Characterization and affinity applications of cellulose-binding domains

Cellulose-binding domains (CBDs) are discrete protein modules found in a large number of carbohydrolases and a few nonhydrolytic proteins. To date, almost 200 sequences can be classified in 13 different families with distinctly different properties. CBDs vary in size from 4 to 20 kDa and occur at different positions within the polypeptides; N-terminal, C-terminal and internal. They have a moderately high and specific affinity for insoluble or soluble cellulosics with dissociation constants in the low micromolar range. Some CBDs bind irreversibly to cellulose and can be used for applications involving immobilization, others bind reversibly and are more useful for separations and purifications. Dependent on the CBD used, desorption from the matrix can be promoted under various different conditions including denaturants (urea, high pH), water, or specific competitive ligands (e.g. cellobiose). Family I and IV CBDs bind reversibly to cellulose in contrast to family II and III CBDs which are in general, irreversibly bound. The binding of family II CBDs (CBD_Cex) to crystalline cellulose is characterized by a large favourable increase in entropy indicating that dehydration of the sorbent and the protein are the major driving forces for binding. In contrast, binding of family IV CBDs (CBD_N1) to amorphous or soluble cellulosics is driven by a favourable change in enthalpy which is partially offset by an unfavourable entropy change. Hydrogen bond formation and van der Waals interactions are the main driving forces for binding. CBDs with affinity for crystalline cellulose are useful tags for classical column affinity chromatography. The affinity of CBD_N1 for soluble cellulosics makes it suitable for use in large-scale aqueous two-phase affinity partitioning systems.     

Importance of Trp59 and Trp60 in chitin-binding, hydrolytic, and antifungal activities of Streptomyces griseus chitinase C

The chitin-binding domain of Streptomyces griseus chitinase C (ChBD_ChiC) belongs to CBM family 5. Only two exposed aromatic residues, W59 and W60, were observed in ChBD_ChiC, in contrast to three such residues on CBD_Cel5 in the same CBM family. To study importance of these residues in binding activity and other functions of ChBD_ChiC, site-directed mutagenesis was carried out. Single (W59A and W60A) and double (W59A/W60A) mutations abolished the binding activity of ChiC to colloidal chitin and decreased the hydrolytic activity toward not only colloidal chitin but also a soluble high Mr substrate, glycol chitin. Interaction of ChBD_ChiC with oligosaccharide was eliminated by these mutations. The hydrolytic activity toward oligosaccharide was increased by deletion of ChBD but not affected by these mutations, indicating that ChBD interferes with oligosaccharide hydrolysis but not through its binding activity. The antifungal activity was drastically decreased by all mutations and significant difference was observed between single and double mutants. Taken together with the structural information, these results suggest that ChBD_ChiC binds to chitin via a mechanism significantly different from CBD_Cel5, where two aromatic residues play major role, and contributes to various functions of ChiC. Sequence comparison indicated that ChBD_ChiC-type CBMs are dominant in CBM family 5.     

Cellulose-binding domain of endoglucanase III from Trichoderma reesei disrupting the structure of cellulose

The DNA fragment encoding the cellulose binding domain of endoglucanase III (CBD_{EG III}) from Trichoderma reesei was subcloned and expressed in E. coli. The CBD_{EG III} had a high affinity for cellulose. The morphological and structural changes of cellulose after treatment with CBD_{EG III} indicated a 17% decrease in number of hydrogen bonds and a 16.5% decrease in crystalline index. X-ray diffraction and IR spectra analyses indicated that the destabilization and breakage of the hydrogen bonds in crystalline cellulose accounted for the non-hydrolytic disruption of the structure of cellulose.     

Site-directed mutagenesis and expression of the soluble form of the family IIIa cellulose binding domain from the cellulosomal scaffolding protein of Clostridium cellulovorans

The planar and anchoring residues of the family IIIa cellulose binding domain (CBD) from the cellulosomal scaffolding protein of Clostridium cellulovorans were investigated by site-directed mutagenesis and cellulose binding studies. By fusion with maltose binding protein, the family IIIa recombinant wild-type and mutant CBDs from C. cellulovorans were expressed as soluble forms. Cellulose binding tests of the mutant CBDs indicated that the planar strip residues played a major role in cellulose binding and that the anchoring residues played only a minor role.     

