Marked variations in patterns of cellulase activity against crystalline- vs. carboxymethyl-cellulose in the digestive systems of diverse, wood-feeding termites

Abstract.  Throughout the history of studies on cellulose digestion in termites, carboxymethyl-cellulose has been preferably used as a substrate for measuring cellulase activity in termites due to its high solubility. However, carboxymethyl-cellulose degradation is not directly related to digestibility of naturally occurring cellulose because many noncellulolytic organisms can also hydrolyse carboxymethyl-cellulose. To address this issue, a comparative study of microcrystalline cellulose digestion is performed in diverse xylophagous termites, using gut homogenates. For those termites harbouring gut flagellates , the majority of crystalline cellulose appears to be digested in the hindgut, both in the supernatant and the pellet. For Nasutitermes takasagoensis , a termite free of gut flagellates, crystalline cellulose is degraded primarily in the midgut supernatant, and partially in the pellet of the hindgut. The fungus-growing termite Odontotermes formosanus , which also does not possess intestinal flagellates, shows only a trace of crystalline cellulose hydrolysis throughout the gut. Comparison of levels of activity against crystalline cellulose with previously reported levels of activity against carboxymethyl-cellulose in the gut of each termite reveals significant differences between these activities. The results suggest that the hindgut flagellates produce commonly cellobiohydrolases in addition to endo-β-1,4-glucanases, which presumably act synergistically to digest cellulose. Preliminary evidence for the involvement of bacteria in the cellulose digestion of N. takasagoensis is also found.     

Role of bacteria in maintaining the redox potential in the hindgut of termites and preventing entry of foreign bacteria

The hindgut of the lower termites, Mastotermes darwiniensis and Coptotermes lacteus and the higher termite Nasutitermes exitiosus were made aerobic by exposure of the termites to pure oxygen, a procedure which killed their spirochaetes and their protozoa (lower termites only). The time taken for the hindgut to become anaerobic after the termites were restored to normal atmospheric conditions ranged from 2 to 4.5 hr. After oxygen treatment the number of gut bacteria increased some six- to ten-fold in all termite species, indicating that the bacteria are poised to use oxygen entering the gut. Removal of all the hindgut microbiota by feeding tetracycline caused the hindgut to become aerobic in M. darwiniensis and N. exitiosus. The transferring of M. darwiniensis to fresh wood, free of antibiotic, resulted in the return of the normal flora and the eventual establishment of anaerobic conditions in the hindgut. Thus the bacteria appear to be important in maintaining anaerobic conditions in the gut. Attempts to determine whether the protozoa (in the lower termites) played any part in maintaining the Eh of the hindgut were unsuccessful. Serratia marcescens failed to colonise the gut of normal C. lacteus and transiently colonized (for 5 days) the gut of normal N. exitiosus. Transient colonization by S. marcescens (from 6 to 10 days) occurred in N. exitiosus when its hindgut spirochaetes were killed and in C. lacteus when its spirochaetes and protozoa were killed, indicating a possible role for the spirochaetes and/or protozoa in influencing the bacteria allowed to reside in the hindgut. Exposure of normal termites to Serratia provoked an increase in the numbers of the normal gut bacteria.     

Cellulose digestion in termites and cockroaches: What role do symbionts play?

