Variations of SSU rDNA group I introns in different isolates of Cordyceps militaris and the loss of an intron during cross-mating

Cordyceps militaris, the type species of genus Cordyceps, is one of the most popular mushrooms and a nutraceutical in eastern Asia. It is considered a model organism for the study of Cordyceps species because it can complete its life cycle when cultured in vitro. In the present study, the occurrence and sequence variation of SSU rDNA group I introns, Cmi.S943 and Cmi.S1199, among different isolates of C. militaris were analyzed. Based on the secondary structure predictions, the Cmi.S943 intron has been placed in subgroup IC1, and the Cmi.S1199 intron has been placed in subgroup IE. No significant similarity between Cmi.S943 and Cmi.S1199 suggested different origins. Three genotypes, based on the frequency and distribution of introns, were described to discriminate the 57 surveyed C. militaris strains. It was found that the genotype was related to the stroma characteristics. The stromata of all of the genotype II strains, which possessed only Cmi.S943, could produce perithecium. In contrast, the stromata of all genotype III strains, which had both Cmi.S943 and Cmi.S1199, could not produce perithecium. Cmi.S1199 showed the lowest level of intra-specific variation among the tested strains. Group I introns can be lost during strain cross-mating. Therefore, we presumed that during cross-mating and recombination, intron loss could be driven by positive Darwinian selection due to the energetic cost of transcribing long introns.     

Identification of group I introns within the SSU rDNA gene in species of Ceratocystiopsis and related taxa

During a recent phylogenetic study, group I introns were noted that interrupt the nuclear small subunit ribosomal RNA (SSU rDNA) gene in species of Ceratocystiopsis. Group I introns were found to be inserted at the following rDNA positions: S943, S989, and S1199. The introns have been characterized and phylogenetic analysis of the host gene and the corresponding intron data suggest that for S943 vertical transfer and frequent loss appear to be the most parsimonious explanation for the distribution of nuclear SSU rDNA introns among species of Ceratocystiopsis. The SSU rDNA data do suggest that a recent proposal of segregating the genus Ophiostoma sensu lato into Ophiostoma sensu stricto, Grosmannia, and Ceratocystiopsis has some merit but may need further amendments, as the SSU rDNA suggests that Ophiostoma s. str. may now represent a paraphyletic grouping.     

Recovery of an Acanthamoeba strain with two group I introns in the nuclear 18S rRNA gene

Nuclear group I introns are parasitic mobile genetic elements occurring in the ribosomal RNA genes of a large variety of microbial eukaryotes. In Acanthamoeba, group I introns were found occurring in the 18S rDNA at four distinct insertion sites. Introns are present as single elements in various strains belonging to four genotypes, T3 (A. griffini), T4 (A. castellanii complex), T5 (A. lenticulata) and T15 (A. jacobsi). While multiple introns can frequently be found in the rDNA of several algae, fungi and slime moulds, they are usually rare and present as single elements in amoebae. We reported herein the characterization of an A. lenticulata strain containing two introns in its 18S rDNA. They are located to already known sites and show basal relationships with respective homologous introns present in the other T5 strains. This is the first and unique reported case of multiple nuclear introns in Acanthamoeba.     

Eu-Chlorella large subunit rDNA sequences and group I introns in ribosomal DNA of the paramecian symbiotic alga NC64A

Although the examination of large subunit ribosomal RNA genes (LSU rDNA) is advanced in phylogenetic studies, no corresponding sequence data from trebouxiophytes have been published, with the exception of ‘Chlorella’ellipsoidea Gerneck. We determined the LSU rDNA sequence of Chlorella vulgaris Beijerinck and of the symbiotic alga of green paramecium, Chlorella sp. NC64A. A total of 59 nucleotide substitutions were found in the LSU rDNA of the two species, which are disproportionately distributed. Primarily, 65% of the substitutions were encountered in the first 800 bp of the alignment. This segment apparently has evolved eight times faster than the complete SSU rDNA sequence, making it a good candidate for a phylogenetic marker and giving a resolution level intermediate between small subunit (SSU) rDNA and internal transcribed spacers. Green algae are known as a group I intron‐rich group along with rhodophytes and fungi. NC64A is particularly rich in the introns; five introns were newly identified from the LSU rDNA sequence, which we named Cnc.L200, Cnc.L1688, Cnc.L1926, Cnc.L2184 and Cnc.L2437, following the insertion positions. In the present study we analyzed these introns with three others (Cnc.S943, Cnc.S1367 and Cnc.S1512) that had already been found in NC64A SSU rDNA. Secondary structure modeling placed these introns in the group I intron family, with four introns belonging to subgroup C1 and the other four introns belonging to subgroup E. Five of the intron insertion positions are unique to the paramecian symbiont, which may indicate relatively recent events of intron infections that includes transpositions. Intron phylogeny showed unprecedented relationships; four Cnc. IC1 introns made a clade with some green algal introns with insertions at nine different positions, whereas four Cnc. IE introns made a clade with the S651 intron (Chlorella sp. AN 1–3), which lay as a sister to the S516 insertion position subfamily.     

