Genetic diversity analysis of Capparis spinosa L. populations by using ISSR markers.

Capparis spinosa L. is an important medicinal species in the Xinjiang Province of China. Ten natural populations of C. spinosa from 3 locations in North, Central, and South Xinjiang were studied using morphological trait inter simple sequence repeat (ISSR) molecular markers to assess the genetic diversity and population structure. In this study, the 10 ISSR primers produced 313 amplified DNA fragments, with 52% of fragments being polymorphic. Unweighted pair-group method with arithmetic average (UPGMA) cluster analysis indicated that 10 C. spinosa populations were clustered into 3 geographically distinct groups. The Nei gene of C. spinosa populations in different regions had Diversity and Shannon's information index ranges of 0.1312-0.2001 and 0.1004-0.1875, respectively. The 362 markers were used to construct the dendrogram based on the UPGMA cluster analysis. The dendrogram indicated that 10 populations of C. spinosa were clustered into 3 geographically distinct groups. The results showed these genotypes have high genetic diversity, and can be used for an alternative breeding program.

Use of asymmetric somatic hybridization for transfer of the bacterial blight resistance trait from Oryza meyeriana L. to O. sativa L. ssp. japonica.

Bacterial blight is one of the major diseases affecting rice productivity. To improve the resistance of cultivated rice to bacterial blight, we introduced a bacterial blight resistance trait from Oryza meyeriana, a wild rice species, into an elite japonica rice cultivar (Dalixiang) using asymmetric somatic hybridization. One hundred and thirty-two independent lines were regenerated. The hybrid plants possessed several morphological features of the donor species, O. meyeriana. Random amplified polymorphic DNA analysis revealed that hybrid plants exhibited banding patterns derived from their parental genotypes. For the majority of the hybrids, resistance to bacterial blight pathogens was intermediate to that observed for O. meyeriana and O. sativa (cv. Dalixiang). Four of the hybrid lines exhibited a high bacterial blight resistance, but it was less than that observed for O. meyeriana. These results demonstrate that O. meyeriana can be used as a good genetic source for improving bacterial blight resistance in commercial rice cultivars through asymmetric somatic hybridization.

A synthetic xylanase as a novel reporter in plants.

Transient gene expression assays are often used to screen promoters before stable transformation. Current transient quantification methods have several problems, including a lack of reporter gene stability and expense. Here we report a synthetic, codon-optimised xylanase gene ( sXynA) as a reporter gene for quantitative transient analyses in plants. Azurine-crosslinked xylan (AZCL-xylan) was used as a substrate for assaying xylanase activity. The enzymatic nature of the protein allows for sensitive assays at the low levels of transgene protein found in transiently transformed tissue extracts. The xylanase (XYN) protein is stable, activity slopes are linear over long time periods and assays are cost-effective. Coupled with the GUS Plus reporter gene, the XYN reporter allows sensitive and accurate quantification of gene control sequences in transient expression systems.

Selectable marker-free transgenic barley producing a high level of cellulase (1,4-beta-glucanase) in developing grains.

The use of barley grains as bioreactors for high-level production of cellulase (1,4-beta-glucanase) was investigated. A hybrid cellulase gene, cel-hyb1, driven by the rice GluB-1 promoter was expressed specifically in developing endosperm. Codon usage optimisation of cel-hyb1 increased its expression in barley grains 527-fold and led to cellulase production of up to 1.5% of total grain protein. CEL-HYB1 enzyme in barley grains was highly stable during post-harvest storage. Selectable marker gene ( hph) was subsequently eliminated from transgenic lines through segregation of hph from synthetic cel-hyb1 ( syn.cel-hyb1) in T1 progeny, using a binary plasmid containing hph and syn.cel-hyb1 in separate T-DNAs. These data suggest that barley grains can potentially be used for the commercial production of cellulase.

Transformation and expression of an anaerobic fungal xylanase in several strains of the rumen bacterium Butyrivibrio fibrisolvens.