Trp22, Trp24, and Tyr8 play a pivotal role in the binding of the family 10 cellulose-binding module from Pseudomonas xylanase A to insoluble ligands

Aromatic amino acids are believed to play a pivotal role in carbohydrate-binding proteins, by forming hydrophobic stacking interactions with the sugar rings of their target ligands. Family 10 cellulose-binding modules (CBM10s), present in a number of cellulases and xylanases expressed by Pseudomonas fluorescens subsp. cellulosa, contain two tyrosine and three tryptophan residues which are highly conserved. To investigate whether these amino acids play an important role in the interaction of CBM10 from P. fluorescens subsp. cellulosa xylanase A (Pf Xyn10A) with cellulose, each of these residues was changed to alanine in CBM10 expressed as a discrete module or fused to the catalytic domain of Pf Xyn10A (CBM10-CD), and the capacity of the mutant proteins of CBM10-CD to bind the polysaccharide was evaluated. The data showed that W22A, W24A, and Y8A bound very weakly to cellulose compared to the wild-type protein, while Y12A retained its capacity to interact with the glucose polymer. When the W7A mutation was introduced into CBM10 the protein domain did not accumulate in Escherichia coli. In contrast, the W7A mutant of CBM10-CD was efficiently expressed in E. coli, although the protein bound very weakly to cellulose. NMR spectra of wild-type CBM10, W22A, and W24A were very similar, suggesting that the mutations did not significantly affect the protein fold. Titration of wild-type CBM10, W22A, and W24A with N-bromosuccinimide indicated that Trp22 and Trp24 were on the surface of the protein, while Trp7 was buried. Collectively, these data indicate that Trp22, Trp24, and Tyr8 play a direct role in the binding of Pf Xyn10A CBM10 to cellulose. The results are discussed in the light of the three-dimensional structure of CBM10 [Raghothama, S., Simpson, P. J., Szabó, L., Nagy, T., Gilbert, H. J., and Williamson, M. P. (2000) Biochemistry 39, 978-984].     

The role of the local environment of engineered Tyr to Trp substitutions for probing the denaturation mechanism of FIS

Factor for inversion stimulation (FIS), a 98-residue homodimeric protein, does not contain tryptophan (Trp) residues but has four tyrosine (Tyr) residues located at positions 38, 51, 69, and 95. The equilibrium denaturation of a P61A mutant of FIS appears to occur via a three-state (N₂ ⇆ I₂ ⇆ 2U) process involving a dimeric intermediate (I₂). Although it was suggested that this intermediate had a denatured C-terminus, direct evidence was lacking. Therefore, three FIS double mutants, P61A/Y38W, P61A/Y69W, and P61A/Y95W were made, and their denaturation was monitored by circular dichroism and Trp fluorescence. Surprisingly, the P61A/Y38W mutant best monitored the N₂ ⇆ I₂ transition, even though Trp38 is buried within the dimer removed from the C-terminus. In addition, although Trp69 is located on the protein surface, the P61A/Y69W FIS mutant exhibited clearly biphasic denaturation curves. In contrast, P61A/Y95W FIS was the least effective in decoupling the two transitions, exhibiting a monophasic fluorescence transition with modest concentration-dependence. When considering the local environment of the Trp residues and the effect of each mutation on protein stability, these results not only confirm that P61A FIS denatures via a dimeric intermediate involving a disrupted C-terminus but also suggest the occurrence of conformational changes near Tyr38. Thus, the P61A mutation appears to compromise the denaturation cooperativity of FIS by failing to propagate stability to those regions involved mostly in intramolecular interactions. Furthermore, our results highlight the challenge of anticipating the optimal location to engineer a Trp residue for investigating the denaturation mechanism of even small proteins.     

