Study of cellulases from a newly isolated thermophilic and cellulolytic <Emphasis Type="Italic">Brevibacillus</Emphasis> sp. strain JXL

A potentially novel aerobic, thermophilic, and cellulolytic bacterium designated as Brevibacillus sp. strain JXL was isolated from swine waste. Strain JXL can utilize a broad range of carbohydrates including: cellulose, carboxymethylcellulose (CMC), xylan, cellobiose, glucose, and xylose. In two different media supplemented with crystalline cellulose and CMC at 57°C under aeration, strain JXL produced a basal level of cellulases as FPU of 0.02 IU/ml in the crude culture supernatant. When glucose or cellobiose was used besides cellulose, cellulase activities were enhanced ten times during the first 24 h, but with no significant difference between these two simple sugars. After that time, however, culture with glucose demonstrated higher cellulase activities compared with that from cellobiose. Similar trend and effect on cellulase activities were also obtained when glucose or cellobiose served as a single substrate. The optimal doses of cellobiose and glucose for cellulase induction were 0.5 and 1%. These inducing effects were further confirmed by scanning electron microscopy (SEM) images, which indicated the presence of extracellular protuberant structures. These cellulosome-resembling structures were most abundant in culture with glucose, followed by cellobiose and without sugar addition. With respect to cellulase activity assay, crude cellulases had an optimal temperature of 50°C and a broad optimal pH range of 6–8. These cellulases also had high thermotolerance as evidenced by retaining more than 50% activity at 100°C after 1 h. In summary, this is the first study to show that the genus Brevibacillus may have strains that can degrade cellulose.     

Purification and properties of an exo-cellulase of Avicelase type from a wood-rotting fungus, Irpex lacteus (Polyporus tulipiferae).

A cellulase component of Avicelase type was obtained from Driselase, a commercial enzyme preparation from a wood-rotting fungus Irpex lacteus (Polyporus tulipiferae). It showed a single band on SDS-polyacrylamide electrophoresis. The amino acid composition of this cellulase resembled those of cellulase components of endo-type from the same fungus. However, it produced exclusively cellobiose from CMC as well as from water-insoluble celluloses such as Avicel or cotton at earlier stages of hydrolysis. In addition, the hydrolysis of CMC practically stopped after an initial rapid stage. The cellulase showed a strong synergistic action with an endo-cellulase of higher randomness (typical CMCase-type) in the hydrolysis of CMC as well as Avicel. In contrast to cellotriose and -tetraose, cellopentaose and -hexaose were attacked very rapidly, and only cellobiose was produced. These results suggest that the cellulase is an exo-type component. However, it mutarotated the products from cellopentaitol in the same direction as endo-cellulases. it represented a relatively large portion of the total cellulase activity, and may play an important role in the degradation of native cellulose in vivo.     

Enzymatic studies on a cellulase system of Trichoderma viride. III. Transglycosylation properties of two cellulase components of random type.

Two highly purified cellulases [EC 3.2.1.4], II-A, and II-B, were obtained from the cellulase system of Trichoderma viride. Both cellulases split cellopentaose retaining the beta-configuration of the anomeric carbon atoms in the hydrolysis products at both pH 3.5 and 5.0. The Km values of cellulases II-A and II-B for cellotetraose were different, but their Vmax values were similar and those for cellooligosaccharides increased in parallel with chain length. Both cellulases produced predominantly cellobiose and glucose from various cellulosic substrates as well as from higher cellooligosaccharides. Cellulase II-A preferentially attacked the holoside linkage of rho-nitrophenyl beta-D-cellobioside, whereas cellulase II-B attacked mainly the aglycone linkage of this cellobioside. Both cellulases were found to catalyze the synthesis of cellotriose from rho-nitrophenyl beta-D-cellobioside by transfer of a glucosyl residue, possibly to cellobiose produced in the reaction mixture. They were also found to catalyze the rapid synthesis of cellotetraose from cellobiose, with accompanying formation of cellotriose and glucose, which seemed to be produced by secondary random hydrolysis of the cellotetraose produced. The capacity to synthesize cellotetraose from cellobiose appeared to be greater with cellulase II-B than with cellulase II-A.     