• 1.1. Termites and cockroaches are excellent models for studying the role of symbionts in cellulose digestion in insects: they eat cellulose in a variety of forms and may or may not have symbionts.
• 2.2. The wood-eating cockroach, Panesthia cribrata, can be maintained indefinitely, free of microorganisms, on a diet of crystalline cellulose. Under these conditions the RQ is 1, indicating that the cockroach is surviving on glucose produced by endogenous cellulase.
• 3.3. The in vitro rate at which glucose is produced from crystalline cellulose by gut extracts from P. cribrata and Nasutitermes walkeri is comparable to the in vivo production of CO₂ in these insects, clearly indicating that the rate of glucose production from crystalline cellulose is sufficient for their needs.
• 4.4. In all termites and cockroaches examined, cellulase activity was found in the salivary glands and predominantly in the foregut and midgut. These regions are the normal sites of secretion of digestive enzymes and are either devoid of microorganisms (salivary glands) or have very low numbers.
• 5.5. Endogeneous cellulases from termites and cockroaches consist of multiple endo-β-1,4-glucanase (EC 3.2.1.4) and β-1,4-glucosidase (EC 3.2.1.21) components. There is no evidence that an exo-β-1,4-glucanase (cellobiohydrolase) (EC 3.2.1.91) is involved in, or needed for, the production of glucose from crystalline cellulose in termites or cockroaches as the endo-β-1,4-glucanase components are active against both crystalline cellulose and carboxymethylcellulose.
• 6.6. There is no evidence that bacteria are involved in cellulose digestion in termites and cockroaches. The cellulase associated with the fungus garden of M. michaelseni is distinct from that in the midgut; there is little indication that the fungal enzymes are acquired or needed. Lower termites such as Coptotermes lacteus have Protozoa in their hindgut which produce a cellulase(s) quite distinct from that in the foregut and midgut.

     

Aerobic state of gut of Nasutitermes exitiosus and Coptotermes lacteus, high and low caste termites

The redox potential and pH of the gut of the termites Nasutitermes exitiosus and Coptotermes lacteus was investigated by feeding the insects with redox dyes and pH indicators. For N. exitiosus the E′₀ (pH 7.0) of the foregut was above +200 mV; the midgut was about +100 to +150 mV and the hindgut was in the region of ?20 to +30 mV. For C. lacteus the fore- and midgut were about +30 to +50 mV and the hindgut about ?20 to +20 mV. The colours of the ingested dyes indicated that the gut was aerobic in both termites. The pH of the whole gut ranged from 6.5 to 7.5 for N. exitiosus and 6.0 to 7.0 for C. lacteus.     

Correlation of cellulase gene expression and cellulolytic activity throughout the gut of the termite Reticulitermes flavipes

Termites have developed cellulose digestion capabilities that allow them to obtain energy and nutrition from nutritionally poor food sources, such as lignocellulosic plant material and residues derived from it (e.g., wood and humus). Lower termites, which are equipped with both endogenous (i.e., of termite origin) and symbiotic cellulases, feed primarily on wood and wood-related materials. This study investigated cellulase gene diversity, structure, and activity in the lower termite, Reticulitermes flavipes (Kollar). We initially used a metagenomics approach to identify four genes encoding one endogenous and three symbiotic cellulases, which we refer to as Cell-1, -2, -3 and -4. These four genes encode proteins that share significant sequence similarity with known endoglucanases, exoglucanases and xylanases. Phylogenetic analyses further supported these inferred relationships by showing that each of the four cellulase proteins clusters tightly with respective termite, protozoan or fungal cellulases. Gene structure studies revealed that Cell-1, -3 and -4 are intron-free, while Cell-2 contains the first intron sequence to be identified from a termite symbiont cellulase. Quantitative real-time PCR (qRT-PCR) revealed that the endogenous Cell-1 gene is expressed exclusively in the salivary gland/foregut, whereas symbiotic Cell-2, -3, and -4 are highly expressed in the hindgut (where cellulolytic protists are harbored). Cellulase activity assays mapped the distribution pattern of endoglucanase, exoglucanase and xylanase activity throughout the R. flavipes digestive tract. Cellulase gene expression correlated well with the specific types of cellulolytic activities observed in each gut region (foregut+salivary gland, midgut and hindgut). These results suggest the presence of a single unified cellulose digestion system, whereby endogenous and symbiotic cellulases work sequentially and collaboratively across the entire digestive tract of R. flavipes.     

16S rRNA metagenomic analysis of the symbiotic community structures of bacteria in foregut,midgut, and hindgut of the wood-feeding termite <Emphasis Type="Italic">Bulbitermes</Emphasis> sp.

