Vibriofischeri is found both as a free-living bacterium in seawater and as the specific, mutualistic light organ symbiont of several fish and squid species. To identify those characteristics of symbiosis-competent strains that are required for successful colonization of the nascent light organ of juvenile Euprymna scolopes squids, we generated a mutant pool by using the transposon Mu dl 1681 and screened this pool for strains that were no longer motile. Eighteen independently isolated nonmotile mutants that were either flagellated or nonflagellated were obtained. In contrast to the parent strain, none of these nonmotile mutants was able to colonize the juvenile squid light organ. The flagellated nonmotile mutant strain NM200 possessed a bundle of sheathed polar flagella indistinguishable from that of the wild-type strain, indicating that the presence of flagella alone is not sufficient for colonization and that it is motility itself that is required for successful light organ colonization. This study identifies motility as the first required symbiotic phenotype of V. fischeri.A number of species in the genus Vibrio are found living in intimate association with specific animal hosts. The associations are often pathogenic, for example, those between Vibrio cholerae, V. vulnificus, or V anguillarum and various vertebrate and invertebrate species (13); however, mutualistic symbioses also exist, such as that between V. fischeri and the luminous squid Euprymna scolopes (6, 34). By examining genetic determinants that have evolved to play a role in mutualistic as well as pathogenic associations, it may be possible to uncover unifying principles that govern the establishment and development of bacterial colonizations of animal host tissues. In this study, we have used transposon mutagenesis to identify for the first time a required symbiotic determinant of a nonpathogenic, animal-associated bacterium.Upon hatching, the juvenile E. scolopes squid is aposymbiotic (i.e., its nascent light organ is devoid of bacteria); thus, the symbiosis needs to be reestablished with each successive generation (24,41). To initiate this benign infection, symbiosiscompetent V fischeri from the ambient seawater must enter the juvenile light organ through superficial pores and travel down narrow, ciliated ducts that lead into several epitheliumlined crypts (26). An inoculum of fewer than 10 bacterial cells enters the light organ and proliferates so rapidly that within 10 to 12 h the crypts are filled with an extracellular, monospecific culture of about 105 V fischeri cells whose luminescence can be easily detected (24,33).The natural occurrence of aposymbiotic juveniles, combined with the rapid and readily initiated colonization process, provides the opportunity to test mutant strains of V fischeri for the loss of symbiotic infectivity, thereby identifying genes required for the colonization of the juvenile E. scolopes light organ. Motility-and flagellum-associated structures have been shown to be important colonization or virulence determinan...
In Vibrio fischeri, the synthesis of N-3-oxohexanoyl-L-homoserine lactone, the autoinducer for population density-responsive induction of the luminescence operon (the lux operon, luxICDABEG), is dependent on the autoinducer synthase gene luxI. Gene replacement mutants of V. fischeri defective in luxI, which had been expected to produce no autoinducer, nonetheless exhibited lux operon transcriptional activation. Mutants released into the medium a compound that, like N-3-oxohexanoyl-L-homoserine lactone, activated expression of the lux system in a dose-dependent manner and was both extractable with ethyl acetate and labile to base. The luxI-independent compound, also like N-3-oxohexanoyl-L-homoserine lactone, was produced by V. fischeri cells in a regulated, population density-responsive manner and required the transcriptional activator LuxR for activity in the lux system. The luxI-independent compound was identified as N-octanoyl-L-homoserine lactone by coelution with the synthetic compound in reversed-phase high-pressure liquid chromatography, by derivatization treatment with 2,4-dinitrophenylhydrazine, by mass spectrometry, and by nuclear magnetic resonance spectroscopy. A locus, ain, necessary and sufficient for Escherichia coli to synthesize N-octanoyl-L-homoserine lactone was cloned from the V. fischeri genome and found to be distinct from luxI by restriction mapping and Southern hybridization. N-Octanoyl-L-homoserine lactone and ain constitute a second, novel autoinduction system for population density-responsive signalling and regulation of lux gene expression, and possibly other genes, in V. fischeri. A third V. fischeri autoinducer, N-hexanoyl-L-homoserine lactone, dependent on luxI for its synthesis, was also identified. The presence of multiple chemically and genetically distinct but cross-acting autoinduction systems in V. fischeri indicates unexpected complexity for autoinduction as a regulatory mechanism in this bacterium.
