Báo cáo khoa học: Starch-binding domains in the CBM45 family – low-affinity domains from glucan, water dikinase and a-amylase involved in plastidial starch metabolism pptx

This suggests that low-affinity starch-binding domains are a recurring feature in plastidial starch metabo-lism, and supports the hypothesis that reversible binding, effectuated through l

domains from glucan, water dikinase and a-amylase

involved in plastidial starch metabolism

Mikkel A Glaring1,2, Martin J Baumann1, Maher Abou Hachem1, Hiroyuki Nakai1, Natsuko Nakai1, Diana Santelia3, Bent W Sigurskjold4, Samuel C Zeeman3, Andreas Blennow2and Birte Svensson1

1 Enzyme and Protein Chemistry, Department of Systems Biology, Technical University of Denmark, Kongens Lyngby, Denmark

2 VKR Research Centre Pro-Active Plants, Department of Plant Biology and Biotechnology, Faculty of Life Sciences, University of

Copenhagen, Frederiksberg, Denmark

3 Department of Biology, ETH Zu¨rich, Switzerland

4 Department of Biology, University of Copenhagen, Denmark

Introduction

Starch is deposited as water-insoluble granules in the

amyloplasts of tubers, roots and seeds for long-term

storage, and in the chloroplasts of green tissues during

the day as short-term storage for the following night

(transitory starch) The granules are composed of two different polymers of glucose linked via a-(1,4)-glyco-sidic bonds: amylose, which is essentially linear, and amylopectin, which also contains a-(1,6)-glycosidic

Keywords

carbohydrate-binding module; starch

metabolism; starch-binding domain;

a-amylase; a-glucan, water dikinase

Correspondence

B Svensson, Enzyme and Protein

Chemistry, Department of Systems Biology,

Technical University of Denmark, Søltofts

Plads, Building 224, DK-2800 Kongens

Lyngby, Denmark

Fax: +45 45886307

Tel: +45 45252740

E-mail: bis@bio.dtu.dk

(Received 17 November 2010, revised 5

January 2011, accepted 31 January 2011)

doi:10.1111/j.1742-4658.2011.08043.x

Starch-binding domains are noncatalytic carbohydrate-binding modules that mediate binding to granular starch The starch-binding domains from the carbohydrate-binding module family 45 (CBM45, http://www.cazy.org) are found as N-terminal tandem repeats in a small number of enzymes, primarily from photosynthesizing organisms Isolated domains from repre-sentatives of each of the two classes of enzyme carrying CBM45-type domains, the Solanum tuberosum a-glucan, water dikinase and the Arabid-opsis thaliana plastidial a-amylase 3, were expressed as recombinant pro-teins and characterized Differential scanning calorimetry was used to verify the conformational integrity of an isolated CBM45 domain, reveal-ing a surprisreveal-ingly high thermal stability (Tmof 84.8C) The functionality

of CBM45 was demonstrated in planta by yellow⁄ green fluorescent protein fusions and transient expression in tobacco leaves Affinities for starch and soluble cyclodextrin starch mimics were measured by adsorption assays, surface plasmon resonance and isothermal titration calorimetry analyses The data indicate that CBM45 binds with an affinity of about two orders

of magnitude lower than the classical starch-binding domains from extra-cellular microbial amylolytic enzymes This suggests that low-affinity starch-binding domains are a recurring feature in plastidial starch metabo-lism, and supports the hypothesis that reversible binding, effectuated through low-affinity interaction with starch granules, facilitates dynamic regulation of enzyme activities and, hence, of starch metabolism

Abbreviations

AMY3, a-amylase 3; AtAMY3, Arabidopsis thaliana a-amylase 3; CBM, carbohydrate-binding module; DSC, differential scanning calorimetry; GWD, a-glucan, water dikinase; IPTG, isopropyl thio-b- D -galactoside; ITC, isothermal titration calorimetry; PWD, phosphoglucan, water dikinase; SBD, starch-binding domain; SPR, surface plasmon resonance; StGWD, Solanum tuberosum a-glucan, water dikinase;

TEV, tobacco etch virus; YFP⁄ GFP, yellow ⁄ green fluorescent protein.

branch points Together, these polymers are laid down

as alternating semicrystalline and amorphous layers to

form the supramolecular granule structure The

semi-crystalline layers are made up primarily of packed

double helices formed by adjacent glucose chains in

amylopectin The amorphous layers are comprised

mainly of amylopectin branch points and interspersed

amylose [1] This semicrystalline structure offers a

sig-nificant challenge for degrading enzymes and, for the

efficient amylolysis of raw starch, requires either

sur-face substrate-binding sites on the catalytic module [2]

or, more commonly, a specialized

carbohydrate-bind-ing module (CBM) known as a starch-bindcarbohydrate-bind-ing domain

(SBD) [3]