The termite gut is a highly structured microhabitat with physicochemically distinct regions. It is generally separated into the foregut, midgut and hindgut. The distribution of gut microbiota is greatly influenced by varying physicochemical conditions within the gut. Thus, each gut compartment has a unique microbial population structure. In this study, the bacterial communities of foregut, midgut and hindgut of wood-feeding higher termite, Bulbitermes sp. were analyzed in detail via metagenomic sequencing of the 16S rRNA V3-V4 region. While the microbiomes of the foregut and midgut shared a similar taxonomic pattern, the hindgut possessed more diverse bacterial phylotypes. The communities in the foregut and midgut were dominated by members of the group Bacilli and Clostridia (Firmicutes) as well as taxon Actinomycetales (Actinobacteria). The main bacterial lineage found in hindgut was Spirochaetaceae (Spirochaetes). The significant difference among the three guts was the relative abundance of the potential lignin-degrading bacteria, Actinomycetales, in both the foregut and midgut. This suggests that lignin modification was probably held in the anterior part of termite gut. Predictive functional profiles of the metagenomes using 16S rRNA marker gene showed that cell motility, energy metabolism and metabolism of cofactors and vitamins were found predominantly in hindgut microbiota, whereas xenobiotics degradation and metabolism mostly occurred in the foregut segment. This was compatible with our 16S rRNA metagenomic results showing that the lignocellulose degradation process was initiated by lignin disruption, increasing the accessibility of celluloses and hemicelluloses.     

Hidden cellulases in termites: revision of an old hypothesis

The intestinal flagellates of termites produce cellulases that contribute to cellulose digestion of their host termites. However, 75% of all termite species do not harbour the cellulolytic flagellates; the endogenous cellulase secreted from the midgut tissue has been considered a sole source of cellulases in these termites. Using the xylophagous flagellate-free termites Nasutitermes takasagoensis and Nasutitermes walkeri, we successfully solubilized cellulases present in the hindgut pellets. Zymograms showed that the hindguts of these termites possessed several cellulases and contained up to 59% cellulase activity against crystalline cellulose when compared with the midgut. Antibiotic treatment administered to N. takasagoensis significantly reduced cellulase activity in the hindgut, suggesting that these cellulases were produced by symbiotic bacteria.     

Enzymes of acetate and glucose metabolism in termites

Extracts of tissues of the lower termites, Reticulitermes flavipes and Coptotermes lacteus, and the higher termite, Nasutitermes exitiosus, possess acetyl-CoA synthetase and all the enzymes of the tricarboxylic acid cycle and are thus able to oxidize acetate to CO₂. The specific activities of these enzymes in R. flavipes are sufficient to cope with the rate of acetogenesis by the gut microbiota. The presence of the malic enzyme and malate dehydrogenase, but not pyruvate carboxylase or phosphoenolpyruvate carboxykinase, indicates that they may be important as anaplerotic enzymes for the conversion of pyruvate to oxalacetate. An apparent absence of pyruvate dehydrogenase in all termites suggests that they do not convert pyruvate to acetyl-CoA, but rather convert acetate (transported from the hindgut) to this compound. All the enzymes of glycolysis were present in termite extracts. Thus any glucose absorbed from the midgut, and originating from hydrolysis of cellulose by salivary or midgut enzymes, can be metabolized by termites as an energy source.     

Symbiotic "Archaezoa" of the primitive termite Mastotermes darwiniensis still play a role in cellulase production

The relictual Mastotermes darwiniensis is one of the world's most destructive termites. Like all phylogenetically basal termites, it possesses protozoa in its hindgut, which are believed to help it digest wood. L. Li, J. Frohlich, P. Pfeiffer, and H. Konig (Eukaryot. Cell 2:1091-1098, 2003) recently cloned the genes encoding cellulases from the protozoa of M. darwiniensis; however, they claimed that these genes are essentially inactive, not contributing significantly to cellulose digestion. Instead, they suggested that the protozoa sequester enzymes produced by the termite in its salivary glands and use these to degrade cellulose in the hindgut. We tested this idea by performing gel filtration of enzymes in extracts of the hindgut, as well as in a combination of the salivary glands, foregut, and midgut. Three major cellulases were found in the hindgut, each of which had a larger molecular size than termite-derived salivary gland enzymes. N-terminal amino acid sequencing of one of the hindgut-derived enzymes showed that it was identical to the putative amino acid sequence of one mRNA sequence isolated by Li et al. (Eukaryot. Cell 2:1091-1098, 2003). The overall activity of the hindgut cellulases was found to be of approximately equal magnitude to the termite-derived cellulases detected in the mixture of salivary gland, foregut, and midguts. Based on these results, we conclude that, contrary to Li et al. (Eukaryot. Cell 2:1091-1098, 2003), the hindgut protozoan fauna of M. darwiniensis actively produce cellulases, which play an important role in cellulose digestion of the host termite.     

