The diffusible factor synthase XanB2 is a bifunctional chorismatase that links the shikimate pathway to ubiquinone and xanthomonadins biosynthetic pathways

The diffusible factor synthase XanB2, originally identified in Xanthomonas campestris pv. campestris (Xcc), is highly conserved across a wide range of bacterial species, but its substrate and catalytic mechanism have not yet been investigated. Here, we show that XanB2 is a unique bifunctional chorismatase that hydrolyses chorismate, the end‐product of the shikimate pathway, to produce 3‐hydroxybenzoic acid (3‐HBA) and 4‐HBA. 3‐HBA and 4‐HBA are respectively associated with the yellow pigment xanthomonadin biosynthesis and antioxidant activity in Xcc. We further demonstrate that XanB2 is a structurally novel enzyme with three putative domains. It catalyses 3‐HBA and 4‐HBA biosynthesis via a unique mechanism with the C‐terminal YjgF‐like domain conferring activity for 3‐HBA biosynthesis and the N‐terminal FGFG motif‐containing domain responsible for 4‐HBA biosynthesis. Furthermore, we show that Xcc produces coenzyme Q8 (CoQ8) via a new biosynthetic pathway independent of the key chorismate‐pyruvate lyase UbiC. XanB2 is the alternative source of 4‐HBA for CoQ8 biosynthesis. The similar CoQ8 biosynthetic pathway, xanthomonadin biosynthetic gene cluster and XanB2 homologues are well conserved in the bacterial species within Xanthomonas, Xylella, Xylophilus, Pseudoxanthomonas, Rhodanobacter, Frateuria, Herminiimonas and Variovorax, suggesting that XanB2 may be a conserved metabolic link between the shikimate pathway, ubiquinone and xanthomonadin biosynthetic pathways in diverse bacteria.     

Efficient production of heat-stable antifungal factor through integrating statistical optimization with a two-stage temperature control strategy in <Emphasis Type="Italic">Lysobacter enzymogenes</Emphasis> OH11

Background

Heat-stable antifungal factor (HSAF) is a newly identified broad-spectrum antifungal antibiotic from the biocontrol agent Lysobacter enzymogenes and is regarded as a potential biological pesticide, due to its novel mode of action. However, the production level of HSAF is quite low, and little research has reported on the fermentation process involved, representing huge obstacles for large-scale industrial production.

Results

Medium capacity, culture temperature, and fermentation time were identified as the most significant factors affecting the production of HSAF and employed for further optimization through statistical methods. Based on the analysis of kinetic parameters at different temperatures, a novel two-stage temperature control strategy was developed to improve HSAF production, in which the temperature was increased to 32 °C during the first 12 h and then switched to 26 °C until the end of fermentation. Using this strategy, the maximum HSAF production reached 440.26?±?16.14 mg L^??1, increased by 9.93% than that of the best results from single-temperature fermentation. Moreover, the fermentation time was shortened from 58 h to 54 h, resulting in the enhancement of HSAF productivity (17.95%) and yield (9.93%).

Conclusions

This study provides a simple and efficient method for producing HSAF that could be feasibly applied to the industrial-scale production of HSAF.

     

Evolution of coumaroyl conjugate 3‐hydroxylases in land plants: lignin biosynthesis and defense

Multiple adaptations were necessary when plants conquered the land. Among them were soluble phenylpropanoids related to plant protection and lignin necessary for upright growth and long‐distance water transport. Cytochrome P450 monooxygenase 98 (CYP98) catalyzes a rate‐limiting step in phenylpropanoid biosynthesis. Phylogenetic reconstructions suggest that a single copy of CYP98 founded each major land plant lineage (bryophytes, lycophytes, monilophytes, gymnosperms and angiosperms), and was maintained as a single copy in all lineages but the angiosperms. In angiosperms, a series of independent gene duplications and losses occurred. Biochemical assays in four angiosperm species tested showed that 4‐coumaroyl‐shikimate, a known intermediate in lignin biosynthesis, was the preferred substrate of one member in each species, while independent duplicates in Populus trichocarpa and Amborella trichopoda each showed broad substrate ranges, accepting numerous 4‐coumaroyl‐esters and ‐amines, and were thus capable of producing a wide range of hydroxycinnamoyl conjugates. The gymnosperm CYP98 from Pinus taeda showed a broad substrate range, but preferred 4‐coumaroyl‐shikimate as its best substrate. In contrast, CYP98s from the lycophyte Selaginella moellendorffii and the fern Pteris vittata converted 4‐coumaroyl‐shikimate poorly in vitro, but were able to use alternative substrates, in particular 4‐coumaroyl‐anthranilate. Thus, caffeoyl‐shikimate appears unlikely to be an intermediate in monolignol biosynthesis in non‐seed vascular plants, including ferns. The best substrate for CYP98A34 from the moss Physcomitrella patens was also 4‐coumaroyl‐anthranilate, while 4‐coumaroyl‐shikimate was converted to lower extents. Despite having in vitro activity with 4‐coumaroyl‐shikimate, CYP98A34 was unable to complement the Arabidopsis thaliana cyp98a3 loss‐of‐function phenotype, suggesting distinct properties also in vivo.     

