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Posters for NIMBioS Investigative Workshop: Systems and Synthetic Microbiology Poster Abstracts for NIMBioS Investigative WorkshopSystems and Synthetic Microbiology Authors: Seda Arat1, Michael Schlais2, George Bullerjahn2, Reinhard Laubenbacher1
Institutions: (1) Dept. of Mathematics & Virginia Bioinformatics Institute, Virginia Tech, Blacksburg,
VA; (2) Dept. of Biological Sciences, Bowling Green State Univ., Bowling Green, OH
Title: A mathematical model of denitrification in Pseudomonas aeruginosa
Abstract: Pseudomonas aeruginosa is a metabolically exible member of the Gammaproteobacteria.
Under anaerobic conditions and the presence of nitrate, P. aeruginosa can perform (complete)
denitrification, a respiratory process of dissimilatory nitrate reduction to nitrogen gas via nitrite
(NO2), nitric oxide (NO) and nitrous oxide (N2O). This study focuses on a mathematical model of a
metabolic network in P. aeruginosa under denitrification and testable hypotheses generation. To our
knowledge, this is the first mathematical model of denitrification for this bacterium. Analysis of the
long-term behavior of the system changing the concentration level of oxygen (O2), nitrate (NO3), and
phosphate (PO4) suggests that PO4 highly acts the denitrification performance of the network. This
study aims to capture the ect of phosphate on a denitrification metabolic network of P. aeruginosa
incorporating systems biology approach in order to shed light on the reason of greenhouse gas N2O
accumulation during oxygen depletion in Lake Erie, OH.
Author: Munehiro Asally
Institution: Univ. of California, San Diego
Title: Localized cell death focuses mechanical forces during biofilm formation
Abstract: From microbial biofilm communities to multicellular organisms, three-dimensional (3D)
macroscopic structures develop through a poorly understood interplay between cellular processes
and mechanical forces. Investigating wrinkled biofilms of Bacillus subtilis, we discovered a pattern of
localized cell death that spatially focuses mechanical forces, and thereby initiates wrinkle formation.
Deletion of genes implicated in biofilm development, together with mathematical modeling, revealed
that extracellular matrix production underlies the localization of cell death. Simultaneously with cell
death, we quantitatively measured mechanical stiffness and movement in wild-type and mutant
biofilms. Results suggest that localized cell death provides an outlet for lateral compressive forces,
thereby promoting vertical mechanical buckling, which subsequently leads to wrinkle formation.
Guided by these findings, we were able to generate artificial wrinkle patterns within biofilms.
Formation of 3D structures facilitated by cell death, may underlie self-organization in other
developmental systems, and could enable engineering of macroscopic structures from cell
populations.
Authors: Dong-Hoon Chung1,2, Åke Västermark3, Jeremy V. Camp1, Carl Bruder2, Susanna K.
Remold4, Yong-Kyu Chu2, Punya Mardhanan2, Ryan McAllister5, and Colleen B. Jonsson1,2,5
Institutions: (1) Department of Microbiology and Immunology, Univ. of Louisville, Louisville,
Kentucky; (2) Center for Predictive Medicine for Biodefense and Emerging Infectious Diseases, Univ.