The evolution of homing endonuclease genes and group I introns in nuclear rDNA

Group I introns are autonomous genetic elements that can catalyze their own excision from pre-RNA. Understanding how group I introns move in nuclear ribosomal (r)DNA remains an important question in evolutionary biology. Two models are invoked to explain group I intron movement. The first is termed homing and results from the action of an intron-encoded homing endonuclease that recognizes and cleaves an intronless allele at or near the intron insertion site. Alternatively, introns can be inserted into RNA through reverse splicing. Here, we present the sequences of two large group I introns from fungal nuclear rDNA, which both encode putative full-length homing endonuclease genes (HEGs). Five remnant HEGs in different fungal species are also reported. This brings the total number of known nuclear HEGs from 15 to 22. We determined the phylogeny of all known nuclear HEGs and their associated introns. We found evidence for intron-independent HEG invasion into both homologous and heterologous introns in often distantly related lineages, as well as the "switching" of HEGs between different intron peripheral loops and between sense and antisense strands of intron DNA. These results suggest that nuclear HEGs are frequently mobilized. HEG invasion appears, however, to be limited to existing introns in the same or neighboring sites. To study the intron-HEG relationship in more detail, the S943 group I intron in fungal small-subunit rDNA was used as a model system. The S943 HEG is shown to be widely distributed as functional, inactivated, or remnant ORFs in S943 introns.     

Evolution of <Emphasis Type="Italic">Pleopsidium</Emphasis> (Lichenized Ascomycota) S943 Group I Introns and the Phylogeography of an Intron-Encoded Putative Homing Endonuclease

The sporadic distribution of nuclear group I introns among different fungal lineages can be explained by vertical inheritance of the introns followed by successive losses, or horizontal transfers from one lineage to another through intron homing or reverse splicing. Homing is mediated by an intron-encoded homing endonuclease (HE) and recent studies suggest that the introns and their associated HE gene (HEG) follow a recurrent cyclical model of invasion, degeneration, loss, and reinvasion. The purpose of this study was to compare this model to the evolution of HEGs found in the group I intron at position S943 of the nuclear ribosomal DNA of the lichen-forming fungus Pleopsidium. Forty-eight S943 introns were found in the 64 Pleopsidium samples from a worldwide screen, 22 of which contained a full-length HEG that encodes a putative 256-amino acid HE, and 2 contained HE pseudogenes. The HEGs are divided into two closely related types (as are the introns that encode them) that differ by 22.6% in their nucleotide sequences. The evolution of the Pleopsidium intron-HEG element shows strong evidence for a cyclical model of evolution. The intron was likely acquired twice in the genus and then transmitted via two or three interspecific horizontal transfers. Close geographical proximity plays an important role in intron-HEG horizontal transfer because most of these mobile elements were found in Europe. Once acquired in a lineage, the intron-HEG element was also vertically transmitted, and occasionally degenerated or was lost. [Reviewing Editor: Dr. Manyuan Long]     

EVIDENCE FOR LATERAL TRANSFER OF AN IE INTRON BETWEEN FUNGAL AND RED ALGAL SMALL SUBUNIT RRNA GENES1

A previous study of the North American biogeography of the red algal genus Hildenbrandia noted the presence of group I introns in the nuclear small subunit (SSU) rRNA gene of the marine species H. rubra (Sommerf.) Menegh. Group IC1 introns have been previously reported at positions 516 and 1506 in the nuclear SSU RNA genes in the Bangiales and Hildenbrandiales. However, the presence of an unclassified intron at position 989 in a collection of H. rubra from British Columbia was noted. This intron is a member of the IE subclass and is the first report of this intron type in the red algae. Phylogenetic analyses of the intron sequences revealed a close relationship between this IE intron inserted at position 989 and similar fungal IE introns in positions 989 and 1199. The 989 IE introns formed a moderately to well‐supported clade, whereas the 1199 IE introns are weakly supported. Unique structural helices in the P13 domain of the 989 and 1199 IE introns also point to a close relationship between these two clades and provide further evidence for the value of secondary structural characteristics in identifying homologous introns in evolutionarily divergent organisms. The absence of the 989 IE intron in all other red algal nuclear SSU rRNA genes suggests that it is unlikely that this intron was vertically inherited from the common ancestor of the red algal and fungal lineages but rather is the result of lateral transfer between fungal and red algal nuclear SSU rRNA genes.     

