and/or product 10 ACS Paragon Plus Environment

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Biochemistry

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release are the slowest steps of catalysis. Interestingly, we can observe kinetic processes (initial

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lag phase) with this variant that are independent of the applied substrate concentration tempting

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us to assign these processes as intrinsic protein dynamics/conformational changes of reversible

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opening⇔closing and substrate binding according to a conformational selection mechanism as

325

previously suggested 5. We did not observe this lag phase in case of the wild-type TAL enzyme

326

suggesting that these processes proceed considerably faster and cannot be resolved by stopped-

327

flow experiments (dead time 1.5 ms). Although F6P is efficiently bound and cleaved in the

328

double variant (kobs ~50 s-1, see Figure 3), TAL activity is greatly impaired as evidenced by the

329

inhibitory effect of E4P onto F6P consumption (kcat