Localization of Symbiotic Clostridia in the Mixed Segment of the Termite Nasutitermes takasagoensis (Shiraki)

doi:10.1128/AEM.66.5.2199-2207.2000

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Applied and Environmental Microbiology, May 2000, p. 2199-2207, Vol. 66, No. 5
0099-2240/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.

Localization of Symbiotic Clostridia in the Mixed Segment of the Termite Nasutitermes takasagoensis (Shiraki)

Gaku Tokuda,¹ Ikuo Yamaoka,² and Hiroaki Noda³^,^*

Bio-oriented Technology Research Advancement Institution, Nisshin-cyo, Omiya, Saitama 331-8537,¹ Department of Biology, Physics and Informatics, Faculty of Science, Yamaguchi University, Yoshida, Yamaguchi 753-8512,² and National Institute of Sericultural and Entomological Science, Owashi, Tsukuba, Ibaraki 305-8634,³ Japan

Received 31 August 1999/Accepted 7 February 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

Phylogeny and the distribution of symbiotic bacteria in the mixed segment of the wood-eating termite Nasutitermes takasagoensis(Shiraki) were studied. Bacterial 16S rRNA genes (rDNA) were amplifiedfrom the mixed segment of the gut by PCR, and two kinds of sequenceswere identified. The phylogenetic tree was constructed by neighbor-joiningand maximum parsimony methods to identify symbionts harbored inthe mixed segment. They are classified as low-G+C-content gram-positivebacteria and are most closely related to the genus Clostridium.The distribution of these bacteria throughout the whole gut wasexamined by PCR using specific primers, which suggested that theyare confined to the mixed segment despite the presence of bacteriathroughout the gut. In situ hybridization indicated that the symbioticbacteria were localized to the ectoperitrophic space between themidgut wall and the peritrophic membrane in the mixed segment.Electron microscopy revealed the close association between thesebacteria and the mesenteric epithelium, suggesting that they havesome interactions with the gut tissue oftermites.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

It is widely known that termites cannot survive without intestinal microorganisms. The physiological functions of symbioticprokaryotes in termites are extremely diverse and include cellulosedigestion (21, 40), hemicellulose digestion (43, 47),acetogenesis (5, 29, 34), hydrogenesis (46, 47), methanogenesis(5, 35), sulfate reduction (28), and nitrogen fixation(39, 48). Moreover, intestinal bacteria contribute to creatingsuitable conditions for symbiotic flagellates through the productionof nutrients and the maintenance of the pH and anaerobic conditionsin "lower termites" (7). Such microorganisms are usually distributedin the enlarged part of the hindgut, called "the paunch"; metabolitesfrom the microorganisms are considered to be absorbed across thehindgut wall (23). It has also been reported that termites belongingto the Termitidae, which do not have symbiotic protozoa and areknown as "higher termites," possess bacteria not only in the hindgutbut also in the mixed segment (1, 12).

The mixed segment is a part of the gut present only in higher termites, where it is situated between the midgut and the firstproctodeal segment (2). The basic structure of the mixed segmentis such that the mesenteric epithelium occupies half of the gutwall and the proctodeal epithelium covers the remaining area.Though the role of the mixed segment is still ambiguous, somephysiological characteristics have recently been clarified. Oneof the most significant features in the mixed segment is an elevatedpH (3, 7, 8). In the case of the wood-eating higher termiteNasutitermes nigriceps, a neutral pH value in the midgut increasesin the mixed segment and reaches 10.23 ± 0.46 in the first proctodealsegment (7). In contrast, oxygen concentration decreases inthe mixed segment and becomes zero in the first proctodeal segment(7). Bacteria have been observed under such conditions in theectoperitrophic space of the mixed segment, which is between thegut wall and the peritrophic membrane (1). Cocci and rods havebeen reported there in the wood-eating termite N. exitiosus (12),while spirochetes and actinomycete-like bacteria have been reportedin the soil-feeding termites Cubitermes severus and Procubitermesaburiensis (1). However, the classes and roles of the mixed-segmentbacteria are still unknown. In the present study, we report thephylogenetic relationship and distribution of symbiotic bacteriain the mixed segment of the wood-eating higher termite N. takasagoensis.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Termites. N. takasagoensis termites were collected at Iriomote island in the Okinawa prefecture (Japan) and kept at room temperaturewith their nest materials. Mature worker insects were used throughoutthe investigations unless otherwiseindicated.

Amplification and cloning of rDNA. A gut was dissected from a termite in STE (0.15 M NaCl, 10 mM EDTA, 25 mM Tris-HCl; pH 8.0), and the mixed segment was collectedin a microtube with 10 µl of STE containing 2 mg of proteinaseK (Sigma Chemical Co., St. Louis, Mo.) per ml. The mixed segmentwas homogenized and incubated at 37°C for 1 h. The homogenatewas boiled for 5 min, diluted 10 times with sterilized distilledwater, and used as a PCR template. PCR was performed using primersfD1 and rP2, which are designed for most eubacterial 16S ribosomalDNA (rDNA) (53). The reaction mixture (50 µl) consisted of 0.15mM deoxynucleotides (Takara, Tokyo, Japan), 0.2 µM forward primer,0.2 µM reverse primer, 2 µl of the PCR template, and 0.05 U ofrecombinant Taq DNA polymerase (Takara) per µl in PCR buffer (Takara).The temperature regimen for 30 cycles of PCR was 94°C for 30 s,55°C for 1 min, 72°C for 2 min, and 72°C for 5 min as a finalextension after the lastcycle.

We designed the specific primers rSymA (5'-GCACCGAAACTCTCATCCCG-3', positions 806 to 787) and rSymB (5'-GGCACCGAAGGTTTCCCTCC-3',positions 805 to 786) for 16S rDNA of the symbiotic bacteria NT-1and NT-2, respectively, and checked for the presence of the bacteriain various gut regions. The gut from a termite was dissected inSTE and divided into the foregut, midgut, mixed segment, firstproctodeal segment, enteric valve plus paunch, and colon plusrectum. Each gut segment was collected in a microtube with 100µl of STE containing 2 mg of proteinase K (Sigma) per ml. Thegut segments were homogenized and incubated at 50°C for 3 h. Thehomogenate was boiled for 5 min and diluted 100 times with sterilizeddistilled water, and 0.5 µl of the diluted sample was used asa PCR template. PCR was performed using primers fD1 and rP2, primersfD1 and rSymA, or primers fD1 and rSymB. The composition of thereaction mixture (10 µl) and the PCR regimen were the same asdescribedabove.

T-vector plasmid was prepared according to the method of Marchuk et al. (31) using pBluescript II KS(+) (Stratagene, LaJolla, Calif.). The amplified DNA fragments and the T vectorswere ligated using a DNA Ligation Kit (version 2; Takara). Theligated mixture was introduced into Escherichia coli JM 109 (Toyobo,Tokyo, Japan), and transformants were selected on Luria-Bertaniplates containing 100 µg of ampicillin per ml. The inserted DNAfragments were amplified directly from the positive white coloniesby PCR (44), and the fragment sizes were confirmed by 1% agarosegelelectrophoresis.

