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De novo assembly of plasmodium interspersed repeat (pir) genes from Plasmodium vivax RNAseq data suggests geographic conservation of sub-family transcription
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De novo assembly of plasmodium interspersed repeat (pir) genes from Plasmodium vivax RNAseq data suggests geographic conservation of sub-family transcription
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De novo assembly of plasmodium interspersed repeat (pir) genes from Plasmodium vivax RNAseq data suggests geographic conservation of sub-family transcription
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Journal Article
De novo assembly of plasmodium interspersed repeat (pir) genes from Plasmodium vivax RNAseq data suggests geographic conservation of sub-family transcription
2025
Overview
Background
The
plasmodium interspersed repeats
(
pir
) multigene family is found across malaria parasite genomes, first discovered in the human-infecting species
Plasmodium vivax
, where they were initially named the
vir
s. Their function remains unknown, although studies have suggested a role in virulence of the asexual blood stages. Sub-families of the
P. vivax pir/vir
s have been identified, and are found in isolates from across the world, however their transcription at different localities and in different stages of the life cycle have not been quantified. Multiple transcriptomic studies of the parasite have been conducted, but many map the
pir
reads to existing reference genomes (as part of standard bioinformatic practice), which may miss members of the multigene family due to its inherent variability. This obscures our understanding of how the
pir
sub-families in
P. vivax
may be contributing to human/vector infection.
Results
To overcome the issue of hidden
pir
diversity from utilising a reference genome, we employed de novo transcriptome assembly to construct the
pir
‘reference’ of different parasite isolates from published and novel RNAseq datasets. For this purpose, a pipeline was written in Nextflow, and first tested on data from the rodent-infecting
P. c. chabaudi
parasite to ascertain its efficacy on a sample with a full, genome-based set of
pir
gene sequences. The pipeline assembled hundreds of
pir
s from the studies included. By performing BLAST sequence identity comparisons with reference genome
pir
s (including
P. vivax
and related species) we found a clustered network of transcripts which corresponded well with prior sub-family annotations, albeit requiring some updated nomenclature. Mapping the RNAseq datasets to the de novo transcriptome references revealed that the transcription of these updated
pir
gene sub-families is generally consistent across the different geographical regions. From this transcriptional quantification, a time course of mosquito bloodmeals (after feeding on an infected patient) highlighted the first evidence of ookinete stage
pir
transcription in a human-infective malaria parasite.
Conclusions
De novo transcriptome assembly is a valuable tool for understanding highly variable multigene families from
Plasmodium spp
., and with pipeline software these can be applied more easily and at scale. Despite a global distribution,
P. vivax
has a conserved
pir
sub-family structure—both in terms of genome copy number and transcription. We suggest that this indicates important roles of the distinct sub-families, or a genetic mechanism maintaining their preservation. Furthermore, a burst of
pir
transcription in the mosquito stages of development is the first glint of ookinete
pir
expression for a human-infective malaria parasite, suggesting a role for the gene family at a new stage of the lifecycle.
Publisher
BioMed Central,BioMed Central Ltd,Springer Nature B.V,BMC
Subject
