Regulation of beta-1,4-Endoglucanase Synthesis in Thermomonospora fusca

In Thermomonospora fusca YX, endocellulase synthesis varies over a 100-fold range depending on the carbon source used. This study shows that the variation is caused by two regulatory mechanisms: an induction mechanism that increases the rate of endocellulase synthesis about 20-fold and a growth rate-dependent repression mechanism that changes the rate of synthesis over a 6-fold range in both induced and noninduced cells. In T. fusca, endocellulase synthesis can be induced by cellulose, cellobiose, or cellodextrin. Cellulase is involved in inducer generation from cellulose. Growth rate-dependent repression can be reversed by limiting cultures for carbon, nitrogen, or, to a lesser extent, phosphorus. Further evidence for two separate regulatory mechanisms is provided by the isolation of mutants (CC-1 and CC-2) whose endocellulases are synthesized constitutively but are still sensitive to growth rate-dependent repression. These conclusions about total endocellulase synthesis were extended to the individual endocellulases by showing that three T. fusca endocellulases are coordinately regulated.     

Biochemistry and Genetics of Actinomycete Cellulases

Abstract

The order Actinomycetales includes a number of genera that contain species that actively degrade cellulose and these include both mesophilic and facultative thermophilic species. Cellulases produced by strains from two of the genera containing thermophilic organisms have been studied extensively: Microbispora bispora and Thermomonospora fusca. Fractionation of M. bispora cellulases has identified six different enzymes, all of which were purified to near homogeneity and partially characterized. Two of these enzymes appear to be exocellulases and gave synergism with each other and with the endocellulases. The structural genes of five M. bispora cellulases have been cloned and one was sequenced. Fractionation of T. fusca cellulases has identified five different enzymes, all of which were purified to near homogeneity and partially characterized. One of the T. fusca enzymes gives synergism in the hydrolysis of crystalline cellulose with several T. fusca endocellulases and with Trichoderma reesei CBHI but not with T. reesei CBHII. Each T. fusca cellulase contains distinct catalytic and cellulose binding domains. The structural genes of four of the T. fusca endoglucanases have been cloned and sequenced, while three cellulase genes have been cloned from “T. curvata”. The T. fusca cellulase genes are expressed at a low level in Escherichia coli, but at a high level in Streptomyces lividans. Sequence comparisons have shown that there are no significant amino acid homologies between any of the catalytic domains of the four T. fusca cellulases, but each of them shows extensive homology to several other cellulases and fits in one of the five existing cellulase gene families. There have been extensive studies of the regulation of the synthesis of these cellulases and a number of regulatory mutants have been isolated. This work has shown that the different T. fusca cellulases are coordinately regulated over a 100-fold range by two independent controls; induction by cellobiose and repression by any good carbon source.     

Characterization of the cellulolytic enzyme system from the brown-rot fungus Coniophora puteana

Summary The cellulolytic enzymes of various strains of the brown-rot fungus Coniophora puteana were studied. The organism was grown in an air-lift fermentor in mineral medium containing glucose, cellobiose or amorphous cellulose. The specific growth rate varied between 0.082 and 0.062 h^–1. On amorphous cellulose as sole carbon source, the organism secreted various proteins, some of which were characterized. The mixture contained inter alia four endocellulases, two exo-cellobiohydrolases and a cellobiose dehydrogenase. Three endocellulases (named type I) were active on soluble cellulose derivatives but inactive on p-nitrophenyllactoside (p-NPL), whereas a fourth endocellulase (named type II) was active on both. The two exo-cellobiohydrolases released cellobiose from amorphous cellulose; they were inactive on soluble cellulose derivatives but hydrolyzed p-NPL with strong cellobiose inhibition. A cellobiose dehydrogenase having spectral characteristics compatible with a flavo b-cytochrome was also identified. Neither the exo-cellobiohydrolase nor the type II endocellulase were secreted during growth on cellobiose whereas type I endocellulases and cellobiose dehydrogenase were formed at a reduced rate. No formation of cellulolytic enzymes was observed during growth on glucose alone. Correspondence to: G. Canevascini     

Expression of a Thermomonospora fusca Cellulase Gene in Streptomyces lividans and Bacillus subtilis