of Louisville, Louisville, Kentucky; (3) Institutionen för Neurovetenskap, BMC, Box 593, 751 24
Uppsala, Sweden; (4) Department of Biology, Univ. of Louisville, Louisville, Kentucky; (5) Department
of Pharmacology and Toxicology, Univ. of Louisville, Louisville, Kentucky
Title: The murine model for Hantaan virus-induced lethal disease shows two distinct paths in viral
evolutionary trajectory with or without ribavirin treatment
Abstract: In vitro, ribavirin acts as a lethal mutagen in Hantaan virus (HTNV)-infected Vero E6 cells
resulting in increased mutation load and viral population extinction. Herein, we asked whether
ribavirin treatment in the lethal, suckling mouse model of HTNV would act similarly. HTNV genomic
RNA (vRNA) copy number and infectious virus were measured in lungs of mice in untreated and
ribavirin-treated mice. In untreated, HTNV-infected mice, vRNA increased to 10 days post-infection
Posters for NIMBioS Investigative Workshop: Systems and Synthetic Microbiology (DPI) and thereafter remained constant to 26 DPI. Surprisingly, in ribavirin-treated, HTNV-infectedmice, vRNA levels were similar to untreated between 10 and 26 DPI. Infectious virus levels, however,differed; in ribavirin-treated mice, infectious HTNV was significantly decreased relative to untreatedmice, suggesting that ribavirin reduced the fitness of the virus (infectious virus produced per vRNAcopy). Mutational analysis revealed a similar ribavirin-associated elevation in mutation frequency inHTNV vRNA as was previously reported in vitro. Codon-based analyses of rates of nonsynonymous(dN) and synonymous (dS) substitutions in the S-segment revealed a positive selection on amino acidsin the HTNV N protein in the ribavirin-treated vRNA population. In contrast, the vRNA population inuntreated HTNV-infected mice showed a lower diversity reflecting purifying selection for thewild-type genome. In summary, these experiments show two different evolutionary paths thatHantavirus may take during infection of a lethal murine model of disease, and the importance of thein vivo host environment in the evolution of the virus that is not apparent in our prior in vitro modelsystem.
Authors: Amiyaal Ilany1, Adi Barocas1,2, Lee Koren1,3, Michael Kam4 and Eli Geffen1
Institutions: (1) Dept. of Zoology, Tel Aviv Univ., Tel Aviv, Israel; (2) Dept. of Zoology and Physiology
and Program in Ecology, Univ. of Wyoming, Laramie, WY, USA; (3) Dept. of Comparative Biology &
Experimental Medicine, Faculty of Veterinary Medicine, Univ. of Calgary, Calgary, Canada; (4) Desert
Animal Adaptations and Husbandry, Wyler Dept. of Dryland Agriculture, The Jacob Blaustein
Institutes for Desert Research, Ben Gurion Univ. of the Negev, Beer Sheva, Israel.
Title: The enemy of my enemy is my friend: structural balance in the social networks of a wild
mammal
Abstract: Our understanding of the forces stabilizing specific social structures in animals is limited.
The social structure of a population is based on individual social associations, which can be
described using network patterns (motifs). Structural balance theory was proposed for exploring
social alliances, and suggested that some network motifs are more stable than others in a society. The
theory models the presence of specific triads in the network and their effect on the global population
structure, based on the differential stability of specific triad configurations. While structural balance
was recently shown in human social networks, the theory has never been tested in animal societies.
Here we use empirical data from an animal social network to examine, for the first time, the
presence and effects of structural balance. We confirm the presence of structural balance in a wild
rock hyrax (Procavia capensis) population and show its ability to predict social changes resulting
from local instability. We show that new individuals entering the population introduce social
instability, which counters the tendency of social relationships to seek balanced structures. Our
findings imply that structural balance has a role in the evolution of social structure.
Author: Tatiana Karpinets
Institution: Biosciences Division, Oak Ridge National Laboratory
Title: Revealing regularities in large datasets with biological annotations using networks and rules of
their association
Abstract: The expanse of experimental data produced by modern biotechnologies requires the
development and application of novel computational tools for their processing. Combined in one
table this mash up of qualitative and quantitative data is challenging to analyze and interpret. To
address this challenge we developed a computational framework that expands current approaches to
viewing, visualizing, searching, and analyzing information in large databases with biological
annotations. The approach is based on two novel concepts, the type-value format and the association
network (Anet) that supplement the idea of association rules (Arules) produced by 'Apriori'.
