Introduction of raw starch-binding domains into Bacillus subtilis alpha-amylase by fusion with the starch-binding domain of Bacillus cyclomaltodextrin glucanotransferase

We constructed two types of chimeric enzymes, Ch1 Amy and Ch2 Amy. Ch1 Amy consisted of a catalytic domain of Bacillus subtilis X-23 alpha-amylase (Ba-S) and the raw starch-binding domain (domain E) of Bacillus A2-5a cyclomaltodextrin glucanotransferase (A2-5a CGT). Ch2 Amy consisted of Ba-S and D (function unknown) plus E domains of A2-5a CGT. Ch1 Amy acquired raw starch-binding and -digesting abilities which were not present in the catalytic part (Ba-S). Furthermore, the specific activity of Ch1 Amy was almost identical when enzyme activity was evaluated on a molar basis. Although Ch2 Amy exhibited even higher raw starch-binding and -digesting abilities than Ch1 Amy, the specific activity was lower than that of Ba-S. We did not detect any differences in other enzymatic characteristics (amylolytic pattern, transglycosylation ability, effects of pH, and temperature on stability and activity) among Ba-S, Ch1 Amy, and Ch2 Amy.     

Characteristics of Two Forms of α-Amylases and Structural Implication

Complete (Ba-L) and truncated (Ba-S) forms of α-amylases from Bacillus subtilis X-23 were purified, and the amino- and carboxyl-terminal amino acid sequences of Ba-L and Ba-S were determined. The amino acid sequence deduced from the nucleotide sequence of the α-amylase gene indicated that Ba-S was produced from Ba-L by truncation of the 186 amino acid residues at the carboxyl-terminal region. The results of genomic Southern analysis and Western analysis suggested that the two enzymes originated from the same α-amylase gene and that truncation of Ba-L to Ba-S occurred during the cultivation of B. subtilis X-23 cells. Although the primary structure of Ba-S was approximately 28% shorter than that of Ba-L, the two enzyme forms had the same enzymatic characteristics (molar catalytic activity, amylolytic pattern, transglycosylation ability, effect of pH on stability and activity, optimum temperature, and raw starch-binding ability), except that the thermal stability of Ba-S was higher than that of Ba-L. An analysis of the secondary structure as well as the predicted three-dimensional structure of Ba-S showed that Ba-S retained all of the necessary domains (domains A, B, and C) which were most likely to be required for functionality as α-amylase.     

Characteristics of two forms of alpha-amylases and structural implication.

Complete (Ba-L) and truncated (Ba-S) forms of alpha-amylases from Bacillus subtilis X-23 were purified, and the amino- and carboxyl-terminal amino acid sequences of Ba-L and Ba-S were determined. The amino acid sequence deduced from the nucleotide sequence of the alpha-amylase gene indicated that Ba-S was produced from Ba-L by truncation of the 186 amino acid residues at the carboxyl-terminal region. The results of genomic Southern analysis and Western analysis suggested that the two enzymes originated from the same alpha-amylase gene and that truncation of Ba-L to Ba-S occurred during the cultivation of B. subtilis X-23 cells. Although the primary structure of Ba-S was approximately 28% shorter than that of Ba-L, the two enzyme forms had the same enzymatic characteristics (molar catalytic activity, amylolytic pattern, transglycosylation ability, effect of pH on stability and activity, optimum temperature, and raw starch-binding ability), except that the thermal stability of Ba-S was higher than that of Ba-L. An analysis of the secondary structure as well as the predicted three-dimensional structure of Ba-S showed that Ba-S retained all of the necessary domains (domains A, B, and C) which were most likely to be required for functionality as alpha-amylase.     

Characterization of an Archaeal Cyclodextrin Glucanotransferase with a Novel C-Terminal Domain

