Alan R. Lax

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 beta-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.

Carbohydrate‐active enzymes revealed in Coptotermes formosanus (Isoptera: Rhinotermitidae) transcriptome

Coptotermes formosanus is one of the most destructive wood‐feeding termites. To understand the molecular mechanisms that regulate the development of the termite, a normalized C. formosanus cDNA library was constructed using mixed RNA isolated from workers, soldiers, nymphs and alates of both sexes. The sequencing of this library generated 131 636 expressed sequence tags (ESTs) and 25 939 assembled unigenes. The carbohydrate‐active enzymes (CAZymes) revealed in this library were analysed in the present report. A total of 509 putative CAZymes were identified. Diverse cellulolytic enzymes were uncovered from both the host termite and from symbionts harboured by the termite, which were possibly the result of the high efficiency of cellulose utilization. CAZymes associated with trehalose biosynthetic and metabolic pathways were also identified, which are potential regulators of the physiological activities of trehalose, an important insect blood sugar. Representative CAZyme coding genes in glycoside hydrolase family 1 (GH1) were quantitatively analysed. The results showed that the five GH1 β‐glucosidase genes were expressed differentially among different castes and one of them was female alate‐specific. Overall, the normalized EST library provides a comprehensive genetic resource of C. formosanus and will serve a diverse range of research areas. The CAZymes represent one of the repositories of enzymes useful for physiological studies and applications in sugar‐based biofuel production.

Solid-phase microextraction for the detection of termite cuticular hydrocarbons

Solid-phase microextraction (SPME)-gas chromatography-mass spectrometry was used to identify the cuticular hydrocarbons of the subterranean termite Coptotermes formosanus Shiraki. Headspace SPME and direct contact SPME methods were evaluated and compared to the hexane extraction method. Variables, such as temperature, time, number of termites, condition of the termites, and the type of SPME fiber were evaluated. Methods were refined to increase the reproducibility as well as the sensitivity. Both SPME methods were successfully used for the identification of all the major termite cuticular hydrocarbons. Using the headspace SPME method, other compounds of interest could also be identified, such as fatty acids. Using the direct contact SPME method, termites could be repeatedly studied over time to monitor chemical changes.

Hydrolysis of filter-paper cellulose to glucose by two recombinant endogenous glycosyl hydrolases of Coptotermes formosanus

Abstract  Genes encoding for glycosyl hydrolases (GH) in multiple families were recovered from an expression sequence tag library of Coptotermes formosanus, a xylophagous lower termite species. Functional analyses of these genes not only shed light on the mechanisms the insect employs to successfully use cellulosic materials as energy sources, which may serve as strategic targets for designing molecular‐based bio‐pesticides, but also enrich discoveries of new cellulolytic enzymes for conversion of biomass into biofuel. Our study demonstrated that cellulose could be converted to glucose by two recombinant endogenous glycosyl hydrolases (endo‐β‐1,4 glucanase in GH9 and β‐glucosidase in GH1). While the former cleaved cellulose to cellobiose and cellotriose, the resulting simple cellodextrins were digested to glucose. Both of the Escherichia coli‐expressed recombinant proteins showed properties that could be incorporated in a glucose‐based ethanol production program.

Functional analyses of the digestive β-glucosidase of Formosan subterranean termites (Coptotermes formosanus).

The research was to elucidate the function of the β-glucosidase of Formosan subterranean termites in vitro and in vivo. The gene transcript was detected predominantly in the salivary gland tissue, relative to the midgut and the hindgut of the foraging worker caste, indicating salivary glands were the major expression sites of the β-glucosidase. Using recombinant β-glucosidase produced in Escherichia coli, the enzyme showed higher affinity and activity toward cellobiose and cellotriose than other substrates tested. In assessing impacts of specific inhibitors, we found that the β-glucosidase could be irreversibly inactivated by conduritol B epoxide (CBE) but not gluconolactone. Termite feeding assays showed that the CBE treatment reduced the glucose supply in the midgut and resulted in the body weight loss while no effect was observed for the gluconolactone treatment. These findings highlighted that the β-glucosidase is one of the critical cellulases responsible for cellulose degradation and glucose production; inactivation of these digestive enzymes by specific inhibitors may starve the termite.

Comparison of the enzymatic composition of cell-free extracts of non-aflatoxigenicAspergillus parasiticus with respect to late stages of aflatoxin biosynthesis

Cell-free extracts of fungal mycelia of two non-aflatoxigenic isolates ofAspergillus parasiticus (SRRC 163 and SRRC 2043) were examined for enzyme activities involved in the latter stages of aflatoxin biosynthesis. Post-microsomal fractions (105 Kxg supernatant) of both SRRC 163 (ATTC 56774) and SRRC 2043 were able to convert sterigmatocystin (ST) toO-methylsterigmatocystin (OMST); whereas the microsomal (105 Kxg pellet) preparation of only SRRC 163 was able to convert OMST to aflatoxin B1 (AFB1). A mixture of the microsomal fraction of SRRC 163 and post-microsomal fraction of SRRC 2043 converted ST to AFB1. Electrophoretic protein separations of the microsomal fractions of the twoA. parasiticus isolates on non-denaturing or denaturing polyacrylamide gel electrophoresis (PAGE) provided equivalent protein profiles.