Effect of tryptophan mutation on the structure of LOV1 domain of phototropin1 protein of Ostreococcus tauri: A combined molecular dynamics simulation and biophysical approach

BackgroundLight, oxygen and voltage (LOV) proteins detect blue light by formation of a covalent ‘photoadduct’ between the flavin chromophore and the neighboring conserved cysteine residue. LOV proteins devoid of this conserved photoactive cysteine are unable to form this ‘photoadduct’ upon light illumination, but they can still elicit functional response via the formation of neutral flavin radical. Recently, tryptophan residue has been shown to be the primary electron donors to the flavin excited state.MethodsPhotoactive cysteine (Cys42) and tryptophan (Trp68) residues in the LOV1 domain of phototropin1 of Ostreococcus tauri (OtLOV1) was mutated to alanine and threonine respectively. Effect of these mutations have been studied using molecular dynamics simulation and spectroscopic techniques.ResultsMolecular dynamics simulation indicated that W68T did not affect the structure of OtLOV1 protein, but C42A leads to some structural changes. An increase in the fluorescence lifetime and quantum yield values was observed for the Trp68 mutant.ConclusionsAn increase in the fluorescence lifetime and quantum yield of Trp68 mutant compared to the wild type protein suggests that Trp68 residue participates in quenching of the flavin excited state followed by photoexcitation.General significanceEnhanced photo-physical properties of Trp68 OtLOV1 mutant might enable its use for the optogenetic and microscopic applications.     

Fluorescence quenching studies of Trp repressor using single-tryptophan mutants

Time-resolved and steady-state fluorescence have been used to resolve the heterogeneous emission of single-tryptophan-containing mutants of Trp repressors W19F and W99F into components. Using iodide as the quencher, the fluorescence-quenching-resolved spectra (FQRS) have been obtained The FQRS method shows that the fluorescence emission of Trp99 can be resolved into two component spectra characterized by maxima of fluorescence emission at 338 and 328 nm. The redder component is exposed to the solvent and participates in about 21% of the total fluorescence emission of TrpR W19F. The second component is inacessible to iodide, but is quenched by acrylamide. The tryptophan residue 19 present in TrpR W99F can be resolved into two component spectra using the FQRS method and iodide as a quencher. Both components of Trp19 exhibit similar maxima of emission at 322–324 nm and both are quenchable by iodide. The component more quenchable by iodide participates in about 38% of the total TrpR W99F emission. The fluorescence lifetime measurements as a function of iodide concentration support the existence of two classes of Trp99 and Trp19 in the Trp repressor. Our results suggest that the Trp aporepressor can exist in the ground state in two distinct conformational states which differ in the microenvironment of the Trp residues.Abbreviations TrpR tryptophan aporepressor fromE. coli - TrpR W19F TrpR mutant with phenylalanine substituted for tryptophan at position 19 - TrpR W99F TrpR mutant with phenylalanine substituted for tryptophan at position 99 - FQRS fluorescence-quenching-resolved spectra - FPLC fast protein liquid chromatography     

Role of Tryptophan Residues in a Class V Chitinase from Nicotiana tabacum

Tryptophan residues located in the substrate-binding cleft of a class V chitinase from Nicotiana tabacum (NtChiV) were mutated to alanine and phenylalanine (W190F, W326F, W190F/W326F, W190A, W326A, and W190A/W326A), and the mutant enzymes were characterized to define the role of the tryptophans. The mutations of Trp326 lowered thermal stability by 5–7 °C, while the mutations of Trp190 lowered stability only by 2–4 °C. The Trp326 mutations strongly impaired enzymatic activity, while the effects of the Trp190 mutations were moderate. The experimental data were rationalized based on the crystal structure of NtChiV in a complex with (GlcNAc)₄, in which Trp190 is exposed to the solvent and involved in face-to-face stacking interaction with the +2 sugar, while Trp326 is buried inside but interacts with the ?2 sugar through hydrophobicity. HPLC analysis of anomers of the enzymatic products suggested that Trp190 specifically recognizes the β-anomer of the +2 sugar. The strong effects of the Trp326 mutations on activity and stability suggest multiple roles of the residue in stabilizing the protein structure, in sugar residue binding at subsite ?2, and probably in maintaining catalytic efficiency by providing a hydrophobic environment for proton donor Glu115.     

