Abstract
Babesia bovis establishes persistent infections of long duration in cattle, despite the development of effective anti-disease immunity. One mechanism used by the parasite to achieve persistence is rapid antigenic variation of the VESA1 cytoadhesion ligand through segmental gene conversion (SGC), a phenomenon thought to be a form of homologous recombination (HR). To begin investigation of the enzymatic basis for SGC we initially identified and knocked out the Bbrad51 gene encoding the B. bovis Rad51 ortholog. BbRad51 was found to be non-essential for in vitro growth of asexual-stage parasites. However, its loss resulted in hypersensitivity to methylmethane sulfonate (MMS) and an apparent defect in HR. This defect rendered attempts to complement the knockout phenotype by reinsertion of the Bbrad51 gene into the genome unsuccessful. To circumvent this difficulty, we constructed an artificial chromosome, BbACc3, into which the complete Bbrad51 locus was inserted, for expression of BbRad51 under regulation by autologous elements. Maintenance of BbACc3 makes use of centromeric sequences from chromosome 3 and telomeric ends from chromosome 1 of the B. bovis C9.1 line. A selection cassette employing human dihydrofolate reductase enables recovery of transformants by selection with pyrimethamine. We demonstrate that the BbACc3 platform is stably maintained once established, assembles nucleosomes to form native chromatin, and expands in telomere length over time. Significantly, the MMS-sensitivity phenotype observed in the absence of Bbrad51 was successfully complemented at essentially normal levels. We provide cautionary evidence, however, that in HR-competent parasites BbACc3 can recombine with native chromosomes, potentially resulting in crossover. We propose that, under certain circumstances this platform can provide a useful alternative for the genetic manipulation of this group of parasites, particularly when regulated gene expression under the control of autologous elements may be important.
Highlights
Babesiosis is a tick-borne disease caused by apicomplexan parasites of the genus Babesia
The other three B. bovis RecA/RadA/Rad51-related proteins cluster more closely with the Escherichia coli RecA protein included as outlier
The pfam14520 "helix-hairpin-helix" domain, which is common to Rad51 proteins, was lacking from the other three candidates
Summary
Babesiosis is a tick-borne disease caused by apicomplexan parasites of the genus Babesia. Humans are not the natural host for any babesial parasite but may be an incidental host, acquiring zoonotic infections with a variety of different species. Babesia microti is the most common species of Babesia to infect humans, in western Europe infections commonly occur with Babesia divergens. In the U.S infections have been observed with Babesia duncani and B. divergens-like organisms, as well as the unspeciated WA1 and MO1 isolates (reviewed in [1]). In cattle babesiosis may be caused by at least five different species, with Babesia bovis generally considered the most virulent. B. bovis shares many parallels with the human malarial parasite, Plasmodium falciparum, including immune evasion via cytoadhesion and antigenic variation, and the capacity for development of a lethal cerebral disease [6]
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