CBMs are noncatalytic structural domains that

mediate the binding of proteins to polysaccharides,

thus bringing the appended catalytic modules into

close contact with the substrate, enabling efficient

hydrolysis of insoluble polysaccharides, such as starch

and cellulose [4] Based on their amino acid sequences,

CBMs are currently grouped into 61 families SBDs

are found in CBM families 20, 21, 25, 26, 34, 41, 45,

48, 53 and 58 (http://www.cazy.org) [5,6] The majority

of characterized SBDs are found in extracellular

microbial amylolytic enzymes, where they enhance

binding to starch and related a-glucans A significant

and so far largely uncharacterized number of SBDs

occur in nonamylolytic enzymes from all domains of

life [3,6] Among these is a recently established small

family of SBDs, named CBM45 [7] CBM45s are

found primarily in photosynthesizing organisms in

only two classes of intracellular enzyme: the a-glucan,

water dikinases (GWDs, EC 2.7.9.4), which

phosphor-ylate starch, and the plastidial a-amylases (AMYs,

EC 3.2.1.1) Two types of CBM45-containing GWD

have been identified in plants, one of which is

plastid-ial and essential for normal starch metabolism

(GWD1⁄ R1 ⁄ SEX1) [8,9] The second GWD, called

GWD2 in Arabidopsis, is extraplastidial and has no

apparent role in starch degradation [10] The plastidial

a-amylase AMY3 is not required for normal transitory

starch metabolism in Arabidopsis [11], but a functional

role in planta has been inferred from knock-out studies

in phosphoglucan phosphatase (SEX4) and quadruple

debranching enzyme (ISA1⁄ ISA2 ⁄ ISA3 ⁄ LDA) mutant

backgrounds [12,13] In both enzyme classes, the

CBM45s are present as N-terminal tandem domains,

separated by a linker domain of varying length No

three-dimensional structure is available for CBM45,

but a recent bioinformatic analysis produced a rough

model and identified two tryptophan residues as

puta-tive binding sites in the N-terminal CBM45 from

Ara-bidopsis GWD1 [14] These two tryptophans have

previously been experimentally confirmed as pivotal for the starch-binding ability of potato GWD [7] The metabolism of plastidial starch in leaves of plants is a tightly regulated process The available pho-tosynthate has to be balanced with the energy and car-bohydrate needs of the plant during the subsequent dark period Perturbations in this process lead to severe phenotypes and retardation of growth [15,16] Plastidial starch metabolism has been well character-ized in the model plant Arabidopsis thaliana, and numerous enzymes are involved in the process of building and degrading the insoluble granule (for recent reviews, see refs [17–19]) Many of these enzymes contain SBDs representing several different CBM families, and starch and⁄ or a-glucan binding has been demonstrated in a number of cases [20–26] Starch binding in the plastidial system is influenced by potential regulatory mechanisms that can reversibly affect the interaction with the granule [24,27] Binding

of potato GWD to starch in planta has been shown to

be diurnally regulated [23] and potentially influenced

by the redox status of the enzyme [23,27] The redox status also influences the binding of the CBM48-con-taining glucan phosphatase SEX4 to starch in vitro [24] Phosphoglucan, water dikinase (PWD⁄ GWD3,

EC 2.7.9.5), a second type of plastidial GWD carrying

an N-terminal CBM20 SBD, shows a relatively low affinity towards the starch mimics, cyclodextrins [20], and it has been proposed that this could facilitate more dynamic interactions with starch, allowing the modulation of affinity necessary for metabolic regula-tion in the plastid [6,20,28]

In this article, we report the characterization of SBDs from representatives of the two classes of enzyme carrying CBM45-type domains, the Sola-num tuberosum a-glucan, water dikinase (StGWD) and the A thaliana plastidial a-amylase 3 (AtAMY3), sug-gesting that the evolution of low-affinity domains is a recurring and functionally important theme in plastid-ial starch metabolism

Results and Discussion

Identification and bioinformatic analysis of CBM45s from GWD and AMY3

Family CBM45 sequences were obtained from the car-bohydrate-active enzymes database (CAZY, http:// www.cazy.org) Furthermore, a search of the translated nucleotide database at the National Center for Bio-technology Information (http://www.ncbi.nlm.nih.gov) uncovered several additional sequences with homology

to StGWD and AtAMY3, which were included in the

analysis Alignment of these sequences showed not

only extensive conservation in the catalytic domains,

suggesting a preservation of function, but also the

exis-tence of the N-terminally appended CBM45 domains

(data not shown) The sequences used in the

subse-quent analysis included CBM45s from 45 proteins

from primarily photosynthetic eukaryotes (plants,

green algae and red algae), as well as from

apicom-plexan parasites (Doc S1) A common characteristic

of these organisms is the presence of starch or

starch-like crystalline polysaccharides The starch synthesis

ability of the apicomplexan parasites is believed to be

derived from an endosymbiosis of a red alga, with

following loss of photosynthetic capacity [29]