Dual cellulose-digesting system of the wood-feeding termite,Coptotermes formosanus Shiraki

The distribution of endo-beta-1,4-glucanase (EG) components in the digestive system of the wood-feeding termite, Coptotermes formosanus Shiraki, was investigated by zymogram analysis using polyacrylamide gel electrophoresis, followed by N-terminal protein sequencing. EG components similar to glycoside hydrolase family (GHF) 9 members were restricted to the salivary glands, the foregut, and the midgut, whereas components similar to GHF7 members were confined to the hindgut where numerous cellulolytic flagellates were harbored. RT-PCR experiments revealed that five GHF9 EG mRNAs (1348 bp) homologous to other termite EGs were expressed in the salivary glands and the midgut. The crude extract prepared from the midgut as well as that from the hindgut produced glucose from crystalline cellulose. These data suggest that C. formosanus has two independent cellulose-digesting systems: one in the midgut where cellulose digestion is accomplished by endogenous cellulases and the other in the hindgut which makes use of other cellulases possibly from symbiotic flagellates.     

Occurrence and metabolic role of the pyruvate dehydrogenase complex in the lower termite Coptotermes formosanus (Shiraki)

The activities of the pyruvate dehydrogenase complex in extracts of the gutted body, head, foregut/midgut and hindgut (hindgut epithelium and microorganisms) tissues of the lower termite Coptotermes formosanus (Shiraki) were determined by measuring the [¹⁴C]-acetyl-CoA produced from [2-¹⁴C]-pyruvate and the ¹⁴CO₂ produced from [1-¹⁴C]-pyruvate. The activities of pyruvate dehydrogenase, l-lactate dehydrogenase, acetyl-CoA synthetase, malate dehydrogenase (decarboxylating), and acetate kinase in the termite tissues and the hindgut also were determined. The sum (7.1 nmol/termite/h) of the pyruvate dehydrogenase complex activities in the termite tissues other than the hindgut was five times higher than the activity in the hindgut. Significant amounts of l-lactate dehydrogenase activity were found in all of the tissues. All of the tissues other than the hindgut had significant amounts of acetyl-CoA synthetase activity. Malate dehydrogenase (decarboxylating) activity was about ten times higher in the hindgut extract than in the gutted body and head extracts and the activity in the foregut/midgut extract was very low. These results indicate that acetyl-CoA for the TCA cycle is produced effectively in the tissues of the termite itself, both from pyruvate by the pyruvate dehydrogenase complex and from acetate by acetyl-CoA synthetase.     

Carbohydrases and carbohydrate digestion in the gut of Locusta migratoria

The digestion of various carbohydrates and synthetic substrates by the gut of Locusta migratoria was analysed quantitatively. Maltose, starch, and sucrose were found to be hydrolysed most rapidly, whereas the splitting of cellobiose, trehalose, lactose, and melecitose took place at much slower rates.The absolute carbohydrase activities in foregut and midgut are nearly equal. However, specific activities are much higher in the foregut. Only low activities were found in extracts from the hindgut and salivary glands. The latter show a pattern of sugar splitting which is different from that found in gut preparations.The distribution of carbohydrase activities between the epithelia and lumina of the foregut, midgut, and hindgut and between soluble and particulate fractions were studied. The midgut epithelium is shown to have a particularly high content of enzymes, although some carbohydrases are rather active also in the epithelium of the hindgut. During hunger periods the relative enzymatic activities of the epithelium are distinctly increased.The isolation and purification of the carbohydrases were attempted and a partial separation of individual enzymes was obtained by gel-filtration. These results indicate the presence of at least seven distinct carbohydrases in the locust gut. The molecular weights of the enzymes were estimated by gel-filtration, and K_M values and pH-optima are reported.     

