Alecia N. Septer’s research while affiliated with University of North Carolina at Chapel Hill and other places

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Publications (51)


Complete genome sequence of Sagittula stellata strain E-37 reveals a plasmid-encoded type six secretion system
  • Article
  • Full-text available

October 2024

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13 Reads

Microbiology Resource Announcements

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John Raymond B. Salazar

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Paul Christian T. Gloria

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Alecia N. Septer

We announce the complete genome sequence of Sagittula stellata strain E-37. The hybrid assembly of long and short reads revealed one chromosome and four plasmids. Furthermore, the genome analysis showed that the plasmid-encoded type six secretion system is linked to plasmid replication genes that may be common to Roseobacters.

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Figure 1. hsp60 amplicon sequencing differentiates Vibrio fischeri from other closely 96 related vibrios at the species level. (A) Known Input corresponds to bacterial isolates 97 added to each culture sample, and Observed Taxa reports the relative abundance (%) of 98
Figure 2. Relative abundance of V. fischeri and other conserved taxa associated with 146 juvenile and adult squid. (A) Relative abundance of V. fischeri, other vibrios, and non-147 vibrio taxa in juvenile squid, juvenile squid ventate, and adult squid. The percentage of 148 reads identified as V. fischeri in each sample is indicated on the y-axis (% Vf). In wild-149 caught adult panel, MB* indicates animal identifier, with A or B indicating paired samples 150 from each lobe of the same light organ. (B) Corresponding relative abundance of non-V. 151 fischeri taxa in the samples described in panel A. Taxa are plotted at the family level, and 152 Vibrionaceae excludes ASVs identified as V. fischeri. Unidentified Bacteria correspond to 153 ASVs that were not assigned taxonomy past the kingdom level, likely due to a lack of similar 154 sequences in available hsp60 reference sequences. Other Taxa correspond to ASVs that 155 were assigned taxonomy to at least the family level but make up < 0.1 % of the total read 156 abundance. Sample order is consistent between panel A and panel B. 157 158
Application of hsp60 amplicon sequencing to characterize microbial communities associated with juvenile and adult Euprymna scolopes squid

September 2024

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7 Reads

Steph Smith

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Clotilde Bongrand

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Susannah Lawhorn

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[...]

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Alecia N. Septer

The symbiotic relationship between Vibrio (Aliivibrio) fischeri and the Hawaiian bobtail squid, Euprymna scolopes, serves as a key model for understanding host microbe interactions. Traditional culture-based methods have primarily isolated V. fischeri from the light organs of wild-caught squid, yet culture-independent analyses of this symbiotic microbiome remain limited. This study aims to enhance species-level resolution of bacterial communities associated with E. scolopes using hsp60 amplicon sequencing. We validated our hsp60 sequencing approach using pure cultures and mixed bacterial populations, demonstrating its ability to distinguish V. fischeri from other closely-related vibrios and the possibility of using this approach for strain-level diversity with further optimization. This approach was applied to whole-animal juvenile squid exposed to either seawater or a clonal V. fischeri inoculum, as well as ventate samples and light organ cores from wild-caught adults. V. fischeri accounted for the majority of the identifiable taxa for whole-animal juvenile samples and comprised 94%-99% of ASVs for adult light organ core samples, confirming that V. fischeri is the dominant, if not sole, symbiont typically associated with E. scolopes light organs. In one ventate sample, V. fischeri comprised 82% of reads, indicating the potential for non-invasive community assessments using this approach. Analysis of non-V. fischeri ASVs revealed that Bradyrhizobium spp. and other members of the Rhodobacterales order are conserved across juvenile and adult samples. These findings provide insight into the presence of additional microbial associations with the squid host tissue outside of the light organ that have not been previously detected through traditional culture methods.