The CBM45s are present as tandem domains in the

N-terminal part of StGWD and AtAMY3 and

sepa-rated by a linker of approximately 200 and 50 amino

acids, respectively (Fig 1A) The alignment of all

iden-tified CBM45s revealed that each contains five

aro-matic amino acids that are widely conserved across all

species (Fig S1) These residues are also present in

StGWD and AtAMY3 (Fig 1B) The ability to bind

to starch has been associated with certain consensus

aromatic residues in other CBM families [6] and,

although there is evidence that two of the aromatic

residues (W139 and W194) are necessary for the

starch-binding ability of StGWD [7], the lack of

struc-tural information on CBM45 precludes the assignment

of residues to specific binding sites as has been

per-formed for CBM20 from Arabidopsis PWD⁄ GWD3

(AtPWD) [20]

It was clear from the collected sequences that the

tandem organization of two domains is a common

characteristic of most CBM45-containing enzymes,

suggesting that this is essential for the functionality of

the appended catalytic modules Isoforms of GWD

and AMY3 from the green algae Chlamydomonas reinhardtii (CreGWD) and Micromonas (MiGWDb, MpGWDb and MpAMY3; Doc S1) contained only one identifiable CBM45 domain Whether this repre-sents a simple misannotation or a distinct function of single-CBM45 SBDs is unknown A previous analysis

of a recombinant truncated StGWD lacking CBM45-1 showed an altered specificity on soluble substrates with

a preference for the phosphorylation of shorter glucan chains [7] A phylogenetic tree based on the complete amino acid alignment of all CBM45s showed obvious groupings of the individual domains from plant sequences (Fig S2) Most of the nonplant sequences formed a separate, mixed group, reflecting the evolu-tionary distance and low homology between these sequences Overall, it appears as though CBM45s and the tandem structure of these domains arose early in evolution, perhaps in an ancestor of the current photo-synthetic eukaryotes It has been proposed that GWD sequences were a prerequisite for the appearance of semicrystalline starch-like polymers [29] If this is indeed the case, the appended CBM45 domains could represent a truly ancient SBD and, perhaps, be one of the first CBMs dedicated to starch binding

Expression and purification of CBM45s from potato GWD and Arabidopsis AMY3

In order to characterize the CBM45s from StGWD, several expression constructs were produced and tested Because there is no structural information on CBM45, putative domain borders were assigned on the basis of the predicted secondary structure and homol-ogy to other CBMs Thirteen constructs with an N-ter-minal tobacco etch virus (TEV) protease-cleavable Histidine (His)-tag, containing both the single and

A

B

Fig 1 Overview of the CBM45 domains.

(A) Domain structure of StGWD and

AtAMY3 showing the chloroplast transit

peptide (TP, black), tandem CBM45s (grey)

and catalytic domain (light grey) The size

of the proteins is given in amino acids (aa).

(B) Sequence alignment of CBM45 domains

1 and 2 from StGWD and AtAMY3 created

using C LUSTAL W2 (http://www.ebi.ac.uk/

tools/clustalw2) Identical (*), conserved (:)

and semiconserved (.) residues are indicated

below the alignment The arrows indicate

the five conserved aromatic amino acid

residues.

double modules with or without the intervening

sequence, were produced and tested for soluble

expres-sion (Fig S3) Two of each of the recombinant single

modules, as well as the double module (CBM45-1B,

amino acids 77–217; CBM45-1E, amino acids 109–217;

CBM45-2A, amino acids 405–545; CBM45-2B, amino

acids 405–551; CBM45-1,2, amino acids 77–551;

Fig S3), were further purified Although the

CBM45-1s and double module could be expressed with

reason-able yields, they precipitated rapidly after His-tag

puri-fication and were not suitable for detailed analyses

The CBM45-2s were stable at pH 8.0 and could be

subjected to TEV protease cleavage and dialysis

with-out significant loss of protein The more stable of the

two resulting proteins (CBM45-2A) was chosen for

detailed characterization This protein precipitated

slowly when stored at 4C The general problem of

aggregation observed with the recombinant CBM45s

suggests that the isolated SBD is destabilized as a

result of the exposure of hydrophobic surface, which

would otherwise be packed on other domains in the

native full-length GWD

Initial differential scanning calorimetry (DSC)

screening of the His-tagged StGWD CBM45-2A

indi-cated a high unfolding temperature This protein gave

rise to a broad asymmetric thermogram with

Tm= 78.1C (data not shown) Proteolytic removal

of the N-terminal His-tag yielded a symmetric single

peak thermogram with Tm= 84.8C at pH 8.0

Inter-estingly, the unfolding was partially reversible, as

dem-onstrated by the 83% and 74% area recovery of the

second and third scans, respectively (Fig 2) Fitting a

two-state model to the reference- and baseline-corrected

calorimetric trace resulted in an excellent fit, yielding

DH = 414.1 ± 0.7 kJÆmol)1, attesting to the high

ther-mal stability and conformational integrity of

CBM45-2A from StGWD This CBM displayed similarly high

conformational stability at pH 7.0 (Tm= 87.1C), but

the reversibility was decreased significantly and the

pro-tein was prone to aggregation (data not shown) The

reason for this extraordinarily high stability is

unknown, but it strongly suggests that CBM45-2A is

correctly folded and justifies the use of the isolated

domain to investigate the binding properties of

CBM45 Thermostability is often associated with lower

structural flexibility, which may influence ligand

inter-actions, but how this affects the binding properties of

the domain is unclear In the case of the CBM20

domain from Aspergillus niger glucoamylase, binding

site 2, which is characterized by high conformational

flexibility and large rearrangements on binding,

dis-plays higher affinity towards b-cyclodextrin when

com-pared with the structurally rigid site 1 [30,31]