AIMS: To obtain reliable transformation of a range of Butyrivibrio fibrisolvens strains and to express a Neocallimastix patriciarum xylanase gene in the recipients. METHODS AND RESULTS: Eight strains (H17c, E14, LP1309, LP1028, AR11a, OB156, LP210B and LP461A) of Bu. fibrisolvens were transformed by the Gram-positive vector pUB110. A xylanase expression/secretion cassette containing Bu. fibrisolvens promoter and signal peptide elements fused to catalytic domain II of the N. patriciarum xylanase A cDNA (xynANp) was inserted into pUB110 to create the plasmid pUBxynA. pUBxynA was used to transform seven of the Bu. fibrisolvens strains transformed by pUB110. In strain H17c pUBxynA, which produced native xylanase, 2.46 U mg-1 total xylanase activity was produced with 45% extracellular xylanase. In strain H17c pUMSX, 0.74 U mg-1 total xylanase activity was produced with 98% extracellular xylanase. H17c pUBxynA exhibited increased (28.7%) degradation of neutral detergent fibre compared with unmodified H17c; however, progressive loss of pUBxynA was observed in long-term cultivation. CONCLUSIONS: A stable transformation system was developed that was applicable for a range of Bu. fibrisolvens strains and high levels of expression of a recombinant xylanase were obtained in H17c which lead to increased fibre digestion. SIGNIFICANCE AND IMPACT OF THE STUDY: This stable transformation system with the accompanying recombinant plasmids will be a useful tool for further investigation aimed at improving ruminal fibre digestion.

Expression of a modified Neocallimastix patriciarum xylanase in Butyrivibrio fibrisolvens digests more fibre but cannot effectively compete with highly fibrolytic bacteria in the rumen.

AIMS: This study investigated the competitive abilities of two Neocallimastix patriciarum-derived xylanases constructs in Butyrivibrio fibrisolvens H17c (xynA and pUMSX) and their ability to compete in vivo. METHODS AND RESULTS: The digestibility of neutral detergent fibre (NDF) increased during co-culture of xynA or pUMSX and weakly cellulolytic, but not with highly cellulolytic, ruminococci. Competition studies among xynA, pUMSX and cellulolytic consortia demonstrated that xynA was the fittest. XynA did not persist at high levels in the rumen and was undetectable after 22 days. CONCLUSION: The construction of recombinant xylanolytic B. fibrisolvens does improve the digestibility of fibre above that of the native, but digestibility is still less than that of the most potent fibre digesters such as ruminococci. SIGNIFICANCE AND IMPACT OF THE STUDY: Fibre digestion may be improved by genetic manipulation of ruminal bacteria but ecological parameters, such as persistence in vivo and the niche of the organism, must be taken into account.

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.

Improvement of expression and secretion of a fungal xylanase in the rumen bacterium Butyrivibrio fibrisolvens OB156 by manipulation of promoter and signal sequences.

Promoters and signal sequences for expression and secretion of a fungal xylanase encoded by a modified Neocallimastix patriciarum xynA cDNA in the rumen bacterium, Butyrivibrio fibrisolvens OB156, were investigated. Successful expression of the fungal xylanase in OB156 was obtained using the putative xylanase promoter from B. fibrisolvens strain 49. Replacing the putative -35 region sequence (TTGCAC) of the xylanase promoter with the sequence TTGACA by mutagenesis reduced the fungal xylanase expression level 4-fold in OB156, indicating that this B. fibrisolvens strain did not efficiently recognise the E. coli consensus -35 sequence. Reduction of the spacer length between the -35 and -10 regions of the xylanase promoter from 18 to 17 base-pairs (bp) considerably increased the expression levels of the fungal enzyme in both E. coli and OB156. Insertion of a pUB110 mob promoter upstream of the xylanase promoter also significantly improved the fungal xylanase expression. Secretion of the fungal xylanase mediated by the alpha-amylase signal peptide from B. fibrisolvens strain H17c was efficient in E. coli, but very poor in OB156. An increase in the hydrophobicity of the signal sequence resulted in a 4-fold increase in the extracellular portion of the fungal xylanase in OB156, indicating marked improvement in xylanase secretion efficiency. The recombinant plasmids and xylanase expression/secretion cassettes were found to be stable in OB156 after prolonged cultivation (100 generations) in the absence of antibiotic selection. These results suggest that the rumen bacterium B. fibrisolvens can be manipulated to produce and secrete a eukaryotic extracellular protein with stable maintenance of the expression cassette in plasmid form.

Cloning of a gene encoding cinnamoyl ester hydrolase from the ruminal bacterium Butyrivibrio fibrisolvens E14 by a novel method.

