From the first identification of bacteria as a causative agent of disease, researchers have been developing methods and techniques to understand their pathogenic processes. For decades, this work has been limited to looking at a small number of genetically manipulatable isolates in in vitro assays or animal models of infection. Despite these limitations such work has facilitated the development of successful therapeutic strategies, most notably vaccines that target specific virulence-related features. There are however many antimicrobial resistant pathogens for which vaccination strategies have not worked, as we simply do not know enough about how they cause disease. We are however at the dawn of a new era in the study of microbial pathogenicity, where large collections of bacteria isolated directly from human infections can be sequenced and assayed to identify the bacterial features that affect disease severity in humans. Here, we describe our attempt to perform such a study focussed on the major human pathogen Staphylococcus aureus, which demonstrates the step changes such approaches can make to understanding microbial pathogenicity

AL DuMont

AP Johnson

D Vorkapic

E Klein

F Vandenesch

FD Lowy

G Sakoulas

GA Somerville

HR Rose

JA Ibarra

L Tuchscherr

M Laabei

Maisem Laabei

MM Dinges

MZ David

NK Priest

Ruth Massey

TJ Foster

VG Fowler Jr

WR Jarvis

X Didelot

Y Rhee

English

PubMed

From the first identification of bacteria as a causative agent of disease, researchers have been developing methods and techniques to understand their pathogenic processes. For decades, this work has been limited to looking at a small number of genetically manipulatable isolates in in vitro assays or animal models of infection. Despite these limitations such work has facilitated the development of successful therapeutic strategies, most notably vaccines that target specific virulence-related features. There are however many antimicrobial resistant pathogens for which vaccination strategies have not worked, as we simply do not know enough about how they cause disease. We are however at the dawn of a new era in the study of microbial pathogenicity, where large collections of bacteria isolated directly from human infections can be sequenced and assayed to identify the bacterial features that affect disease severity in humans. Here, we describe our attempt to perform such a study focussed on the major human pathogen Staphylococcus aureus, which demonstrates the step changes such approaches can make to understanding microbial pathogenicity.</p