Nucleotide sequencing and phylogenetic analysis. A DNA fragment inserted into plasmid was amplified by PCR by using M13-20 and reverse primers, and the DNA was used for sequencingtemplates after purification with Sephacryl S-300 HR spin columns(Pharmacia Biotech, Uppsala, Sweden). The sequences of all positiveclones were determined in both opposite orientations by usingABI PRISM Dye Primer Cycle Sequencing Kits (Perkin-Elmer, AppliedBiosystems Division, Foster City, Calif.) with a DNA SequenceSystem (model 373S; Perkin-Elmer). The homology of the sequencesobtained was examined with the MPsrch program at the DNA Informationand Stock Center at the National Institute of Agrobiological Resources,Tsukuba, Japan. Related sequences were aligned with CLUSTAL W1.7 software (50) for multiple sequence alignment, and the nucleotidesof ambiguous alignments were corrected or removed manually. Treetopology was built using the maximum parsimony method with PAUP4.0 and the neighbor-joining method of Kimura's two-parametermodel with PHYLIP 3.5. Relative support for the different nodeswas assessed by using 1,000 bootstrap replicates with seven randomadditional replicates per bootstrapreplicate.

In situ hybridization. Oligonucleotide probes (5'-CCCATTCCCCATGCGGTGTTAAGG-3') and (5'-TCCCTGTATGATGCCATACTGTGA-3') were designed using complementarysequences in positions of 16S rRNA from 184 to 161 for NT-1 and182 to 159 for NT-2 and were labeled with digoxigenin (DIG)-11-ddUTPusing a DIG Oligonucleotide 3'-End Labeling Kit (Boehringer MannheimGmbH Biochemica, Mannheim, Germany). The gut was removed froma termite and fixed with 70% ethanol at 4°C for 1 h. The gut wasdehydrated in an ordinary ethanol series, xylen, and then embeddedin paraffin. The gut was sectioned at 6 µm and rehydrated in theethanol series in reverse order. The sections were rinsed brieflyin phosphate-buffered saline (PBS) and fixed with 4% paraformaldehydein PBS containing 0.2% Tween 20 (PBST). The sections were thenrinsed with PBST and treated with 0.1% lysozyme in a 0.1 M Tris-HClbuffer (pH 8.0) containing 50 mM EDTA at 4°C for 20 min. Prehybridizationwas performed at room temperature for 1 h, and hybridizationswere carried out at 37°C overnight in the hybridization bufferdescribed by Hirota et al. (22), including 10 pmol of a labeledprobe per ml. A mixture of 10 labeled and 100 pmol of nonlabeledprobes per ml was applied to the sections as negative controls.After hybridization, the specimens were washed in 2× SSC (1× SSCis 0.15 M NaCl plus 0.015 M sodium citrate) at room temperaturetwice for 30 min each and in 1× SSC at room temperature for 10min. The specimens were incubated with 10% normal goat serum inPBST for 1 h and with alkaline phosphatase-conjugated anti-DIGantibody (Boehringer Mannheim) in PBST containing 2 mM levamisoleat 37°C for 2 h. The specimens were rinsed with PBST containing2 mM levamisole and stained using a DIG Detection Kit (BoehringerMannheim).

Whole-cell hybridization of symbiotic bacteria. The mixed segments and hindguts (paunches) were collected from five termites, and the gut contents were washed out in 200µl of 0.2-µm (pore-size) filtered Solution U (52). Paraformaldehydewas added to be 4% and fixed at 4°C for 1.5 h. The gut contentswere briefly rinsed with PBST for three times and suspended with20 µl of 50% ethanol. The suspension was spread on coverslipsand then air dried for 2 h. The aforementioned probes were labeledwith rhodamine using the Label IT Rhodamine Labeling Kit (PanVeraCo., Madison, Wis.) and, to strengthen the hybridization signals,the primers rSymA and rSymB were also labeled with rhodamine andused as supplementary probes. Hybridization was performed in aculture dish using the mixture of the probes (at 50 pmol/ml) inthe hybridization buffer at 37°C overnight. After hybridization,the coverslips were briefly washed in 4× SSC at room temperatureand then washed in 2× SSC followed by 1× SSC for 10 min each atroom temperature. The gut contents on the coverslips were counterstainedwith 1 µg of DAPI (4',6'-diamidino-2-phenylindole) per ml (in0.2-µm-filtered, distilled water), and the morphologies of thebacteria were observed with an epifluorescencemicroscope.

Electron microscopy. The midguts and mixed segments from mature workers were fixed with 2.5% glutaraldehyde in 0.05 M phosphate buffer (pH 7.4)for 2 h at 4°C. The specimens were rinsed three times in the samebuffer, for 10 min each time, at 4°C. The specimens were thenpostfixed with 1% osmium tetraoxide in 0.05 M phosphate bufferfor 1 h at 4°C, dehydrated in an ordinary ethanol series, andembedded in Spurr's epoxy resin. Ultrathin sections were stainedwith uranyl acetate and lead citrate and examined with a transmissionelectron microscope (JEM-100C; JEOL, Ltd., Tokyo,Japan).

Nucleotide sequence accession numbers. The sequence data determined in this study are in the DDBJ, EMBL, and GenBank nucleotide sequence databases under accessionnumbers AB031327 and AB031328 for NT-1 and NT-2,respectively.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Composition of intestinal bacteria in the mixed segment. Bacterial 16S rRNA genes were amplified using primers fD1 and rP2, which resulted in an approximately ~1.5-kb band in an agarosegel. Amplified fragments of prokaryotic rDNA were cloned intoE. coli JM109, and 22 clones were partially sequenced. The sameprocedure was repeated using the mixed segment from another individual,and 20 clones were partially sequenced. The cloned rDNA sequenceswere composed of 11 NT-1 clones, 7 NT-2 clones, and 4 other clonesin the first investigation. On the other hand, there were 13 NT-2clones, 4 NT-1 clones, and 3 other clones in the second examination.The same procedure was repeated using another individual froma different colony, resulting in 8 clones that were NT-1, 5 clonesthat were NT-2, and 3 other clones, making a total of 16. Thesedata indicate that intestinal bacteria primarily consist of twospecies in the mixed segment of N. takasagoensis.

Phylogeny of symbiotic bacteria in the mixed segment. Totals of 1,442 and 1,440 bp of 16S rDNA were determined for NT-1 and NT-2, respectively; the sequence of NT-1 was 85.6% identicalto that of NT-2. The sequences of both NT-1 and NT-2 clones weresubjected to a homology search with the MPsrch program. No sequencein the database showed more than 90% identity to these sequences.The highest identity to NT-1 and NT-2 was obtained from Tizzer'sorganism (45), Clostridium piliforme (formerly known as Bacilluspiliformis), which showed 85.8 and 83.7% identities to NT-1 andNT-2, respectively. The phylogenetic tree was constructed by neighbor-joiningand maximum-parsimony methods, and both methods resulted in essentiallythe same topology. The symbiotic bacteria were placed into thelow-G+C-content gram-positive group of bacteria (Fig. 1). Furtherphylogenetic analysis was performed within the low-G+C-contentgram-positive bacterial group. Among them, both NT-1 and NT-2were most likely to be assigned to the genus Clostridium, andthey showed a monophyletic relationship with C. piliforme andC. colinum (Fig. 2), with 98% bootstrap supports for neighbor-joiningand maximum-parsimony methods.