A gene (cinI) encoding a cinnamoyl ester hydrolase (CEH) has been isolated from the ruminal bacterium, Butyrivibrio fibrisolvens E14, using a model substrate, MUTMAC [4-methylumbelliferoyl (p-trimethylammonium cinnamate chloride)]. CinI has significant amino-acid similarities with members of a large and diverse family of hydrolases with a serine/aspartic acid/histidine catalytic triad. Our analyses identified two previously unclassified amino acid sequences, the amino-terminal domain of unknown function in XynZ from Clostridium thermocellum and XynC, an acetylxylan esterase from Caldicellulosiruptor saccharolyticus, as members of the same family of hydrolases. A previously described esterase with CEH activity, XylD from Pseudomonas fluorescens ssp. cellulosa, is not similar to CinI. CinI was expressed at high levels in the periplasmic fraction of E. coli TOPP2 and released ferulic acid from Fara [5-O-(trans-feruloyl)-arabinofuranose] prepared from wheat bran.

Characterization of a Neocallimastix patriciarum cellulase cDNA (celA) homologous to Trichoderma reesei cellobiohydrolase II.

The nucleotide sequence of a cellulase cDNA (celA) from the rumen fungus Neocallimastix patriciarum and the primary structure of the protein which it encodes were characterized. The celA cDNA was 1.95 kb long and had an open reading frame of 1,284 bp, which encoded a polypeptide having 428 amino acid residues. A sequence alignment showed that cellulase A (CELA) exhibited substantial homology with family B cellulases (family 6 glycosyl hydrolases), particularly cellobiohydrolase II from the aerobic fungus Trichoderma reesei. In contrast to previously characterized N. patriciarum glycosyl hydrolases, CELA did not exhibit homology with any other rumen microbial cellulases described previously. Primary structure and function studies in which deletion analysis and a sequence comparison with other well-characterized cellulases were used revealed that CELA consisted of a cellulose-binding domain at the N terminus and a catalytic domain at the C terminus. These two domains were separated by an extremely Asn-rich linker. Deletion of the cellulose-binding domain resulted in a marked decrease in the cellulose-binding ability and activity toward crystalline cellulose. When CELA was expressed in Escherichia coli, it was located predominantly in the periplasmic space, indicating that the signal sequence of CELA was functional in E.coli. Enzymatic studies showed that CELA had an optimal pH of 5.0 and an optimal temperature of 40 degrees C. The specific activity of immunoaffinity-purified CELA against Avicel was 9.7 U/mg of protein, and CELA appeared to be a relatively active cellobiohydrolase compared with the specific activities reported for other cellobiohydrolases, such as T. reesei cellobiohydrolases I and II.

Temperature-regulated expression of the tac/lacl system for overproduction of a fungal xylanase in Escherichia coli.

Temperature-regulated expression of recombinant proteins in the tac promoter (Ptac) system was investigated. Expression levels of fungal xylanase and cellulase from N. patriciarum in E. coli strains containing the natural lacI gene under the control of the Ptac markedly increased with increasing cultivation temperature in the absence of a chemical inducer. The specific activities (units per milligram protein of crude enzyme) of the fungal xylanase and cellulase produced from recombinant E. coli strain pop2136 grown at 42 degrees C were about 4.5 times higher than those of the cells grown at 23 degrees C and were even slightly higher when compared with cells grown in the presence of the inducer isopropyl beta-D-thiogalactopyranoside. The xylanase expression level in the temperature-regulated Ptac system was about 35% of total cellular protein. However, this system can not be applied to E. coli strains containing lacIq, which confers over production of the lac repressor, for high-level expression of recombinant proteins. In comparison with the lambda PL system, the Ptac-based xylanase plasmid in E. coli pop2136 gave a considerably higher specific activity of the xylanase than did the best lambda PL-based construct using the same thermal induction procedure. The high-level expression of the xylanase using the temperature-regulated Ptac system was also obtained in 10-litre fermentation studies using a fed-batch process. These results unambiguously demonstrated that the temperature-modulated Ptac system can be used for overproduction of some non-toxic recombinant proteins.

Modification of a xylanase cDNA isolated from an anaerobic fungus Neocallimastix patriciarum for high-level expression in Escherichia coli.