The luxI gene is not necessary for luminescence induction. (A) Specific luminescence as a function of cell density for ES114 wild type (WT, black circles), luxI point mutant VCW2G7 (luxI pt., open black circles), luxI deletion mutant, ANS3 (ΔluxI, gray circles), ainS deletion mutant, NL60 (ΔainS, open gray circles), and luxI ainS double deletion mutant, KB12 (ΔluxI ΔainS, black squares). (B) Peak luminescence values (Luminescence/OD600) for indicated strains. To determine statistically significant differences between treatments in panel (B), a one-way ANOVA was performed, followed by a multiple t-test with Fisher’s least significant difference (LSD) post-test. Letters indicate statistical relatedness (P < 0.05). Error bars indicate standard error (n = 9). Panels (A) and (B) show representatives of multiple experiments performed at least three times.
Effect of exogenous 3OC6-HSL or luxI in trans on luxI mutants and wild type. (A and C) Specific luminescence as a function of cell density for the following strains grown with 3200 nM 3OC6-HSL added exogenously (A) or with luxI expressed in trans from plasmid pCRG36 (C): ES114 wild type (WT, black circles), luxI point mutant VCW2G7 (luxI pt., open black circles), and luxI deletion mutant ANS3 (ΔluxI, gray circles). (B and D) Peak luminescence values (Luminescence/OD600) for the indicated strains with added 3OC6-HSL (B) or carrying luxI on pCRG36 (D). Induction of luxI on pCRG36 was achieved by adding 500 µM isopropyl-ß-d-thiogalactoside. To determine statistically significant differences between treatments in panel (B), an ANOVA was performed, followed by a multiple t-test with Fisher’s LSD post-test. Letters indicate statistical relatedness (P < 0.05). Error bars indicate standard error (n = 9). Panels show representatives of multiple experiments performed at least three times. 3OC6-HSL, N-3-oxohexanoyl homoserine lactone.
Deletion of luxI increases luminescence of Vibrio fischeri

September 2024

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10 Reads

Bioluminescence in Vibrio fischeri is regulated by a quorum-dependent signaling system composed of LuxI and LuxR. LuxI generates N-3-oxohexanoyl homoserine lactone (3OC6-HSL), which triggers LuxR to activate transcription of the luxICDABEG operon responsible for bioluminescence. Surprisingly, a ∆luxI mutant produced more bioluminescence than the wild type in culture. In contrast, a 4 bp duplication within luxI, resulting in a frameshift mutation and null allele, decreased luminescence tenfold. A second signaling system encoded by ainSR affects bioluminescence by increasing levels of LuxR, via the transcriptional activator LitR, and the N-octanoyl homoserine lactone (C8-HSL) signal produced by AinS is considered only a weak activator of LuxR. However, ainS is required for the bright phenotype of the ∆luxI mutant in culture. When 3OC6-HSL was provided either in the medium or by expression of luxI in trans, all cultures were brighter, but the ∆luxI mutant remained significantly brighter than the luxI frameshift mutant. Taken together, these data suggest that the enhanced bioluminescence due to the LuxI product 3OC6-HSL counteracts a negative cis-acting regulatory element within the luxI gene and that when luxI is absent the C8-HSL signal is sufficient to induce luminescence. IMPORTANCE The regulation of bioluminescence by Vibrio fischeri is a textbook example of bacterial quorum-dependent pheromone signaling. The canonical regulatory model is that an autoinducer pheromone produced by LuxI accumulates as cells achieve a high density, and this LuxI-generated signal stimulates LuxR to activate transcription of the lux operon that underlies bioluminescence. The surprising observation that LuxI is dispensable for inducing bioluminescence forces a re-evaluation of the role of luxI. More broadly, the results underscore the potential deceptiveness of complex regulatory circuits, particularly those in which bacteria produce multiple related signaling molecules.


Lighting the way: how the Vibrio fischeri model microbe reveals the complexity of Earth’s “simplest” life forms

May 2024

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97 Reads

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1 Citation

Vibrio (Aliivibrio) fischeri’s initial rise to fame derived from its alluring production of blue-green light. Subsequent studies to probe the mechanisms underlying this bioluminescence helped the field discover the phenomenon now known as quorum sensing. Orthologs of quorum-sensing regulators (i.e., LuxR and LuxI) originally identified in V. fischeri were subsequently uncovered in a plethora of bacterial species, and analogous pathways were found in yet others. Over the past three decades, the study of this microbe has greatly expanded to probe the unique role of V. fischeri as the exclusive symbiont of the light organ of the Hawaiian bobtail squid, Euprymna scolopes. Buoyed by this optically amenable host and by persistent and insightful researchers who have applied novel and cross-disciplinary approaches, V. fischeri has developed into a robust model for microbe-host associations. It has contributed to our understanding of how bacteria experience and respond to specific, often fluxing environmental conditions and the mechanisms by which bacteria impact the development of their host. It has also deepened our understanding of numerous microbial processes such as motility and chemotaxis, biofilm formation and dispersal, and bacterial competition, and of the relevance of specific bacterial genes in the context of colonizing an animal host. Parallels in these processes between this symbiont and bacteria studied as pathogens are readily apparent, demonstrating functional conservation across diverse associations and permitting a reinterpretation of “pathogenesis.” Collectively, these advances built a foundation for microbiome studies and have positioned V. fischeri to continue to expand the frontiers of our understanding of the microbial world inside animals.