A gene encoding a cyclodextrin glucanotransferase (CGTase) from Thermococcus kodakaraensis KOD1 (CGT(Tk)) was identified and characterized. The gene (cgt(Tk)) encoded a protein of 713 amino acid residues harboring the four conserved regions found in all members of the alpha-amylase family. However, the C-terminal domain corresponding to domain E of previously known CGTases displayed a completely distinct primary structure. In order to elucidate the catalytic function of the gene product, the recombinant enzyme was purified by anion-exchange chromatography, and its enzymatic properties were investigated. The enzyme displayed significant starch-degrading activity (750 U/mg of protein) with an optimal temperature and pH of 80 degrees C and 5.5 to 6.0, respectively. The presence of Ca(2+) enhanced the enzyme activity and elevated the optimum temperature to 85 to 90 degrees C. With the addition of Ca(2+), the enzyme showed extreme thermostability, with almost no loss of enzymatic activity after 80 min at 85 degrees C, and a half-life of 20 min at 100 degrees C. CGT(Tk) could hydrolyze soluble starch and glycogen but failed to hydrolyze pullulan. Most importantly, although CGT(Tk) harbored a unique C-terminal domain, we found that the protein also exhibited significant CGTase activity, with beta-cyclodextrin as the main product. In order to identify the involvement, if any, of the C-terminal region in the CGTase activity, we analyzed a truncated protein (CGT(Tk)DeltaC) with 23 C-terminal amino acid residues deleted. CGT(Tk)DeltaC displayed similar properties in terms of starch-binding activity, substrate specificity, and thermostability, but unexpectedly showed higher starch-degrading activity than the parental CGT(Tk). In contrast, the cyclization activity of CGT(Tk)DeltaC was abolished. The results indicate that the presence of the structurally novel C-terminal domain is essential for CGT(Tk) to properly catalyze the cyclization reaction.     

Two additional carbohydrate-binding sites of beta-amylase from Bacillus cereus var. mycoides are involved in hydrolysis and raw starch-binding

In the previous X-ray crystallographic study, it was found that beta-amylase from Bacillus cereus var. mycoides has three carbohydrate-binding sites aside from the active site: two (Site2 and Site3) in domain B and one (Site1) in domain C. To investigate the roles of these sites in the catalytic reaction and raw starch-binding, Site1 and Site2 were mutated. From analyses of the raw starch-binding of wild-type and mutant enzymes, it was found that Site1 contributes to the binding affinity to raw-starch more than Site2, and that the binding capacity is maintained when either Site1 or Site2 exists. The raw starch-digesting ability of this enzyme was poor. From inhibition studies by maltitol, GGX and alpha-CD for hydrolyses of maltopentaose (G5) and amylose ( (n) = 16) catalyzed by wild-type and mutant enzymes, it was found that alpha-CD is a competitive inhibitor, while, maltitol behaves as a mixed-type or competitive inhibitor depending on the chain length of the substrate and the mutant enzyme. From the analysis of the inhibition mechanism, we conclude that the bindings of maltitol and GGX to Site2 in domain B form an abortive ESI complex when amylose ( (n) = 16) is used as a substrate.     

Expression of modified xynA gene fragments from Bacillus subtilis BE-91

Expression of modified xynA gene fragments in Escherichia coli BL21 was studied, using the complete xynA gene from Bacillus subtilis BE-91 as the positive control. The technical workflow consisted of the following steps: (1) predicting protein structures relative to the xynA gene; (2) designing primers for modifiers; (3) amplifying the modifiers; (4) integrating the modifiers with the pET-28a(+) vector; (5) transferring the recombinant plasmids into E. coli BL21; (6) evaluating and analyzing the expression of modified cells. The results were: (1) the xynA gene from BE-91 with the untranslated region deleted on both ends was able to promote XynA activity by 28.9 %; (2) deletion of the 1- to 16-amino acid (AA) coding sequence in the open reading frame on the 5′-end, deletion of the 209- to 213-AA fragment on the 3′-end and deletion of the 20 AA on both ends could promote XynA activity by 27.2, 27.7 and 24.0 %,respectively; (3) deletion of the 1- to 29-AA fragment on the 5′-end and deletion of the 197- to 213-AA fragment on the 3′-end could reduce XynA activity dramatically by 95.6 and 74.8 %, respectively; (4) inactivation factors of XynA would be either the first β-fold and the hydrophilic structure domain or the last two α-screws and the seventeenth turn region. The results mean that any deletion in the catalytic domain would lead to a decline or inactivation in XynA activity while the deletion of any sequence outside the catalytic domain could effectively promote XynA activity, as such sequences are unnecessary for XynA function.     