Four closely related species, Vibrio fischeri, Vibrio logei, Vibrio salmonicida and Vibrio wodanis, form a clade within the family Vibrionaceae; the taxonomic status and phylogenetic position of this clade have remained ambiguous for many years. To resolve this ambiguity, we tested these species against other species of the Vibrionaceae for phylogenetic and phenotypic differences. Sequence identities for the 16S rRNA gene were ≥97.4 % among members of the V. fischeri group, but were ≤95.5 % for members of this group in comparison with type species of other genera of the Vibrionaceae (i.e. Photobacterium and Vibrio, with which they overlap in G+C content, and Enterovibrio, Grimontia and Salinivibrio, with which they do not overlap in G+C content). Combined analysis of the recA, rpoA, pyrH, gyrB and 16S rRNA gene sequences revealed that the species of the V. fischeri group form a tightly clustered clade, distinct from these other genera. Furthermore, phenotypic traits differentiated the V. fischeri group from other genera of the Vibrionaceae, and a panel of 13 biochemical tests discriminated members of the V. fischeri group from type strains of Photobacterium and Vibrio. These results indicate that the four species of the V. fischeri group represent a lineage within the Vibrionaceae that is distinct from other genera. We therefore propose their reclassification in a new genus, Aliivibrio gen. nov. Aliivibrio is composed of four species: Aliivibrio fischeri comb. nov. (the type species) (type strain ATCC 7744T =CAIM 329T =CCUG 13450T =CIP 103206T =DSM 507T =LMG 4414T =NCIMB 1281T), Aliivibrio logei comb. nov. (type strain ATCC 29985T =CCUG 20283T =CIP 104991T =NCIMB 2252T), Aliivibrio salmonicida comb. nov. (type strain ATCC 43839T =CIP 103166T =LMG 14010T =NCIMB 2262T) and Aliivibrio wodanis comb. nov. (type strain ATCC BAA-104T =NCIMB 13582T =LMG 24053T).
In Vibrio fischeri, the autoinducer N-3-oxohexanoyl-L-homoserine lactone (AI-1) governs the cell densitydependent induction of the luminescence operon via the LuxR transcriptional activator. The synthesis of AI-1 from bacterial metabolic intermediates is dependent on luxI. Recently, we found a second V. fischeri autoinducer molecule, N-octanoyl-L-homoserine lactone (AI-2), that in E. coli also activates the luminescence operon via LuxR. A locus independent of luxI was identified as being required for AI-2 synthesis. This 2.7-kb ain (autoinducer) locus was characterized by transposon insertion mutagenesis, deletion and complementation analysis, and DNA sequencing. A single 1,185-bp gene, ainS, was found to be the sole exogenous gene necessary for the synthesis of AI-2 in Escherichia coli. In addition, a V. fischeri ainS mutant produced AI-1 but not AI-2, confirming that in its native species ainS is specific for the synthesis of AI-2. ainS is predicted to encode a 45,580-Da protein which exhibits no similarity to LuxI or to any of the LuxI homologs responsible for the synthesis of N-acyl-L-homoserine lactones in a variety of other bacteria. The existence of two different and unrelated autoinducer synthesis genes suggests the occurrence of convergent evolution in the synthesis of homoserine lactone signaling molecules. The C-terminal half of AinS shows homology to a putative protein in Vibrio harveyi, LuxM, which is required for the synthesis of a V. harveyi bioluminescence autoinducer. Together, AinS and LuxM define a new family of autoinducer synthesis proteins. Furthermore, the predicted product of another gene, ainR, encoded immediately downstream of ainS, shows homology to LuxN, which is similarly encoded downstream of luxM in V. harveyi and proposed to have sensor/regulator functions in the bioluminescence response to the V. harveyi autoinducer. This similarity presents the possibility that AI-2, besides interacting with LuxR, also interacts with AinR under presently unknown conditions.