A Neocallimastix patriciarum xylanase cDNA with the core coding sequence essentially identical to xynA was isolated and modified for high-level expression in Escherichia coli. The xylanase cDNA was truncated into individual catalytic domains, which were modified at the N-terminus. These modified xylanases were synthesised as non-fusion proteins under the control of the tac promoter. High-level expression was obtained with the modified domain II construct, accounting for approx. 25% of total cellular protein. However, with the same vector and expression cassette, expression levels of constructs containing domain I or domains I and II fused in tandem were very low. RNA analysis revealed that the striking difference in expression levels of these three constructs was not due to transcription efficiency, but was mainly related to transcript stability. Further analysis of the domain II construct revealed that the high-level expression of the domain II xylanase was largely attributed to the presence of a favourable N-terminal coding sequence, as mutation at the N-terminus of the domain II dramatically reduced the expression level. The modified domain II xylanase produced in E. coli had a specific activity of 1229 U mg-1 protein at pH 7 and 50 degrees C without purification. The availability of a recombinant fungal xylanase with high specific activity and in high yield offers a potentially attractive source of xylanase for industrial applications.

Xylanase B from Neocallimastix patriciarum contains a non-catalytic 455-residue linker sequence comprised of 57 repeats of an octapeptide.

A Neocallimastix patriciarum cDNA library was screened for xylanase-expressing clones, which were distinct from the previously characterized N. patriciarum xynA cDNA encoding xylanase A. A single cDNA, designated xynB, which did not exhibit homology with xynA, was isolated. Northern-blot analysis of mRNA from Avicel-grown N. patriciarum showed that xynB hybridized to a 3.4 kb mRNA species. The nucleotide sequence of xynB revealed a single open reading frame of 2580 bp coding for a protein designated xylanase B (XYLB), of M(r) 88,066. The primary structure of XYLB was comprised of a 21-residue N-terminal signal peptide, followed by a 304-amino acid sequence that exhibited substantial homology with the catalytic domains of family F xylanases. The N-terminal domain was linked to a C-terminal 70-residue sequence by a putative linker region, comprising 12 tandem repeats of a sequence containing TLPG as the core sequence, followed by an octapeptide XSKTLPGG where X can be S, K or N, which was repeated in tandem 45 times. Truncated derivatives of xynB encoding the N-terminal 338 residues directed the synthesis of a functional xylanase, confirming that the region of XYLB, which exhibited homology with family F xylanases, constitutes the catalytic domain. To investigate the catalytic properties of XYLB, the catalytic domain was fused to the Escherichia coli maltose-binding protein, and the fusion protein purified by amylose affinity chromatography. The purified enzyme hydrolysed oat, rye and wheat arabinoxylan releasing primarily xylobiose, xylotriose and some xylose. The XYLB fusion did not cleave any cellulosic substrates. The data presented in this report suggest that the multiple xylanases of N. patriciarum arose, not through the duplication of a single gene, but by the transfer of distinct xylanase-encoding DNA sequences into the anaerobic fungus. The possible origin of the xynB gene is discussed.

Intronless celB from the anaerobic fungus Neocallimastix patriciarum encodes a modular family A endoglucanase.

The cDNA designated celB from the anaerobic rumen fungus Neocallimastix patriciarum contained a single open reading frame of 1422 bp coding for a protein (CelB) of M(r) 53,070. CelB expressed by Escherichia coli harbouring the full-length gene hydrolysed carboxymethylcellulose in the manner of an endoglucanase, but was most active against barley beta-glucan. It also released reducing sugar from xylan and lichenan, but was inactive against crystalline cellulose, laminarin, mannan, galactan and arabinan. The rate of hydrolysis of cellulo-oligosaccharides by CelB increased with increasing chain length from cellotriose to cellopentaose. The predicted structure of CelB contained features indicative of modular structure. The first 360 residues of CelB constituted a fully functional catalytic domain that was homologous with bacterial endoglucanases belonging to cellulase family A, including five which originate from three different species of anaerobic rumen bacteria. Downstream from this domain, and linked to it by a serine/threonine-rich hinge, was a non-catalytic domain containing short tandem repeats, homologous to the C-terminal repeats contained in xylanase A from the same anaerobic fungus. Unlike previous fungal cellulases, genomic celB was devoid of introns. This lack of introns and the homology of its encoded product with rumen bacterial endoglucanases suggest that acquisition of celB by the fungus may at some stage have involved horizontal gene transfer from a prokaryote to N. particiarum.

[Effect of intracerebroventricular injection of N-methyl-D-aspartate on learning and memory in mice].