Type-value format simplifies computational processing, filtering and grouping of biological
annotations by preserving their two-level structural organization in the transaction records and
further in Arules and Anets. For annotation types presented by quantitative data, such as genome
size or GC content, quantities are replaced with their quality levels based on distributions of the
quantities in the dataset records. Association network provides a way to link a diverse set of
Posters for NIMBioS Investigative Workshop: Systems and Synthetic Microbiology annotations directly, by the number of transactions where each pair of annotations co-occurred, andindirectly, by considering similarity between profiles of their co-occurrences with other annotations.
Monte Carlo simulation is used to assess the significance of similarity by p-value. The resulting Anetis further analyzed and visualized at different levels of resolution, or p-value thresholds, usingclustering and visualization techniques. In combination, Anets and Arules provide researchers apowerful tool to create a bird's-eye view of the collected information, to extract hidden biologicalregularities and to generate hypotheses for further experimental validation. To test this frameworkwe applied it to the analysis of metadata of sequenced prokaryotic genomes from the GenomeOnLineDatabase (GOLD). The overlapping structure of the data provides a good case study for the proposedframework. The generated Anet revealed a hidden structure in metadata of the prokaryoticorganisms with three major clusters representing metadata of pathogens, environmental isolates andplant symbionts. The annotations clustered in each group represented a distinct signature profile ofmetadata for each group and showed a strong link between phenotypic, genomic and environmentalfeatures of the organisms.
Authors: Minsu Kim
Institutions: Physics, Emory Univ., Atlanta, Georgia
Title: Steady state growth of E. coli in low ammonium environment
Abstract: Ammonium is the preferred nitrogen source for many microorganisms. In medium with
low ammonium concentrations, enteric bacteria turn on the Ammonium/methylammonium
transporter AmtB, an inner membrane protein that transports NH4+ across the cell membrane
against a concentration gradient. In order to study ammonium uptake at low NH4+ concentration at
neutral pH, we developed a microfluidic flow chamber that maintains a homogenous nutrient
environment during the course of exponential cell growth, even at very low concentration of
nutrients. Cell growth can be accurately monitored using time-lapse microscopy. We followed steady
state growth down to micro-molar range of NH4+ for the wild type and amtB strains. The mutant
exhibited reduced growth at ˜20 M of NH4+ while wild type strain is able to maintain the growth rate
below that. Using a combination of quantitative gene expression and flux analysis, we show that E.
coli
cells maintain the internal ammonia concentrations at a steady level barely above the minimal
needed for rapid cell growth in poor ammonium conditions. The robust maintenance is achieved by
ultra-sensitive response of AmtB activity, which can be understood in light of a simple integral
feedback model of carbon-nitrogen coordination suggested by the characterized molecular
interactions, without invoking any molecular cooperativity.
Authors: Babak Momeni1, Kristen A. Brileya2, Matthew W. Fields2, and Wenying Shou1
Institutions: (1) Division of Basic Sciences, Fred Hutchinson Cancer Research Center, Seattle, WA; (2)
Center for Biofilm Engineering, Montana State Univ., Bozeman
Title: Compositional stability and spatial patterning driven by ecological interactions in microbial
communities
Abstract: Community structure – the population composition and the pattern of spatial distribution
of individuals within a microbial community – is often critical to community function. However,
understanding the mechanisms of structure formation in natural communities is hampered by the
multitude of cell-cell and cell-environment interactions as well as environmental variability. Here,
through simulations and experiments on communities in defined environments, we examined how
ecological interactions between two distinct partners impacted community structure. Using a simple
mathematical model based on the fitness effects of local cell-cell interactions, we made two
predictions. First, we showed analytically that disparate initial population ratios have the potential to
converge and thus confer compositional stability only if the interaction is beneficial to at least one
partner. Second, only strongly-cooperating partners intermix by appearing successively on top of
each other. Both predictions were validated in engineered yeast communities engaging in different
metabolic interactions. We then used a more detailed and realistic "diffusion model," tailored to the
yeast communities and experimentally validated, to explore conditions that were difficult to achieve
Posters for NIMBioS Investigative Workshop: Systems and Synthetic Microbiology experimentally. We found that partner intermixing required spatial localization of large benefits forboth partners and was otherwise insensitive to initial conditions and interaction dynamics. Even insimulated communities consisting of several species, most of the strongly-cooperating pairs appearedintermixed. Partner intermixing was also observed in a methane-producing bacteria-archaeacommunity cooperating through redox-coupling. We have thus described the expected compositionand patterning of microbial communities when the fitness effects of pair-wise interactions are themajor driving force. Analogous to how Gause's competitive exclusion principle has fueled researchon mechanisms that generate exceptions to the principle, i.e. the coexistence of species, we hope thatour work will create a framework to examine other forces that shape community structure.
