TAPEWORM FOUND LIVING INSIDE A PATIENT'S BRAIN
A genome of a rare
species of tapeworm found living inside a patient's brain has been sequenced
for the first time, in research published in the open access journal Genome Biology. The study provides insights into potential drug targets
within the genome for future treatments.
A 50-year-old man of
Chinese ethnicity was admitted to hospital in the East of England after
reporting symptoms of headaches, seizures, altered smell and memory impairment.
The patient had lived in the UK for 20 years but visited his homeland often.
After testing negative for a range of diseases and not presenting any other
abnormalities, doctors began to take a series of MRI images of his brain. Over
the course of four years, they noticed a lesion migrate at least 5 cm across
his brain, and after taking a biopsy from his left thalamus, they discovered a
1 cm long ribbon-shaped larval worm. The patient, who remains anonymous, was
cured of his infection by the operation and is now recovering.
Small samples of the
worm were sent to researchers at the Wellcome Trust Sanger Institute, where
they began to investigate its genome. Through sequencing its DNA, they
identified it as Spirometra erinaceieuropaei,
a rare tapeworm species typically found in China, South Korea, Japan and
Thailand, and known to cause infection by ingesting undercooked frogs or
snakes, using frog meat for treating wounds, and ingesting contaminated water.
The researchers
sequenced the worm's entire genome for the first time, measuring it as 1.26
billion base pairs long, which is currently the largest reported genome for any
flatworm. This was despite the fact they had such a small sample to work from
after removal from the patient's brain. By investigating specific sections of
the worm's genome, they were also able to identify genes for resistance to
certain treatments, and other potential drugs targets.
Lead author Hayley
Bennett from the Wellcome Trust Sanger Institute said: "This infection is
so rare worldwide and completely unexpected in this country that the patient
was not diagnosed with sparganosis until the worm was pulled out from the
brain. We were also surprised at how large the genome was, it is much bigger
than those of other known flatworms, and roughly a third of the size of the
human genome. By comparing the genome to other tapeworms we can see that
certain gene families are expanded -- these possibly underpin this worm's
success in a large variety of host species. The data gave us a first look at a
whole group of tapeworms that have not been sequenced before."
Through
investigating specific parts of the genome for sensitivity to known tapeworm
treatments, the researchers found that the tapeworm had genes providing
resistance to benzimidazole, but possible sensitivity to another tapeworm drug
praziquantel.
The team also
investigated the genome to find potential targets which could be exploited by
drugs already on the market but known for treating other diseases. They found a
number of genes which are targets for known cancer drugs, suggesting that these
treatments could be re-purposed for treating this type of infection.
The researchers also
identified twenty expanded gene families with unknown function, which they say
demonstrates how little is known about this order of tapeworms, and could
explain its ability to live in a wide range of hosts (crustaceans, reptiles,
amphibians and mammals) as well as in aquatic environments. They have made all
their data publicly available so as to help other researchers.
Hayley Bennett said:
"We think that it is important to make the genomic data available as is it
offers a resource predicting whether other drugs can be repurposed for use in
really rare infections such as in this case."
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