Flagella are required to coordinately activate competition and host colonization factors in response to a mechanical signal

January 2024

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36 Reads

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1 Citation

Bacteria employ antagonistic strategies to eliminate competitors of an ecological niche. Contact-dependent mechanisms, such as the type VI secretion system (T6SS), are prevalent in host-associated bacteria, yet we know relatively little about how T6SS+ strains make contact with competitors in highly viscous environments, such as host mucus. To better understand how cells respond to and contact one another in such environments, we performed a genome-wide transposon mutant screen of the T6SS-wielding beneficial bacterial symbiont, Vibrio fischeri , and identified two sets of genes that are conditionally required for killing. LPS/capsule and flagellar-associated genes do not affect T6SS directly and are therefore not required for interbacterial killing when cell contact is forced yet are necessary for killing in high-viscosity liquid (hydrogel) where cell-cell contact must be biologically mediated. Quantitative transcriptomics revealed that V. fischeri significantly increases expression of both T6SS genes and cell surface modification factors upon transition from low-to high-viscosity media. Consistent with coincubation and fluorescence microscopy data, flagella are not required for T6SS expression in hydrogel. However, flagella play a key role in responding to the physical environment by promoting expression of the surface modification genes identified in our screen, as well as additional functional pathways important for host colonization including uptake of host-relevant iron and carbon sources, and nitric oxide detoxification enzymes. Our findings suggest that flagella may act as a mechanosensor for V. fischeri to coordinately activate competitive strategies and host colonization factors, underscoring the significance of the physical environment in directing complex bacterial behaviors. Significance The physical environment can have dramatic effects on bacterial behavior, but little is known about how mechanical signals impact antagonistic interactions. Symbiotic bacteria use molecular weapons to eliminate competitors for limited space within highly viscous host tissue and mucus. To better understand how the physical environment affects competition and adhesion within eukaryotic hosts, we used quantitative transcriptomics to reveal the flagella-dependent transcriptional response to bacterial transition from lower to a higher viscosity environment. This work revealed the T6SS interbacterial weapon is coordinately activated with host colonization factors, emphasizing the importance of integrating activation of interbacterial weapons into host colonization pathways to enhance a symbiont’s ability to successfully colonize the host while efficiently eliminating potential competitors from the host niche.


Widespread use of proton-pumping rhodopsin in Antarctic phytoplankton

September 2023

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88 Reads

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10 Citations

Proceedings of the National Academy of Sciences

Photosynthetic carbon (C) fixation by phytoplankton in the Southern Ocean (SO) plays a critical role in regulating air–sea exchange of carbon dioxide and thus global climate. In the SO, photosynthesis (PS) is often constrained by low iron, low temperatures, and low but highly variable light intensities. Recently, proton-pumping rhodopsins (PPRs) were identified in marine phytoplankton, providing an alternate iron-free, light-driven source of cellular energy. These proteins pump protons across cellular membranes through light absorption by the chromophore retinal, and the resulting pH energy gradient can then be used for active membrane transport or for synthesis of adenosine triphosphate. Here, we show that PPR is pervasive in Antarctic phytoplankton, especially in iron-limited regions. In a model SO diatom, we found that it was localized to the vacuolar membrane, making the vacuole a putative alternative phototrophic organelle for light-driven production of cellular energy. Unlike photosynthetic C fixation, which decreases substantially at colder temperatures, the proton transport activity of PPR was unaffected by decreasing temperature. Cellular PPR levels in cultured SO diatoms increased with decreasing iron concentrations and energy production from PPR photochemistry could substantially augment that of PS, especially under high light intensities, where PS is often photoinhibited. PPR gene expression and high retinal concentrations in phytoplankton in SO waters support its widespread use in polar environments. PPRs are an important adaptation of SO phytoplankton to growth and survival in their cold, iron-limited, and variable light environment.