A Functional Raw Starch-Binding Domain of Barley α-Amylase Expressed in Escherichia coli

The mature form of barley seed low-pI α-amylase (BAA1) possesses a raw starch-binding site in addition to the catalytic site. A truncated cDNA encoding the C-terminal region (aa 281–414) and containing the proposed raw starch-binding domain (SBD) but lacking Trp278/Trp279, a previously proposed starch granule-binding site, was synthesized via PCR and expressed in Escherichia coli as an N-terminal His-Tag fusion protein. SBD was produced in the form of insoluble inclusion bodies that were extracted with urea and successfully refolded into a soluble form via dialysis. To determine binding, SBD was purified by affinity chromatography with cycloheptaamylose as ligand cross-linked to Sepharose. This work demonstrates that a SBD is located in the C-terminal region and retains sufficient function in the absence of the N-terminal, catalytic, and Trp278/279 regions.     

Structure of raw starch-digesting Bacillus cereus beta-amylase complexed with maltose.

The crystals of beta-amylase from Bacillus cereus belong to space group P21 with the following cell dimensions: a = 57.70 A, b = 92.87 A, c = 65.93 A, and beta =101.95 degrees. The structures of free and maltose-bound beta-amylases were determined by X-ray crystallography at 2.1 and 2.5 A with R-factors of 0.170 and 0.164, respectively. The final model of the maltose-bound form comprises 516 amino acid residues, four maltose molecules, 275 water molecules, one Ca2+, one acetate, and one sulfate ion. The enzyme consists of a core (beta/alpha)8-barrel domain (residues 5-434) and a C-terminal starch-binding domain (residues 435-613). Besides the active site in the core where two maltose molecules are bound in tandem, two novel maltose-binding sites were found in the core L4 region and in the C-terminal domain. The structure of the core domain is similar to that of soybean beta-amylase except for the L4 maltose-binding site, whereas the C-terminal domain has the same secondary structure as domain E of cyclodextrin glucosyltransferase. These two maltose-binding sites are 32-36 A apart from the active site. These results indicate that the ability of B. cereus beta-amylase to digest raw starch can be attributed to the additional two maltose-binding sites.     

Domain E of Bacillus macerans cyclodextrin glucanotransferase: An independent starch-binding domain

The starch-binding domains of glucoamylase I (SBD of GA-I) from Aspergillus awamori and of cyclodextrin glucanotransferase (domain E of CGTase) from Bacillus macerans were fused to the C-terminus of beta-galactosidase (beta-gal) The majority of the fusion proteins produced in Escherichia coli were found as inclusion bodies. Active fusion proteins were purified by partial solubilization of the inclusion bodies with 2 M urea followed by affinity chromatography. Adsorption isotherms of purified fusion proteins on corn starch and cross-linked amylose were generated. The beta-gal fusion proteins had similar affinities for cross-linked amylose and corn starch but significantly different saturation capacities on corn starch. The adsorption and elution data from the potato starch column as well as the adsorption isotherms of p-gal-domain E fusion protein (BDE109) on corn starch and cross-linked amylose demonstrated that domain E of CGTase is an independent domain, which retained its starch-binding activity when separated from the other four (A-D) domains in CGTase. (c) 1995 John Wiley & Sons Inc.     

Deletion analysis of the C-terminal region of the alpha-amylase of Bacillus sp. strain TS-23

The alpha-amylase from Bacillus sp. strain TS-23 is a secreted starch hydrolase with a domain organization similar to that of other microbial alpha-amylases and an additional functionally unknown domain (amino acids 517-613) in the C-terminal region. By sequence comparison, we found that this latter domain contained a sequence motif typical for raw-starch binding. To investigate the functional role of the C-terminal region of the alpha-amylase of Bacillus sp. strain TS-23, four His(6)-tagged mutants with extensive deletions in this region were constructed and expressed in Escherichia coli. SDS-PAGE and activity staining analyses showed that the N- and C-terminally truncated alpha-amylases had molecular masses of approximately 65, 58, 54, and 49 kDa. Progressive loss of raw-starch-binding activity occurred upon removal of C-terminal amino acid residues, indicating the requirement for the entire region in formation of a functional starch-binding domain. Up to 98 amino acids from the C-terminal end of the alpha-amylase could be deleted without significant effect on the raw-starch hydrolytic activity or thermal stability. Furthermore, the active mutants hydrolyzed raw corn starch to produce maltopentaose as the main product, suggesting that the raw-starch hydrolytic activity of the Bacillus sp. strain TS-23 alpha-amylase is functional and independent from the starch-binding domain.     