Aromatic compound degradation by the wood-feeding termite Coptotermes formosanus (Shiraki)

Wood-feeding termites (WFT) have proven to be highly efficient for wood digestion. There is evidence to support the hypothesis that there are ligninolytic enzymes existing in the gut of WFT responsible for wood pretreatment toward cellulose utilization. Elucidating the mechanism of biomass pretreatment through lignin modification in termites will help to develop more efficient lignocellulosic biofuel production processes. The in-vivo degradation of aromatic compounds with different substructures, including dyes, lignin model monomers and dimers, and lignin sulfonate, by Coptotermes formosanus (Shiraki) was investigated. The degradation of aromatic compounds was determined using pyrolysis-gas chromatography/mass spectrometry. The results revealed that WFT were able to metabolize the conjugated aromatic structures and that the degradation efficiency is higher in the foregut and midgut regions than in the hindgut. This is the first time that evidence has been provided to show different aromatic compound degradation in the separate gut segments of a termite. This study provides information on the C. formosanus (Shiraki) lignin modification phenomenon, and it demonstrates that phenomenon’s potential in the breakdown of the plant cell wall. Understanding this lignin modification could contribute to technology that will supplant current harsh pretreatment protocols for plant cell walls and thereby better facilitate the conversion of cellulose and hemicellulose.     

Dual origin of gut proteases in Formosan subterranean termites (Coptotermes formosanus Shiraki) (Isoptera: Rhinotermitidae)

Cellulose digestion in lower termites, mediated by carbohydrases originating from both termite and endosymbionts, is well characterized. In contrast, limited information exists on gut proteases of lower termites, their origins and roles in termite nutrition. The objective of this study was to characterize gut proteases of the Formosan subterranean termite (Coptotermes formosanus Shiraki) (Isoptera: Rhinotermitidae). The protease activity of extracts from gut tissues (fore-, mid- and hindgut) and protozoa isolated from hindguts of termite workers was quantified using hide powder azure as a substrate and further characterized by zymography with gelatin SDS-PAGE. Midgut extracts showed the highest protease activity followed by the protozoa extracts. High level of protease activity was also detected in protozoa culture supernatants after 24 h incubation. Incubation of gut and protozoa extracts with class-specific protease inhibitors revealed that most of the proteases were serine proteases. All proteolytic bands identified after gelatin SDS-PAGE were also inhibited by serine protease inhibitors. Finally, incubation with chromogenic substrates indicated that extracts from fore- and hindgut tissues possessed proteases with almost exclusively trypsin-like activity while both midgut and protozoa extracts possessed proteases with trypsin-like and subtilisin/chymotrypsin-like activities. However, protozoa proteases were distinct from midgut proteases (with different molecular mass). Our results suggest that the Formosan subterranean termite not only produces endogenous proteases in its gut tissues, but also possesses proteases originating from its protozoan symbionts.     

Characterization of four esterase genes and esterase activity from the gut of the termite Reticulitermes flavipes

Four esterase genes and general esterase activity were investigated in the gut of the termite Reticulitermes flavipes. Two genes (RfEst1 and RfEst2) share significant translated identity with a number of insect JH esterases. The two remaining genes (RfEst3 and RfEst4) apparently code for much shorter proteins with similarity to fungal phenolic acid esterases involved in hemicellulose solubilization. All four genes showed consistently high midgut expression. This result was further supported by colorimetric activity assays and Native polyacrylamide gel electrophoresis, which showed significant esterase activity and a number of isoforms in the midgut. The greatest esterase activity and isoform composition were detected when α‐naphthyl propionate was used as a substrate. Moreover, esterase activity and diverse isoforms were present in gut mitochondrial, microsomal, and cytosolic sub‐cellular protein fractions, as well as in the hindgut lumen. These findings reveal an agreement between gut esterase gene expression and activity distributions, and support the idea that R. flavipes gut esterase activity is host (not symbiont)‐derived. In addition, these findings support the hypotheses that termite gut esterases may play important roles in lignocellulose digestion and caste differentiation. This study provides important baseline data that will assist ongoing functional‐genomic efforts to identify novel genes with roles in semiochemical, hormone, and lignocellulose processing in the termite gut. © 2009 Wiley Periodicals, Inc.     