Fig. 2. Competition outcomes vary due to intraspecific variations in T6SS killing dynamics. (A)-(C) Fluorescence microscopy images of ES401 and FQ-A002 strains at 24 h following coincubation on LBS agar, compared side by side with representative ABM simulation images. The ES401 strain harbored the GFP-encoding plasmid pVSV102 (green), and the FQ-A002 strain harbored the dsRed-encoding plasmid pVSV208 (magenta). Microscopy images were taken at 10X; scale bars are 50 µm for all microscopy and simulation images. (A) Wildtype (WT) vs. wildtype pair under unprimed treatment. In the microscopy images, ES401 occupied 99.3% of the total area and FQ-A002 0.7%. In simulations, ES401 occupies 91.4%, and FQ-A002 1.8%. (B) WT vs. WT pair under primed treatment. In the microscopy images, ES401 occupied 46.6% of the total area and FQ-A002 53.4%. In simulations, ES401 occupies 53.2%, and FQ-A002 46.8%. (C) vasA − vs. vasA − pair under unprimed treatment. In microscopy images, ES401 occupied 48.7% of the total area and FQ-A002 51.3%. In simulations, ES401 occupies 51.2%, and FQ-A002 48.8%. The vasA − vs. vasA − pair under primed treatment gives a similar outcome to (C) experimentally; in simulation, it is identical to vasA − vs. vasA − under unprimed treatment, hence not repeated. All experiments were performed three times; all simulations were repeated 100 times. For additional experiment and simulation data, see SI Appendix Section 1, Fig. S1, SI movies S1&S2. For simulation parameters, see SI Appendix Tables S1&S2. (D) Total colony forming unit (CFU) counts of each strain in each coincubation at 0 h and 6 h following coincubation on LBS agar. (E) Total target strain CFU counts taken each hour for 5 h in unprimed coincubation between either wildtype FQ-A002 and ES401 vasA − or wildtype ES401 and an FQ-A002 vasA − . CFU data taken after time T ≥ 2 h of either strain is fit to an exponential decay model a exp(−bt) with a, b as fitting parameters. Data points at 0 h and 1 h are excluded. Decay rate b is reported for both strains.
Fig. 5. Target strains survive longer when competing against slow-activating lethal strains in a range expansion. (A) The cell counts of a target strain over time when it competes against two lethal strains in a range expansion; all results are averaged over 50 simulations. Colors correspond to the activation rate of the lethal strain in the coincubation: blue = lethal strain activates slower with λ+=0.25 h −1 , red = lethal strain activates faster with λ+=0.6 h −1 . The shaded region on each curve shows ±1 standard deviation. (B) Top: a representative simulation image of the slow activating (λ+ = 0.25 h −1 ) lethal (hidden) vs. target (green) coincubation in range expansion. Scale bar is 200 µm. Bottom: a fluorescence microscopy image of the ES114 target strain following a coincubation with the ES401 inhibitor strain; scale bar is 1 mm. Unprimed strains were mixed at a 1:1 ratio and coincubated for 24 h on LBS agar plates. For more details and simulation parameters, see SI Appendix Section 2, SI movie S3, and SI Tables S1&S3. Spatial environment of competition affects target survival. Bacteria 512
Fig. 6. Competitive outcomes and surviving mechanisms are affected by the cost of T6SS production. (A) Phase space of competitive outcome in mutually lethal competitions as a function of two dimensionless param-
A subcellular biochemical model for T6SS dynamics reveals winning competitive strategies

June 2023

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78 Reads

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4 Citations

PNAS Nexus

The type VI secretion system (T6SS) is a broadly distributed interbacterial weapon that can be used to eliminate competing bacterial populations. Although unarmed target populations are typically used to study T6SS function in vitro, bacteria most likely encounter other T6SS-armed competitors in nature. However, the connection between subcellular details of the T6SS and the outcomes of such mutually lethal battles is not well understood. Here, we incorporate biological data derived from natural competitors of Vibrio fischeri light organ symbionts to build a biochemical model for T6SS at the single-cell level, which we then integrate into an agent-based model (ABM). Using the ABM, we isolate and experiment with strain-specific physiological differences between competitors in ways not possible with biological samples to identify winning strategies for T6SS-armed populations. Through in vitro experiments, we discover that strain-specific differences exist in T6SS activation speed. ABM simulations corroborate that faster activation is dominant in determining survival during competition. Once competitors are fully activated, the energy required for T6SS creates a tipping point where increased weapon building and firing becomes too costly to be advantageous. Through ABM simulations, we identify the threshold where this transition occurs in the T6SS parameter space. We also find that competitive outcomes depend on the geometry of the battlefield: unarmed target cells survive at the edges of a range expansion where unlimited territory can be claimed. Alternatively, competitions within a confined space, much like the light organ crypts where natural V. fischeri compete, result in the rapid elimination of the unarmed population.