Properties and mutation analysis of the CelK cellulose-binding domain from the Clostridium thermocellum cellulosome

The family IV cellulose-binding domain of Clostridium thermocellum CelK (CBD(CelK)) was expressed in Escherichia coli and purified. It binds to acid-swollen cellulose (ASC) and bacterial microcrystalline cellulose (BMCC) with capacities of 16.03 and 3.95 micromol/g of cellulose and relative affinities (K(r)) of 2.33 and 9.87 liters/g, respectively. The CBD(CelK) is the first representative of family IV CBDs to exhibit an affinity for BMCC. The CBD(CelK) also binds to the soluble polysaccharides lichenin, glucomannan, and barley beta-glucan, which are substrates for CelK. It does not bind to xylan, galactomannan, and carboxymethyl cellulose. The CBD(CelK) contains 1 mol of calcium per mol. The CBD(CelK) has three thiol groups and one disulfide, reduction of which results in total loss of cellulose-binding ability. To reveal amino acid residues important for biological function of the domain and to investigate the role of calcium in the CBD(CelK) four highly conserved aromatic residues (Trp(56), Trp(94), Tyr(111), and Tyr(136)) and Asp(192) were mutated into alanines, giving the mutants W56A, W94A, Y111A, Y136A, and D192A. In addition 14 N-terminal amino acids were deleted, giving the CBD-N(CelK). The CBD-N(CelK) and D192A retained binding parameters close to that of the intact CBD(CelK), W56A and W94A totally lost the ability to bind to cellulose, Y136A bound to both ASC and BMCC but with significantly reduced binding capacity and K(r) and Y111A bound weakly to ASC and did not bind to BMCC. Mutations of the aromatic residues in the CBD(CelK) led to structural changes revealed by studying solubility, circular-dichroism spectra, dimer formation, and aggregation. Calcium content was drastically decreased in D192A. The results suggest that Asp192 is in the calcium-binding site of the CBD(CelK) and that calcium does not affect binding to cellulose. The 14 amino acids from the N terminus of the CBD(CelK) are not important for binding. Tyr136, corresponding to Cellulomonas fimi CenC CBD(N1) Y85, located near the binding cleft, might be involved in the formation of the binding surface, while Y111, W56A, and W94A are essential for the binding process by keeping the CBD(CelK) correctly folded.     

Optimization of a β‐sheet‐cap for long loop closure

Protein loops make up a large portion of the secondary structure in nature. But very little is known concerning loop closure dynamics and the effects of loop composition on fold stability. We have designed a small system with stable β‐sheet structures, including features that allow us to probe these questions. Using paired Trp residues that form aromatic clusters on folding, we are able to stabilize two β‐strands connected by varying loop lengths and composition (an example sequence: R W ITVTI – loop – KKIRV W E). Using NMR and CD, both fold stability and folding dynamics can be investigated for these systems. With the 16 residue loop peptide (sequence: R W ITVTI‐(GGGGKK)₂GGGG‐KKIRV W E) remaining folded (ΔG_U = 1.6 kJ/mol at 295K). To increase stability and extend the series to longer loops, we added an additional Trp/Trp pair in the loop flanking position. With this addition to the strands, the 16 residue loop (sequence: R W ITVRI W ‐(GGGGKK)₂GGGG‐ W KTIRV W E) supports a remarkably stable β‐sheet (ΔG_U = 6.3 kJ/mol at 295 K, T_m = ～55°C). Given the abundance of loops in binding motifs and between secondary structures, these constructs can be powerful tools for peptide chemists to study loop effects; with the Trp/Trp pair providing spectroscopic probes for assessing both stability and dynamics by NMR.     