A cellulase gene from Thermomonospora fusca coding for endocellulase E₅ was introduced into Streptomyces lividans by using shuttle plasmids that can replicate in either S. lividans or Escherichia coli. Plasmid DNA isolated from E. coli was used to transform S. lividans, selecting for thiostrepton resistance. The transformants expressed and excreted the endocellulase, but the ability to produce the endocellulase was unstable. This instability was shown to result from deletion of the endocellulase gene from the plasmid. Plasmid DNA prepared from a culture in which plasmid modification had occurred was used to transform E. coli, selecting for Amp⁺ cells, and all of the transformants were cellulase positive, showing that pBR322 and T. fusca DNA were deleted together. When a plasmid was constructed containing only T. fusca DNA in plasmid pIJ702, the transformants were more stable, and the level of endocellulase activity produced in the culture supernatant after growth on 0.2% glucose was close to the level produced by T. fusca cultures grown on 0.2% cellulose. About 50% of the total protein in the culture supernatant of the S. lividans transformant was endocellulase E₅. The enzyme produced by the S. lividans transformant was identical to pure T. fusca E₅ in its electrophoretic mobility and was completely inhibited by antiserum to E₅. Shuttle plasmids containing the E₅ gene that could replicate in Bacillus subtilis and E. coli were also constructed and used to transform B. subtilis. Again there was extensive deletion of the plasmid DNA during transformation and growth in B. subtilis. There was no evidence of E₅ activity, even in those B. subtilis transformants that retained the E₅ gene.     

Biochemistry and genetics of actinomycete cellulases.

The order Actinomycetales includes a number of genera that contain species that actively degrade cellulose and these include both mesophilic and facultative thermophilic species. Cellulases produced by strains from two of the genera containing thermophilic organisms have been studied extensively: Microbispora bispora and Thermomonospora fusca. Fractionation of M. bispora cellulases has identified six different enzymes, all of which were purified to near homogeneity and partially characterized. Two of these enzymes appear to be exocellulases and gave synergism with each other and with the endocellulases. The structural genes of five M. bispora cellulases have been cloned and one was sequenced. Fractionation of T. fusca cellulases has identified five different enzymes, all of which were purified to near homogeneity and partially characterized. One of the T. fusca enzymes gives synergism in the hydrolysis of crystalline cellulose with several T. fusca endocellulases and with Trichoderma reesei CBHI but not with T. reesei CBHII. Each T. fusca cellulase contains distinct catalytic and cellulose binding domains. The structural genes of four of the T. fusca endoglucanases have been cloned and sequenced, while three cellulase genes have been cloned from "T. curvata". The T. fusca cellulase genes are expressed at a low level in Escherichia soli, but at a high level in Streptomyces lividans. Sequence comparisons have shown that there are no significant amino acid homologies between any of the catalytic domains of the four T. fusca cellulases, but each of them shows extensive homology to several other cellulases and fits in one of the five existing cellulase gene families. There have been extensive studies of the regulation of the synthesis of these cellulases and a number of regulatory mutants have been isolated. This work has shown that the different T. fusca cellulases are coordinately regulated over a 100-fold range by two independent controls; induction by cellobiose and repression by any good carbon source.     

An Apparent Cellulase Complex in Tomato (Lycopersicon esculentum L.) Fruit

Four enzyme-containing fractions were separated by ammonium sulfate fractionation of 2-day, postbreaker tomato (Lycopersicon esculentum L. cv. Manhattan). The pH optima and substrate specificities are reported. The enzymes were identified as a nonspecific β-glucosidase, an exo-β-1,4-glucanase, and two endocellulases. Both endocellulase fractions were able to catalyze the hydrolysis of various insoluble cellulose materials.     