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FIG. 1. Eubacterial phylogenetic tree constructed by the neighbor-joining method on the basis of 1,189 unambiguously aligned bases. The archaebacterial 16S rDNA sequence of Sulfolobus solfataricus is used as an outgroup. The scale bar represents a 0.05 substitution per nucleotide position. Numbers above and below the branches indicate the percentage bootstrap support out of 1,000 resampling data from neighbor-joining and maximum parsimony methods, respectively (values of <50% are not shown). Accession numbers are indicated in parentheses. Spirochetes marked with an asterisk have been affiliated with the genus Treponema (30, 38).

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FIG. 2. Phylogenetic tree of low-G+C-gram positive group constructed by the neighbor-joining method on the basis of 1,245 unambiguously aligned bases. The scale bar represents a 0.02 substitution per nucleotide position. Numbers above and below the branches indicate the percentage bootstrap support out of 1,000 resampling data from neighbor-joining and maximum parsimony methods, respectively (values of <50% are not shown). The sequence from E. coli is used as an outgroup. Accession numbers are indicated in parentheses.

Distribution of the symbiotic bacteria in the gut. Based on these sequences, we designed specific primers rSymA and rSymB to study the distribution of the symbiotic bacteriain the gut. A gut from a termite was dissected and divided intosix segments: the foregut, the midgut, the mixed segment, thefirst proctodeal segment, the second plus the third proctodealsegments (the enteric valve and paunch), and the forth plus thefifth proctodeal segments (the colon and rectum) (Fig. 3A). PCRwas performed to study general distribution of bacteria usingprimers fD1 and rP2 to each gut segment. This PCR revealed anexpected fragment in all gut segments (Fig. 3B), suggesting thatbacteria are present throughout the gut. We then performed PCRusing the primer set rSymA-fD1 or rSymB-fD1, which is specificto NT-1 or NT-2, respectively. The expected bands were detectedonly in the mixed segment for both NT-1 and NT-2 (Fig. 3C andD), suggesting that they are confined to the mixed segment.

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FIG. 3. Distribution of bacteria in the gut of N. takasagoensis. (A) A schematic drawing of the gut showing the following: 1, foregut; 2, midgut; 3, mixed segment; 4, first proctodeal segment; 5, enteric valve and paunch; and 6, colon and rectum. (B) PCR using general eubacterial primers. (C) PCR using specific primers to NT-1. (D) PCR using specific primers to NT-2. M, molecular marker ( $lambda$ -Eco T14I digest); N, negative control without template. The number of each lane corresponds to the numbers in panel A.

Infection of the symbiotic bacteria in colony members of N. takasagoensis. It is difficult to properly select each stage of the termites since caste systems are not well studied in N. takasagoensis.Therefore, we randomly selected 10 soldiers and 10 workers ofvarious sizes and collected the mixed segments from all selectedtermites. PCR was performed using the specific primers for NT-1and NT-2 to determine whether these bacteria infected variousstages of the termites. The expected bands for NT-1 and NT-2 weredetected in all worker and soldier termites (data not shown).This result suggests that NT-1 and NT-2 infect most termites inacolony.

In situ hybridization. An in situ hybridization technique was applied to paraffin sections of the gut with short oligonucleotide probes (24 bp) specificto the 16S rRNAs of NT-1 and NT-2. The hybridization signals forboth NT-1 and NT-2 showed very similar distributions. They wereobserved in the ectoperitrophic space between the peritrophicmembrane and the midgut wall throughout the mixed segment, andthe strong NT-1 signals were detected especially in the anteriorpart of the mixed segment (Fig. 4A). The NT-2 signals were strongin the middle to the posterior part of the mixed segment (Fig.4B). However, such signals were not observed in the gut lumenor in the ectoperitrophic space of the proctodeal side. Signalswere not detected in control sections (Fig. 4C and D), which werehybridized with a mixture of 10 pmol of labeled probes per mland an excess amount (100 pmol/ml) of nonlabeled probes.

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FIG. 4. In situ hybridization to 16S rRNA of the symbiotic bacteria in the mixed segment of N. takasagoensis. Arrowheads indicate the ectoperitrophic space of the mesenteric side, which is filled with bacteria. (A) Cross-section of the anterior part hybridized to NT-1. (B) The posterior part hybridized to NT-2. (C) Control section hybridized to NT-1. (D) Control section hybridized to NT-2. Bars, 50 µm.

Whole-cell hybridization. To observe morphologies of the symbiotic bacteria, we performed whole-cell hybridization to gut contents from the mixed segmentusing the rhodamine-labeled probes. Because the signals were tooweak to recognize the individual bacteria by using only one probe,the aforementioned primers rSymA and rSymB were also labeled withrhodamine and applied to the gut contents with the former probesat the same time to strengthen the signals. The probes specificfor NT-1 recognized short rods in chains, which have gnarl-likestructures at the edge of each cell (Fig. 5A to D), while theprobes specific for NT-2 detected not only bacteria similar tothose recognized by NT-1 probes but also simple short rods inchains (Fig. 5E and F). Even after the gut contents were washedout, several chained short rods remained adhered to pieces ofthe mesenteric tissue (Fig. 5G). Although the strong red autofluorescencefrom the tissue interfered with the detection of signals fromsuch bacteria, NT-2 probes could detect some signals from thebacteria attached to the midgut wall (Fig. 5H). It is not clearwhether the NT-2 probes specifically detected NT-2 or whetherthey detected both NT-1 and NT-2 in this experiment because theystained two types of morphologies and it was difficult to performthe hybridization in more severe conditions due to very weak signals.However, in contrast, both probes did not hybridize to cocci inthe mixed segment and bacteria present in the hindgut (Fig. 5Ito L), suggesting that these probes are specific enough to detectthe target bacteria NT-1 and NT-2.

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FIG. 5. Whole-cell hybridization to 16S rRNA of the symbiotic bacteria in the mixed segment of N. takasagoensis. Rhodamine-labeled probes specific for NT-1 were applied to the gut contents, and bacteria were viewed with the DAPI filter set (A and C) and the rhodamine filter set (B and D). Stained short rods in chains have gnarl-like structure at the edges of the cells. Bacteria hybridized with the NT-2 probes were viewed with the DAPI filter set (E) or the rhodamine filter set (F). Simple short rods in chains were weakly stained, and nonspecific autofluorescence from gut contents or contaminated tissues was detected throughout the experiments. Several bacteria (arrowheads) are adhered to a piece of the mesenteric tissue (G), and some of them were detected by the NT-2 probes (H), although the strong autofluorescence from the tissue interferes with the signals from most bacteria. (I and K) Numerous bacteria were observed in the hindgut by DAPI staining. However, these bacteria are not stained with NT-1 (J) or NT-2 (L) probes. t, mesenteric tissue; n, nucleus. Bar, 50 µm.