Type IV pilus biogenesis genes and their roles in biofilm formation in the biological control agent Lysobacter enzymogenes OH11

Type IV pilus (T4P) is widespread in bacteria, yet its biogenesis mechanism and functionality is only partially elucidated in a limited number of bacterial species. Here, by using strain OH11 as the model organism, we reported the identification of 26 T4P structural or functional component (SFC) proteins in the Gram-negative Lysobacter enzymogenes, which is a biocontrol agent potentially exploiting T4P-mediated twitching motility for antifungal activity. Twenty such SFC coding genes were individually knocked-out in-frame to create a T4P SFC deletion library. By using combined phenotypic and genetic approaches, we found that 14 such SFCs, which were expressed from four operons, were essential for twitching motility. These SFCs included the minor pilins (PilE_i, PilX_i, PilV_i, and FimT_i), the anti-retraction protein PilY1_i, the platform protein PilC, the extension/extraction ATPases (PilB, PilT, and PilU), and the PilMNOPQ complex. Among these, mutation of pilT or pilU caused a hyper piliation, while the remaining 12 SFCs were indispensable for pilus formation. Ten (FimT_i, PilY1_i, PilB, PilT, PilU, and the PilMNOPQ complex) of the 14 SFC proteins, as well as PilA, were further shown to play a key role in L. enzymogenes biofilm formation. Overall, our results provide the first report to dissect the genetic basis of T4P biogenesis and its role in biofilm formation in L. enzymogenes in detail, which can serve as an alternative platform for studying T4P biogenesis and its antifungal function.

     

Lysobacter enzymogenes antagonizes soilborne bacteria using the type IV secretion system

Soil microbiome comprises numerous microbial species that continuously interact with each other. Among the modes of diverse interactions, cell–cell killing may play a key role in shaping the microbiome composition. Bacteria deploy various secretion systems to fend off other microorganisms and Type IV Secretion System (T4SS) in pathogenic bacteria was shown to function as a contact-dependent, inter-bacterial killing system only recently. The present study investigated the role played by T4SS in the killing behaviour of the soilborne biocontrol bacterium Lysobacter enzymogenes OH11. Results showed that L. enzymogenes OH11 genome encompasses genes encoding all the components of T4SS and effectors potentially involved in inter-bacterial killing system. Generation of knock-out mutants revealed that L. enzymogenes OH11 uses T4SS as the main contact-dependent weapon against other soilborne bacteria. The T4SS-mediated killing behaviour of L. enzymogenes OH11 decreased the antibacterial and antifungal activity of two Pseudomonas spp. but at the same time, protected carrot from infection by Pectobacterium carotovorum. Overall, this study showed for the first time the involvement of T4SS in the killing behaviour of L. enzymogenes and its impact on the multiple interactions occurring in the soil microbiome.     

Chorismate‐dependent transcriptional regulation of quinate/shikimate utilization genes by LysR‐type transcriptional regulator QsuR in Corynebacterium glutamicum: carbon flow control at metabolic branch point

The qsu operon of Corynebacterium glutamicum comprises four genes (qsuABCD) that underpin the microorganism's quinate/shikimate utilization pathways. The genes encode enzymes that catalyse reactions at the metabolic branch point between the biosynthesis route for synthesis of aromatic compounds and the catabolic route for degradation of quinate and shikimate for energy production. A qsuR gene located immediately upstream of qsuA encodes a protein (QsuR) which activates the operon in the presence of quinate or shikimate. Three observations support chorismate, an intermediate of the biosynthesis route, as a direct effector of QsuR: First, induction of qsuA mRNA in the presence of either quinate or shikimate disappears upon deletion of the gene encoding chorismate synthase. Second, chorismate accumulates when the operon is induced. Third, a DNase I‐protected segment by QsuR is shortened in the presence of chorismate. The QsuR tetramer senses the accumulation of chorismate and activates qsu genes that promote the quinate/shikimate catabolic instead of the aromatic compounds biosynthetic route. Such chorismate‐dependent control of carbon flow has not been previously described.     