Cell calcium signalling induced by endogenous lectin carbohydrate interaction in the Jurkat T cell line

The effects of the -galactoside-binding lectin from human placenta (HPL14) on intracellular calcium concentration ([Ca²⁺]_i) were examined in the human Jurkat T cell line. The lectin induces a concentration dependent increase in [Ca²⁺]_i. This calcium signalling effect is clearly mediated through complementary cell surface galactoglycoconjugates because it can be blocked by -galactosides. The observed Ca²⁺-response involves both the release of calcium from intracellular stores and a calcium influx from the extracellular space. It is sustained in the presence of 1 mM extracellular calcium whereas it becomes transient when the influx of extracellular calcium was blocked by calcium chelation to EGTA. Voltage-sensitive calcium channel blockers like verapamil and prenylamine were without effect on the action of HPL14. Protection of the sugar binding activity of HPL14 in the absence of a thiol-reducing reagent by carboxamidomethylation (CM-HPL14) or by substitution Cys2 with serine (C2S) results in lectin proteins with considerably decreased calcium signalling efficiency. The recombinant lectin (Rec H) and the mutant protein obtained by substitution of highly conservative Trp68 with tyrosine (W68Y) induce lower levels of [Ca²⁺]_i compared to wild type lectin.Abbreviation [Ca²⁺]_i concentration of intracytoplasmic free calcium - CM carboxamidomethylation - CRD earbohydrate recognition domain - C2S mutant lectin protein in which Cys2 was replaced by serine - EGTA ethyleneglycol-bis(2-aminoethylether)-N,N,N - N-tetraacetic acid HEPES,N-(2-hydroxyethyl)piperazine-N-2-ethanesulfonic acid - HPL14 human -galactoside-binding placental lectin - Rec H recombinant human 14 kDa lectin - W68Y mutant lectin protein in which Trp68 was substituted to tyrosine     

Role of Phe-114 in substrate specificity of Candida tenuis xylose reductase (AKR2B5)

The 2.2 Å X-ray crystal structure of Candida tenuis xylose reductase (AKR2B5) bound with NADP⁺ reveals that Phe-114 contributes to the substrate binding pocket of the enzyme. In the related human aldose reductase (AKR1B1), this phenylalanine is replaced by a tryptophan. The side chain of Trp was previously implicated in forming a hydrogen bond with bound substrate or inhibitor. The apparent Michaelis constant of AKR2B5 for xylose (K_m≈90 mM) is 60 times that of AKR1B1, perhaps because critical enzyme–substrate interactions of Trp are not available to Phe-114. We, therefore, prepared a Phe-114→Trp mutant (F114W) of AKR2B5, to mimic the aldose reductase relationship in xylose reductase. Detailed analysis of the kinetic consequences in purified F114W revealed that the K_m values for xylose and xylitol at pH 7.0 and 25°C were increased 5.1- and 4.4-fold, respectively, in the mutant compared with the wild-type. Turnover numbers (k_cat) of F114W for xylose reduction and xylitol oxidation were half those of the wild-type. Apparent dissociation constants of NADH (K_iNADH=44 µM) and NAD⁺ (K_iNAD⁺=177 µM) were increased 1.6- and 1.4-fold in comparison with values of K_iNADH and K_iNAD⁺ for the wild-type, respectively. Catalytic efficiencies (k_cat/K_m) for NADH-dependent reduction of different aldehydes were between 3.1- and 31.5-fold lower than the corresponding k_cat/K_m values of the wild-type. Therefore, replacement of Phe-114 with Trp weakens rather than strengthens apparent substrate binding by AKR2B5, suggesting that xylose reductase exploits residue 114 in a different manner from aldose reductase.     

Mutagenesis of Trp(54) and Trp(203) residues on Fibrobacter succinogenes 1,3-1,4-beta-D-glucanase significantly affects catalytic activities of the enzyme

The possible structural and catalytic functions of the nine tryptophan amino acid residues, including Trp(54), Trp(105), Trp(112), Trp(141), Trp(148), Trp(165), Trp(186), Trp(198), and Trp(203) in Fibrobacter succinogenes 1,3-1,4-beta-D-glucanase (Fs beta-glucanase), were characterized using site-directed mutagenesis, initial rate kinetics, fluorescence spectrometry, and structural modeling analysis. Kinetic studies showed that a 5-7-fold increase in K(m) value for lichenan was observed for W141F, W141H, and W203R mutant Fs beta-glucanases, and approximately 72-, 56-, 30-, 29.5-, 4.9-, and 4.3-fold decreases in k(cat) relative to that for the wild-type enzyme were observed for the W54F, W54Y, W141H, W203R, W141F, and W148F mutants, respectively. In contrast, W186F and W203F, unlike the other 12 mutants, exhibited a 1.4- and 4.2-fold increase in k(cat), respectively. W165F and W203R were the only two mutants that exhibited a 4-7-fold higher activity relative to the wild-type enzyme after they were incubated at pH 3.0 for 1 h. Fluorescence spectrometry indicated that all of the mutations on the nine tryptophan amino acid residues retained a folding similar to that of the wild-type enzyme. Structural modeling and kinetic studies suggest that Trp(54), Trp(141), Trp(148), and Trp(203) play important roles in maintaining structural integrity in the substrate-binding cleft and the catalytic efficiency of the enzyme.     