Photobacterium comprises several species in Vibrionaceae, a large family of Gram-negative, facultatively aerobic, bacteria that commonly associate with marine animals. Members of the genus are widely distributed in the marine environment and occur in seawater, surfaces, and intestines of marine animals, marine sediments and saline lake water, and light organs of fish. Seven Photobacterium species are luminous via the activity of the lux genes, luxCDABEG. Much recent progress has been made on the phylogeny, genomics, and symbiosis of Photobacterium. Phylogenetic analysis demonstrates a robust separation between Photobacterium and its close relatives, Aliivibrio and Vibrio, and reveals the presence of two well-supported clades. Clade 1 contains luminous and symbiotic species and one species with no luminous members, and Clade 2 contains mostly nonluminous species. The genomes of Photobacterium are similar in size, structure, and organization to other members of Vibrionaceae, with two chromosomes of unequal size and multiple rrn operons. Many species of marine fish form bioluminescent symbioses with three Photobacterium species: Photobacterium kishitanii, Photobacterium leiognathi, and Photobacterium mandapamensis. These associations are highly, but not strictly species specific, and they do not exhibit symbiont-host codivergence. Environmental congruence instead of host selection might explain the patterns of symbiont-host affiliation observed from nature.
A phylogeny was generated for Leiognathidae, an assemblage of bioluminescent, Indo-Pacific schooling fishes, using 6175 characters derived from seven mitochondrial genes (16S, COI, ND4, ND5, tRNA-His, tRNA-Ser, tRNA-Leu), two nuclear genes (28S, histone H3), and 15 morphological transformations corresponding to features of the fishes' sexually dimorphic light-organ system (LOS; e.g., circumesophageal light organ, lateral lining of the gas bladder, transparent flank and opercular patches). Leiognathidae comprises three genera, Gazza, Leiognathus, and Secutor. Our results demonstrate that Leiognathidae, Gazza, and Secutor are monophyletic, whereas Leiognathus is not. The recovered pattern of relationships reveals that a structurally complex, strongly sexually dimorphic and highly variable species-specific light organ is derived from a comparatively simple non-dimorphic structure, and that evolution of other sexually dimorphic internal and external features of the male LOS are closely linked with these light-organ modifications. Our results demonstrate the utility of LOS features, both for recovering phylogeny and resolving taxonomic issues in a clade whose members otherwise exhibit little morphological variation. We diagnose two new leiognathid genera, Photopectoralis and Photoplagios, on the basis of these apomorphic LOS features and also present derived features of the LOS to diagnose several additional leiognathid clades, including Gazza and Secutor. Furthermore, we show that five distinct and highly specialized morphologies for male-specific lateral luminescence signaling, which exhibit species-specific variation in structure, have evolved in these otherwise outwardly conservative fishes. Leiognathids inhabit turbid coastal waters with poor visibility and are often captured in mixed assemblages of several species. We hypothesize that the species-specific, sexually dimorphic internal and external modifications of the leiognathid LOS provide compelling evidence for an assortative mating scheme in which males use species-specific patterns of lateral luminescence signaling to attract mates, and that this system functions to maintain reproductive isolation in these turbid coastal environments.