Processivity,Synergism, and Substrate Specificity of Thermobifida fusca Cel6B

A relationship between processivity and synergism has not been reported for cellulases, although both characteristics are very important for hydrolysis of insoluble substrates. Mutation of two residues located in the active site tunnel of Thermobifida fusca exocellulase Cel6B increased processivity on filter paper. Surprisingly, mixtures of the Cel6B mutant enzymes and T. fusca endocellulase Cel5A did not show increased synergism or processivity, and the mutant enzyme which had the highest processivity gave the poorest synergism. This study suggests that improving exocellulase processivity might be not an effective strategy for producing improved cellulase mixtures for biomass conversion. The inverse relationship between the activities of many of the mutant enzymes with bacterial microcrystalline cellulose and their activities with carboxymethyl cellulose indicated that there are differences in the mechanisms of hydrolysis for these substrates, supporting the possibility of engineering Cel6B to target selected substrates.Cellulose is a linear homopolymer of β-1,4-linked anhydrous glucosyl residues with a degree of polymerization (DP) of up to 15,000 (5). Adjacent glucose residues in cellulose are oriented at an angle of 180° to each other, making cellobiose the basic unit of cellulose structure (5). The β-1,4-glycosidic bonds of cellulose are enzymatically hydrolyzed by three classes of cellulases. Endocellulases (EC 3.2.1.4) cleave cellulose chains internally, generating products of variable length with new chain ends, while exocellulases, also called cellobiohydrolases (EC 3.2.1.91), act from one end of a cellulose chain and processively cleave off cellobiose as the main product. The third class is the processive endocellulases, which can be produced by bacteria (2, 20).Processivity and synergism are important properties of cellulases, particularly for hydrolysis of crystalline substrates. Processivity indicates how far a cellulase molecule proceeds and hydrolyzes a substrate chain before there is dissociation. Processivity can be measured indirectly by determining the ratio of soluble products to insoluble products in filter paper assays (14, 19, 39). Although this approach might not discriminate exocellulases from highly processive endocellulases (12), it is very helpful for comparing mutants of the same enzyme (19). The processivity of some glycoside hydrolases also can be determined from the ratio of dimers to monomers in the hydrolysate (13).Four types of synergism have been demonstrated in cellulase systems: synergism between endocellulases and exocellulases, synergism between reducing- and nonreducing-end-directed exocellulases, synergism between processive endocellulases and endo- or exocellulases, and synergism between β-glucosidases and other cellulases (3). Synergism is dependent on a number of factors, including the physicochemical properties of the substrate and the ratio of the individual enzymes (10).Great effort has been focused on improving enzymatic hydrolysis of cellulases in biomass (24). However, studying biomass is difficult due to its complexity; instead, nearly pure cellulose, amorphous cellulose, or carboxymethyl cellulose (CMC) are commonly used as substrates (22).Random mutagenesis approaches and rational protein design have been used to study cellulose hydrolysis (18), to improve the activity of catalytic domains and carbohydrate-binding modules (19), and to thermostabilize cellulases (9). Increased knowledge of cellulase structures and improvements in modeling software (1) have facilitated rational protein design. The structures of five glycoside hydrolase family 6 cellulases from four microorganisms, Trichoderma reesei (23), Thermobifida fusca (26), Humicola insolens (6, 29), and Mycobacterium tuberculosis (30), have been determined. Structural analysis showed that the active sites of the exocellulases are enclosed by two long loops forming a tunnel, while the endocellulases have an open active site groove. Movement of one of these loops is important for enzymatic activity (6, 35, 37).In nature, as well as for industrial applications, mixtures of cellulase are required; therefore, a better strategy for designing individual enzymes to improve the activity of mixtures is critical. In this study, we used Cel6B, a nonreducing-end-directed, inverting exocellulase from Thermobifida fusca, a thermophilic soil bacterium, as a model cellulase to investigate the impact of improved exocellulases in mixtures with endocellulases since T. fusca Cel6B is important for achieving the maximum activity of synergistic mixtures (35). Cel6B activity is similar to that of the fungal T. reesei exocellulase Cel6A, but Cel6B has higher thermostability and a much broader pH optimum (36). Six noncatalytic residues in the active site tunnel of T. fusca exocellulase Cel6B were mutated to obtain insight into the role of these residues in processivity and substrate specificity. Two mutant enzymes that showed higher activity with filter paper and processivity were investigated further for production of oligosaccharides and synergism to analyze the relationship between processivity and synergism.     

Influence of carbon source on production of a heat stable protease from Thermomonospora fusca YX

Summary Thermomonospora fusca YX produced a very active heat stable protease when incubated in media containing cellulose as the substrate. Cultures grown on Solka-floc generated the highest amount of protease whereas the protease was produced at significantly lower levels when T. fusca YX was grown on cellobiose or glucose. Negligible growth or protease production was observed when protein was used as a carbon source. The production of the protease did not appear to be constitutive. While rapid growth was observed on either cellobiose or glucose, protease levels were at least two to fourfold lower than for the T. fusca YX cultures grown on Solka-floc wich generated 33% less cell mass. Protease production was four times lower in cultures which employed casein hydrolysate (tryptone) or xylan as carbon sources than for cellulose.     