AtAMY3 was expressed as either the full-length pro-tein, excluding the chloroplast transit peptide (amino acids 68–887), or as the tandem CBM45s (amino acids 68–388) Two versions of the double module carrying

a His-tag at either end gave rise to some soluble pro-tein but, as these propro-teins were prone to aggregation and rapid degradation, they could not be characterized any further In contrast, full-length AtAMY3 carrying

a C-terminal His-tag was soluble and was produced in satisfactory yields (2–3 mgÆL)1) in a fermentor This recombinant AtAMY3 was capable of releasing reduc-ing sugars from amylopectin, glycogen and b-limit dex-trin at both pH 6.2 and pH 8.0 and 30–37C (data not shown), indicating that the recombinant protein was correctly folded

Affinity measurements using surface plasmon resonance (SPR) and isothermal titration calorim-etry (ITC)

It has been shown previously that the isolated CBM20 domain from AtPWD has relatively low affinity towards cyclodextrins [20] SPR was employed to mea-sure the affinity of StGWD CBM45-2A for selected soluble oligosaccharides The domain was biotinylated, immobilized on a streptavidin-coated chip and probed for carbohydrate-binding ability at pH 8.0 (Fig 3) The resulting dissociation constants (Kd) towards both a- and b-cyclodextrin, as well as

6-O-a-maltosyl-b-Fig 2 Differential scanning calorimetry (DSC) analysis of StGWD CBM45-2A Reference subtracted thermograms of 50 l M

StGWD CBM45-2A in 25 m M Hepes, pH 8.0 The full black line, grey line and broken black line are the thermograms of the first, second and third scans, respectively, at a rate of 1 CÆmin)1.

cyclodextrin, were in the submillimolar range and

com-parable with the values obtained for the AtPWD

CBM20 (Table 1) [20] The related function of the

cat-alytic modules in AtPWD and StGWD is thus

matched by a similar range of affinity of their SBDs,

despite the fact that they have been assigned to two

different CBM families This property was confirmed

by SPR analysis of the binding of b-cyclodextrin to

AtAMY3 in a similar experimental set-up, using a

dif-ferent immobilization chemistry The Kd value

obtained was in the same range as for StGWD

CBM45-2A, suggesting that the weak binding of the

starch mimic b-cyclodextrin is a general feature of

CBM45s (Table 1) For both proteins, an approximate

two-fold variation was observed in the calculated Kd

value between identical experiments This was most

probably a consequence of the low affinity manifested

in low signal-to-noise ratios, particularly at high

cyclo-dextrin concentrations, resulting in elevated back-ground levels For this reason, cyclodextrin concentrations above 1 mm were excluded from the subsequent data analysis The data in Table 1 were obtained from a representative experiment giving the best fit to the binding curve (lowest v2) The StGWD CBM45-2A domain showed no detectable affinity towards maltoheptaose This is not surprising, as the affinity of SBDs for linear oligosaccharides is generally much lower than for cyclodextrins, because of the additional entropic penalty associated with the stabil-ization of the conformation of the linear ligand upon binding [32]

To corroborate the affinity range acquired in the SPR experiment, StGWD CBM45-2A was analysed by ITC with b-cyclodextrin at pH 7.0 and pH 8.0 Although binding was evident in both cases, the heat responses were small The data obtained at pH 7.0 were noisy, suggesting that the protein was more prone

to aggregation at this pH A one-site binding model was fitted to the integrated ITC data, giving a Kdvalue

of 0.68 ± 0.02 mm for the binding of b-cyclodextrin

to StGWD CBM45-2A at pH 8.0 (Fig 4), in good agreement with the value obtained using SPR (Table 1) The measured heat of dilution was negligible and was disregarded in the integrations The binding was driven by a favourable enthalpy change, which compensated for an unfavourable entropy change (DH =)42.1 ± 0.9 kJÆmol)1; TDS =)24.1 kJÆmol)1) The binding affinity at pH 7.0 (Kd= 0.44 mm) was similar to that at pH 8.0 This thermodynamic finger-print is consistent with the binding of b-cyclodextrin to other SBDs [33]

The observed binding affinity of CBM45 for cyclo-dextrins is considerably lower than that of other char-acterized SBDs from microbial amylolytic enzymes Analysis of CBM20 and CBM21 SBDs from two glu-coamylases gave Kdvalues of 14.4 and 5.1 lm, respec-tively, for the interaction with b-cyclodextrin [30,34]

0

5

10

15

20

25

30

35

-cyclodextrin (µM)

Fig 3 Surface plasmon resonance (SPR) analysis of b-cyclodextrin

binding to CBM45 The instrument response level (RU, response

units) is plotted (±SE) as a function of b-cyclodextrin concentration

for StGWD CBM45-2A (squares) and full-length AtAMY3 (triangles).

