Dr Leah Roberts
Dr

Leah Roberts

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Background

Dr Leah Roberts is a bacterial bioinformatician currently working on clinically important bacterial pathogens and antimicrobial resistance. She uses whole genome sequencing to investigate mobile genetic elements, such as plasmids, that can transfer horizontally between bacteria thereby spreading resistance within a bacterial population. Her research is focused on developing bioinformatic tools and studying the epidemiology of bacteria commonly associated with Hospital Acquired Infections.

After obtaining her PhD from the University of Queensland in 2019 she moved to the United Kingdom to undertake a Biomedical Fellowship with the European Molecular Biology Laboratory's European Bioinformatics Institute and the University of Cambridge. In 2023 she returned to Australia with a lecturer position at the Queensland University of Technology. In the same year she was awarded an NHMRC EL1 Investigator Fellowship and has since moved to the UQ Centre for Clinical Research on the Herston campus. She collaborates with a number of public health providers including Pathology Queensland and Forensic Scientific Services.

Availability

Dr Leah Roberts is:
Available for supervision

Research interests

  • Tracking plasmid spread using whole genome sequencing

    Plasmids are small extra-chromosomal DNA that can transfer horizontally between bacteria. They often harbour genes that confer antimicrobial resistance, and can rapidly spread resistance through a bacterial population via this horizontal transfer. Using whole genome sequencing, we are interested in understanding how plasmids evolve and tracking their movement in bacterial populations. This will allow us to identify plasmid-mediated AMR outbreaks as they occur in healthcare settings.

  • Pangenomes to track bacterial outbreaks in hospital settings

    Outbreak investigations using whole genome sequencing usually rely on a single reference genome. However, depending on how representative this genome is to the diversity of the species, the resolution of the outbreak may or may not be sufficient for practical interventions. We aim to develop novel pangenome methods to better capture species-level diversity to improve the resolution of bacteria outbreaks.

Research impacts

My research program has focused heavily on the integration of bacterial whole-genome sequencing (WGS) for hospital epidemiology and infection control. My work has been pivotal for advancing the field of real-time WGS reporting to clinical collaborators in nosocomial outbreaks, with my WGS findings directly informing infection control interventions. Some examples include: (i) the decision not to close a surgery theatre when WGS revealed the isolate to be unrelated to the outbreak, and (ii) rigorous cleaning of hospital plumbing based on source-tracing of the outbreak strain using metagenomics. My work has also led to several further studies evaluating the cost of integrating genomics to prevent outbreaks and featured in a perspectives article in Med J Aust on major antimicrobial resistance (AMR) threats facing Australia.

Internationally, I have co-conceived and co-led large bacterial genomics projects at Addenbrooke’s Hospital, United Kingdom. My work reported unknown retrospective transmission events to infection control staff and identified the 1st documented outbreak of the ST78 Klebsiella pneumoniae lineage, which appears unique to this hospital setting. I also led the largest genomic epidemiology study of AMR bacteria conducted in Vietnam to date. This study adds crucial new information on circulating AMR in low- and middle-income countries and highlights the urgent need for more resources to combat the rising threat of AMR in Vietnam and beyond. Finally, I have worked in close collaboration with researchers in South Africa, understanding local epidemiology of Mycobacterium tuberculosis and the emergence of bedaquiline resistance.

Search Professor Leah Roberts’s works on UQ eSpace

25 works between 2015 and 2024
All (25) Journal Article (22) Other Outputs (3)

21 - 25 of 25 works

2017

Journal Article

From isolate to answer: how whole genome sequencing is helping us rapidly characterise nosocomial bacterial outbreaks

Roberts, Leah (2017). From isolate to answer: how whole genome sequencing is helping us rapidly characterise nosocomial bacterial outbreaks. Microbiology Australia, 38 (3), 127-130. doi: 10.1071/MA17047

From isolate to answer: how whole genome sequencing is helping us rapidly characterise nosocomial bacterial outbreaks

2016

Journal Article

Comprehensive analysis of type 1 fimbriae regulation in fimB-null strains from the multidrug resistant Escherichia coli ST131 clone

Sarkar, Sohinee, Roberts, Leah W., Phan, Minh-Duy, Tan, Lendl, Lo, Alvin W., Peters, Kate M., Paterson, David L., Upton, Mathew, Ulett, Glen C., Beatson, Scott A., Totsika, Makrina and Schembri, Mark A. (2016). Comprehensive analysis of type 1 fimbriae regulation in fimB-null strains from the multidrug resistant Escherichia coli ST131 clone. Molecular Microbiology, 101 (6), 1069-1087. doi: 10.1111/mmi.13442

Comprehensive analysis of type 1 fimbriae regulation in fimB-null strains from the multidrug resistant Escherichia coli ST131 clone

2016

Journal Article

Erratum for Ben Zakour et al., Sequential Acquisition of Virulence and Fluoroquinolone Resistance Has Shaped the Evolution of Escherichia coli ST131

