The Mesorhizobium loti strain R7A symbiosis island is a 502-kb chromosomally integrated element which transfers to nonsymbiotic mesorhizobia in the environment, converting them to Lotus symbionts. It integrates into a phenylalanine tRNA gene in a process mediated by a P4-type integrase encoded at the left end of the element. We have determined the nucleotide sequence of the island and compared its deduced genetic complement with that reported for the 611-kb putative symbiosis island of M. loti strain MAFF303099. The two islands share 248 kb of DNA, with multiple deletions and insertions of up to 168 kb interrupting highly conserved colinear DNA regions in the two strains. The shared DNA regions contain all the genes likely to be required for Nod factor synthesis, nitrogen fixation, and island transfer. Transfer genes include a trb operon and a cluster of potential tra genes which are also present on the strain MAFF303099 plasmid pMLb. The island lacks plasmid replication genes, suggesting that it is a site-specific conjugative transposon. The R7A island encodes a type IV secretion system with strong similarity to the vir pilus from Agrobacterium tumefaciens that is deleted from MAFF303099, which in turn encodes a type III secretion system not found on the R7A island. The 414 genes on the R7A island also include putative regulatory genes, transport genes, and an array of metabolic genes. Most of the unique hypothetical genes on the R7A island are strain-specific and clustered, suggesting that they may represent other acquired genetic elements rather than symbiotically relevant DNA.The symbiosis between legumes and the root nodule bacteria collectively known as rhizobia is of critical agronomic and environmental importance, accounting for the majority of the nitrogen fixed through biological processes. Rhizobia are phylogenetically diverse, falling into five genera of ␣-proteobacteria (Rhizobium, Bradyrhizobium, Sinorhizobium, Azorhizobium, and Mesorhizobium) (64, 70) and at least two genera of -proteobacteria (Burkholderia and Ralstonia) (35). It is thought that the rhizobial lineages diverged well before the evolution of legumes and that the genes required for the formation of the symbiosis were subsequently acquired by lateral transfer from undefined sources (8,33). Reflecting the accessory nature of the traits, several species of rhizobia contain the genes required for nodulation and nitrogen fixation on large plasmids that can be cured under laboratory conditions without affecting the survival of the bacteria (31). Exceptions in which the symbiosis genes are encoded on the chromosome include Bradyrhizobium species, in which the symbiosis genes are clustered but not known to be mobile (18), and at least one strain of Mesorhizobium loti, strain ICMP3153, in which the genes are located on a mobile symbiosis island (57).M. loti is the microsymbiont of several Lotus species, including Lotus corniculatus and L. japonicus. The symbiosis island of M. loti strain ICMP3153 was discovered through its ability to transfe...
SummaryThe Mesorhizobium loti strain R7A symbiosis island is an Integrative Conjugative Element (ICE), herein termed ICEMlSym R7A, which integrates into a phetRNA gene. Integration reconstructs the phetRNA gene at one junction with the core chromosome, and a direct repeat of the 3-prime 17 bp of the gene is formed at the other junction. We show that the ICEMlSym R7A intS gene, which encodes an integrase of the phage P4 family, is required for integration and excision of the island. Excision also depended on a novel recombination directionality factor encoded by msi109 (rdfS). Constitutive expression of rdfS resulted in curing of ICEMlSym R7A. The rdfS gene is part of an operon with genes required for conjugative transfer, allowing co-ordinate regulation of ICEMlSym R7A excision and transfer. The excised form of ICEMlSym R7A was detectable during exponential growth but occurred at higher frequency during stationary phase. ICEMlSym R7A encodes homologues of the traR and traI genes of Agrobacterium tumefaciens that regulate Ti plasmid transfer via quorum sensing. The presence of a plasmid with cloned island traR traI2 genes resulted in excision of ICEMlSym R7A in all cells regardless of culture density, indicating that excision may be similarly regulated. Maintenance of ICEMlSym R7A in these cells depended on msi106 (rlxS) that encodes a putative relaxase. Transfer of the island to non-symbiotic mesorhizobia required intS, rlxS and rdfS. The rdfS and rlxS genes are conserved across a diverse range of a-, b-and gproteobacteria and identify a large family of genomic islands with a common transfer mechanism.