The Vibrio fischeri type VI secretion system incurs a fitness cost under host-like conditions

March 2023

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35 Reads

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6 Citations

The type VI secretion system (T6SS) is an interbacterial weapon composed of thousands of protein subunits and predicted to require significant cellular energy to deploy, yet a fitness cost from T6SS use is rarely observed. Here, we identify host-like conditions where the T6SS incurs a fitness cost using the beneficial symbiont, Vibrio fischeri, which uses its T6SS to eliminate competitors in the natural squid host. We hypothesized that a fitness cost for the T6SS could be dependent on the cellular energetic state and used theoretical ATP cost estimates to predict when a T6SS-dependent fitness cost may be apparent. Theoretical energetic cost estimates predicted a minor relative cost for T6SS use in fast-growing populations (0.4-0.45% of total ATP used cell-1), and a higher relative cost (3.1-13.6%) for stationary phase cells. Consistent with these predictions, we observed no significant T6SS-dependent fitness cost for fast-growing populations typically used for competition assays. However, the stationary phase cell density was significantly lower in the wild-type strain, compared to a regulator mutant that does not express the T6SS, and this T6SS-dependent fitness cost was between 11 and 23%. Such a fitness cost could influence the prevalence and biogeography of T6SSs in animal-associated bacteria. While the T6SS may be required in kill or be killed scenarios, once the competitor is eliminated there is no longer selective pressure to maintain the weapon. Our findings indicate an evolved genotype lacking the T6SS would have a growth advantage over its parent, resulting in the eventual dominance of the unarmed population.


Calcium Promotes T6SS-Mediated Killing and Aggregation between Competing Symbionts

December 2022

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18 Reads

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9 Citations

Microbiology Spectrum

Bacteria use a variety of strategies to exclude competitors from accessing resources, including space within a host niche. Because these mechanisms are typically costly to deploy, they are often tightly regulated for use in environments where the benefits outweigh the energetic cost. The type VI secretion system (T6SS) is a competitive mechanism that allows inhibitors to kill competing microbes by physically puncturing and translocating cytotoxic effectors directly into neighboring competitor cells. Although T6SSs are encoded in both symbiotic and free-living taxa where they may be actively secreting into the extracellular milieu during growth in liquid culture, there is little evidence for bacteria engaging in T6SS-mediated, contact-dependent killing under low-viscosity liquid conditions. Here, we determined that calcium acts as a pH-dependent cue to activate the assembly of an antibacterial T6SS in a Vibrio fischeri light organ symbiont in a low-viscosity liquid medium. Moreover, competing V. fischeri isolates formed mixed-strain aggregates that promoted the contact necessary for T6SS-dependent elimination of a target population. Our findings expand our knowledge of V. fischeri T6SS ecology and identify a low-viscosity liquid condition where cells engage in contact-dependent killing. IMPORTANCE Microbes deploy competitive mechanisms to gain access to resources such as nutrients or space within an ecological niche. Identifying when and where these strategies are employed can be challenging given the complexity and variability of most natural systems; therefore, studies evaluating specific cues that conditionally regulate interbacterial competition can inform the ecological context for such competition. In this work, we identified a pH-dependent chemical cue in seawater, calcium, which promotes activation of a contact-dependent interbacterial weapon in the marine symbiont Vibrio fischeri. This finding underscores the importance of using ecologically relevant salts in growth media and the ability of bacterial cells to sense and integrate multiple environmental cues to assess the need for a weapon. Identification of these cues provides insight into the types of environments where employing a weapon is advantageous to the survival and propagation of a bacterial population.