The full lines represent the fit to a one-site binding model The

experiments were carried out in triplicate at 25 C and pH 8.0.

Table 1 Dissociation constants for CBM45 determined using SPR Data are from representative experiments (±SE) giving the best fit (low-est v2) to the binding curves Each experiment was run in triplicate K d , dissociation constant; R max , maximum binding response; RU, response units; v 2 , chi-squared test value for the fitted curve.

a Previously published data [20].

Similarly, a CBM41 SBD from Thermotoga maritima

pullulanase showed a Kdvalue of 42 lm for the

inter-action with b-cyclodextrin [35] An amylase from

Bacillus halodurans carrying both a CBM25 and a

CBM26 SBD gave Kd values in the range 0.01–1 mm

for the binding of various linear maltooligosaccharides

to the individual SBDs [36] As mentioned above, the

affinity for linear ligands is generally lower than for

cyclic ligands, and StGWD CBM45-2A showed no

binding to maltoheptaose Taken together, the data

presented here show that the binding affinity of the

CBM45 SBD is one to two orders of magnitude lower than the SBDs typically appended to microbial amylo-lytic enzymes This clearly distinguishes the CBM45s from these more thoroughly studied SBDs and, together with the previous report on the CBM20 domain from AtPWD [20], suggests that low-affinity interactions are a recurring characteristic of plastidial starch metabolism This would permit a more dynamic interaction with the starch granule, which may be nec-essary for the accurate control of the rate of degrada-tion [6,20,28] The glucan phosphoryladegrada-tion carried out

by GWD and PWD is an essential initial step in starch degradation in both tubers and leaves, and it has been suggested that the plant controls the release of energy from starch at this crucial step [18,19] It is possible that the low binding affinity of the single domain is masked by avidity effects of the tandem arrangement

of CBMs in the native enzyme This has recently been observed for the triple-CBM53-containing chloroplas-tic starch synthase III from Arabidopsis [25] The low binding affinity of native AtAMY3 towards b-cyclo-dextrin would suggest that this is not the case for the tandem CBM45s but, based on the current data, a small avidity effect cannot be entirely ruled out

AtAMY3 binding to starch in vitro The full-length AtAMY3 offered an advantage when examining the binding affinity of CBM45 SBDs to starch, as it displayed catalytic activity and, being a full-length enzyme, misinterpretation of binding data

as a result of instability or aggregation would most likely be minimal compared with the isolated CBM45s Hence, the starch-binding ability of purified recombi-nant AtAMY3 was demonstrated by incubation with starch isolated from leaves of tobacco plants Binding was carried out at 4C and the a-amylase activity of the unbound fraction was subsequently measured A one-site binding model was fitted to the binding iso-therm (Fig 5), resulting in a Kd value of 36 ± 6.8 mgÆmL)1 and maximum binding capacity (Bmax) of

93 ± 5.6% This affinity is up to two orders of magni-tude lower than that reported previously for the bind-ing of various CBM20 domains to starch [6] A similar experiment using maize starch resulted in comparable affinity, but substantially lower binding capacity (Kd= 21 ± 9.5 mgÆmL)1, Bmax= 42 ± 4.2%) A pre-vious binding analysis of a construct encompassing the isolated recombinant StGWD CBM45-1 to granular potato starch yielded a dissociation constant in the same range (Kd= 7.2 mgÆmL)1, Bmax= 53%) [7] This construct, however, contained approximately 70 amino acids of the C-terminal intervening sequence of

Fig 4 Isothermal titration calorimetry (ITC) analysis of StGWD

CBM45-2A interaction with b-cyclodextrin The top panel depicts

the raw heat response for each b-cyclodextrin injection, and the

bottom panel depicts the binding isotherm; open circles represent

the integrated binding heat of the data in the top panel, and the full

line is the fit of a one-site binding model to the integrated binding

data The experiment was carried out at 25 C by titrating 50 l M

protein in 25 m M Hepes, pH 8.0 with 4 m M b-cyclodextrin in the

same buffer.