The roles of the shikimate pathway genes,aroA and aroB,in virulence,growth and UV tolerance of Burkholderia glumae strain 411gr‐6

Burkholderia glumae is the major causal agent of bacterial panicle blight of rice, which is a growing disease problem for rice growers worldwide. In our previous study, some B. glumae strains showed pigmentation phenotypes producing at least two (yellow–green and purple) pigment compounds in casein–peptone–glucose agar medium. The B. glumae strains LSUPB114 and LSUPB116 are pigment‐deficient mutant derivatives of the virulent and pigment‐proficient strain 411gr‐6, having mini‐Tn5gus insertions in aroA encoding 3‐phosphoshikimate 1‐carboxyvinyltransferase and aroB encoding 3‐dehydroquinate synthase, respectively. Both enzymes are known to be involved in the shikimate pathway, which leads to the synthesis of aromatic amino acids. Here, we demonstrate that aroA and aroB are required for normal virulence in rice and onion, growth in M9 minimal medium and tolerance to UV light, but are dispensable for the production of the phytotoxin toxoflavin. These results suggest that the shikimate pathway is involved in bacterial pathogenesis by B. glumae without a significant role in the production of toxoflavin, a major virulence factor of this pathogen.     

Deletion of fucose residues in plant N‐glycans by repression of the GDP‐mannose 4,6‐dehydratase gene using virus‐induced gene silencing and RNA interference

Production of pharmaceutical glycoproteins in plants has many advantages in terms of safety and reduced costs. However, plant‐produced glycoproteins have N‐glycans with plant‐specific sugar residues (core β‐1,2‐xylose and α‐1,3‐fucose) and a Lewis a (Le^a) epitope, i.e., Galβ(1‐3)[Fucα(1‐4)]GlcNAc. Because these sugar residues and glycan structures seemed to be immunogenic, several attempts have been made to delete them by repressing their respective glycosyltransferase genes. However, until date, such deletions have not been successful in completely eliminating the fucose residues. In this study, we simultaneously reduced the plant‐specific core α‐1,3‐fucose and α‐1,4‐fucose residues in the Le^a epitopes by repressing the Guanosine 5′‐diphosphate (GDP)‐D‐mannose 4,6‐dehydratase (GMD) gene, which is associated with GDP‐L‐fucose biosynthesis, in Nicotiana benthamiana plants. Repression of GMD was achieved using virus‐induced gene silencing (VIGS) and RNA interference (RNAi). The proportion of fucose‐free N‐glycans found in total soluble protein from GMD gene‐repressed plants increased by 80% and 95% following VIGS and RNAi, respectively, compared to wild‐type plants. A small amount of putative galactose substitution in N‐glycans from the NbGMD gene‐repressed plants was observed, similar to what has been previously reported GMD‐knockout Arabidopsis mutant. On the other hand, the recombinant mouse granulocyte‐macrophage colony‐stimulating factor (GM‐CSF) with fucose‐deleted N‐glycans was successfully produced in NbGMD‐RNAi transgenic N. benthamiana plants. Thus, repression of the GMD gene is thus very useful for deleting immunogenic total fucose residues and facilitating the production of pharmaceutical glycoproteins in plants.     

Genetic and biochemical characterization of a 4-hydroxybenzoate hydroxylase from <Emphasis Type="Italic">Corynebacterium glutamicum</Emphasis>

Corynebacterium glutamicum uses 4-hydroxybenzoic acid (4HBA) as sole carbon source for growth. Previous studies showed that 4HBA was taken up into cells via PcaK, and the aromatic ring was cleaved via protocatechuate 3,4-dioxygenase. In this study, the gene pobA _Cg (ncgl1032) involved in the conversion of 4HBA into 3,4-dihydroxybenzoate (protocatechuate) was identified, and the gene product PobA _Cg was characterized as a 4HBA 3-hydroxylase, which is a homodimer of PobA_Cg. The pobA _Cg is physically associated with pcaK and formed a putative operon, but the two genes were located distantly to the pca cluster, which encode other enzymes for 4HBA/protocatechuate degradation. This new 4HBA 3-hydroxylase is unique in that it prefers NADPH to NADH as a cosubstrate, although its sequence is similar to other 4HBA 3-hydroxylases that prefer NADH as a cosubstrate. Sited-directed mutagenesis on putative NADPH-binding sites, D38 and T42, further improved its affinity to NADPH as well as its catalytic efficiency.