SummaryVascular endothelial growth factor (VEGF)-A, a key regulator of cutaneous blood vessel formation, appears to have an additional role during wound healing, enhancing re-epithelialization. Orf virus, a zoonotic parapoxvirus, induces proliferative skin lesions that initiate in wounds and are characterized by extensive blood vessel formation, epidermal hyperplasia and rete ridge formation. The vascular changes beneath the lesion are largely due to viral-expressed VEGF-E. This study investigated using mouse skin models whether VEGF-E can induce epidermal changes such as that seen in the viral lesion. Injection of VEGF-E into normal skin increased the number of endothelial cells and blood vessels within the dermis and increased epidermal thickening and keratinocyte number. Injection of VEGF-E into wounded skin, which more closely mimics orf virus lesions, increased neo-epidermal thickness and area, promoted rete ridge formation, and enhanced wound re-epithelialization. Quantitative RT-PCR analysis showed that VEGF-E did not induce expression of epidermal-specific growth factors within the wound, but did increase matrix metalloproteinase (MMP)-2 and MMP-9 expression. In cell-based assays, VEGF-E induced keratinocyte migration and proliferation, responses that were inhibited by a neutralizing antibody against VEGF receptor (VEGFR)-2. These findings demonstrate that VEGF-E, both directly and indirectly, regulates keratinocyte function, thereby promoting epidermal regeneration.
Interleukin (IL)-10 plays a critical role in controlling wound inflammation and scar formation. Orf virus, a zoonotic parapoxvirus, induces proliferative skin lesions that resolve with minimal scarring. Orf virus encodes a range of factors that subvert the host's response to infection, including a homolog of IL-10. This study investigated, using a murine full-thickness wound model, whether purified orf virus IL-10 (ovIL-10) can regulate skin repair and scarring. Repeat injections of ovIL-10 into wounded skin accelerated wound closure. Histological analyses of wound sections revealed that treatment with ovIL-10 accelerated wound reepithelialization, granulation tissue coverage of the wound bed, and improved wound revascularization. In addition, wounds treated with ovIL-10 showed a reduction in macrophage infiltration, myofibroblast differentiation, and wound contraction. Treatment of wounds with ovIL-10 also resulted in a reduction in visible scarring that was consistent with the extent of scar tissue formed. Quantitative polymerase chain reaction analysis confirmed that ovIL-10 reduced the expression of key mediators of inflammation and granulation tissue formation. These findings show that ovIL-10, like mammalian IL-10, limits inflammation and scar tissue formation and reveal a new role for both mammalian and viral IL-10 in mediating tissue repair.
Many burn interventions aim to target the inflammatory response as a means of enhancing healing or limiting hypertrophic scarring. Murine models of human burns have been developed, but the inflammatory response to injury in these models has not been well defined. The aim of this study was to profile inflammatory cell populations and gene expression relative to healing and scarring in a murine model of thermal burns. Cutaneous injuries were created on the dorsal region of C57Bl/6 mice using a heated metal rod. Animals were euthanized at selected time points over ten weeks, with the lesions evaluated using macroscopic measurements, histology, immunofluorescent histochemistry and quantitative PCR. The burn method generated a reproducible, partial-thickness injury that healed within two weeks through both contraction and re-epithelialization, in a manner similar to human burns. The injury caused an immediate increase in pro-inflammatory cytokine and chemokine expression, coinciding with an influx of neutrophils, and the disappearance of Langerhans cells and mast cells. This preceded an influx of dendritic cells and macrophages, a quarter of which displayed an inflammatory (M1) phenotype, with both populations peaking at closure. As with human burns, the residual scar increased in size, epidermal and dermal thickness, and mast cell numbers over 10 weeks, but abnormal collagen I-collagen III ratios, fibre organization and macrophage populations resolved 3–4 weeks after closure. Characterisation of the inflammatory response in this promising murine burn model will assist future studies of burn complications and aid in the preclinical testing of new anti-inflammatory and anti-scarring therapies.
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