unknown function (amino acids 68–286) and the

struc-tural integrity of the protein was not verified

The data obtained not only support the affinity

range measured using SPR and ITC with the

cyclodex-trin starch mimics, but also verify the starch-binding

ability of AtAMY3 in vitro It cannot be precluded

that some binding may involve secondary binding sites

in the catalytic domain, but the demonstrated

starch-binding ability of different isolated CBM45s used in

both the present and other studies [7,10] suggests that

AtAMY3 does indeed interact with starch granules

through the tandem CBM45 domains

CBM45 interaction with starch granules in planta

It has been shown by immunoblotting that StGWD

binds to starch in planta in its active full-length form

[23] To investigate whether the isolated CBM45s from

StGWD function as SBDs in planta, they were

C-termi-nally fused to yellow fluorescent protein (YFP), either

singly or as the double module, and transiently

expressed in tobacco leaves The constructs were

tar-geted to the chloroplasts by an N-terminal fusion to the

transit peptide of Arabidopsis GWD1 In a similar

experimental set-up, fusions between green fluorescent

protein (GFP) and either full-length AtAMY3 or the

tandem CBM45s were analysed Investigation of

locali-zation using confocal laser scanning microscopy showed

clear targeting to the chloroplasts of mesophyll cells

and binding to disc-shaped transient starch granules

for StGWD CBM45-2, CBM45-1,2 and full-length

AtAMY3 (Fig 6) The StGWD CBM45-1 fusion, in

contrast, gave rise to numerous highly fluorescent inclu-sion body-like structures with no clear targeting (data not shown) The double module from AtAMY3 did not yield any visible signal The behaviour of these proteins

is likely to be affected by their instability and observed tendency to aggregate in isolated form (see above), sug-gesting that the CBM45s depend on packing contacts with other domains in the native enzyme Further support for the binding of isolated CBM45s to starch comes from a previous report showing binding to starch

in vitroof an StGWD construct encompassing

CBM45-1 [7] and an in planta localization analysis of GFP-tagged CBM45-1 from Arabidopsis GWD2 [10] In the present study, it has been demonstrated that both iso-lated single and double CBM45 domains from StGWD are capable of binding to starch, and that full-length AtAMY3 binds to starch both in vitro and in planta

Conclusion

In the present study, the carbohydrate-binding proper-ties of two representative plastidial enzymes containing CBM45-type SBDs were characterized The CBM45s

A

B

C

Fig 6 Transient expression of CBM45-YFP ⁄ GFP fusions in tobacco leaf mesophyll cells Single and double CBM45 domains from StGWD and the full-length AtAMY3 were fused to YFP or GFP, respectively, and transiently expressed in Nicotiana benthami-ana leaves by infiltration with Agrobacterium tumefaciens Expres-sion and localization were investigated by confocal laser scanning microscopy YFP ⁄ GFP fluorescence (green), chlorophyll autofluores-cence (red) and a merged image of the two channels are shown (A) StGWD CBM45-2 fused to YFP (B) StGWD CBM45-1,2 fused

to YFP (C) Full-length AtAMY3 fused to GFP Scale bar, 20 lm.

Starch (mg·mL –1 )

0

20

40

60

80

100

Fig 5 Binding of AtAMY3 to tobacco leaf starch in vitro

Recombi-nant AtAMY3 protein was incubated with starch isolated from

leaves of Nicotiana benthamiana for 45 min at 4 C Unbound

pro-tein was assayed for activity by measuring the release of

reducing-end sugars from amylopectin Each data point (±SE) is the average

of four independent experiments.

were demonstrated to exhibit up to two orders of

mag-nitude lower affinity towards both cyclodextrins and

granular starch, compared with typical SBDs

encoun-tered in microbial amylolytic enzymes This behaviour

is analogous to that of the CBM20-type SBD from

AtPWD [20] and supports the hypothesis that

low-affinity SBDs are important for dynamic and reversible

interactions in starch metabolism [28] It remains

unclear how the functionality of these low-affinity

SBDs is integrated with other levels of regulation, such

as the observed diurnal effects of light and redox

conditions [23,27] Further studies will be required to

elucidate these details of starch metabolism and the

structural elements responsible for the lower affinity of

CBM45 The outcome of the present study

demon-strates the large functional diversity of SBDs that has

only started to be addressed, and the investigation of

SBDs occurring in nonhydrolytic, starch- and

glyco-gen-active enzymes will be essential to understand the

contribution of such atypical SBDs to this group of

important enzymes

Materials and methods

Cloning, expression and purification of CBM45

domains from potato GWD

DNA fragments of S tuberosum GWD (accession number

AY027522) were amplified as outlined in Fig S3 using the

primers given in Table S1 The PCR products were cloned

using Gateway technology (Invitrogen, Carlsbad, CA,

USA) via the entry vector pENTR⁄ TEV ⁄ D-TOPO, and

subsequently moved into the expression vector pDEST17

(Invitrogen) with an N-terminal TEV protease-cleavable

His-tag The expression vectors were transformed into

Escherichia coliBL21 cells Cultures were grown in 6· 1 L

scale in Tunair flasks (Sigma-Aldrich, St Louis, MO, USA)

at 37C, cooled to 16 C before induction with 0.5 mm

iso-propyl thio-b-d-galactoside (IPTG), and harvested 16 h

after induction For protein purification, cell pellets were

lysed in 15 mL Bugbuster (Novagen, Merck4Biosciences,

Nottingham, UK) with 5 lL of Benzonase Nuclease

(Sigma-Aldrich) Following centrifugation, the supernatant

was loaded onto a HisTrap HP, 5 mL column (GE

Health-care, Uppsala, Sweden) and eluted by a 40–400 mm

imidaz-ole gradient in 20 mm Tris⁄ HCl pH 8.0, 500 mm NaCl,

10% v⁄ v glycerol and 0.5 m betaine according to the

manu-facturer’s instructions

TEV protease cleavage of the His-tag was performed

with AcTEV protease according to the manufacturer’s

instructions (Invitrogen) For large-scale production,

incu-bation was performed overnight at room temperate using

25% of the recommended amount of protease The cleaved

untagged protein was purified by anion exchange on a

Mono Q 10⁄ 100 GL column (GE Healthcare) in 20 mm Tris⁄ HCl pH 8.0 and eluted with 20 column volumes of a 0–0.5 m NaCl gradient After dialysis to remove NaCl, the protein was stored at 4C