Electron microscopy. Transverse sections of the mixed segment were observed with an electron microscope to more precisely determine the distributionof the symbionts. Numerous bacteria were observed in the ectoperitrophicspace of the mesenteric side (Fig. 6A), while some bacteria weresparsely distributed in the ectoperitrophic space of the proctodealside (Fig. 6B). On the contrary, bacteria are very rare in theectoperitrophic space of the actual midgut (Fig. 6C). Except forthe most anterior part, several bacteria were situated betweenthe microvilli, and some were attached to the midgut wall (Fig.6D) throughout the mesenteric tissue of the mixed segment. Thelongitudinal section shows that several rods were situated betweenthe microvilli (Fig. 6E), and this finding corresponds to theobservations made by whole-cell hybridization. These results suggestclose associations between these bacteria and the gut tissue.

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FIG. 6. Electron micrographs of the mixed segment in N. takasagoensis. (A) The most anterior part of the mixed segment. Numerous bacteria are present in the ectoperitrophic space between the mesenteric epithelium and peritrophic membrane. (B) Proctodeal epithelium and luminal bacteria. Some bacteria are sparsely distributed in the ectoperitrophic space. (C) Posterior part of the actual midgut. Bacteria are rare in the ectoperitrophic space, and microvilli are well developed. (D) Mesenteric side in the middle part of the mixed segment. Bacteria are observed not only in the ectoperitrophic space but also among the microvilli. (E) Longitudinal section of the apical surface of the mesenteric epithelium. Rods (arrowheads) are situated between microvilli (v). P, peritrophic membrane. Bars, 1 µm.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

The role of symbiotic microbes is important for clarifying the digestive physiology in termites. However, precise informationwas not available about symbiotic bacteria in the mixed segment,except for their morphology. In the present study, we first clarifiedthe phylogeny and distribution of symbiotic bacteria in the mixedsegment.

Our phylogenetic study suggests that the symbiotic bacteria in the mixed segment are closely related to the Clostridium group,which is one of the largest bacterial genera. These symbiontsdiffer from bacteria found in the wood-eating lower termite Reticulitermessperatus (36) and from the clostridia isolated from higher termites(21, 26) based on 16S rDNA sequences, and no low-G+C-contentgram-positive bacteria have been discovered in the gut of thedrywood-eating lower termite Cryptotermes domesticus (37). Itis commonly known that Clostridium species are usually obligateanaerobes, and some are facultative anaerobes and appear as rods,short rods, or cocci (42). These characters correspond to themorphological observations in N. exitiosus (12) and N. takasagoensis.Since the microflora in the mixed segment consist mainly of twospecies in an aspect of 16S rDNA sequences, these bacteria probablycontribute to the dramatic decrease of oxygen concentration observedin the mixed segment (7). Clostridia are usually known as soilbacteria and are also found in the rumens and intestines of animalsand humans (11, 13, 19). Intestinal bacteria are importantto the health of human beings (11), and some predicted rolesof intestinal bacteria in termites (6) are similar to thosein humans, such as producing short-chain fatty acids from carbohydratesor synthesizing amino acids (11). Because many clostridia degradepolysaccharides to produce acetone, alcohol, acetate, lactate,CO₂, and hydrogen (9, 20, 24, 33, 41) and others canferment nitrogenous or lipidic compounds (16, 25), it is expectedthat the symbiotic bacteria of N. takasagoensis play a role inthe nutritional physiology of the termite; in fact, an acetogenicclostridial species has already been isolated from a soil-feedingtermite (26). However, pathogenic activities are also well knownin many anaerobic clostridia (4). The symbiotic bacteria forma clade with Tizzer's organism and C. colinum with high bootstrappercentages, suggesting that they share a common ancestor. Tizzer'sorganism, Bacillus piliformis is widely known as a pathogen forlaboratory, domesticated, and wild animals and is characterizedby multifocal necrotizing hepatitis, carditis, and/or severe hemorrhagicenteritis (18, 45). This organism has never been grown ina cell-free medium, although it has been cultured in mammaliancells and chicken eggs (45). B. piliformis was assigned to thegenus Clostridium by 16S rRNA sequencing in 1993 and renamed Clostridiumpiliforme (15). Similarly, C. colinum is also known as a pathogenicanaerobe that causes ulcerative enteritis in avian species (4).They were both assigned to Cluster XIV of the clostridia, basedon 16S rRNA gene sequences (10), which signifies that our bacteriaare a new species belonging to this cluster. It is interestingthat the symbionts of the termite are the most closely relatedto these pathogenic bacteria, which prefer the closed environmentpresent in living organisms and demonstrate significant associationsto guttissues.

Our PCR experiments suggest that bacteria are generally present throughout the guts of termites. This fact in turn suggeststhat many of the bacteria in termite guts are just passing throughor are digested by termites as a nutritional source. Such bacteriacould also be not-yet-identified species as well as essentialgut residents. Therefore, it is important to distinguish the facultativeresidents from the essential residents in termites to understandthe roles of microorganisms in termite guts. We assume that microflorain the foregut are occasional residents, because the foregut isan organ used simply for physical digestion of wood particlesand is not a fermentation chamber like the paunch. Moreover, theforegut is the part nearest to the mouth and completely aerobic,in contrast to the hindgut (7, 17). The symbionts in thisstudy were not detected in the foregut and, surprisingly, thesebacteria were also not detected in the paunch, which is inhabitedby numerous bacteria. Both symbionts are likely to be confinedto the mixed segment. It is known that a dramatic increase inthe pH value occurs in the mixed segment (3, 7, 8), andalkaline fluid, predominantly including potassium ions, is thoughtto be secreted from the mesenteric tissue of the mixed segment(1). These symbiotic bacteria seem to be completely suitedto this region, and it might be interesting to study how theyadapt to this very strict alkaline environment. Na⁺ or K⁺-H⁺ antiporters are known to be involved in the pH homeostasis ofbacteria in some alkaline bacillus species that are closely relatedto clostridia (27). A K⁺-H⁺ antiporter-like structure is probably developed in the symbioticbacteria of the mixedsegment.

The in situ hybridization and electron microscopy clearly showed the localization of the symbiotic bacteria to the mesentericside of the mixed segment. Since there is a trace amount of cellulaseactivity in this region (51), since the peritrophic membranekeeps the bacteria from wood particles in the lumen, and sincethese bacteria do not distribute uniformly around the peritrophicmembrane, we suspect that their nutritional source does not comefrom the lumen. Electron microscopy revealed the close relationshipbetween the bacteria and mesenteric epithelium, suggesting thatthe symbiotic bacteria utilize some substances secreted from themesenteric tissue in the mixed segment. It is known that midgutcells are replenished very quickly in cockroaches (14). Suchphenomena have also been observed in the termite R. speratus,in which the midgut cells that have fulfilled their function arebelieved to be endocytosed by neighbor epithelial cells and digestedin phagolysosomes (54). Similar phagosomes are observed throughoutthe midgut columnar cells, including the mixed segment regionof N. takasagoensis (data not shown); the symbionts trapped amongthe microvilli of old cells could be endocytosed by young columnarcells and digested with the oldcells.