Ben Zakour, Nouri L, Alsheikh-Hussain, Areej S, Ashcroft, Melinda M, Khanh Nhu, Nguyen Thi, Roberts, Leah W, Stanton-Cook, Mitchell, Schembri, Mark A and Beatson, Scott A (2016). Erratum for Ben Zakour et al., Sequential Acquisition of Virulence and Fluoroquinolone Resistance Has Shaped the Evolution of Escherichia coli ST131. mBio, 7 (3), 1-1. doi: 10.1128/mBio.00958-16

Erratum for Ben Zakour et al., Sequential Acquisition of Virulence and Fluoroquinolone Resistance Has Shaped the Evolution of Escherichia coli ST131

2016

Journal Article

Sequential acquisition of virulence and fluoroquinolone resistance has shaped the evolution of Escherichia coli ST131

Ben Zakour, Nouri L., Alsheikh-Hussain, Areej S., Ashcroft, Melinda M., Nhu, Nguyen Thi Khanh, Roberts, Leah W., Stanton-Cook, Mitchell, Schembri, Mark A. and Beatson, Scott A. (2016). Sequential acquisition of virulence and fluoroquinolone resistance has shaped the evolution of Escherichia coli ST131. MBio, 7 (2) e00347-16, e00347-16.1-e00347-16.11. doi: 10.1128/mBio.00347-16

Sequential acquisition of virulence and fluoroquinolone resistance has shaped the evolution of Escherichia coli ST131

2015

Journal Article

Third-generation cephalosporin resistance conferred by a chromosomally encoded blaCMY-23 gene in the Escherichia coli ST131 reference strain EC958

Phan, Minh-Duy, Peters, Kate M., Sarkar, Sohinee, Forde, Brian M., Lo, Alvin W., Stanton-Cook, Mitchell, Roberts, Leah W., Upton, Mathew, Beatson, Scott A. and Schembri, Mark A. (2015). Third-generation cephalosporin resistance conferred by a chromosomally encoded blaCMY-23 gene in the Escherichia coli ST131 reference strain EC958. Journal of Antimicrobial Chemotherapy, 70 (7) dkv066, 1969-1972. doi: 10.1093/jac/dkv066

Third-generation cephalosporin resistance conferred by a chromosomally encoded blaCMY-23 gene in the Escherichia coli ST131 reference strain EC958

Availability

Dr Leah Roberts is:
Available for supervision

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Available projects

  • De novo identification of insertion sequences with De Bruijn graphs

    Insertion sequences (IS) are small DNA elements that can replicate and move throughout a bacterial genome independently. This ability often results in their insertion upstream of or within genes, which consequently leads to large effects on gene expression within the bacteria. These changes in expression can affect a multitude of phenotypes, including resistance to antibiotics and virulence. As such, is it necessary that we characterise where these IS move to within the genome.

    Unfortunately, as IS are small and repetitive throughout the genome, they cause issues for short-read de novo assemblers, most notably collapsed repeats. Because of this, it can be difficult to determine the exact location of IS throughout the genome.

    This project aims to develop an end-to-end pipeline for de novo IS discovery using De Bruijn graphs, and quantify in a collection of bacterial genomes the effect of IS insertions on phenotype.

    This project is suitable for an honours or Masters student. Some background in command line, HPC and python is highly desirable. In this project, you will learn about bacterial genomics and pipeline managers (e.g. Snakemake) in addition to bioinformatic tool development and testing. This project will be based at UQCCR (Herston Campus) and co-supervised by Dr Tom Stanton (Monash University).

  • Machine Learning to predict plasmids from bacterial isolates

    Plasmids play a key role in gene exchange between bacteria and often carry gene conferring resistance to antibiotics and survival in hospital environments. However, they are difficult to fully characterise from short-read whole genome sequencing data alone. This is because plasmids are typically full of repeat sequences which can cause problems for short-reads assemblers. Long-read sequencing can solve this issue, however this technology is currently not routinely used in healthcare settings.

    We have developed a plasmid network that allows users to predict the types of plasmids in their bacterial samples based on gene presence/absence. This project would build upon this work by creating a machine learning framework (Random Forest) that can predict plasmid presence from short-read bacteria.

    This project is suitable for an honours or Masters student. Background in command line, HPC and python is highly desirable. This project will be based at UQCCR (Herston Campus) and co-supervised by Prof Zamin Iqbal (University of Bath, UK).

  • Pangenomes to predict bacterial transmission in healthcare settings

    Predicting whether two bacterial isolates are the same (and thereby inferring if transmission has occurred) has traditionally been performed by identifying and counting single nucleotide variants (SNVs). To do this, a reference genome is usually selected, and isolate reads are mapped to the reference to identify SNVs in regions shared between all isolates. However, for large datasets of very diverse bacterial strains, a single reference genome is usually insufficient, as the shared regions between the strains becomes a very small proportion of the total genomic content.

    We propose a novel method using pangenome reference graphs to better identify and discriminate transmission of bacterial pathogens. This project would start to build test datasets and develop novel workflows for predicting transmission from pangenome graphs.

    This project is suitable for an honours, Masters, or PhD student. Background in command line, HPC and python is highly desirable. This project will be based at UQCCR (Herston Campus) and co-supervised by Dr Michael Hall (University of Melbourne).

Supervision history

Current supervision

Enquiries

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