Cloning, expression and purification of

A thaliana AMY3

An AtAMY3 cDNA clone (At1g69830, accession number AY050398) was obtained from the RIKEN Arabidopsis Genome Encyclopedia (RARGE, http://rarge.psc.riken.jp) Full-length AtAMY3 excluding the chloroplast transit pep-tide and stop codon (amino acids 68–887) was amplified (primers AtCBM1-NcoI and AtpAMY-NotI, Table S1) and cloned into the NcoI and NotI sites of the expression vector pET-28a containing a C-terminal 6· His-tag The con-struct was transformed into E coli BL21 Rosetta (DE3) cells (Novagen) Protein expression was carried out in either

a 5 L bioreactor (Biostat B, B Braun Biotech International, Melsungen, Germany) on defined medium [37] by induction

at an absorbance at 600 nm (A600) of 5 with 0.1 mm IPTG

at 16C and harvesting after 22 h, or in shake-flasks by induction with 0.2 mm IPTG at 20C and harvesting after 16–18 h The cell pellet was resuspended in buffer A (20 mm Hepes pH 7.5, 500 mm NaCl, 40 mm imidazole, 40% v⁄ v glycerol, 0.1% v ⁄ v Triton X-100, 0.5 mm CaCl2) containing 2 mm dithithreitol, 0.1 lLÆmL)1 Benzonase Nuclease (Sigma-Aldrich) and one Complete Mini protease inhibitor tablet (Roche, Basle, Switzerland), and lysed using

a French press The lysate was incubated on ice for 30 min, clarified by centrifugation and filtered through a 0.22 lm filter The filtrate was applied to a HisTrap HP, 1 mL col-umn (GE Healthcare), washed with a 40–70 mm imidazole gradient for 10 column volumes, and eluted with 20 column volumes of a 70–400 mm imidazole gradient at 0.5 mLÆ min)1 Concentrated, partially pure AtAMY3 was applied

to a HiLoad Superdex 200 16⁄ 60 gel filtration column (GE Healthcare) and eluted in 20 mm Hepes pH 7.5, 150 mm NaCl, 25% v⁄ v glycerol and 0.5 mm CaCl2 The fractions containing AtAMY3 were pooled and concentrated to approximately 1 mgÆmL)1and stored at 4C

DSC analysis

DSC analysis was performed using a VP-DSC calorimeter (MicroCal, Northampton, MA, USA) with a cell volume of 0.52061 mL at a scan rate of 1CÆmin)1 Samples were dialysed in at least 500 volumes of 25 mm Hepes–NaOH,

pH 7.0 or pH 8.0, and degassed for 10 min at 20C Base-line scans collected with buffer in the reference and sample cells were subtracted from sample scans The reversibility of the thermal transitions was evaluated by checking the reproducibility of the scan on immediate cooling and rescanning The initial screening of the conformational sta-bility of purified StGWD constructs was performed using a

protein concentration of 0.5 mgÆmL)1 in 25 mm Hepes–

NaOH, pH 8.0 The DSC analysis of the form with the

highest Tmvalue (StGWD CBM45-2A) was performed

fol-lowing cleavage of the His-tag with TEV protease (see

above), and subsequent repurification and dialysis of 50 lm

protein as mentioned above Origin v7.038 software with a

DSC add-on module was used for data analysis, Tm

(unfolding temperature, defined as the temperature of

maxi-mum apparent heat capacity) assignment and unfolding

enthalpy calculations

SPR analysis

Measurements of interactions with soluble ligands using

SPR were carried out on a Biacore T100 (GE Healthcare)

Domains of StGWD were biotinylated using EZ-Link

Sul-fo-NHS-LC-Biotin (Pierce, Thermo Scientific, Rockford,

IL, USA) in 10 mm Mes pH 6.8, 5 mm CaCl2 and 8 mm

b-cyclodextrin, and immobilized on a streptavidin-coated

chip (sensor chip SA, GE Healthcare) using a standard

pro-gram, aiming for a density of 1250 response units (RU)