Insights into the catalytic properties of bamboo vacuolar invertase through mutational analysis of active site residues

Plant acid invertases, which are either associated with the cell wall or present in vacuoles, belong to family 32 of glycoside hydrolases (GH32). Homology modeling of bamboo vacuolar invertase Boβfruct3 using Arabidopsis cell-wall invertase AtcwINV1 as a template showed that its overall structure is similar to GH32 enzymes, and that the three highly conserved motifs, NDPNG, RDP and EC, are located in the active site. This study also used site-directed mutagenesis to examine the roles of the conserved amino acid residues in these three motifs, which include Asp135, Arg259, Asp260, Glu316 and Cys317, and a conserved Trp residue (Trp159) that resides between the NDPNG and RDP motifs. The mutants W159F, W159L, E316Q and C317A retained acid invertase activity, but no invertase activity was observed for the mutant E316A or mutants with changes at Asp135, Arg259, or Asp260. The apparent K_m values of the four mutants with invertase activity were all higher than that of the wild-type enzyme. The mutants W159L and E316Q exhibited lower k_cat values than the wild-type enzyme, but an increase in the k_cat value was observed for the mutants W159F and C317A. The results of this study demonstrate that these residues have individual functions in catalyzing sucrose hydrolysis.     

Functional characterization and mutation analysis of family 11, Carbohydrate-Binding Module (<Emphasis Type="Italic">Ct</Emphasis>CBM11) of cellulosomal bifunctional cellulase from <Emphasis Type="Italic">Clostridium thermocellum</Emphasis>

The non-catalytic, family 11 carbohydrate binding module (CtCBM11) belonging to a bifunctional cellulosomal cellulase from Clostridium thermocellum was hyper-expressed in E. coli and functionally characterized. Affinity electrophoresis of CtCBM11 on nondenaturing PAGE containing cellulosic polysaccharides showed binding with β-glucan, lichenan, hydroxyethyl cellulose and carboxymethyl cellulose. In order to elucidate the involvement of conserved aromatic residues Tyr 22, Trp 65 and Tyr 129 in the polysaccharide binding, site-directed mutagenesis was carried out and the residues were changed to alanine. The results of affinity electrophoresis and binding adsorption isotherms showed that of the three mutants Y22A, W65A and Y129A of CtCBM11, two mutants Y22A and Y129A showed no or reduced binding affinity with polysaccharides. These results showed that tyrosine residue 22 and 129 are involved in the polysaccharide binding. These residues are present in the putative binding cleft and play a critical role in the recognition of all the ligands recognized by the protein.     

Time-resolved fluorescence studies of flavodoxin. Fluorescence decay and fluorescence anisotropy decay of tryptophan in Desulfovibrio flavodoxins