The transmission mechanism of these symbionts from generation to generation remains unclear. Since usually bacteria cannotpass through the peritrophic membrane (49) and since they arenot present in any other gut regions, it is unlikely that theyinfect the termites at the stage when the peritrophic membraneis intact. However, the bacteria are present not only in workerinsects but also in soldier insects, which cannot feed directlyon wood and ingest stomodeal and/or proctodeal foods from workers(32). This suggests that a trace of the bacteria might be ingestedas the contamination of stomodeal and/or proctodeal foods andreaches the mixed segment immediately after molting, when theperitrophic membrane has not yetformed.

The results of phylogeny and distribution studies of the symbiotic bacteria in the mixed segment indicated that these bacteriamight play a significant role in the gut physiology of termites.Since the mixed segments of soil-feeding termites exhibit microfloradifferent from that of wood-eating termites (1), it is possiblethat symbionts in the mixed segment have a close relationshipto the feeding habits, gut physiology, and/or phylogeny of thehosts. Clarification of the physiological function of the symbioticclostridia will greatly contribute to our understanding of host-symbiontinteraction and the role of the mixed segment in highertermites.

	ACKNOWLEDGMENT

This work was supported by Program for Promotion of Basic Research Activities for Innovative Biosciences of Bio-oriented TechnologyResearch AdvancementInstitution.

	FOOTNOTES

^* Corresponding author. Mailing address: National Institute of Sericultural and Entomological Science, Owashi, Tsukuba, Ibaraki305-8634, Japan. Phone: (81) 298-38-6109. Fax: (81) 298-38-6028.E-mail: hnada{at}nises.affrc.go.jp.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Bignell, D. E., H. Oskarsson, J. M. Anderson, and P. Ineson. 1983. Structure, microbial associations and function of the so-called "mixed segment" of the gut in two soil-feeding termites, Procubitermes aburiensis and Cubitermes severus (Termitidae, Termitinae). J. Zool. 201:445-480.

2. Bignell, D. E. 1994. Soil-feeding and gut morphology in higher termites, p. 131-158. In J. H. Hunt, and C. A. Nalepa (ed.), Nourishment and evolution in insect societies. Westview Press, Inc., Boulder, Colo.

3. Bignell, D. E., and P. Eggleton. 1995. On the elevated intestinal pH of higher termites (Isoptera: Termitidae). Insectes Soc. 42:57-69[CrossRef].

4. Borriello, S. P. 1995. Clostridial disease of the gut. Clin. Infect. Dis. 20:S242-S250.

5. Brauman, A., M. D. Kane, M. Labat, and J. A. Breznak. 1992. Genesis of acetate and methane by gut bacteria of nutritionally diverse termites. Science 257:1384-1387[Abstract/Free Full Text].

6. Breznak, J. A., and A. Brune. 1994. Role of microorganisms in the digestion of lignocellulose by termites. Annu. Rev. Entomol. 39:453-487[CrossRef].

7. Brune, A., D. Emerson, and J. A. Breznak. 1995. The termite gut microflora as an oxygen sink: microelectrode determination of oxygen and pH gradients in guts of lower and higher termites. Appl. Environ. Microbiol. 61:2681-2687[Abstract].

8. Brune, A., and M. Kühl. 1996. pH profiles of the extremely alkaline hindguts of soil-feeding termites (Isoptera: Termitidae) determined with microelectrodes. J. Insect Physiol. 42:1121-1127[CrossRef].

9. Chen, J. S. 1995. Alcohol dehydrogenase: multiplicity and relatedness in the solvent-producing clostridia. FEMS Microbiol. Rev. 17:263-273[CrossRef][Medline].

10. Collins, M. D., P. A. Lawson, A. Willems, J. J. Cordoba, J. Fernandez-Garayzabal, P. Garcia, J. Cai, H. Hippe, and J. A. E. Farrow. 1994. The phylogeny of the genus Clostridium: proposal of five new genera and eleven new species combinations. Int. J. Syst. Bacteriol. 44:812-826[Abstract/Free Full Text].

11. Cummings, J. H., and G. T. Macfarlane. 1997. Role of intestinal bacteria in nutrient metabolism. J. Parenter. Enteral Nutr. 21:357-365[Abstract/Free Full Text].

12. Czolij, R., M. Slaytor, and R. W. O'Brien. 1985. Bacterial flora of the mixed segment and the hindgut of the higher termite Nasutitermes exitiosus Hill (Termitidae, Nasutitermitinae). Appl. Environ. Microbiol. 49:1226-1236.

13. Dehority, B. A. 1991. Cellulose degradation in ruminants, p. 327-354. In C. H. Haigler, and P. J. Weimer (ed.), Biosynthesis and biodegradation of cellulose. Marcel Dekker, Inc., New York, N.Y.

14. Dow, J. A. T. 1986. Insect midgut function. Adv. Insect. Physiol. 19:188-328.

15. Duncan, A. J., R. J. Carman, G. J. Olsen, and K. H. Wilson. 1993. Assignment of the agent of Tizzer's disease to Clostridium piliforme comb. nov. on the basis of 16S rRNA sequence analysis. Int. J. Syst. Bacteriol. 43:314-318[Abstract/Free Full Text].

16. Elsden, S. R., and M. G. Hilton. 1979. Amino acid utilization patterns in clostridial taxonomy. Arch. Microbiol. 123:137-141[CrossRef][Medline].

17. Eutick, M. L., R. W. O'Brien, and M. Slaytor. 1976. Aerobic state of gut of Nasutitermes exitiosus and Coptotermes lacteus, high and low caste termites. J. Insect Physiol. 22:1377-1380[CrossRef].

18. Goto, K., and T. Itoh. 1994. Detection of Bacillus piliformis by specific amplification of ribosomal sequences. Exp. Anim. 43:389-394.

19. Haagsma, J. 1991. Pathogenic bacteria and the environment. Rev. Sci. Tech. Off. Int. Epizoot. 10:749-764.

20. Hazlewood, G. P., and H. J. Gilbert. 1993. Xylan and cellulose utilization by the clostridia. Bio/Technology 25:311-341[Medline].

21. Hethener, P., A. Brauman, and J.-L. Garcia. 1992. Clostridium termitidis sp. nov., a cellulolytic bacterium from the gut of the wood-feeding termite Nasutitermes lujae. Syst. Appl. Microbiol. 15:52-58.

22. Hirota, S., A. Ito, E. Morii, A. Wanaka, M. Tohyama, Y. Kitamura, and S. Nomura. 1992. Localization of mRNA for c-kit receptor and its ligand in the brain of adult rats: an analysis using in situ hybridization. Mol. Brain Res. 15:47-54[Medline].