AtAMY3 was immobilized on a carboxymethylated dextran

chip (sensor chip CM5, GE Healthcare) in 10 mm sodium

acetate pH 4.6, 20% v⁄ v glycerol, 1 mm CaCl2 and 2 mm

b-cyclodextrin, using a standard program, aiming for a

den-sity of 7500 RU Sensograms were collected at 25C in

25 mm Hepes pH 8.0, 150 mm NaCl, 0.5 mm CaCl2 and

0.005% v⁄ v P20 surfactant (GE Healthcare) at a flow rate

of 30 lLÆmin)1, contact time of 90–180 s and dissociation

time of 100–240 s Experiments were run in triplicate in the

range 0–2000 lm for each carbohydrate dissolved in the same

buffer All data evaluation was carried out using the Biacore

T100 evaluation software

ITC analysis

Experiments were performed using an MCS isothermal

titration calorimeter (MicroCal) Titrations were performed

by injecting 5 lL b-cyclodextrin in 25 mm Hepes–NaOH

pH 7.0 or 8.0 into a stirred (400 rpm) 1.3187 mL cell

con-taining 50 lm StGWD CBM45-2A in the same buffer For

each titration of enzyme, the dialysis buffer of the sample

was titrated as a control using the same b-cyclodextrin

stock to measure the heat of dilution The control titration

consisted of 10 injections of 1 lL in 2.5 s for the first

injec-tion and 5 lL for the rest, and with 180 s of equilibrainjec-tion

between injections Titrations of the protein were carried

out similarly, but were continued until no significant

response was observed on ligand injections Origin software

supplied with the instrument was used to analyse the data

Starch-binding assays

Tobacco leaf starch was isolated from 5-week-old

Nicoti-ana benthamiNicoti-ana The harvested leaves were homogenized

in 0.2% SDS in a polytron PT3000 blender (Kinematica

AG, Lucerne, Switzerland) and filtered sequentially through

2· 100 lm and 2 · 20 lm filtration cloth Following cen-trifugation, the starch pellet was washed twice in 0.2% SDS, three times in water, twice in 96% ethanol and air dried

Recombinant AtAMY3 (3 lg) was incubated with tobacco leaf starch granules in a 350 lL mixture containing

20 mm Hepes pH 7.5, 0.5 mm CaCl2, 0.05 mgÆmL)1 BSA and 0–200 mgÆmL)1 starch The suspension was incubated with gentle mixing at 4C for 45 min The supernatant (198 lL) containing unbound AtAMY3 was treated with

10 mm dithiothreitol for 20 min at 25C, and a-amylase activity was measured by adding 50 lL of a 25 mgÆmL)1 amylopectin solution (Fluka 10118, dissolved in 20 mm Hepes pH 7.5, 0.5 mm CaCl2) and incubating for 45 min at

37C Reactions were stopped by mixing with an equal volume of 0.5 m NaOH, and liberated reducing ends were determined by the 3-methyl-2-benzothiazolinone hydrazone method, as described previously [38] The activity (expressed as the percentage of bound AtAMY3 when com-pared with a no-starch control) was plotted against the starch concentration, and the data were fitted to a one-site binding model

Transient expression of CBM45s in tobacco

The CBM45s from StGWD were C-terminally fused to YFP, either singly (CBM45-1, amino acids 109–217; CBM45-2, amino acids 405–545) or as the entire double module (CBM45-1,2, amino acids 77–551) Fragments were PCR amplified using uracil-containing primers (Table S1) and cloned into the vector pPS48uYFP using an improved USER (uracil-specific excision reagent; New England Biolabs, Ipswich, MA, USA) cloning procedure [39] The chloroplast transit peptide of Arabidopsis GWD1 (amino acids 1–77) was fused to each construct by simultaneous cloning of both fragments as described previously [10] The full-length ORF of AtAMY3 (primers AMY3-F and AMY3-R, Table S1), as well as an N-terminal fragment (amino acids 1–391) covering both CBM45s (primers AMY3-F and AMY3SBD-R, Table S1), were fused to enhanced GFP in the binary vector pK7FWG2 [40] using GATEWAY cloning technology (Invitrogen) Constructs were transformed into Agrobacterium tumefaciens and tran-siently expressed by infiltration in Nicotiana benthamiana as described previously [41] Expression and localization were analysed by a confocal laser scanning microscope (TCS SP2, Leica Microsystems, Wetzlar, Germany) equipped with a 20· ⁄ 0.70 or 63 · ⁄ 1.20 PL APO water immersion objective A 488 nm laser line was used for excitation, and emission was detected between 520 and 550 nm for YFP fluorescence, between 510 and 535 nm for GFP fluores-cence, and between 600 and 750 nm for chlorophyll auto-fluorescence

MAG was supported by a grant from the Danish

Research Council for Technology and Production

Sci-ences (grant no 274-06-0312) and MJB by a Hans

Christian Ørsted postdoctoral fellowship from the

Technical University of Denmark The financial

sup-port from the Carlsberg Foundation (to BS), the

Vil-lum Kann Rasmussen Foundation (to the VKR

Research Centre Pro-Active Plants) and ETH Zu¨rich

and the Swiss–South African Joint Research

Pro-gramme (grant no 08 IZ LS Z3122916, to SCZ and

DS) is gratefully acknowledged

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