Author: Michele K. Nishiguchi
Institution: Dept. of Biology, New Mexico State Univ., Las Cruces
Title: From saltwater to genes and back again: How beneficial bacteria can help decipher the
evolutionary mechanisms of symbiosis
Abstract: The mutualistic association between sepiolid squids (Mollusca: Cephalopoda) and their
Vibrio symbionts is an experimentally tractable model to study the evolution of animal-bacterial
associations through both wild-caught and experimentally evolved populations. Since Vibrio bacteria
are environmentally transmitted to new hosts with every generation, it provides a unique
opportunity to resolve how changing environmental conditions may effect bacterial infection,
colonization, and persistence in different host species. Vibrio bacteria encounter potentially
conflicting selective pressures, competing with one another to colonize the sepiolid light organ, but
also competing for resources in the environment outside the squid. Both abiotic and biotic factors
contribute to the fitness of individual strains of Vibrio bacteria, but which of these factors are
amenable to adaptation and eventually lead to a successful beneficial association has yet to be
elucidated. This poster will cover how environmental conditions and host specificity lead to the
development of symbiotically adapted Vibrio bacteria, generating new ideas on the evolution of
beneficial associations.
Authors: Shaneka S. Simmons and Raphael D. Isokpehi
Institution: Center for Bioinformatics & Dept. of Biology, Jackson State Univ., Jackson, Mississippi
Title: Iron transport gene neighbors of stress-responsive major facilitator in the genome of bioenergy
relevant Rhodopseudomonas palustris
Abstract: Gene clustering properties have been used to predict gene functions based on annotation
of its gene neighborhoods, with the assumption that conserved gene sets are proximally arranged
along the chromosome, are dependent on each other, and that conserved neighbors with similar
functions are preserved between several genomes. In bacterial species occupying highly complex
and unstable environments, gene order conservation is shaped by the relative importance of genes
for cell survival and by interference from various selective pressures imposed upon genome stability,
affecting different genes and operons or putative operons. Furthermore, remnants of gene order
conservation can be found as highly conserved clusters across very distantly related taxonomic
lineages, suggesting that selective processes maintain gene organization in various genomic regions.
Through the use of bioinformatics tools available in the Integrated Microbial Genome (IMG) systems,
we identified the gene specific chromosomal cassette for R. palustris major facilitator fused Universal
Stress Protein domain based on the presence/absence of genes within the neighbor of organisms
containing a similar chromosomal cluster. The UspA domain (Pfam accession number PF00582) has
been shown to respond to a variety of stressors including those causing oxidative stress. One Usp
gene (RPC_3634 or UniProt Q210L7) encodes a 565 aa protein that in addition to the USP domain
contains a carbohydrate transport Major Facilitator Superfamily (MFS_1) domain. The fused gene is
present only in the genome of strain BisB18. The Pfam functional annotation of the upstream gene
cluster of RPC_3634 also revealed genes encoding transporters of iron. Genes (RPC_3632, RPC_3631,
and RPC_3630) were predicted to be in a transcription unit in the BioCyc database. Chromosomal
cassette alignment using RPC_3631 as gene of focus was performed to determine other prokaryotes
Posters for NIMBioS Investigative Workshop: Systems and Synthetic Microbiology with the iron transport cluster. The Usp domain may mediate co-regulation and co-functionality ofneighboring genes that are involved in various biochemical pathways in an effort to combatenvironmental stress.