Isolation and purification of isoenzymes of cellobiohydrolase I and II of trichoderma reesei using LPLC methods

Five cellulases were fractionated from a commercial cellulase preparation (Celluclast^TM) Two isoenzymes of cellobiohydrolase I (CBHI)(pI = 4.1) could be proved to be real exo-glucanases due to their activity towards MU (=methylumbelliferyl)-lactoside being inhibited by cellobiose (5 mM) and due to production of cellobiose from carboxymethylcellulose (CMC) as the sole final product.Two isoenzymes of CBHII (pI=6.15, 6.0) were shown to act as endo-glucanases because they produced glucose, cellobiose and cellotetraose from CMC and because they were not inhibited by cellobiose when decomposing MU-lactoside. Results confirm recent reports in the literature classifying CBHI and CBHII as exo-type and endo-type cellulases, respectively. Both the CBHI and the CBHII isoenzymes were shown to be active towards CMC and amorphous cellulose.CBHI and CBHII reactions could be differentiated from one another by the velocities of decomposition of CMC: CBHI acts slowly and linearly whereas CBHII acts strongly and exponentially.The fifth of the purified enzymes must be classed as a conventional endoglucanase which exhibits activity towards CMC but fails to be active towards MU-lactoside and amorphous cellulose.     

Purification and characterization of cellulase produced by Bacillus amyoliquefaciens DL-3 utilizing rice hull

A microorganism hydrolyzing rice hull was isolated from soil and identified as Bacillus amyloliquefaciens by analysis of 16S rDNA and partial sequences of the gyrA gene, and named as B. amyloliquefaciens DL-3. With the analysis of SDS-PAGE, the molecular weight of the purified cellulase was estimated to be 54kDa. The purified cellulase hydrolyzed avicel, caboxymethylcellulose (CMC), cellobiose, beta-glucan and xylan, but not p-Nitrophenyl-beta-D-glucopyranoside (PNPG). Optimum temperature and pH for the CMCase activity of the purified cellulase were found to be 50 degrees C and pH 7.0, respectively. The CMCase activity was inhibited by some metal ions, N-bromosuccinimide and EDTA in the order of Hg(2+)>EDTA>Mn(2+)>N-bromosuccinimide>Ni(2+)>Pb(2+)>Sr(2+)>Co(2+)>K(+). The open reading frame of the cellulase from B. amyloliquefaciens DL-3 was found to encode a protein of 499 amino acids. The deduced amino acid sequence of the cellulase from B. amyloliquefaciens DL-3 showed high identity to cellulases from other Bacillus species, a modular structure containing a catalytic domain of the glycoside hydrolase family 5 (GH5), and a cellulose-binding module type 3 (CBM3).     

Cellulose degradation and cellulase formation by Phialophora malorum

The formation of cellulases and -glucosidase and their location in the fungus Phialophora malorum was studied on some different carbon sources. The cellulases were found to be partly cell-free and partly cell-bound during growth on cellulose and carboxymethyl-cellulose. Glucose and cellobiose repressed the cellulase formation but a low carboxymethylcellulase activity was measurable on the glucose-grown mycelium. The unicellular stage did not appear to grow on carboxymethyl-cellulose or cellulose, but mycelium was formed on these carbon sources.     

Affinity chromatography of extracellular cellulase from chaetomium cellulolyticum

Summary An endo--glucanase of C.cellulolyticum was purified by a procedure involving concanavalin A (Con A)-Sepharose chromatography and polyacrylamide gel electrophoresis (PAGE). The enzyme produced G1 and oligosaccharides from CMC. Chromatography on Procion Red HE3B-Agarose proved to be useful in the separation of cellobiase from cellobiose dehydrogenase.Abbreviations CMC carboxymethyl cellulose - CM-cellulase carboxymethyl cellulase - FP-cellulase filter paper degrading cellulase - G1 glucose - G2 cellobiose - G3 cellotriose - G4 cellotetraose - G5 cellopentaose - G6 cellohexaose - G7 celloheptaose - -MG methyl--D-glucoside - pNPG p-nitrophenyl--glucopyranoside - pNP p-nitrophenol - CBDH cellobiose dehydrogenase     

Production and Purification of Thermostable Cellulases from Humicola insolens YH-8

Humicola insolens YH-8, a thermophilic fungus isolated from manure and compost heaps, produced a significant amount of thermostable cellulases in cultures on wheat bran medium (50°C, 4 days). The mold bran extract hydrolyzed Avicel, CMC and newsprint at 90%, 45% and 35%, respectively, to glucose. Then, Avicelase and CMCase were purified from the culture extract by adsorption onto Avicel, heat and acid treatment and consecutive column chromatographies to a homogeneous state on polyacrylamide gel disc electrophoresis. The purified cellulases, especially CMCase, was found highly thermostable. The optimal temperature of both enzymes was 50°C. Avicelase was stable after heating at 65°C for 5 mm and CMCase retained 45% of the original activity after heating at 95°C for 5 min.     