Group I Introns from Zygomycota: Evolutionary Implications for the Fungal IC1 Intron Subgroup

The origins of fungal group I introns within nuclear small-subunit (nSSU) rDNA are enigmatic. This is partly because they have never been reported in basal fungal phyla (Zygomycota and Chytridiomycota), which are hypothesized to be ancestral to derived phyla (Ascomycota and Basidiomycota). Here we report group I introns from the nSSU rDNA of two zygomycete fungi, Zoophagus insidians (Zoopagales) and Coemansia mojavensis (Kickxellales). Secondary structure analyses predicted that both introns belong to the IC1 subgroup and that they are distantly related to each other, which is also suggested by different insertion sites. Molecular phylogenetic analyses indicated that the IC1 intron of Z. insidians is closely related to the IC1 intron inserted in the LSU rDNA of the basidiomycete fungus Clavicorona taxophila, which strongly suggests interphylum horizontal transfer. The IC1 intron of C. mojavensis has a low phylogenetic affinity to other fungal IC1 introns inserted into site 943 of nSSU rDNA (relative to E. coli 16S rDNA). It is noteworthy that this intron contains a putative ORF containing a His–Cys box motif in the antisense strand, a hallmark for nuclear-encoded homing endonucleases. Overall, molecular phylogenetic analyses do not support the placement of these two introns in basal fungal IC1 intron lineages. This result leads to the suggestion that fungal IC1 introns might have invaded or been transferred laterally after the divergence of the four major fungal phyla. Received: 8 February 2001 / Accepted: 1 November 2001     

A structural and phylogenetic analysis of the group IC1 introns in the order Bangiales (Rhodophyta)

Our previous study of the North American biogeography of Bangia revealed the presence of two introns inserted at positions 516 and 1506 in the nuclear-encoded SSU rRNA gene. We subsequently sequenced nuclear SSU rRNA in additional representatives of this genus and the sister genus Porphyra in order to examine the distribution, phylogeny, and structural characteristics of these group I introns. The lengths of these introns varied considerably, ranging from 467 to 997 nt for intron 516 and from 509 to 1,082 nt for intron 1506. The larger introns contained large insertions in the P2 domain of intron 516 and the P1 domain of intron 1506 that correspond to open reading frames (ORFs) with His-Cys box homing endonuclease motifs. These ORFs were found on the complementary strand of the 1506 intron in Porphyra fucicola and P. umbilicalis (HG), unlike the 516 intron in P. abbottae, P. kanakaensis, P. tenera (SK), Bangia fuscopurpurea (Helgoland), and B. fuscopurpurea (MA). Frameshifts were noted in the ORFs of the 516 introns in P. kanakaensis and B. fuscopurpurea (HL), and all ORFs terminated prematurely relative to the amino acid sequence for the homing endonuclease I-Ppo I. This raises the possibility that these sequences are pseudogenes. Phylogenies generated using sequences of both introns and the 18S rRNA gene were congruent, which indicated long-term immobility and vertical inheritance of the introns followed by subsequent loss in more derived lineages. The introns within the florideophyte species Hildenbrandia rubra (position 1506) were included to determine relationships with those in the Bangiales. The two sequences of intron 1506 analyzed in Hildenbrandia were positioned on a well-supported branch associated with members of the Bangiales, indicating possible common ancestry. Structural analysis of the intron sequences revealed a signature structural feature in the P5b domain of intron 516 that is unique to all Bangialean introns in this position and not seen in intron 1506 or other group IC1 introns.     