Regulation of Biosynthesis of Individual Cellulases in Thermomonospora fusca

Regulation of the biosynthesis of the six cellulases comprising the cellulolytic system of the thermophilic soil bacterium Thermomonospora fusca ER1 was studied. The levels of the individual enzymes produced on different noninducing and inducing carbon sources were determined. The lowest level of cellulase synthesis (3 nM) was observed with xylose as a carbon source, and the highest level (247 to 1,670 nM for different enzymes) was found in cultures grown on microcrystalline cellulose. Endocellulases and exocellulases showed distinctly different regulation patterns. Differences in the regulation of individual enzymes appear to be determined by the specific structural organization of the upstream regulatory sequences of their genes.     

Metabolic engineering of a laboratory‐evolved Thermobifida fusca muC strain for malic acid production on cellulose and minimal treated lignocellulosic biomass

Malic acid is mainly used as an acidulant and taste enhancer in the beverage and food industry. Previously, a mutant strain Thermobifida fusca muC, obtained by adaptive evolution was found to accumulate malic acid on cellulose with low yield. In this study, the malic acid synthesis pathway in T. fusca muC was confirmed to be from phosphoenolpyruvate to oxaloacetate, followed by reduction of oxaloacetate to malate. To increase the yield of malic acid by the muC strain significantly, the carbon flux from pyruvate was redirected to oxaloacetate by expressing an exogenous pyruvate carboxylase (PCx) gene from Corynebacterium glutamicum ATCC 13032 in the chromosome of T. fusca muC‐16. The yield of malic acid in the engineered strain muC‐16 was increased by 47.9% compared to the parent strain muC. The muC‐16 strain was then grown on ～100 g/L cellulose and the highest titer of malic acid was 62.76 g/L by batch fermentation. T. fusca muC‐16 strain converted milled corn stover to malic acid with the highest titer of 21.47 g/L with minimal treatment. © 2016 American Institute of Chemical Engineers Biotechnol. Prog., 32:14–20, 2016     

A Distinct Model of Synergism between a Processive Endocellulase (TfCel9A) and an Exocellulase (TfCel48A) from Thermobifida fusca

Lignocellulosic biomass is digested in nature by the synergistic activities of enzymes with complementary properties, and understanding synergistic interactions will improve the efficiency of industrial biomass use for sustainable fuels and chemicals. Cel9A and Cel48A from a model bacterium, Thermobifida fusca (TfCel9A and TfCel48A, respectively), are two cellulases with different properties and have previously been shown to synergize well with each other. TfCel9A is a processive endocellulase with relatively high activity on crystalline cellulose. TfCel48A is a reducing end-directed exocellulase with very low activity on crystalline cellulose. Neither enzyme fits its respective role in the classical synergism model of enzymatic cellulose digestion. Using the results of time course, endpoint, and sequential addition activity assays, we propose a model of synergistic cooperation between the two cellulases. TfCel9A is most effective on fresh bacterial cellulose with a presumably uniform surface at the molecular level. Its processive activity likely erodes the surface and thus reduces its own activity. TfCel48A is able to hydrolyze the TfCel9A-modified substrate efficiently and replenish the uniform surface required by TfCel9A, creating a feedback mechanism. The model of synergistic interactions is comparable to an earlier proposed model for Trichoderma reesei Cel7A and Cel7B, but the roles of endo- and exocellulases are reversed, a finding which suggests that bacteria and fungi may have evolved different approaches to efficient biomass degradation.     