In one trial passive avoidance response in mice, the effect of N-methyl-D-aspartate (NMDA) on acquisition, consolidation and retrieval of memory were observed after icv administration of 10 ng, 1 ng or 0.1 ng/mouse. The results showed that NMDA 10 ng/mouse could promote the consolidation of memory in step-down test and 1 ng/mouse could promote the retrieval of memory in step-through test. NMDA 1 ng/mouse significantly improved the retrieval impairment induced by 30% alcohol and the consolidation impairment induced by NaNO2 in step-down and step-through tests. The effect of NMDA on memory was antagonized by NMDA receptor antagonist, AP5. These results provide direct evidence for the action of NMDA subtype of glutamate receptor on memory.

A novel polysaccharide hydrolase cDNA (celD) from Neocallimastix patriciarum encoding three multi-functional catalytic domains with high endoglucanase, cellobiohydrolase and xylanase activities.

A plant polysaccharide hydrolase cDNA, designated celD, was isolated from a cDNA library of the rumen fungus Neocallimastix patriciarum. The enzyme encoded by celD had endoglucanase, cellobiohydrolase and xylanase activities. Deletion analysis revealed that celD cDNA can be truncated to code for three catalytically active domains. Each domain had the same substrate specificity as the enzyme produced by the untruncated celD and also possessed cellulose-binding capacity. Substrate competition studies showed that carboxymethylcellulose and xylan appear to compete with methylumbelliferyl cellobioside for the same active site within each domain. Expression of celD transcript in the rumen fungus was constitutive and was not affected by the presence of cellulose in the culture medium.

Homologous catalytic domains in a rumen fungal xylanase: evidence for gene duplication and prokaryotic origin.

A cDNA (xynA), encoding xylanase A (XYLA), was isolated from a cDNA library, derived from mRNA extracted from the rumen anaerobic fungus, Neocallimastix patriciarum. Recombinant XYLA, purified from Escherichia coli harbouring xynA, had a M(r) of 53,000 and hydrolysed oat-spelt xylan to xylobiose and xylose. The enzyme did not hydrolyse any cellulosic substrates. The nucleotide sequence of xynA revealed a single open reading frame of 1821 bp coding for a protein of M(r) 66,192. The predicted primary structure of XYLA comprised an N-terminal signal peptide followed by a 225-amino-acid repeated sequence, which was separated from a tandem 40-residue C-terminal repeat by a threonine/proline linker sequence. The large N-terminal reiterated regions consisted of distinct catalytic domains which displayed similar substrate specificities to the full-length enzyme. The reiterated structure of XYLA suggests that the enzyme was derived from an ancestral gene which underwent two discrete duplications. Sequence comparison analysis revealed significant homology between XYLA and bacterial xylanases belonging to cellulase/xylanase family G. One of these homologous enzymes is derived from the rumen bacterium Ruminococcus flavefaciens. The homology observed between XYLA and a rumen prokaryote xylanase could be a consequence of the horizontal transfer of genes between rumen prokaryotes and lower eukaryotes, either when the organisms were resident in the rumen, or prior to their colonization of the ruminant. It should also be noted that Neocallimastix XYLA is the first example of a xylanase which consists of reiterated sequences. It remains to be established whether this is a common phenomenon in other rumen fungal plant cell wall hydrolases.

Cloning and expression of multiple cellulase cDNAs from the anaerobic rumen fungus Neocallimastix patriciarum in Escherichia coli.

A cDNA expression library of the rumen fungus Neocallimastix patriciarum was made in Escherichia coli. Cellulolytic clones were identified by screening on a medium containing carboxymethylcellulose. Restriction mapping and Southern hybridization analysis of selected clones revealed three distinct cellulase cDNAs, designated celA, celB and celC. Studies on the substrate specificity showed that the enzyme encoded by celA had high activity towards amorphous and microcrystalline cellulose, while the celB and celC enzymes had relatively high activity on carboxymethylcellulose, with little activity on microcrystalline cellulose. Analysis of hydrolysis products from defined cellodextrins showed that the celB and celC enzymes hydrolysed beta-1,4-glucosidic linkages randomly, whereas the celA enzyme cleaved cellotetraose to cellobiose, and cellopentaose to cellobiose and cellotriose. Cellobiose was also the only product detectable from hydrolysis of microcrystalline cellulose by the celA enzyme. Based on substrate specificity and catalytic mode, celA appears to encode a cellobiohydrolase, while celB and celC encode endoglucanases. Northern blot hybridization analysis showed that expression of the three cellulase transcripts in N. patriciarum was induced by cellulose.