Structural features and evolutionary considerations of group IB introns in SSU rDNA of the lichen fungus Teloschistes

Different species of the lichen-forming ascomycete fungus Teloschistes were found to contain group IB introns at position S1506 in the small subunit ribosomal RNA gene. We have characterized the structural organization and phylogeny of the Teloschistes introns Tco.S1506, Tla.S1506, and Tvi.S1506. Common features to all the introns are a small size, a compact RNA structure, and an atypical catalytic ribozyme core sequence motif. Variations in intron sizes, due to sequence extensions in the P1 and P8 loop segments, were observed in different species and isolates. Phylogenetic analyses based on the ITS1-5.8S-ITS2 region as well as the introns show that the Teloschistes S1506 introns represent a distinct evolutionary isolated cluster among the nuclear group I introns. Furthermore, introns from different lineages of Teloschistes villosus appear not strictly vertically inherited probably due to horizontal transfer in one of the lineages.     

Patterns of Group I Intron Presence in Nuclear SSU rDNA of the Lichen Family Parmeliaceae

Group I introns are commonly reported within nuclear SSU ribosomal DNA of eukaryotic micro-organisms, especially in lichen-forming fungi. We have studied the primary and secondary structure of 70 new nuclear SSU rDNA group I introns of Parmeliaceae (Ascomycota: Lecanorales) and compared them with those available in databases, covering more than 60 species. The analyzed samples of Parmeliaceae fell into two groups, one having an intron at the 1506 site and another lacking this one but having another at the 1516 or 1521 position. Introns at the 1521 position seem to be transposed from 1516 sites. Introns at the 1516 position were similar in structure to ones previously reported at this site and known from other lecanoralean fungi, while those at the 1506 position showed structural differences and no similar introns are known from related fungi. The study of the distribution of group I introns within a large monophyletic ensemble of fungi has revealed an unexpected correlation between intron types and ecological and geographical parameters. The introns at the 1516 position occurred in mainly arctic, boreal, and temperate lichens, while those at position 1506 were present in mainly tropical and subtropical to oceanic mild-temperate taxa. Further, the 1516 introns occurred in genera with few distributed species that could represent older taxa, while the 1506 ones were mainly in species-rich genera that could be of recent speciation, as many species have wide distribution areas. The transition between two different environments has been accompanied by a change in introns gained and lost. [Reviewing Editor: Dr. Debashish Bhattacharya]     

Niche-Partitioning of Prochlorococcus Populations in a Stratified Water Column in the Eastern North Atlantic Ocean

The in situ community structure of Prochlorococcus populations in the eastern North Atlantic Ocean was examined by analysis of Prochlorococcus 16S rDNA sequences with three independent approaches: cloning and sequencing, hybridization to specific oligonucleotide probes, and denaturing gradient gel electrophoresis (DGGE). The hybridization of high-light (HL) and low-light (LL) Prochlorococcus genotype-specific probes to two depth profiles of PCR-amplified 16S rDNA sequences revealed that in these two stratified water columns, an obvious niche-partitioning of Prochlorococcus genotypes occurred. In each water column a shift from the HL to the LL genotype was observed, a transition correlating with the depth of the surface mixed layer (SML). Only the HL genotype was found in the SML in each water column, whereas the LL genotype was distributed below the SML. The range of in situ irradiance to which each genotype was subjected within these distinct niches was consistent with growth irradiance studies of cultured HL- and LL-adapted Prochlorococcus strains. DGGE analysis and the sequencing of Prochlorococcus 16S rDNA clones were in full agreement with the genotype-specific oligonucleotide probe hybridization data. These observations of a partitioning of Prochlorococcus genotypes in a stratified water column provide a genetic basis for the dim and bright Prochlorococcus populations observed in flow cytometric signatures in several oceanic provinces.     

Complex Evolutionary Patterns of tRNAUAALeu Group I Introns in Cyanobacterial Radiation

Based on the findings that plastids and cyanobacteria have similar group I introns inserted into tRNAUAALeu genes, these introns have been suggested to be immobile and of ancient origin. In contrast, recent evidence suggests lateral transfer of cyanobacterial group I introns located in tRNAUAALeu genes. In light of these new findings, we have readdressed the evolution and lateral transfer of tRNAUAALeu group I introns in cyanobacteral radiation. We determined the presence of introns in 38 different strains, representing the major cyanobacterial lineages, and characterized the introns in 22 of the strains. Notably, two of these strains have two tRNAUAALeu genes, with each of these genes interrupted by introns, while three of the strains have both interrupted and uninterrupted genes. Two evolutionary distinct clusters of tRNA genes, with the genes interrupted by introns belonging to two distinct intron clusters, were identified. We also compared 16S rDNA and intron evolution for both closely and distantly related strains. The distribution of the introns in the clustered groups, as defined from 16S rDNA analysis, indicates relatively recent gain and/or loss of the introns in some of these lineages. The comparative analysis also suggests differences in the phylogenetic trees for 16S rDNA and the tRNAUAALeu group I introns. Taken together, our results show that the evolution of the intron is considerably more complex than previous studies found to be the case. We discuss, based on our results, evolutionary models involving lateral intron transfer and models involving differential loss of the intron.     