The Non-Catalytic Amino Acid Asp<Subscript>446</Subscript> Is Essential for Enzyme Activity of the Modular Endocellulase Cel9 from <Emphasis Type="Italic">Myxobacter</Emphasis> sp. AL-1

The modular endocellulase Cel9 of the bicistronic operon cel9-cel48 of Myxobacter sp. AL-1 shares not only amino acid sequence similarity but also biochemical properties similar to those of Thermobifida fusca endo/exocellulase E4. Amino acid alignments of a T. fusca E4 cellulase subfamily of family 9 cellulases revealed that Asp₄₄₆ of Myxobacter sp. AL-1 Cel9, a putatively noncatalytic residue, is highly conserved in one of the catalytic domains of this subfamily. Directed mutagenesis of residue aspartate (Asp₄₄₆) to alanine generated a Cel9 mutant that lost more than 99% of its activity, suggesting that Asp₄₄₆ plays an essential structural role in Cel9 during cellulose degradation. Owing to its high degree of conservation and essential role, we propose that Asp₄₄₆ of Myxobacter sp. AL-1 Cel9 is a good landmark that distinguishes members of the E4 subfamily of family 9 cellulases. Received: 4 May 2002 / Accepted: 5 July 2002     

Effect of molecular hydrogen on histidine utilization by Alcaligenes eutrophus

The effect of molecular hydrogen on heterotrophic metabolism of the facultative chemolithoautotrophic bacterium Alcaligenes eutrophus strain H 16 was representatively investigated on histidine utilization. The presence of hydrogen in a histidine or urocanate-containing medium had two effects (i) growth of the cells was inhibited, and (ii) formation of histidase was repressed. Both effects were relieved by supplying the cells with exogenous carbon dioxide. Studies on mutants defective in chemolithoautotrophic metabolism revealed that growth inhibition by hydrogen was exclusively mediated by the catalytic function of the soluble hydrogenase. Mutants containing only particulate hydrogenase activity did not exhibit growth inhibition. Repression of histidase formation, however, was mediated by the catalytic activity of the soluble as well as the particulate hydrogenase. Unexpectedly, mutants defective in autotrophic carbon dioxide fixation but unaffected in hydrogen oxidation showed an inhibition of growth by hydrogen but no repression of histidase synthesis. Mutants which formed histidase constitutively were still sensitive to repression in the presence of hydrogen. The results indicate that repression of enzyme synthesis by hydrogen is dependent on the function of both, the hydrogen-oxidizing and the carbon dioxide-fixing system. It is concluded that the hydrogen effect is a transient regulatory mechanism and only relevant for unbalanced conditions of growth.     

Metabolic engineering of Thermobifida fusca for direct aerobic bioconversion of untreated lignocellulosic biomass to 1-propanol

Biofuel production from renewable resources can potentially address lots of social, economic and environmental issues but an efficient production method has yet to be established. Combinations of different starting materials, organisms and target fuels have been explored with the conversion of cellulose to higher alcohols (1-propanol, 1-butanol) being one potential target. In this study we demonstrate the direct conversion of untreated plant biomass to 1-propanol in aerobic growth conditions using an engineered strain of the actinobacterium, Thermobifida fusca. Based upon computational predictions, a bifunctional butyraldehyde/alcohol dehydrogenase was added to T. fusca leading to 1-propanol production during growth on glucose, cellobiose, cellulose, switchgrass and corn stover. The highest 1-propanol titer (0.48 g/L) was achieved for growth on switchgrass. These results represent the first demonstration of direct conversion of untreated lignocellulosic biomass to 1-propanol in an aerobic organism and illustrate the potential utility of T. fusca as an aerobic, cellulolytic bioprocess organism.     

Reversibility and binding kinetics of Thermobifida fusca cellulases studied through fluorescence recovery after photobleaching microscopy

Cellulases are enzymes capable of depolymerizing cellulose. Understanding their interactions with cellulose can improve biomass saccharification and enzyme recycling in biofuel production. This paper presents a study on binding and binding reversibility of Thermobifida fusca cellulases Cel5A, Cel6B, and Cel9A bound onto Bacterial Microcrystalline Cellulose. Cellulase binding was assessed through fluorescence recovery after photobleaching (FRAP) at 23, 34, and 45 °C. It was found that cellulase binding is only partially reversible. For processive cellulases Cel6B and Cel9A, an increase in temperature resulted in a decrease of the fraction of cellulases reversibly bound, while for endocellulase Cel5A this fraction remained constant. Kinetic parameters were obtained by fitting the FRAP curves to a binding-dominated model. The unbinding rate constants obtained for all temperatures were highest for Cel5A and lowest for Cel9A. The results presented demonstrate the usefulness of FRAP to access the fast binding kinetics characteristic of cellulases operating at their optimal temperature.