23. Hogan, M. E., M. Slaytor, and R. W. O'Brien. 1985. Transport of volatile fatty acids across the hindgut of the cockroach Panesthia ciribrata Saussure and the termite, Mastotermes darwiniensis Froggatt. J. Insect Physiol. 31:587-591[CrossRef].

24. Johnston, N. C., and H. Goldfine. 1985. Phospholipid aliphatic chain composition modulates lipid class composition, but not lipid asymmetry in Clostridium butyricum. Biochim. Biophys. Acta 813:10-18[Medline].

25. Jones, D. T., and D. R. Woods. 1986. Acetone-butanol fermentation revisited. Microbiol. Rev. 50:484-525[Free Full Text].

26. Kane, M. D., A. Brauman, and J. A. Breznak. 1991. Clostridium mayombei sp. nov., an H₂/CO₂ acetogenic bacterium from the gut of the African soil-feeding termite Cubitermes speciosus. Arch. Microbiol. 156:99-104[CrossRef].

27. Krulwich, T. A., M. Ito, R. Gilmour, D. B. Hicks, and A. A. Guffanti. 1998. Energetics of alkaliphilic Bacillus species: physiology and molecules. Adv. Microb. Physiol. 40:401-438[Medline].

28. Kuhnigk, T., J. Branke, D. Krekeler, H. Cypionka, and H. König. 1996. A feasible role of sulfate-reducing bacteria in the termite gut. System Appl. Microbiol. 19:139-149.

29. Leadbetter, J. R., T. M. Schmidt, J. R. Graber, and J. A. Breznak. 1999. Acetogenesis from H₂ plus CO₂ by spirochetes from termite guts. Science 283:686-689[Abstract/Free Full Text].

30. Lilburn, T. G., T. M. Schmidt, and J. A. Breznak. 1999. Phylogenetic diversity of termite gut spirochetes. Environ. Microbiol. 1:331-345[CrossRef][Medline].

31. Marchuk, D., M. Drumm, A. Saulino, and F. S. Collins. 1991. Construction of T-vectors, a rapid and general system for direct cloning of unmodified PCR products. Nucleic Acids Res. 19:1154[Free Full Text].

32. Mcmahan, E. A. 1969. Feeding relationships and radioisotope techniques, p. 387-406. In K. Krishna, and F. M. Weesner (ed.), Biology of termites, vol. 1. Academic Press, New York, N.Y.

33. Mitchell, W. J. 1992. Carbohydrate assimilation by saccharolytic clostridia. Res. Microbiol. 143:245-250[Medline].

34. Odelson, D. A., and J. A. Breznak. 1983. Volatile fatty acid production by the hindgut microbiota of xylophagous termites. Appl. Environ. Microbiol. 45:1602-1613[Abstract/Free Full Text].

35. Ohkuma, M., S. Noda, K. Horikoshi, and T. Kudo. 1995. Phylogeny of symbiotic methanogens in the gut of the termite Reticulitermes speratus. FEMS Microbiol. Lett. 134:45-50[CrossRef][Medline].

36. Ohkuma, M., and T. Kudo. 1996. Phylogenetic diversity of the intestinal bacterial community in the termite Reticulitermes speratus. Appl. Environ. Microbiol. 62:461-468[Abstract].

37. Ohkuma, M., and T. Kudo. 1998. Phylogenetic analysis of the symbiotic intestinal microflora of the termite Cryptotermes domesticus. FEMS Microbiol. Lett. 164:389-395[CrossRef].

38. Ohkuma, M., T. Iida, and T. Kudo. 1999. Phylogenetic relationships of symbiotic spirochetes in the gut of diverse termites. FEMS Microbiol. Lett. 181:123-129[CrossRef][Medline].

39. Ohkuma, M., S. Noda, R. Usami, K. Horokoshi, and T. Kudo. 1996. Diversity of nitrogen fixation genes in the symbiotic intestinal microflora of the termite Reticulitermes speratus. Appl. Environ. Microbiol. 62:2747-2752[Abstract].

40. Pasti, M. B., and M. L. Belli. 1985. Cellulolytic activity of Actinomycetes isolated from termites (Termitidae) gut. FEMS Microbiol. Lett. 26:107-112[CrossRef].

41. Rainey, F. A., and E. Stackebrandt. 1993. 16S rDNA analysis reveals phylogenetic diversity among the polysaccharolytic clostridia. FEMS Microbiol. Lett. 113:125-128[CrossRef][Medline].

42. Rieu-Lesme, F., C. Dauga, B. Morvan, O. M. Bouvet, P. A. Grimont, and J. Dore. 1996. Acetogenic coccoid spore-forming bacteria isolated from the rumen. Res. Microbiol. 147:753-764[Medline].

43. Schäfer, A., R. Konrad, T. Kuhnigk, P. Kämpfer, H. Hertei, and K. König. 1996. Hemicellulose-degrading bacteria and yeasts from the termite gut. J. Appl. Bacteriol. 80:471-478[Medline].

44. Simada, H., and Y. Tada. 1991. Rapid isolation of a rice waxy sequence: a simple PCR method for the analysis of recombinant plasmids from intact Escherichia coli cells. Gene 98:243-248[CrossRef][Medline].

45. Smith, K. J., H. G. Skelton, E. J. Hilyard, C. T. Hadfield, R. S. Moeller, S. Tuur, C. Decker, K. F. Wagner, and P. Angritt. 1996. Bacillus piliformis infection (Tizzer's disease) in a patient infected with HIV-1: confirmation with 16S ribosomal RNA sequence analysis. J. Am. Acad. Dermatol. 34:343-348[Medline].

46. Taguchi, F., J. D. Chang, N. Mizukami, T. Saito-Taki, K. Hasegawa, and M. Morimoto. 1993. Isolation of a hydrogen-producing bacterium, Clostridium beijerinckii strain AM21B, from termites. Can. J. Microbiol. 39:726-730.93.

47. Taguchi, F., K. Hasagawa, T. Saito-Taki, and K. Hara. 1996. Simultaneous production of xylanase and hydrogen using xylan in batch culture of Clostridium sp. strain X53. J. Ferment. Bioeng. 81:178-180[CrossRef].

48. Tayasu, I., A. Sugimoto, E. Wada, and T. Abe. 1994. Xylophagous termites depending on atmospheric nitrogen. Naturwissenschaften 81:229-231[CrossRef].

49. Tellam, R. L., G. Wijffels, and P. Willadsen. 1999. Peritrophic matrix proteins. Insect Biochem. Mol. Biol. 29:87-101[CrossRef][Medline].

50. Thompson, J. D., D. G. Higgins, and T. J. Gibson. 1994. CLUSTAL W: improving the sensitivity of progressive multiple sequence alignment through sequence weighting, position-specific gap penalties and weight matrix choice. Nucleic Acids Res. 22:4673-4680[Abstract/Free Full Text].