Laabei, Maisem

Massey, Ruth

Explore Bristol Research

Using functional genomics to decipher the complexity of microbial pathogenicity

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1 3Curr Genet (2016) 62:523–525DOI 10.1007/s00294-016-0576-4REVIEWUsing functional genomics to decipher the complexity of microbial pathogenicityMaisem Laabei1 · Ruth Massey1  Received: 11 December 2015 / Revised: 2 February 2016 / Accepted: 3 February 2016 / Published online: 22 February 2016 © The Author(s) 2016. This article is published with open access at Springerlink.comStaphylococcus aureus is the primary cause of a wide range of human infections, including septicaemia, abscesses and endocarditis (Lowy 1998). Although the rates of methi-cillin-resistant S. aureus (MRSA) are declining in certain European hospitals, a recent study showed that the inci-dence of MRSA bacteraemia was greater than 25 % in over one-third of European countries (Johnson 2011). In the United States, the rate of MRSA infection has decreased since 2006 (Klein et al. 2007); however, the proportion of those infections caused by the highly virulent, sequence type 8, USA300 clone has risen sharply (Jarvis et al. 2012; Rhee et al. 2015). USA300 is the predominant clone caus-ing community-acquired infections in otherwise healthy individuals, and is now considered endemic in many US communities and hospitals (David and Daum 2010; Rhee et al. 2015). Even with increased surveillance, improved patient management and treatment regimes, S. aureus remains a major public health concern (Johnson 2011; Jarvis et al. 2012). As a response to the severe threat S. aureus possesses to global human health, a deeper under-standing of its pathogenesis at the genetic and molecular level is warranted.Staphylococcus aureus is both a major human pathogen and resident of the normal microflora. For decades, it has been considered an opportunistic pathogen, where breaches in host immunity are considered the route through which it transitions from being a coloniser to an invasive pathogen. This suggests that disease onset and severity are wholly driven by the host, where given identical opportunity two genetically distinct S. aureus isolates will cause identical disease. However, the fact that we have globally successful clones of S. aureus circulating and hyper-virulent strains causing a significant burden of disease suggests that spe-cific bacterial features contribute significantly to the onset and severity of disease. Until we understand the effect of Abstract From the first identification of bacteria as a causative agent of disease, researchers have been develop-ing methods and techniques to understand their pathogenic processes. For decades, this work has been limited to look-ing at a small number of genetically manipulatable isolates in in vitro assays or animal models of infection. Despite these limitations such work has facilitated the develop-ment of successful therapeutic strategies, most notably vac-cines that target specific virulence-related features. There are however many antimicrobial resistant pathogens for which vaccination strategies have not worked, as we sim-ply do not know enough about how they cause disease. We are however at the dawn of a new era in the study of microbial pathogenicity, where large collections of bacteria isolated directly from human infections can be sequenced and assayed to identify the bacterial features that affect disease severity in humans. Here, we describe our attempt to perform such a study focussed on the major human pathogen Staphylococcus aureus, which demonstrates the step changes such approaches can make to understanding microbial pathogenicity.Keywords Staphylococcus aureus · Toxicity · GWAS · Evolutionary trade-offs · BacteraemiaCommunicated by M. Kupiec. * Ruth Massey  r.c.massey@bath.ac.uk1 Department of Biology and Biochemistry, University of Bath, Bath BA2 7AY, UK524 Curr Genet (2016) 62:523–5251 3these on disease in humans we will not have a full picture of this microbe’s pathogenicity.Staphylococcus aureus possesses an extensive repertoire of virulence factors facilitating its dual life-style as a com-mensal and a pathogen (Foster and Hook 1998; Vandenesch et al. 2012; Vorkapic et al. 2015), where the secretion of toxins is classically considered an essential element in the development of infection (Dinges et al. 2000). The staphy-lococcal scientific literature is abundant with many excel-lent studies involving the mechanism of action, host recep-tor tropism and regulation of the many toxins secreted by S. aureus (Vandenesch et al. 2012; Ibarra et al. 2013; DuMont and Torres 2014). At present, we are at a stage where it is affordable to rapidly and accurately sequence large num-bers of clinical isolates, resulting in new opportunities to study pathogen evolution, epidemiology and antibiotic resistance (Didelot et al. 2012). The question that has been presented is whether this revolution in next-generation sequencing and abundance in genomic information can aid in our understanding of the fundamental basis of S. aureus virulence.As the secretion of toxins is an integral part of the S. aureus virulence repertoire, we focussed on investigating the molecular and genetic basis of toxin secretion. Here, we combined whole-genome sequencing and phenotypic data, developing a genome-wide association study (GWAS) to detail how polymorphisms affect bacterial cytotoxicity. In two recent publications, we document the functional genomics approach we undertook to determine which mutations affected this phenotype. In our first paper ‘Pre-dicting the virulence of MRSA from its genome sequence’ (Laabei et al. 2014), we explored the use of GWAS to identify genes, acting singularly or in epistasis, which we predicted to have an impact of toxicity, using the globally important, widely-disseminated ST239 lineage (Laabei et al. 2014). From our list of 121 statistically significant polymorphisms affecting toxicity, we sought to functional verify 13 of these loci, resulting in the description of four previously uncharacterised regions of the ST239 genome, that when disrupted significantly impact on toxicity. Addi-tionally, by adopting a machine learning approach using a subset of these polymorphisms (unique SNPs and one SNP from each group of SNPs in linkage disequilibrium) we