Fig. 2 Phylogenetic characterization of bacterial isolates. Phylogenetic tree based on 16S rRNA DNA sequences of indicated reference strains and bacterial isolates. Clades are color-coded by bacterial genera and isolates used for cocultures are indicated by a black circle. Classlevel designation is as follows: Flavobacteria (purple and blue), Alphaproteobacteria (green), Gammaproteobacteria (cyan, pink, orange). Node values represent maximum likelihood bootstrap.
Fig. 5 Co-isolated bacterial strains physically associate with P. subcurvata in coculture. Single cell DIC microscopy images were taken with a Nikon Ti-2 inverted epifluorescence microscope using 100x objective and NIS Elements acquisition software. Images are from vitaminlimited cocultures at day 42. Images are representatives of P. subcurvata cells grown alone (A) or with indicated bacteria (B-F). Arrows indicate bacterial cells.
Genome statistics for draft genomes of Sulfitobacter sp. SA1 and Olleya sp. A30.
A tripartite model system for Southern Ocean diatom-bacterial interactions reveals the coexistence of competing symbiotic strategies

October 2022

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73 Reads

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7 Citations

ISME Communications

Southern Ocean (SO) diatoms play an important role in global carbon flux, and their influence on carbon export is directly linked to interactions with epiphytic bacteria. Bacterial symbionts that increase diatom growth promote atmospheric carbon uptake, while bacterial degraders divert diatom biomass into the microbial loop where it can then be released as carbon dioxide through respiration. To further explore SO diatom-bacterial associations, a natural model system is needed that is representative of these diverse and important interactions. Here, we use concurrent cultivation to isolate a species of the ecologically-important SO diatom, Pseudo-nitzschia subcurvata , and its co-occurring bacteria. Although vitamin-depleted, axenic Pseudo-nitzschia grew poorly in culture, addition of a co-isolated Roseobacter promoted diatom growth, while addition of a co-isolated Flavobacterium negatively impacted diatom growth. Microscopy revealed both bacterial isolates are physically associated with diatom cells and genome sequencing identified important predicted functions including vitamin synthesis, motility, cell attachment mechanisms, and diverse antimicrobial weapons that could be used for interbacterial competition. These findings revealed the natural coexistence of competing symbiotic strategies of diatom-associated bacteria in the SO, and the utility of this tripartite system, composed of a diatom and two bacterial strains, as a co-culture model to probe ecological-relevant interactions between diatoms and the bacteria that compete for access to the phycosphere.


Citations (34)


... It was previously reported that there was cross-talk between the flagellar hierarchy system and the bacterial secretion system. Speare L et al. demonstrated that flagelladependent aggregation factors and TasL (T6SS2) may act in concert to facilitate cell-cell contact, thus mediating the killing ability of bacteria [47]. In the early stages of infection, Huang Z et al. demonstrated that the lateral flagellar-associated flhA gene was crucial for the adhesion and colonization of V. metschnikovii. ...

Reference:

Transcriptome Analysis Reveals Cross-Talk between the Flagellar Transcriptional Hierarchy and Secretion System in Plesiomonas shigelloides
Flagella are required to coordinately activate competition and host colonization factors in response to a mechanical signal

... This proposed function would create a proton gradient driving chloroplast-localized ATP synthase and increase cellular fitness under low-iron conditions (Figure 2b). Alternatively, xanthorhodopsin was localized to vacuolar membranes in the polar diatom Pseudo-nitzschia subcurvata, suggesting that it pumps protons to support vacuolar-type ATPases (4,156). ...

Widespread use of proton-pumping rhodopsin in Antarctic phytoplankton
  • Citing Article
  • September 2023

Proceedings of the National Academy of Sciences

... However, as a dynamic and specialized secretion system, despite the cost for "resource sharing", bacterial T6SS functionality may not incur a cost for intra-species competition, as reported recently [14], possibly due to the intrinsic defense via immunity proteins. In contrast, our data, supported by others, suggest that T6SS activity during intra-or inter-species interaction could be costly under specific conditions and in the presence of certain bacteria [22,35,89,90]. ...

A subcellular biochemical model for T6SS dynamics reveals winning competitive strategies

PNAS Nexus

... Selection to evolve such a genomic switch in bacteria could originate in the need to deactivate the expression of energycostly molecular machineries. Recent studies on Vibrio, Pseudomonas, and Bacteroides strains suggest that T6SS activity does have a fitness cost (64)(65)(66)(67). Ultimately, the imperfection of IS excision (Fig. 4E) (68) may promote the evolution of the machinery. ...