Phototoxicity of protoporphyrin as related to its subcellular localization in mice livers after short-term feeding with griseofulvin.

The substrate specificities of three cellulases and a beta-glucosidase purified from Thermoascus aurantiacus were examined. All three cellulases partially degraded native cellulose. Cellulase I, but not cellulase II and cellulase III, readily hydrolyzed the mixed beta-1,3; beta-1,6-polysaccharides such as carboxymethyl-pachyman, yeast glucan and laminarin. Both cellulase I and the beta-glucosidase degraded xylan, and it is proposed that the xylanase activity is an inherent feature of these two enzymes. Lichenin (beta-1,4; beta-1,3) was degraded by all three cellulases. Cellulase II cannot degrade carboxymethyl-cellulose, and with filter paper as substrate the end product was cellobiose, which indicates that cellulase II is an exo-beta-1,4-glucan cellobiosylhydrolase. Degradation of cellulose (filter paper) can be catalysed independently by each of the three cellulases; there was no synergistic effect between any of the cellulases, and cellobiose was the principal product of degradation. The mode of action of one cellulase (cellulase III) was examined by using reduced cellulodextrins. The central linkages of the cellulodextrins were the preferred points of cleavage, which, with the rapid decrease in viscosity of carboxymethyl-cellulose, confirmed that cellulase III was an endocellulase. The rate of hydrolysis increased with chain length of the reduced cellulodextrins, and these kinetic data indicated that the specificity region of cellulase III was five or six glucose units in length.     

Differential cellulolytic activity of native-form and C-terminal tagged-form cellulase derived from Coptotermes formosanus and expressed in E. coli

An endogenous cellulase gene (CfEG3a) of Coptotermes formosanus, an economically important pest termite, was cloned and overexpressed in both native form (nCfEG) and C-terminal His-tagged form (tCfEG) in Escherichia coli. Both forms of recombinant cellulases showed hydrolytic activity on cellulosic substrates. The nCfEG was more active and stable than tCfEG even though the latter could be purified to near homogeneity with a simple procedure. The differential activities of nCfEG and tCfEG were also evidenced by hydrolytic products they produced on different substrates. On CMC, both acted as an endoglucanase, randomly hydrolyzing internal β-1,4-glycosidic bonds and resulting in a smear of polymers with different lengths, although cellobiose, cellotriose, and cellotetraose equivalents were noticeable. The hydrolytic products of tCfEG were one unit sugar less than those produced by nCfEG. Using filter paper as substrate, however, the major hydrolytic products of nCfEG were cellobiose, cellotriose and trace of glucose; those of tCfEG were cellobiose, cellotriose and trace of cellotetraose, indicating a property similar to that of cellobiohydrolase, an exoglucanase. The results presented in this report uncovered the biochemical properties of the recombinant cellulase derived from the intact gene of Formosan subterranean termites. The recombinant cellulase would be useful in designing cellulase-inhibiting termiticides and incorporating into a sugar-based biofuel production program.     

Carboxymethylcellulase and avicelase activities from a cellulolytic Clostridium strain A11

The extracellular cellulase enzyme system of Clostridium A11 was fractionated by affinity chromatography on Avicel: 80% of the initial carboxymethylcellulase (CMCase) activity was adhered. This cellulase system was a multicomponent aggregate. Several CMCase activities were detected, but the major protein P1 had no detectable activity. Adhered and unadhered cellulases showed CMCase activity with the highest specific activity in Avicel-adhered fraction. However, only afhered fractions could degrade Avicel. Thus, efficiency of the enzymatic hydrolysis of Avicel was related to the cellulase-adhesion capacity. Carboxymethylcellulase and Avicelase activities were studied with the extracellular enzyme system and cloned cellulases. Genomic libraries from Clostridium A11 were constructed with DNA from this Clostridium, and a new gene cel1 was isolated. The gene(s) product(s) from cel1 exhibited CMCase and p-nitrophenylcellobiosidase (pNPCbase) activities. This cloned cellulase adhered to cellulose. Synergism between adhered enzyme system and cloned endoglucanases was observed on Avicel degradation. Conversely, no synergism was observed on CMC hydrolysis. Addition of cloned endoglucanase to cellulase complex led to increase of the V_max without significant K _m variation. Cloned endoglucanases can be added to cellulase complexes to efficiently hydrolyze cellulose.     