were able to make predictions on the toxicity of these strains using sequencing data with high accuracy (>85 %) (Laabei et al. 2014).Staphylococcus aureus gene expression is tightly con-trolled and has evolved to be energetically efficient. The secretion of toxins, generally considered to be positively associated with increased disease severity, comes at a high energetic price and is readily switched off in vitro (Somer-ville et al. 2002) with recent observational studies sug-gesting that this also occurs in vivo (Fowler et al. 2004; Rose et al. 2015). In our most recent paper, ‘Evolutionary trade-offs underlie the multifaceted virulence of S. aureus’ (Laabei et al. 2015), we adopted our functional genomics approach to understand and define mutations associated with this reduction in toxicity. Therein, we describe the elu-cidation of six novel loci that when mutated significantly decrease toxicity, highlighting the complex nature of S. aureus toxin regulation (Laabei et al. 2015). The decrease in toxicity was significantly associated with strains origi-nating from bacteraemia, compared to strains from skin and soft tissue infections (SSTIs) or carriage strains. Pre-vious groups showed that clinical strains isolated from the blood had increased defective mutations in the accessory gene regulator (Agr) operon, the main quorum sensing sys-tem which regulates toxins in S. aureus and had increased resistance to vancomycin (Sakoulas et al. 2005). Interest-ingly, in this collection of isolates there was no difference in the number of Agr mutations present in the carriage/SSTI group compared to the bacteraemia group, and no sig-nificant difference between vancomycin resistance between the two groups (data not published).We further investigated several hypotheses as to why a decrease in toxicity may be selected for and associated with bacteraemia. By measuring growth dynamics and relative fitness, we found that low-toxic isolates were significantly more fit when grown in the presence of serum than high-toxic isolates. Given the extreme bottleneck bacteria have to traverse to establish a bloodstream infection, our hypoth-esis is that a reduction in toxicity by mutation of various genes increases its relative fitness compared to high-toxic strains due to the energy cost of toxin production.The discovery and elucidation of novel virulence regulators has been an immensely important feature of understanding S. aureus pathogenesis. To the best of our knowledge there are approximately 30 known virulence regulators, including two-component systems, DNA-bind-ing proteins and regulatory RNAs (Priest et al. 2012; Tuch-scherr and Loffler 2015). Virulence factors’ expression in S. aureus occurs in a temporal growth-phase-dependent man-ner employing multiple arms of this complex regulon at any one time. In the past 2 years, as a result of our functional genomics approach a further 10 genetic loci have been shown to be affected by S. aureus virulence, specifically toxicity. From our unpublished work, we have identified a further three loci important in the regulation of toxicity, of which we are currently characterising. Following with this theme, and focusing on S. aureus biofilm activity, we have identified two novel regions that increase biofilm forma-tion following gene inactivation. These preliminary forays into applying functional genomics approaches to microbial pathogens clearly illustrate how fruitful this can be.The functional genomics approach we have developed makes use of assaying large numbers of clonally related 525Curr Genet (2016) 62:523–525 1 3clinical strains. This methodology has not only allowed us to make significant leaps in understanding the vast regulon that affects toxicity, and virulence in general, but has high-lighted that intra-clonally, strains have highly variable tox-icity levels, a feature that has not been shown to this extent before. The functional genomics approach allows us to bet-ter understand pathogen biology, shown here by the discov-ery of the trade-off which exists between S. aureus toxicity and fitness in serum which we hypothesise is an essential step in the progression of bacteraemia. As we are entering the next-generation sequencing era, whereby the cost of sequencing a single strain has reduced dramatically, whilst the accuracy has increased significantly, we desperately need a strategy to understand this abundance in genomic information and how it impacts on pathogen behaviour. By combining large-scale sequencing with comprehensive phenotypic studies, we can begin to map the entire viru-lence pathway, identifying virulence signatures responsible for hyper-virulence. These strategies may play a central role in developing the holy-grail of patient care, personal-ised medicine, whereby detailed patient data and bacterial genome sequences will be used in combination to optimise treatment and improve the outcome for patients.Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://crea-tivecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.ReferencesDavid MZ, Daum RS (2010) Community-associated methicillin-resistant Staphylococcus aureus: epidemiology and clinical consequences of an emerging epidemic. Clin Microbiol Rev 23:616–687Didelot X, Bowden R, Wilson DJ, Peto TE, Crook DW (2012) Trans-forming clinical microbiology with bacterial genome sequenc-ing. 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BMC Genom 14:126Jarvis WR, Jarvis AA, Chinn RY (2012) National prevalence of methicillin-resistant Staphylococcus aureus in inpatients at United States health care facilities, 2010. Am J Infect Control 40:194–200Johnson AP (2011) Methicillin-resistant Staphylococcus aureus: the European landscape. J Antimicrob Chemother 66(Suppl 4):iv43–iv48Klein E, Smith DL, Laxminarayan R (2007) Hospitalizations and deaths caused by methicillin-resistant Staphylococcus aureus, United States, 1999–2005. Emerg Infect Dis 13:1840–1846Laabei M, Recker M, Rudkin JK, Aldeljawi M, Gulay Z, Sloan TJ, Williams P, Endres JL, Bayles KW, Fey PD, Yajjala VK, Wid-helm T, Hawkins E, Lewis K, Parfett S, Scowen L, Peacock SJ, Holden M, Wilson D, Read TD, van den Elsen J, Priest NK, Feil EJ, Hurst LD, Josefsson E, Massey RC (2014) Predicting the virulence of MRSA from its genome sequence. 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