A functional raw starch-binding domain of barley alpha-amylase expressed in Escherichia coli

The mature form of barley seed low-pI -amylase (BAA1) possesses a raw starch-binding site in addition to the catalytic site. A truncated cDNA encoding the C-terminal region (aa 281–414) and containing the proposed raw starch-binding domain (SBD) but lacking Trp278/Trp279, a previously proposed starch granule-binding site, was synthesized via PCR and expressed in Escherichia coli as an N-terminal His-Tag fusion protein. SBD was produced in the form of insoluble inclusion bodies that were extracted with urea and successfully refolded into a soluble form via dialysis. To determine binding, SBD was purified by affinity chromatography with cycloheptaamylose as ligand cross-linked to Sepharose. This work demonstrates that a SBD is located in the C-terminal region and retains sufficient function in the absence of the N-terminal, catalytic, and Trp278/279 regions.     

Starch-Binding Domain Affects Catalysis in Two Lactobacillus α-Amylases

A new starch-binding domain (SBD) was recently described in α-amylases from three lactobacilli (Lactobacillus amylovorus, Lactobacillus plantarum, and Lactobacillus manihotivorans). Usually, the SBD is formed by 100 amino acids, but the SBD sequences of the mentioned lactobacillus α-amylases consist of almost 500 amino acids that are organized in tandem repeats. The three lactobacillus amylase genes share more than 98% sequence identity. In spite of this identity, the SBD structures seem to be quite different. To investigate whether the observed differences in the SBDs have an effect on the hydrolytic capability of the enzymes, a kinetic study of L. amylovorus and L. plantarum amylases was developed, with both enzymes acting on several starch sources in granular and gelatinized forms. Results showed that the amylolytic capacities of these enzymes are quite different; the L. amylovorus α-amylase is, on average, 10 times more efficient than the L. plantarum enzyme in hydrolyzing all the tested polymeric starches, with only a minor difference in the adsorption capacities.     

Distinct Characteristics of Single Starch-Binding Domain SBD1 Derived from Tandem Domains SBD1-SBD2 of Halophilic <Emphasis Type="Italic">Kocuria varians</Emphasis> Alpha-Amylase

Kocuria varians alpha-amylase contains tandem starch-binding domains SBD1-SBD2 (SBD12) that possess typical halophilic characteristics. Recombinant tandem domains SBD12 and single domain SBD1, both with amino-terminal hexa-His tag, were expressed in and purified to homogeneity from Escherichia coli. The circular dichroism (CD) spectrum of His-SBD12 was characterized by a positive peak at 233 nm ascribed to the aromatic stacking. Although the signal occurred in the far UV region, it is an indication of tertiary structure folding. CD spectrum of single domain His-SBD1 exhibited the same peak position, signal intensity and spectral shape as those of His-SBD12, suggesting that the aromatic stacking must occur within the domain, and that two SBD domains in SBD12 and SBD1 has a similar folded structure. This structural observation was consistent with the biological activity that His-SBD1 showed binding activity against raw starch granules and amylose resin with 70–80% efficiency compared with binding of equimolar His-SBD12. Although the thermal unfolding rate of SBD12 and SBD1 were similar, the refolding rates of SBD12 and SBD1 from thermal melting were greatly different: His-SBD12 refolded slowly (T_1/2 = ~84 min), while refolding of single domain His-SBD1 was found to be 20-fold faster (T_1/2 = 4.2 min). The possible mechanism of this large difference in refolding rate was discussed. Maltose at 20 mM showed 5–6 °C increase in thermal melting of both His-SBD12 and His-SBD1, while its effects on the time course of unfolding and refolding were insignificant.     

Complexes of Thermoactinomyces vulgaris R-47 alpha-amylase 1 and pullulan model oligossacharides provide new insight into the mechanism for recognizing substrates with alpha-(1,6) glycosidic linkages