Activity studies of eight purified cellulases: Specificity, synergism, and binding domain effects

The activities of six purified Thermomonospora fusca cellulases and Trichoderma reesei CBHI and CBHII were determined on filter paper, swollen cellulose, and CMC. A simple method to measure the soluble and insoluble reducing sugar products from the hydrolysis of filter paper was found to effectively distinguish between exocellulases and endocellulases. Endocellulases produced 34% to 50% insoluble reducing sugar and exocellulases produced less than 8% insoluble reducing sugar. The ability of a wide variety of mixtures of these cellulases to digest 5.2% of a filter paper disc in 16 h was measured quantitatively. The specific activities of the mixtures varied from 0.41 to 16.31 mumol cellobiose per minute per micromole enzyme. The degree of synergism ranged from 0.4 to 7.8. T. reesei CBHII and T. fusca E3 were found to be functionally equivalent in mixtures. The catalytic domains (cd) of T. fusca endocellulases E2 and E5 were purified and found to retain 93% and 100% of their CMC activity, respectively, but neither cd protein could digest filter paper to 5.2%. When E2cd and E5cd were substituted in synergistic mixtures for the native proteins, the mixtures containing E2cd retained 60%, and those containing E5cd retained 94% of the original activity. Addition of a beta-glucosidase was found to double the activity of the best synergistic mixture. Addition of CBHI to T. fusca crude cellulase increased its activity on filter paper 1.7-fold. (c) 1993 John Wiley & Sons, Inc.     

Production and characterization of thermostable cellulases from Streptomyces transformant T3-1

A total of 26 thermophilic isolates, selected from a compost of agricultural waste, which was mostly composed of vegetable, corncob and rice straw, were cultivated at 50 °C for further studies of thermostable cellulase production. The thermostable cellulase gene from the chromosomal DNA of actinomycetes isolate no. 10 was shotgun-cloned and transformed into Streptomyces sp. IAF 10-164. A transformant, T3-1, was found to be a good strain for the production of thermostable cellulases. Cultivation of T3-1 in modified Mandels–Reese broth containing 1% carboxymethylcellulose (CMC)-sodium salt and the optimal condition for microbial growth were studied. Batch cultivation in a flask revealed that CMCase and Avicelase production reached the maximum between the third to fifth day, whereas maximum -glucosidase production occurred on the ninth day. Microbial biomass increased from the first day to the fifth day and then decreased. The crude enzyme had the highest activity at 50 °C and at pH 6.5. The enzyme was shown to be a thermostable cellulase whose activities were stable at 50 °C for more than 7 days.     

Characterization and substrate specificity of an endo-beta-1,4-D-glucanase I (Avicelase I) from an extracellular multienzyme complex of Bacillus circulans.