Authors: Adam M. Sullivan1,2, Xiaopeng Zhao1,2, Yasuhiro Suzuki3, Eri Ochiai3, Stephen Crutcher3,
Michael A. Gilchrist2,4
Institutions: (1) Dept. of Mechanical, Aerospace and Biomedical Engineering, Univ. of Tennessee,
Knoxville; (2) National Institute of Mathematical and Biological Synthesis, Univ. of Tennessee,
Knoxville; (3) Dept. of Microbiology, Immunology, and Molecular Genetics, Univ. of Kentucky,
Lexington; (4) Dept. of Ecology and Evolutionary Biology, Univ. of Tennessee, Knoxville
Title: Evidence of asynchronous growth of Toxoplasma gondii cyst based on data-driven model
selection
Abstract: Toxoplasma gondii establishes a chronic infection by forming cysts preferentially in the
brain. This chronic infection is one of the most common parasitic infections in humans and can be
reactivated to develop life-threatening toxoplasmic encephalitis in immunocompromised patients.
Analyzing the growth mechanism of T. gondii cyst is important for understanding the pathogenesis
mechanism. We developed a differential equation framework of cyst growth and employed Akaike
Information Criteria (AIC) to determine the growth and removal functions that best describe the data
of cyst sizes measured from the brains of chronically infected mice. The AIC results showed that the
T. gondii cyst size grows at a constant rate. Correspondingly, the per capita growth rate of the parasite
is inversely proportional to the number of parasites within a cyst, indicating asynchronous
replication of the parasite. The modeling and analysis framework may provide a useful tool for
understanding the pathogenesis of many apicomplexan parasites.
Author: Yu Tanouchi
Institution: Dept. Biomedical Engineering, Duke Univ.
Title 1: A synthetic-biology approach to understanding bacterial programmed death and implications
for antibiotic treatment
Abstract: Programmed death is often associated with a bacterial stress response. This behavior
appears paradoxical, as it offers no benefit to the individual. This paradox can be explained if the
death is 'altruistic': the sacrifice of some cells can benefit the survivors through release of 'public
goods'. However, the conditions where bacterial programmed death becomes advantageous have not
been unambiguously demonstrated experimentally. Here, we determined such conditions by
engineering tunable, stress-induced altruistic death in the bacterium Escherichia coli. Using a
mathematical model, we predicted the existence of an optimal programmed death rate that
maximizes population growth under stress. We further predicted that altruistic death could generate
the 'Eagle effect', a counter-intuitive phenomenon where bacteria appear to grow better when
treated with higher antibiotic concentrations. In support of these modeling insights, we
experimentally demonstrated both the optimality in programmed death rate and the Eagle effect
using our engineered system. These findings fill a critical conceptual gap in the analysis of the
evolution of bacterial programmed death, and have implications for a design of antibiotic treatment.
Author: Yu Tanouchi
Institution: Dept. Biomedical Engineering, Duke Univ.