Thermoactinomyces vulgaris R-47 alpha-amylase 1 (TVAI) has unique hydrolyzing activities for pullulan with sequence repeats of alpha-(1,4), alpha-(1,4), and alpha-(1,6) glycosidic linkages, as well as for starch. TVAI mainly hydrolyzes alpha-(1,4) glycosidic linkages to produce a panose, but it also hydrolyzes alpha-(1,6) glycosidic linkages with a lesser efficiency. X-ray structures of three complexes comprising an inactive mutant TVAI (D356N or D356N/E396Q) and a pullulan model oligosaccharide (P2; [Glc-alpha-(1,6)-Glc-alpha-(1,4)-Glc-alpha-(1,4)]2 or P5; [Glc-alpha-(1,6)-Glc-alpha-(1,4)-Glc-alpha-(1,4)]5) were determined. The complex D356N/P2 is a mimic of the enzyme/product complex in the main catalytic reaction of TVAI, and a structural comparison with Aspergillus oryzaealpha-amylase showed that the (-) subsites of TVAI are responsible for recognizing both starch and pullulan. D356N/E396Q/P2 and D356N/E396Q/P5 provided models of the enzyme/substrate complex recognizing the alpha-(1,6) glycosidic linkage at the hydrolyzing site. They showed that only subsites -1 and -2 at the nonreducing end of TVAI are effective in the hydrolysis of alpha-(1,6) glycosidic linkages, leading to weak interactions between substrates and the enzyme. Domain N of TVAI is a starch-binding domain acting as an anchor in the catalytic reaction of the enzyme. In this study, additional substrates were also found to bind to domain N, suggesting that domain N also functions as a pullulan-binding domain.     

Activity and thermal stability of genetically truncated forms of Aspergillus glucoamylase

Glucoamylase (GA) from Aspergillus awamori (EC 3.2.1.3) is a secreted starch hydrolase with a large catalytic domain (aa 1-440), a starch-binding domain (aa 513-616), and a highly O-glycosylated region of 72 aa of unknown function that links the catalytic and starch-binding domains. We have genetically engineered a series of truncated forms of GA to determine how much of the highly O-glycosylated region is necessary for the activity or stability of GAII, a fully active form of the enzyme that lacks the starch-binding domain. Mutations were made by inserting stop-codon linkers into restriction sites within the coding region of the GA gene, and mutated genes were expressed in Saccharomyces cerevisiae for analysis of the truncated enzymes. Our results show that up to 30 aa from the C-terminal end of GAII can be deleted with little effect on the activity, thermal stability, or secretion of the enzyme. Further deletions resulted in diminution or loss of enzyme activity on starch plates, and loss of detectable enzyme in culture supernatants, indicating that these residues are essential for GAII function.     

Complex structures of Thermoactinomyces vulgaris R-47 alpha-amylase 1 with malto-oligosaccharides demonstrate the role of domain N acting as a starch-binding domain

The X-ray structures of complexes of Thermoactinomyces vulgaris R-47 alpha-amylase 1 (TVAI) with an inhibitor acarbose and an inactive mutant TVAI with malto-hexaose and malto-tridecaose have been determined at 2.6, 2.0 and 1.8A resolution, and the structures have been refined to R-factors of 0.185 (R(free)=0.225), 0.184 (0.217) and 0.164 (0.200), respectively, with good chemical geometries. Acarbose binds to the catalytic site of TVAI, and interactions between acarbose and the enzyme are very similar to those found in other structure-solved alpha-amylase/acarbose complexes, supporting the proposed catalytic mechanism. Based on the structure of the TVAI/acarbose complex, the binding mode of pullulan containing alpha-(1,6) glucoside linkages could be deduced. Due to the structural difference caused by the replaced amino acid residue (Gln396 for Glu) in the catalytic site, malto-hexaose and malto-tridecaose partially bind to the catalytic site, giving a mimic of the enzyme/product complex. Besides the catalytic site, four sugar-binding sites on the molecular surface are found in these X-ray structures. Two sugar-binding sites in domain N hold the oligosaccharides with a regular helical structure of amylose, which suggests that the domain N is a starch-binding domain acting as an anchor to starch in the catalytic reaction of the enzyme. An assay of hydrolyzing activity for the raw starches confirmed that TVAI can efficiently hydrolyze raw starch.     

A Structural Hinge in Eukaryotic MutY Homologues Mediates Catalytic Activity and Rad9-Rad1-Hus1 Checkpoint Complex Interactions