An endo-1,4-beta-D-glucanase I (Avicelase I; EC 3.2.1.4) was purified to homogeneity from an extracellular celluloxylanosome of Bacillus circulans F-2. The purification in the presence of 6 M urea yielded homogeneous enzyme. The enzyme had a monomeric structure, its relative molecular mass being 75 kDa as determined by gel filtration and 82 kDa as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The pI was 5.4, and the N-terminal amino acid sequence was ASNIGGWVGGNESGFEFG. The optimal pH was 4.5, and the enzyme was stable at pH 4 to 10. The enzyme has a temperature optimum of 50 degrees C, it was stable at 55 degrees C for 46 h, and it retains approximately 20% of its activity after 30 min at 80 degrees C. It showed high-level activity towards carboxymethyl cellulose (CMC) as well as p-nitrophenyl-beta-D-cellobioside, 4-methylumbelliferyl cellobioside, xylan, Avicel, filter paper, and some cello-oligosaccharides. Km values for birch xylan, CMC, and Avicel were 4.8, 7.2, and 87.0 mg/ml, respectively, while Vmax values were 256, 210, and 8.6 mumol x min-1 x mg-1, respectively. Cellotetraose was preferentially cleaved into cellobiose (G2) plus G2, and cellopentaose was cleaved into G2 plus cellotriose (G3), while cellohexaose was cleaved into cellotetraose plus G2 and to a lesser extent G3 plus G3. G3 was not cleaved at all. G2 was the main product of Avicel hydrolysis. Xylotetraose (X4) and xylobiose (X2) were mainly produced by the enzyme hydrolysis of xylan. G2 inhibited the activity of carboxymethyl cellulase and Avicelase, whereas Mg2+ stimulated it. The enzyme was completely inactivated by Hg2+, and it was inhibited by a thiol-blocking reagent. Hydrolysis of CMC took place, with a rapid decrease in viscosity but a slow liberation of reducing sugars. On the basis of these results, it appeared that the cellulase should be regarded as endo-type cellulase, although it hydrolyzed Avicel.     

Adsorption ofTrichoderma reesei cellulases on protein-extracted lucerne fibers

Summary Protein-extracted lucerne fibers (PELF) had a higher adsorptive capacity forTrichoderma reesei cellulases than a variety of other cellulosic substrates compared on an equal carbohydrate basis. Adsorption at room temperature reached a maximum at about 5 min; desorption was directly proportional to the extent of carbohydrate solubilization. Cellulase binding conformed to a Langmuir isotherm; the maximum cellulasebinding capacity of PELF was 111 filter paper units per g dry weight. About 85% of the cellulase was recovered in the soluble fraction after PELF hydrolysis. Soluble carbohydrates in the hydrolysate inhibited cellulase adsorption to fresh substrate (50% inhibition at a hydrolysate concentration of 7% glucose equivalents). The effect of these carbohydrates on cellulase adsorption was a complex one composed of both enhancing and inhibitory influences. Artificial hydrolysates (known sugars in proportions identical to actual hydrolysates) inhibited adsorption, but glucose, cellobiose and xylose resulted in adsorption enhancement. Acid treatment of the hydrolysate to convert oligosaccharides to monomers increased reducing sugar concentrations and eliminated its capacity for adsorption inhibition.     

Product binding varies dramatically between processive and nonprocessive cellulase enzymes

Cellulases hydrolyze β-1,4 glycosidic linkages in cellulose, which are among the most prevalent and stable bonds in Nature. Cellulases comprise many glycoside hydrolase families and exist as processive or nonprocessive enzymes. Product inhibition negatively impacts cellulase action, but experimental measurements of product-binding constants vary significantly, and there is little consensus on the importance of this phenomenon. To provide molecular level insights into cellulase product inhibition, we examine the impact of product binding on processive and nonprocessive cellulases by calculating the binding free energy of cellobiose to the product sites of catalytic domains of processive and nonprocessive enzymes from glycoside hydrolase families 6 and 7. The results suggest that cellobiose binds to processive cellulases much more strongly than nonprocessive cellulases. We also predict that the presence of a cellodextrin bound in the reactant site of the catalytic domain, which is present during enzymatic catalysis, has no effect on product binding in nonprocessive cellulases, whereas it significantly increases product binding to processive cellulases. This difference in product binding correlates with hydrogen bonding between the substrate-side ligand and the cellobiose product in processive cellulase tunnels and the additional stabilization from the longer tunnel-forming loops. The hydrogen bonds between the substrate- and product-side ligands are disrupted by water in nonprocessive cellulase clefts, and the lack of long tunnel-forming loops results in lower affinity of the product ligand. These findings provide new insights into the large discrepancies reported for binding constants for cellulases and suggest that product inhibition will vary significantly based on the amount of productive binding for processive cellulases on cellulose.     