The recent transfer of a homing endonuclease gene

The myxomycete Didymium iridis (isolate Panama 2) contains a mobile group I intron named Dir.S956-1 after position 956 in the nuclear small subunit (SSU) rRNA gene. The intron is efficiently spread through homing by the intron-encoded homing endonuclease I-DirI. Homing endonuclease genes (HEGs) usually spread with their associated introns as a unit, but infrequently also spread independent of introns (or inteins). Clear examples of HEG mobility are however sparse. Here, we provide evidence for the transfer of a HEG into a group I intron named Dir.S956-2 that is inserted into the SSU rDNA of the Costa Rica 8 isolate of D.iridis. Similarities between intron sequences that flank the HEG and rDNA sequences that flank the intron (the homing endonuclease recognition sequence) suggest that the HEG invaded the intron during the recent evolution in a homing-like event. Dir.S956-2 is inserted into the same SSU site as Dir.S956-1. Remarkably, the two group I introns encode distantly related splicing ribozymes with phylogenetically related HEGs inserted on the opposite strands of different peripheral loop regions. The HEGs are both interrupted by small spliceosomal introns that must be removed during RNA maturation.     

124 Evidence for Lateral Transfer of a IE Intron between Fungal and Red Algal Small Subunit Ribosomal RNA Genes

In a recent study of the North American biogeography of the red algae genus Hildenbrandia, the presence of group I introns were noted in the nuclear SSU rRNA gene of the marine species H. rubra (Hildenbrandiales). Group I introns in the nuclear encoded rRNAs have been previously reported in the Hildenbrandiales as well as the Bangiales. All reported introns within the red algae have been identified as belonging to the IC1 subclass and occur at two insertion sites in the nuclear small subunit rRNA (516 and 1506). However, an unclassified intron was discovered at position 989 in the nuclear SSU rRNA gene of a collection of H. rubra from British Columbia, Canada. We have determined that the intron is a member of the IE subclass and this is the first report of an IE intron and an intron in position 989 in the red algae. Phylogenetic analyses of the intron sequences reveal a close relationship between this group IE intron and similar ascomycete and basidiomycete fungal IE introns in the nuclear SSU rRNA genes at positions 989 and 1199. In addition, a common unique helix (structural signature) in the P13 domain of the Hildenbrandia intron and those of the fungi at the 989 and 1199 IE positions in the nuclear SSU rRNA gene also indicates a close relationship. Hence, this study provides evidence for a possible lateral transfer of the IE intron in position 989 between fungal and red algal nuclear SSU rRNA genes.     

Evolutionary dynamics of multiple group I introns in nuclear ribosomal RNA genes of endoparasitic fungi of the genus Cordyceps

A large number of group I introns were discovered in coding regions of small and large subunits of nuclear ribosomal RNA genes (SSU rDNA and LSU rDNA) in ascomycetous fungi of the genus CORDYCEPS: From 28 representatives of the genus, we identified in total 69 group I introns which were inserted at any of four specific sites in SSU rDNA and four specific sites in LSU rDNA. These group I introns reached sizes of up to 510 bp, occurred in up to eight sites in the same organism, and belonged to either subgroup IB3 or subgroup IC1 based on their sequence and structure. Introns inserted at the same site were closely related to each other among Cordyceps fungi, whereas introns inserted at different sites were phylogenetically distinct even in the same species. Mapped on the host phylogeny, the group I introns were generally not restricted to a particular lineage, but, rather, widely and sporadically distributed among distinct lineages. When the phylogenetic relationships of introns inserted at the same site were compared with the phylogeny of their hosts, the topologies were generally significantly congruent to each other. From these results, the evolutionary dynamics of multiple group I introns in Cordyceps fungi was inferred as follows: (1) most of the group I introns were already present at the eight sites in SSU and LSU rDNAs of the ancestor of the genus Cordyceps; (2) the introns have principally been immobile and vertically transmitted throughout speciation and diversification of Cordyceps fungi, which resulted in the phylogenetic congruence between the introns at the same site and their hosts; (3) in the course of vertical transmission, the introns have repeatedly been lost in a number of lineages independently, which has led to the present sporadic phylogenetic distribution of the introns; and (4) a few acquisitions of new introns, presumably through horizontal transmission, were identified in the evolutionary history of the genus Cordyceps, while no transpositions were detected. Losses of group I introns in SSU rDNA have occurred at least 27 times in the evolutionary course of the 28 Cordyceps members.     