Title 2: Optimality and robustness in QS-mediated regulation of a costly public-good enzyme
Abstract: Bacteria secrete a variety of 'public-good' exoproducts into their environment. These
exoproducts are typically produced under the control of quorum sensing (QS), a signaling
mechanism by which bacteria sense and respond to changes in their density.QS appears to provide
an advantageous strategy to regulate these costly yet beneficial exoproducts: it delays production
until sufficiently high cell density, when the overall benefit of exoproducts outweighs cost of their
Posters for NIMBioS Investigative Workshop: Systems and Synthetic Microbiology production. This notion raises several fundamental questions about QS as a general control strategyadopted by bacteria: How much delay is advantageous? Under what conditions does QS-mediatedregulation become advantageous? How does this advantage depend on the kinetic properties of QS?How robust is a given QS system to the stochastic events that occur over bacterial lifecycles? Toquantitatively address these questions, we engineered a gene circuit in Escherichia coli to control thesynthesis and secretion of a costly but beneficial exoenzyme. We show that exoenzyme production isoverall advantageous only if initiated at a sufficiently high density. This property sets the potentialadvantage for QS-mediated regulation when initial density is low and the growth cycle sufficientlylong in comparison to exoenzyme response time. This advantage of QS-mediated regulation is robustto varying initial cell densities and growth durations and is particularly striking when bacteria faceuncertainty, such as from stochastic dispersal during their lifecycle. We show, however, that for QS tobe optimal, its kinetic properties must be appropriately tuned; this property has implications forantibacterial treatments that target QS.
Authors: KL Whiteson1, S Meinard2, YW Lim1, R Schmieder1, M Haynes1, D Blake2, D Conrad 3, FL
Rohwer1
Institutions: (1) San Diego State Univ.; (2) Univ. of California, Irvine; (3) Dept of Medicine, Univ. of
California San Diego
Title: Breath gasses as biomarkers in cystic fibrosis
Abstract: Long-term microbial infections in the lungs of Cystic Fibrosis (CF) patients are complex,
individual, and difficult to correlate with patient condition or response to treatment. Gasses found in
the breath of CF patients may enable detection of the presence of specific microbial metabolism in a
particular microbial community and disease state. Our goal is to find molecules in breath samples
that are specific to microbial metabolism and unique to CF patients. Ultimately, we would like to
unveil mechanisms that explain how bacteria persist in the CF lung. This information could be used
to diagnose and treat infection specifically.
Using the Gas Chromotography and Mass Spectrometry methods established in the Rowland-Blakelab at UCI, we have analyzed seven triplicate breath samples at approximately monthly timepointsfrom a cystic fibrosis patient and three gender-matched controls along with a room sample toestablish the background. We also took induced sputum samples from the same CF patient, atdifferent timepoints, and sequenced the total viral DNA, microbial DNA and RNA. We find elevatedlevels of 2,3-butanedione in the CF patient, which is not present in the three healthy controls.
2,3-butanedione is a fermentation product specific to a subset of bacteria including Enterobacter spp,Streptococcus spp and Klebsiella spp. In a bacterial fuel cell model recently published by theAngenent lab at Cornell University, 2,3-butanediol produced by Enterobacter aerogenes fueledincreased growth rates in Pseudomonas aeruginosa. When P. aeruginosa had access to 2,3-butanediolas a carbon source, production of a particular phenazine, pyocyanin, greatly increased. Phenazinesare redox active compounds that have been described as antibiotics, however they can also reduceFe(III) to Fe(II), which P. aeruginosa is equipped to uptake with an Fe(II) specific transporter, FeoB.
Phenazines can also act as electron acceptors, enabling anaerobic respiration in the low oxygenconditions of CF sputum. We find hits to genes involved in 2,3-butanedione metabolism andcatabolism, along with phenazine production and Fe(II) transport in our CF microbial metagenomes.
The combination of 2,3-butanedione in the CF patient’s breath with the presence of genes encodingenzymes required for butanedione and phenazine metabolism suggest that this CF patient’s lungharbors the same productive bacterial interaction as the bacterial fuel cell model. Access to scarceiron resources and the ability to carry out anaerobic respiration could both give P. aeruginosa asurvival advantage in the lungs of a CF patient. Synergism between bacteria which arises in thebiogeochemical circumstances unique to an individual CF lung may be an important driver ofmicrobial growth and provide explanations for difficult to diagnose exacerbations in CF patients.

Source: http://www.nimbios.org/workshops/posters/WS_ss_micro_posterabstracts.pdf

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