高效降解木质纤维素的白蚁肠道微生物组

木食性白蚁是自然界木质纤维素的高效降解者,在长期进化过程中白蚁与其肠道微生物组协同作用发展出不同的纤维素降解机制。木食性白蚁具有分别来源于白蚁和共生微生物的两套纤维素酶系统。在低等白蚁中,木质颗粒经过白蚁前、中肠分泌的内源性酶初步消化后,在后肠共生鞭毛虫中被降解为乙酸、二氧化碳和氢。高等木食性白蚁在进化中丢失了鞭毛虫,木质颗粒经白蚁自身分泌的酶初步消化后,在后肠大量共生细菌的帮助下被有效降解。培菌类白蚁利用其菌圃中的蚁巢伞菌和肠道微生物协同作用降解木质纤维素。共生微生物在白蚁的氮素固定与循环、中间产物代谢及纤维素降解等过程中发挥了重要作用。学习和模拟白蚁高效降解木质纤维素的体系,对生物质能源的产业化发展具有积极的意义。     

Foxh1 and Foxa2 are not required for formation of the midgut and hindgut definitive endoderm

The definitive endoderm forms during gastrulation and is rapidly transformed into the gut tube which is divided along the anterior-posterior axis into the foregut, midgut, and hindgut. Lineage tracing and genetic analysis have examined the origin of the definitive endoderm during gastrulation and demonstrated that the majority of definitive endoderm arises at the anterior end of the primitive streak (APS). Foxh1 and Foxa2 have been shown to play a role in specification of the APS and definitive endoderm. However, prior studies have focused on the role of these factors in specification of foregut definitive endoderm, while their role in the specification of midgut and hindgut definitive endoderm is less understood. Furthermore, previous analyses of these mutants have utilized definitive endoderm markers that are restricted to the anterior endoderm, expressed in extraembryonic endoderm, or present in other germ layers. Here, we characterized the expression of several novel definitive and visceral endoderm markers in Foxh1 and Foxa2 null embryos. In accordance with previous studies, we observed a deficiency of foregut definitive endoderm resulting in incorporation of visceral endoderm into the foregut. Interestingly, this analysis revealed that formation of midgut and hindgut definitive endoderm is unaffected by loss of Foxh1 or Foxa2. This finding represents a significant insight into specification and regionalization of mouse definitive endoderm.     

Functional and translational analyses of a beta-glucosidase gene (glycosyl hydrolase family 1) isolated from the gut of the lower termite Reticulitermes flavipes

This research focused on digestive beta-glucosidases from glycosyl hydrolase family (GHF) 1 from the gut of the lower termite Reticulitermes flavipes. In preceding studies on R. flavipes, we characterized beta-glucosidase activity across the gut and its inhibition by carbohydrate-based inhibitors, and subsequently we identified two partial beta-glucosidase cDNA sequences from a host gut cDNA library. Here, we report on the full-length cDNA sequence for one of the R. flavipes beta-glucosidases (RfBGluc-1), the expression of its mRNA in the salivary gland and foregut, the production of recombinant protein using a baculovirus–insect expression system, optimal recombinant substrate specificity profiles and parameters, and significant inhibition by the established beta-glucosidase inhibitor cellobioimidazole. We also report the partial cDNA sequence for a second gut beta-glucosidase (RfBGluc-2), and show that like RfBGluc-1 its mRNA is localized mainly in the salivary gland. Other results for RfBGluc-1 showing activity against laminaribose, a component of microbial cell walls, suggest that RfBGluc-1 may serve dual functions in cellulose digestion and immunity. These findings provide important information that will enable the testing of hypotheses related to collaborative host–symbiont lignocellulose digestion, and that contributes to the development of next-generation termiticides and novel biocatalyst cocktails for use in biomass-to-bioethanol applications.