51. Tokuda, G., H. Watanabe, T. Matsumoto, and H. Noda. 1997. Cellulose digestion in the wood-eating higher termite, Nasutitermes takasagoensis (Shiraki): distribution of cellulases and properties of endo- $beta$ -1,4-glucanase. Zool. Sci. 14:83-93[CrossRef][Medline].

52. Trager, W. 1934. The cultivation of a cellulose-digesting flagellate Trichomonas termopsidis and of certain other termite protozoa. Biol. Bull. 66:182-190[Abstract/Free Full Text].

53. Weisburg, W. G., S. M. Barns, D. A. Pelletier, and D. J. Lane. 1991. 16S ribosomal DNA amplification for phylogenetic study. J. Bacteriol. 173:697-703[Abstract/Free Full Text].

54. Yamaoka, I., and Y. Nagatani. 1980. Phagocytic cells in the midgut epithelium of the termite, Reticulitermes speratus (Kolbe). Zool. Mag. 89:308-311.

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1.	Bignell, D. E., H. Oskarsson, J. M. Anderson, and P. Ineson. 1983. Structure, microbial associations and function of the so-called "mixed segment" of the gut in two soil-feeding termites, Procubitermes aburiensis and Cubitermes severus (Termitidae, Termitinae). J. Zool. 201:445-480.
2.	Bignell, D. E. 1994. Soil-feeding and gut morphology in higher termites, p. 131-158. In J. H. Hunt, and C. A. Nalepa (ed.), Nourishment and evolution in insect societies. Westview Press, Inc., Boulder, Colo.
3.	Bignell, D. E., and P. Eggleton. 1995. On the elevated intestinal pH of higher termites (Isoptera: Termitidae). Insectes Soc. 42:57-69[CrossRef].
4.	Borriello, S. P. 1995. Clostridial disease of the gut. Clin. Infect. Dis. 20:S242-S250.
5.	Brauman, A., M. D. Kane, M. Labat, and J. A. Breznak. 1992. Genesis of acetate and methane by gut bacteria of nutritionally diverse termites. Science 257:1384-1387[Abstract/Free Full Text].
6.	Breznak, J. A., and A. Brune. 1994. Role of microorganisms in the digestion of lignocellulose by termites. Annu. Rev. Entomol. 39:453-487[CrossRef].
7.	Brune, A., D. Emerson, and J. A. Breznak. 1995. The termite gut microflora as an oxygen sink: microelectrode determination of oxygen and pH gradients in guts of lower and higher termites. Appl. Environ. Microbiol. 61:2681-2687[Abstract].
8.	Brune, A., and M. Kühl. 1996. pH profiles of the extremely alkaline hindguts of soil-feeding termites (Isoptera: Termitidae) determined with microelectrodes. J. Insect Physiol. 42:1121-1127[CrossRef].
9.	Chen, J. S. 1995. Alcohol dehydrogenase: multiplicity and relatedness in the solvent-producing clostridia. FEMS Microbiol. Rev. 17:263-273[CrossRef][Medline].
10.	Collins, M. D., P. A. Lawson, A. Willems, J. J. Cordoba, J. Fernandez-Garayzabal, P. Garcia, J. Cai, H. Hippe, and J. A. E. Farrow. 1994. The phylogeny of the genus Clostridium: proposal of five new genera and eleven new species combinations. Int. J. Syst. Bacteriol. 44:812-826[Abstract/Free Full Text].
11.	Cummings, J. H., and G. T. Macfarlane. 1997. Role of intestinal bacteria in nutrient metabolism. J. Parenter. Enteral Nutr. 21:357-365[Abstract/Free Full Text].
12.	Czolij, R., M. Slaytor, and R. W. O'Brien. 1985. Bacterial flora of the mixed segment and the hindgut of the higher termite Nasutitermes exitiosus Hill (Termitidae, Nasutitermitinae). Appl. Environ. Microbiol. 49:1226-1236.
13.	Dehority, B. A. 1991. Cellulose degradation in ruminants, p. 327-354. In C. H. Haigler, and P. J. Weimer (ed.), Biosynthesis and biodegradation of cellulose. Marcel Dekker, Inc., New York, N.Y.
14.	Dow, J. A. T. 1986. Insect midgut function. Adv. Insect. Physiol. 19:188-328.
15.	Duncan, A. J., R. J. Carman, G. J. Olsen, and K. H. Wilson. 1993. Assignment of the agent of Tizzer's disease to Clostridium piliforme comb. nov. on the basis of 16S rRNA sequence analysis. Int. J. Syst. Bacteriol. 43:314-318[Abstract/Free Full Text].
16.	Elsden, S. R., and M. G. Hilton. 1979. Amino acid utilization patterns in clostridial taxonomy. Arch. Microbiol. 123:137-141[CrossRef][Medline].
17.	Eutick, M. L., R. W. O'Brien, and M. Slaytor. 1976. Aerobic state of gut of Nasutitermes exitiosus and Coptotermes lacteus, high and low caste termites. J. Insect Physiol. 22:1377-1380[CrossRef].
18.	Goto, K., and T. Itoh. 1994. Detection of Bacillus piliformis by specific amplification of ribosomal sequences. Exp. Anim. 43:389-394.
19.	Haagsma, J. 1991. Pathogenic bacteria and the environment. Rev. Sci. Tech. Off. Int. Epizoot. 10:749-764.
20.	Hazlewood, G. P., and H. J. Gilbert. 1993. Xylan and cellulose utilization by the clostridia. Bio/Technology 25:311-341[Medline].
21.	Hethener, P., A. Brauman, and J.-L. Garcia. 1992. Clostridium termitidis sp. nov., a cellulolytic bacterium from the gut of the wood-feeding termite Nasutitermes lujae. Syst. Appl. Microbiol. 15:52-58.
22.	Hirota, S., A. Ito, E. Morii, A. Wanaka, M. Tohyama, Y. Kitamura, and S. Nomura. 1992. Localization of mRNA for c-kit receptor and its ligand in the brain of adult rats: an analysis using in situ hybridization. Mol. Brain Res. 15:47-54[Medline].
23.	Hogan, M. E., M. Slaytor, and R. W. O'Brien. 1985. Transport of volatile fatty acids across the hindgut of the cockroach Panesthia ciribrata Saussure and the termite, Mastotermes darwiniensis Froggatt. J. Insect Physiol. 31:587-591[CrossRef].
24.	Johnston, N. C., and H. Goldfine. 1985. Phospholipid aliphatic chain composition modulates lipid class composition, but not lipid asymmetry in Clostridium butyricum. Biochim. Biophys. Acta 813:10-18[Medline].
25.	Jones, D. T., and D. R. Woods. 1986. Acetone-butanol fermentation revisited. Microbiol. Rev. 50:484-525[Free Full Text].
