CHROMATIN ORGANISATION AND REGULATION OF PARARSITISM-ASSOCIATED GENOMIC ISLANDS IN PARASITIC NEMATODE GENOMES

Project: Research council

Project Details

Description

It is estimated that at least 40% of animals have a parasitic lifestyle. Parasites contribute to a huge global disease burden, for example, soil-transmitted helminths such as Strongyloides parasites, infect 1.5 billion people globally. Investigating the genomic and genetic basis of parasitism is important for understanding the fundamental principles of what makes a parasite a parasite and the evolution of parasitism. Furthermore, understanding how the genes involved in parasitism are regulated and organised can inform the development of control strategies and treatments for parasite infections. We have discovered that genes important for parasitism are physically arranged in clusters or 'parasitism-associated genomic islands' (PGIs) in the genome. Organisation of these genes into PGIs is likely to be important in rapidly turning on these genes during infection. This is important for the parasite so that it can rapidly respond to, and survive in, the harsh environment of its host. In this project we will investigate PGIs in a parasitic worm which infects the gut of mammals. We aim to investigate the common features and differences of PGIs across several different species of closely related gut worm parasites (Strongyloides spp.) to identify features in PGIs that are shared or different. We will use DNA and RNA sequencing to generate data to carry out this aim. We will also carry out experiments to explore how PGIs are regulated. We will look for specific signatures associated with histone proteins, which are involved in packaging DNA sequences, to establish if PGIs are precisely regulated by histone proteins during parasitism. We will also use a technology called Hi-C to see how different parts of the genome interact with each other during parasitism and how these interactions relate to PGIs. Finally, we have discovered that RNA molecules that don't code for proteins are also located in PGIs and these molecules are known to be important for regulating genes that are in close proximity. We will use an improved method to sequence and identify these non-coding RNA molecules, and investigate if they are involved in turning the genes on or off in PGIs.
StatusActive
Effective start/end date1/11/2331/10/26

Collaborative partners

Funding

  • Biotechnology and Biological Sciences Research Council

RCUK Research Areas

  • Animal science
  • Animal diseases
  • Genetics and development
  • Epigenetics
  • Genome organisation
  • Omic sciences and technologies
  • Transcriptomics
  • Parasitology

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