The DNA glycosylase MutY homologue (MYH or MUTYH) removes adenines misincorporated opposite 8-oxoguanine as part of the base excision repair pathway. Importantly, defects in human MYH (hMYH) activity cause the inherited colorectal cancer syndrome MYH-associated polyposis. A key feature of MYH activity is its coordination with cell cycle checkpoint via interaction with the Rad9-Rad1-Hus1 (9-1-1) complex. The 9-1-1 complex facilitates cell cycle checkpoint activity and coordinates this activity with ongoing DNA repair. The interdomain connector (IDC, residues 295-350) between the catalytic domain and the 8-oxoguanine recognition domain of hMYH is a critical element that maintains interactions with the 9-1-1 complex. We report the first crystal structure of a eukaryotic MutY protein, a fragment of hMYH (residues 65-350) that consists of the catalytic domain and the IDC. Our structure reveals that the IDC adopts a stabilized conformation projecting away from the catalytic domain to form a docking scaffold for 9-1-1. We further examined the role of the IDC using Schizosaccharomyces pombe MYH as model system. In vitro studies of S. pombe MYH identified residues I261 and E262 of the IDC (equivalent to V315 and E316 of the hMYH IDC) as critical for maintaining the MYH/9-1-1 interaction. We determined that the eukaryotic IDC is also required for DNA damage selection and robust enzymatic activity. Our studies also provide the first evidence that disruption of the MYH/9-1-1 interaction diminishes the repair of oxidative DNA damage in vivo. Thus, preserving the MYH/9-1-1 interaction contributes significantly to minimizing the mutagenic potential of oxidative DNA damage.     

Cloning and characterization of a recombinant family 5 endoglucanase from Bacillus licheniformis strain B-41361

The gene encoding a family 5 endoglucanase, cel5A, was cloned from the moderate thermophile Bacillus licheniformis strain B-41361. The primary structure of the translated cel5A gene predicts a 49 amino acid putative secretion signal and a 485 residue endoglucanase consisting of an N-terminal family 5 catalytic domain and C-terminal family 3 cellulose binding domain. The endoglucanase portion of the gene was expressed in Escherichia coli, but soluble activity in cell lysates was due to a truncated enzyme with an apparent mass of 42 kDa, the equivalent of the predicted catalytic domain. Insoluble protein renatured from inclusion bodies was protected against truncation, yielding an active holoenzyme (rCel5A) with apparent mass of 62 kDa. The recombinant rCel5A was optimally active at 65 °C and pH 6.0, but retained only 10% activity after 1 h incubation at this temperature. At 55 °C, rCel5A had a broad pH range for activity and stability, with greater than 75% relative activity from pH 4.5–7.0, and retaining greater than 80% relativity activity across the range pH 4.5–8.0 following 1 h incubation at 55 °C. It readily hydrolyzed pNPC, carboxymethylcellulose, barley β-glucan, and lichenan, but despite binding to cellulose, had only weak activity against avicel. Hydrolysis products from soluble polysaccharides included glucose, cellobiose, cellotriose, and cellotetraose. The catalytic properties, broad pH range and thermostability of the recombinant B. licheniformis endoglucanase may prove suitable for industrial applications.     

Differences and similarities in enzymes from the neopullulanase subfamily isolated from thermophilic species

Six glycoside hydrolase (GH) family 13 members, classified under the polyspecific neopullulanase subfamily GH13_20 (also termed cyclomaltodextrinase) were analysed. They originate from thermophilic bacterial strains (Anoxybacillus flavithermus, Laceyella sacchari, and Geobacillus thermoleovorans) or from environmental DNA, collected after in situ enrichments in Icelandic hot springs. The genes were isolated following the CODEHOP consensus primer strategy, utilizing the first two of the four conserved sequence regions in GH13. The typical domain structure of GH13_20, including an N-terminal domain (classified as CBM34), the catalytic module composed of the A-and B-domains, and a C-terminal domain, was found in five of the encoded enzymes (abbreviated Amy1, 89, 92, 98 and 132). These five enzymes degraded cyclomaltodextrins (CDs) and starch, while only three, Amy92 (L. sacchari), Amy98 (A. flavithermus) and Amy132 (environmental DNA), also harboured neopullulanase activity. The L. sacchari enzyme was monomeric, but with CD as the preferred substrate, which is an unusual combination. The sixth enzyme (Amy29 from environmental DNA), was composed of the ABC-domains only. Preferred substrate for Amy29 was pullulan, which was degraded to panose, and the enzyme had no detectable activity on CDs. In addition to its different activity profile and domain composition, Amy29 also displayed a different conservation (LPKF) in the fifth conserved region (MPKL) proposed to identify the subfamily. All enzymes had apparent temperature optima in the range 50–65°C, while thermostability varied, and was highest for Amy29 with a half-life of 480 min at 80°C. Calcium dependent activity or stability was monitored in four enzymes, but could not be detected for Amy29 or 98. Tightly bound calcium can, however, not be ruled out, and putative calcium ligands were conserved in Amy98.