The time-resolved fluorescence characteristics of tryptophan in flavodoxin isolated from the sulfate-reducing bacteria Desulfovibrio vulgaris and Desulfovibrio gigas have been examined. By comparing the results of protein preparations of normal and FMN-depleted flavodoxin, radiationless energy transfer from tryptophan to FMN has been demonstrated. Since the crystal structure of the D. vulgaris flavodoxin is known, transfer rate constants from the two excited states ¹ L _a and ¹ L _b can be calculated for both tryptophan residues (Trp 60 and Trp 140). Residue Trp 60, which is very close to the flavin, transfers energy very rapidly to FMN, whereas the rate of energy transfer from the remote Trp 140 to FMN is much smaller. Both tryptophan residues have the indole rings oriented in such a way that transfer will preferentially take place from the ¹ L _a excited state. The fluorescence decay of all protein preparations turned out to be complex, the parameter values being dependent on the emission wavelength. Several decay curves were analyzed globally using a model in which tryptophan is involved in some nanosecond relaxation process. A relaxation time of about 2 ns was found for both D. gigas apo- and holoflavodoxin. The fluorescence anisotropy decay of both Desulfovibrio FMN-depleted flavodoxins is exponential, whereas that of the two holoproteins is clearly non-exponential. The anisotropy decay was analyzed using the same model as that applied for fluorescence decay. The tryptophan residues turned out to be immobilized in the protein. A time constant of a few nanoseconds results from energy transfer from tryptophan to flavin, at least for D. gigas flavodoxin. The single tryptophan residue in D. gigas flavodoxin occupies a position in the polypeptide chain remote from the flavin prosthetic group. Because of the close resemblance of steady-state and time-resolved fluorescence properties of tryptophan in both flavodoxins, the center to center distance between tryptophan and FMN in D. gigas flavodoxin is probably very similar to the distance between Trp 140 and FMN in D. vulgaris flavodoxin (i.e. 20 Å). Offprint requests to: A.J.W.G. Visser     

The Unique Binding Mode of Cellulosomal CBM4 from Clostridium thermocellum Cellobiohydrolase A

The crystal structure of the carbohydrate-binding module (CBM) 4 Ig fused domain from the cellulosomal cellulase cellobiohydrolase A (CbhA) of Clostridium thermocellum was solved in complex with cellobiose at 2.11 Å resolution. This is the first cellulosomal CBM4 crystal structure reported to date. It is similar to the previously solved noncellulosomal soluble oligosaccharide-binding CBM4 structures. However, this new structure possesses a significant feature—a binding site peptide loop with a tryptophan (Trp118) residing midway in the loop. Based on sequence alignment, this structural feature might be common to all cellulosomal clostridial CBM4 modules. Our results indicate that C. thermocellum CbhA CBM4 also has an extended binding pocket that can optimally bind to cellodextrins containing five or more sugar units. Molecular dynamics simulations and experimental binding studies with the Trp118Ala mutant suggest that Trp118 contributes to the binding and, possibly, the orientation of the module to soluble cellodextrins. Furthermore, the binding cleft aromatic residues Trp68 and Tyr110 play a crucial role in binding to bacterial microcrystalline cellulose (BMCC), amorphous cellulose, and soluble oligodextrins. Binding to BMCC is in disagreement with the structural features of the binding pocket, which does not support binding to the flat surface of crystalline cellulose, suggesting that CBM4 binds the amorphous part or the cellulose “whiskers” of BMCC. We propose that clostridial CBM4s have possibly evolved to bind the free-chain ends of crystalline cellulose in addition to their ability to bind soluble cellodextrins.     

Heterologous expression of enterocin A, a bacteriocin from Enterococcus faecium, fused to a cellulose-binding domain in Escherichia coli results in a functional protein with inhibitory activity against Listeria

The genes for the bacteriocins enterocin A and B were isolated from Enterococcus faecium ATB 197a. Using the pET37b(+) vector, the enterocin genes were fused to an Escherichia coli specific export signal sequence, a cellulose-binding domain (CBD_cenA) and a S-tag under the control of a T7lac promotor. The constructs were subsequently cloned into E. coli host cells. The expression of the recombinant enterocins had different effects on both the host cells and other Gram-positive bacteria. The expression of entA in Esc. coli led to the synthesis and secretion of functional active enterocin A fusion proteins, which were active against some Gram-positive indicator bacteria, but did not influence the viability of the host cells. In contrast, the expression of enterocin B fusion proteins led to a reduced viability of the host cells, indicating a misfolding of the protein or interference with the cellular metabolism of Esc. coli. Indicator strains of Gram-positive bacteria were not inhibited by purified enterocin B fusion proteins. However, recombinant enterocin B displayed inhibitory activity after the proteolytic cleavage of the fused peptides.