26.	Kane, M. D., A. Brauman, and J. A. Breznak. 1991. Clostridium mayombei sp. nov., an H₂/CO₂ acetogenic bacterium from the gut of the African soil-feeding termite Cubitermes speciosus. Arch. Microbiol. 156:99-104[CrossRef].
27.	Krulwich, T. A., M. Ito, R. Gilmour, D. B. Hicks, and A. A. Guffanti. 1998. Energetics of alkaliphilic Bacillus species: physiology and molecules. Adv. Microb. Physiol. 40:401-438[Medline].
28.	Kuhnigk, T., J. Branke, D. Krekeler, H. Cypionka, and H. König. 1996. A feasible role of sulfate-reducing bacteria in the termite gut. System Appl. Microbiol. 19:139-149.
29.	Leadbetter, J. R., T. M. Schmidt, J. R. Graber, and J. A. Breznak. 1999. Acetogenesis from H₂ plus CO₂ by spirochetes from termite guts. Science 283:686-689[Abstract/Free Full Text].
30.	Lilburn, T. G., T. M. Schmidt, and J. A. Breznak. 1999. Phylogenetic diversity of termite gut spirochetes. Environ. Microbiol. 1:331-345[CrossRef][Medline].
31.	Marchuk, D., M. Drumm, A. Saulino, and F. S. Collins. 1991. Construction of T-vectors, a rapid and general system for direct cloning of unmodified PCR products. Nucleic Acids Res. 19:1154[Free Full Text].
32.	Mcmahan, E. A. 1969. Feeding relationships and radioisotope techniques, p. 387-406. In K. Krishna, and F. M. Weesner (ed.), Biology of termites, vol. 1. Academic Press, New York, N.Y.
33.	Mitchell, W. J. 1992. Carbohydrate assimilation by saccharolytic clostridia. Res. Microbiol. 143:245-250[Medline].
34.	Odelson, D. A., and J. A. Breznak. 1983. Volatile fatty acid production by the hindgut microbiota of xylophagous termites. Appl. Environ. Microbiol. 45:1602-1613[Abstract/Free Full Text].
35.	Ohkuma, M., S. Noda, K. Horikoshi, and T. Kudo. 1995. Phylogeny of symbiotic methanogens in the gut of the termite Reticulitermes speratus. FEMS Microbiol. Lett. 134:45-50[CrossRef][Medline].
36.	Ohkuma, M., and T. Kudo. 1996. Phylogenetic diversity of the intestinal bacterial community in the termite Reticulitermes speratus. Appl. Environ. Microbiol. 62:461-468[Abstract].
37.	Ohkuma, M., and T. Kudo. 1998. Phylogenetic analysis of the symbiotic intestinal microflora of the termite Cryptotermes domesticus. FEMS Microbiol. Lett. 164:389-395[CrossRef].
38.	Ohkuma, M., T. Iida, and T. Kudo. 1999. Phylogenetic relationships of symbiotic spirochetes in the gut of diverse termites. FEMS Microbiol. Lett. 181:123-129[CrossRef][Medline].
39.	Ohkuma, M., S. Noda, R. Usami, K. Horokoshi, and T. Kudo. 1996. Diversity of nitrogen fixation genes in the symbiotic intestinal microflora of the termite Reticulitermes speratus. Appl. Environ. Microbiol. 62:2747-2752[Abstract].
40.	Pasti, M. B., and M. L. Belli. 1985. Cellulolytic activity of Actinomycetes isolated from termites (Termitidae) gut. FEMS Microbiol. Lett. 26:107-112[CrossRef].
41.	Rainey, F. A., and E. Stackebrandt. 1993. 16S rDNA analysis reveals phylogenetic diversity among the polysaccharolytic clostridia. FEMS Microbiol. Lett. 113:125-128[CrossRef][Medline].
42.	Rieu-Lesme, F., C. Dauga, B. Morvan, O. M. Bouvet, P. A. Grimont, and J. Dore. 1996. Acetogenic coccoid spore-forming bacteria isolated from the rumen. Res. Microbiol. 147:753-764[Medline].
43.	Schäfer, A., R. Konrad, T. Kuhnigk, P. Kämpfer, H. Hertei, and K. König. 1996. Hemicellulose-degrading bacteria and yeasts from the termite gut. J. Appl. Bacteriol. 80:471-478[Medline].
44.	Simada, H., and Y. Tada. 1991. Rapid isolation of a rice waxy sequence: a simple PCR method for the analysis of recombinant plasmids from intact Escherichia coli cells. Gene 98:243-248[CrossRef][Medline].
45.	Smith, K. J., H. G. Skelton, E. J. Hilyard, C. T. Hadfield, R. S. Moeller, S. Tuur, C. Decker, K. F. Wagner, and P. Angritt. 1996. Bacillus piliformis infection (Tizzer's disease) in a patient infected with HIV-1: confirmation with 16S ribosomal RNA sequence analysis. J. Am. Acad. Dermatol. 34:343-348[Medline].
46.	Taguchi, F., J. D. Chang, N. Mizukami, T. Saito-Taki, K. Hasegawa, and M. Morimoto. 1993. Isolation of a hydrogen-producing bacterium, Clostridium beijerinckii strain AM21B, from termites. Can. J. Microbiol. 39:726-730.93.
47.	Taguchi, F., K. Hasagawa, T. Saito-Taki, and K. Hara. 1996. Simultaneous production of xylanase and hydrogen using xylan in batch culture of Clostridium sp. strain X53. J. Ferment. Bioeng. 81:178-180[CrossRef].
48.	Tayasu, I., A. Sugimoto, E. Wada, and T. Abe. 1994. Xylophagous termites depending on atmospheric nitrogen. Naturwissenschaften 81:229-231[CrossRef].
49.	Tellam, R. L., G. Wijffels, and P. Willadsen. 1999. Peritrophic matrix proteins. Insect Biochem. Mol. Biol. 29:87-101[CrossRef][Medline].
50.	Thompson, J. D., D. G. Higgins, and T. J. Gibson. 1994. CLUSTAL W: improving the sensitivity of progressive multiple sequence alignment through sequence weighting, position-specific gap penalties and weight matrix choice. Nucleic Acids Res. 22:4673-4680[Abstract/Free Full Text].
51.	Tokuda, G., H. Watanabe, T. Matsumoto, and H. Noda. 1997. Cellulose digestion in the wood-eating higher termite, Nasutitermes takasagoensis (Shiraki): distribution of cellulases and properties of endo- $beta$ -1,4-glucanase. Zool. Sci. 14:83-93[CrossRef][Medline].
52.	Trager, W. 1934. The cultivation of a cellulose-digesting flagellate Trichomonas termopsidis and of certain other termite protozoa. Biol. Bull. 66:182-190[Abstract/Free Full Text].
53.	Weisburg, W. G., S. M. Barns, D. A. Pelletier, and D. J. Lane. 1991. 16S ribosomal DNA amplification for phylogenetic study. J. Bacteriol. 173:697-703[Abstract/Free Full Text].
54.	Yamaoka, I., and Y. Nagatani. 1980. Phagocytic cells in the midgut epithelium of the termite, Reticulitermes speratus (Kolbe). Zool. Mag. 89:308-311.