The Vibrio fischeri type VI secretion system incurs a fitness cost under host-like conditions

... ES114, which can be killed by FQ-A001 in a T6SS2-dependent manner (80), is an example of a T6SS2-negative strain, i.e., one that does not have the T6SS2 gene cluster. In addition, ES114 does not exhibit killing activity towards other strains of V. fischeri, which has led to its frequent use as a competitor in culture-based assays that test for T6SS activity in other strains (78)(79)(80)(84)(85)(86)(87). In fact, these assays readily identify strains that encode the T6SS2 gene cluster through their inhibition of ES114 growth (80,83), which provides further evidence that T6SS2 represents a mechanism of interference competition that is widespread among symbiotic strains of V. fischeri. ...

Coincubation Assay for Quantifying Competitive Interactions between Vibrio fischeri Isolates
  • Citing Article
  • July 2019

Journal of Visualized Experiments

... Previously, a study showed that Ca 2+ induces bile saltdependent virulence gene expression of V. cholerae through promoting bile salt-induced TcpP-TcpP interaction (Hay et al., 2017). Another study in V. fischeri showed that Ca 2+ functions as a pH-dependent cue to promote the T6SS-mediated competition in low-viscosity liquid environments (Speare et al., 2022). The data presented here showed that Ca 2+ can also regulate the virulence-associated phenotypes of V. parahaemolyticus RIMD2210633, including lethality in zebrafish, cytoxicity against HeLa cells and adhesion toward HeLa cells ( Figure 6). ...

Calcium Promotes T6SS-Mediated Killing and Aggregation between Competing Symbionts

Microbiology Spectrum

... Specifically, the microscopic environment (i.e., the phycosphere) of diatoms and bacteria [31,32] has been explored in depth. Then, the signaling mechanisms responsible for intra-and inter-species communication based on biochemical molecules have been explored [33,34]. In addition, the potential technological applications derived from diatombacterial interactions (including wastewater treatment and bioremediation, aquaculture, controlling harmful algal blooms, biofuel and pharmaceutical production) have been studied and developed during the last two decades [4]. ...

A tripartite model system for Southern Ocean diatom-bacterial interactions reveals the coexistence of competing symbiotic strategies

ISME Communications

... For example, the choice of ES114 as an initial focal strain certainly set a course for discoveries that may have been quite different if another strain had been chosen. With >70 V. fischeri genomes now sequenced and more labs exploring inter-strain variation, strain-specific differences have been reported for a variety of phenotypes, including T6SS content and effectors, regulation of biofilm and luminescence, aggregation size, and speed of host colonization [e.g., references (27,112,139,(171)(172)(173)]. Strain ES114 was selected initially because of its plasmid characteristics, but it was the genetic tractability of this strain that allowed for the rapid development of genetic tools that facilitated answering questions about bacterial physiology, interbacterial interactions, and host colonization. ...

Prevalence and diversity of type VI secretion systems in a model beneficial symbiosis

... Such co-colonization events might act as a strong selective pressure for V. fischeri symbionts to evolve one or more interference competition mechanisms to directly kill or stop the growth of a competitor in the same crypt. Studies using strains FQ-A001 and ES401 demonstrated that a strain-specific, type VI secretion system (T6SS2) interbac terial weapon (Fig. 5C) is necessary to prevent co-colonized crypts and outcompete a T6SS-deficient competitor in the light organ (112,162,163). By using fluorescence microscopy to localize each competitor within the crypt spaces, these data also revealed that T6SS-mediated killing is also capable of spatially structuring a host-associated microbiome through interference competition. ...

A Putative Lipoprotein Mediates Cell-Cell Contact for Type VI Secretion System-Dependent Killing of Specific Competitors

... Chemists have applied their imaging mass spectrometry approach (52) to reveal details about the chemical landscape of bacterial colonies and in symbiosis. Protein biochemists have explored symbiotically relevant signal transduction systems (53), and omics experts have applied their skills to explore the proteomes and transcrip tomes of V. fischeri [e.g., references (54)(55)(56)]. ...

Para-Aminobenzoic Acid, Calcium, and c-di-GMP Induce Formation of Cohesive, Syp-Polysaccharide-Dependent Biofilms in Vibrio fischeri