采用PCR-RFLP技术在不同水平上鉴定大豆根瘤菌

采用16S rRNA基因PCR扩增与限制性酶切片段多态性分析(RFLP)技术对选自弗氏中华根瘤菌(S.fredii)、大豆慢生根瘤菌(B.japonicum)和埃氏慢生根瘤菌(B.elkanii)的19株代表菌进行了比较分析,根据用3种限制性内切酶的RFLP分析结果,可将供试菌株分为S.fredii,B.japonicum, B.elkanii Ⅱ和B.elkanii Ⅱa等4种基因型。各类菌株之间没有交叉,因此本研究采用的PCR-RFLP技术不失为一种快速鉴别大豆根瘤菌的新方法。采用本技术已将分离自中国的22株快生菌和19株慢生菌分别鉴定为S.fredii和B.japonicum。对供试参比菌株和野生型菌株进行的16S～23S基因间隔DNA(IGS)的PCR-RFLP分析结果表明：S.fredii和B.japonicum菌株的IGS长度不同,所有供试S.fredii菌株的IGS为2.1 kb,而供试B.japonicum菌株则为2.0 kb。依据RFLP的差异,可将来自中国两个不同地区的S.fredii株区分为2个基因型,而来自中国东北黑龙江地区的19株B.japonicum菌株则可分为11个基因型。对上述野生型菌株还进行了REP-PCR和ERIC-PCR分析并确定其具有菌株水平的特异性。     

Unconventional GIY-YIG homing endonuclease encoded in group I introns in closely related strains of the Bacillus cereus group

Several group I introns have been previously found in strains of the Bacillus cereus group at three different insertion sites in the nrdE gene of the essential nrdIEF operon coding for ribonucleotide reductase. Here, we identify an uncharacterized group IA intron in the nrdF gene in 12 strains of the B. cereus group and show that the pre-mRNA is efficiently spliced. The Bacillus thuringiensis ssp. pakistani nrdF intron encodes a homing endonuclease, denoted I-BthII, with an unconventional GIY-(X)₈-YIG motif that cleaves an intronless nrdF gene 7 nt upstream of the intron insertion site, producing 2-nt 3′ extensions. We also found four additional occurrences of two of the previously reported group I introns in the nrdE gene of 25 sequenced B. thuringiensis and one B. cereus strains, and one non-annotated group I intron at a fourth nrdE insertion site in the B. thuringiensis ssp. Al Hakam sequenced genome. Two strains contain introns in both the nrdE and the nrdF genes. Phylogenetic studies of the nrdIEF operon from 39 strains of the B. cereus group suggest several events of horizontal gene transfer for two of the introns found in this operon.     

Distribution and Evolution of the Xylanase Genes xynA and xynB and Their Homologues in Strains of Butyrivibrio fibrisolvens

The ruminal bacterium Butyrivibrio fibrisolvens is being engineered by the introduction of heterologous xylanase genes in an attempt to improve the utilization of plant material in ruminants. However, relatively little is known about the diversity and distribution of the native xylanase genes in strains of B. fibrisolvens. In order to identify the most appropriate hosts for such modifications, the xylanase genotypes of 28 strains from the three 16S ribosomal DNA (rDNA) subgroups of Butyrivibrio fibrisolvens have been investigated. Only 4 of the 20 strains from 16S rDNA group 2 contained homologues of the strain Bu49 xynA gene. However, these four xynA-containing strains, and two other group 2 strains, contained members of a second xylanase gene family clearly related to xynA (subfamily I). Homologues of xynB, a second previously described xylanase gene from B. fibrisolvens, were identified only in three of the seven group 1 strains and not in the group 2 and 3 strains. However, six of the group 1 strains contained one or more members of the two subfamilies of homologues of xynA. The distribution of genes and the nucleotide sequence relationships between the members of the two xynA subfamilies are consistent with the progenitor of all strains of B. fibrisolvens having contained a xynA subfamily I gene. Since many xylanolytic strains of B. fibrisolvens did not contain members of either of the xynA subfamilies or of the xynB family, at least one additional xylanase gene family remains to be identified in B. fibrisolvens.