Formation and release of cellulolytic enzymes during growth of Trichoderma reesei on cellobiose and glycerol

Summary Production and release of cellulolytic enzymes by Trichoderma reesei QM 9414 were studied under induced and non-induced conditions. For that purpose, a method was developmed to produce cellulases by Trichoderma reesei QM 9414 using the soluble inducer, cellobiose, as the only carbon source. The production was based on continuous feeding of cellobiose to a batch culture. For optimum production, the cellobiose supply had to be adjusted according to the consumption so that cellobiose was not accumulated in the culture. With a proper feeding program the repression and/or inactivation by cellobiose could be avoided and the cellulase production by Trichoderma reesei QM 9414 was at least equally as high as with cellulose as the carbon source.During the cultivation, specific activities against filter paper, carboxymethyl cellulose (CMC) and p-nitrophenyl glucoside were analyzed from the culture medium as well as from the cytosol and the cell debris fractions. There was a base level of cell debris bound hydrolytic activity against filter paper and p-nitrophenyl glucoside even in T. reesei grown non-induced on glycerol. T. reesei grown on cellobiose was induced to produce large amounts of extracellular filter paper and CMC hydrolyzing enzymes, which were actively released into the medium even in the early stages of cultivation. -Glucosidase was mainly detected in the cell debris and was not released unless the cells were autolyzing.     

The cellulolytic system of Streptomyces reticuli

The bacterium Streptomyces reticuli produces an unusual mycelia-associated cellulase (Avicelase, Cell) which is solely sufficient to degrade crystalline cellulose to cellobiose. The enzyme consists of a binding domain, one adjoining region with unknown function, and a catalytic domain belonging to the cellulase family E. During cultivation, the strain produces a specific protease which processes the Avicelase to a truncated enzyme lacking the binding domain. The cellulase synthesis is regulated by induction (Avicel) and repression (metabolizable sugars and glycerol).     

Screening and characterization of a cellulase gene from the gut microflora of abalone using metagenomic library

A metagenomic fosmid library was constructed using genomic DNA isolated from abalone intestine. Screening of a library of 3,840 clones revealed a 36 kb insert of a cellulase positive clone (pAMHElO). A shotgun clone library was constructed using the positive clone (pAMHElO) and further screening of 3,840 shotgun clones with an approximately 5 kb insert size using a Congo red overlay revealed only one cellulase positive clone (pAMHL9). The pAMHL9 consisted of a 5,293-bp DNA sequence and three open reading frames (ORFs). Among the three ORFs, cellulase activity was only shown in the recombinant protein (CelAMll) coded by ORF3, which showed 100% identity with outer membrane protein A from Vibrio alginolyticus 12G01, but no significant sequence homology to known cellulases. The expressed protein (CelAMll) has a molecular weight of approximately 37 kDa and the highest CMC hydrolysis activity was observed at pH 7.0 and 37°C. The carboxymethyl cellulase activity was determined by zymogram active staining and different degraded product profiles for CelAMll were obtained when cellotetraose and cellopentaose were used as the substrates, while no substrate hydrolysis was observed on oligosaccharides such as cellobiose and cellotriose.     

Cellulase production by a thermophilic clostridium species

Strain M7, a thermophilic, anaerobic, terminally sporing bacterium (0.6 by 4.0 μm) was isolated from manure. It degraded filter paper in 1 to 2 days at 60 C in a minimal cellulose medium but was stimulated by yeast extract. It fermented a wide variety of sugars but produced cellulase only in cellulose or carboxymethyl-cellulose media. Cellulase synthesis not only was probably repressed by 0.4% glucose and 0.3% cellobiose, but also cellulase activity appeared to be inhibited by these sugars at these concentrations. Both C₁ cellulase (degrades native cellulose) and C_x cellulase (β-1,4-glucanase) activities in strain M7 cultures were assayed by measuring the liberation of reducing sugars with dinitrosalicylic acid. Both activities had optima at pH 6.5 and 67 C. One milliliter of a 48-h culture of strain M7 hydrolyzed 0.044-meq of glucose per min from cotton fibers. The cellulase(s) from strain M7 was extracellular, produced during exponential growth, but was not free in the growth medium until approximately 30% of the cellulose was hydrolyzed. Glucose and cellobiose were the major soluble products liberated from cellulose by the cellulase. ZnCl₂ precipitation appeared initially to be a good method for the concentration of cellulase activity, but subsequent purification was not successful. Isoelectric focusing indicated the presence of four C_x cellulases (pI 4.5, 6.3, 6.8, and 8.7). The rapid production and high activity of cellulases from this organism strongly support the basic premise that increased hydrolysis of native cellulose is possible at elevated temperature.