Expression of the Vibrio fischeri luminescence genes (lux genes) requires two transcriptional activators: the V. fischeri luxR gene product with autoinducer and the cyclic AMP (cAMP) receptor protein (CRP) with cAMP. It has been established that autoinducer and the luxR gene product are required for transcriptional activation of the luxICDABE operon, which contains a gene required for autoinducer synthesis and genes required for light emission. However, the role of cAMP-CRP in the induction of luminescence is not clear. We examined transcriptional control of the lux genes in Escherichia coli, using catabolite repression mutants carrying lux DNA-containing plasmids. Transcriptional fusions between the lacZ gene on Mu dl and luxR were used to assess luxR promoter activity, and the luxAB genes (which encode the two luciferase subunits) were used as a natural reporter of luxlCDABE promoter activity. A plasmid containing luxR under control of the cAMP-CRP-independent tac promoter was constructed to direct the synthesis of the luxR gene product in cells containing compatible luxR::Mu dI insertion mutant plasmids. In E. coli, cAMP-CRP activated transcription of luxR and concurrently decreased luxICDABE transcription. In the presence of relatively high levels of the luxR gene product, cAMP and CRP were not required for induction of the luxICDABE operon. The luxR gene product in the presence of autoinducer activated transcription of the luxICDABE operon, as has been shown previously, and we demonstrate that It also decreased luxR transcription. Apparently, control of the V.fischeri luminescence genes involves a regulatory circuit in which cAMP and CRP activate luxR transcription and in turn the luxR gene product activates transcription of the operon responsible for light emission (luxICDABE). Furthermore, in lux gene regulation cAMP-CRP and autoinducer-LuxR protein appear to function as transcriptional antagonists.Luminescence of Vibriofischeri, the light organ symbiont of pinecone fish, requires autoinduction. The autoinducer [N-(3-oxo-hexanoyl)homoserine lactone] is a specific V. fischeri metabolite that activates transcription of the luminescence genes (lux genes) when it reaches a critical concentration of a few molecules per cell. Cells are permeable to autoinducer, so this molecule accumulates within V. fischeri and in the external medium at equal concentrations (7,15,18,22). At high cell densities, autoinducer can accumulate and cause induction of the luminescence enzymes. This is thought to be the case in the light organ symbiosis in which V. fischeri occurs at densities of 109 to 1010 cells per ml of organ fluid. In environments in which V. fischeri density is low, such as seawater (<103 cells per ml), autoinducer does not accumulate and V. fischeri luminescence would not be expected (19,(21)(22)(23).A 9-kilobase (kb) fragment of V. fischeri DNA that encodes all the functions for luminescence and contains regulatory elements sufficient for their expression in Escherichia coli has been isolated (8). The cloned DN...
Several groups of marine fishes and squids form mutualistic bioluminescent symbioses with luminous bacteria. The dependence of the animal on its symbiont for light production, the animal's specialized anatomical adaptations for harboring bacteria and controlling light emission, and the host family bacterial species specificity characteristic of these associations suggest that bioluminescent symbioses are tightly coupled associations that might involve coevolutionary interactions. Consistent with this possibility, evidence of parallel cladogenesis has been reported for squid-bacterial associations. However, genetic adaptations in the bacteria necessary for and specific to symbiosis have not been identified, and unlike obligate endosymbiotic associations in which the bacteria are transferred vertically, bacterially bioluminescent hosts acquire their light-organ symbionts from the environment with each new host generation. These contrasting observations led us to test the hypotheses of species specificity and codivergence in bioluminescent symbioses, using an extensive sampling of naturally formed associations. Thirty-five species of fish in seven teleost families (Chlorophthalmidae, Macrouridae, Moridae, Trachichthyidae, Monocentridae, Acropomatidae, Leiognathidae) and their light-organ bacteria were examined. Phylogenetic analysis of a taxonomically broad sampling of associations was based on mitochondrial 16S rRNA and cytochrome oxidase I gene sequences for the fish and on recA, gyrB and luxA sequences for bacteria isolated from the light organs of these specimens. In a fine-scale test focused on Leiognathidae, phylogenetic analysis was based also on histone H3 subunit and 28S rRNA gene sequences for the fish and on gyrB, luxA, luxB, luxF and luxE sequences for the bacteria. Deep divergences were revealed among the fishes, and clear resolution was obtained between clades of the bacteria. In several associations, bacterial species identities contradicted strict host family bacterial species specificity. Furthermore, the fish and bacterial phylogenies exhibited no meaningful topological congruence; evolutionary divergence of host fishes was not matched by a similar pattern of diversification in the symbiotic bacteria. Re-analysis of data reported for squids and their luminous bacteria also revealed no convincing evidence of codivergence. These results refute the hypothesis of strict host family bacterial species specificity and the hypothesis of codivergence in bioluminescent symbioses.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.