5 results on '"Antoine Claessens"'
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2. RecQ helicases in the malaria parasite Plasmodium falciparum affect genome stability, gene expression patterns and DNA replication dynamics.
- Author
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Antoine Claessens, Lynne M Harris, Slavica Stanojcic, Lia Chappell, Adam Stanton, Nada Kuk, Pamela Veneziano-Broccia, Yvon Sterkers, Julian C Rayner, and Catherine J Merrick
- Subjects
Genetics ,QH426-470 - Abstract
The malaria parasite Plasmodium falciparum has evolved an unusual genome structure. The majority of the genome is relatively stable, with mutation rates similar to most eukaryotic species. However, some regions are very unstable with high recombination rates, driving the generation of new immune evasion-associated var genes. The molecular factors controlling the inconsistent stability of this genome are not known. Here we studied the roles of the two putative RecQ helicases in P. falciparum, PfBLM and PfWRN. When PfWRN was knocked down, recombination rates increased four-fold, generating chromosomal abnormalities, a high rate of chimeric var genes and many microindels, particularly in known 'fragile sites'. This is the first identification of a gene involved in suppressing recombination and maintaining genome stability in Plasmodium. By contrast, no change in mutation rate appeared when the second RecQ helicase, PfBLM, was mutated. At the transcriptional level, however, both helicases evidently modulate the transcription of large cohorts of genes, with several hundred genes-including a large proportion of vars-showing deregulated expression in each RecQ mutant. Aberrant processing of stalled replication forks is a possible mechanism underlying elevated mutation rates and this was assessed by measuring DNA replication dynamics in the RecQ mutant lines. Replication forks moved slowly and stalled at elevated rates in both mutants, confirming that RecQ helicases are required for efficient DNA replication. Overall, this work identifies the Plasmodium RecQ helicases as major players in DNA replication, antigenic diversification and genome stability in the most lethal human malaria parasite, with important implications for genome evolution in this pathogen.
- Published
- 2018
- Full Text
- View/download PDF
3. Generation of antigenic diversity in Plasmodium falciparum by structured rearrangement of Var genes during mitosis.
- Author
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Antoine Claessens, William L Hamilton, Mihir Kekre, Thomas D Otto, Adnan Faizullabhoy, Julian C Rayner, and Dominic Kwiatkowski
- Subjects
Genetics ,QH426-470 - Abstract
The most polymorphic gene family in P. falciparum is the ∼60 var genes distributed across parasite chromosomes, both in the subtelomeres and in internal regions. They encode hypervariable surface proteins known as P. falciparum erythrocyte membrane protein 1 (PfEMP1) that are critical for pathogenesis and immune evasion in Plasmodium falciparum. How var gene sequence diversity is generated is not currently completely understood. To address this, we constructed large clone trees and performed whole genome sequence analysis to study the generation of novel var gene sequences in asexually replicating parasites. While single nucleotide polymorphisms (SNPs) were scattered across the genome, structural variants (deletions, duplications, translocations) were focused in and around var genes, with considerable variation in frequency between strains. Analysis of more than 100 recombination events involving var exon 1 revealed that the average nucleotide sequence identity of two recombining exons was only 63% (range: 52.7-72.4%) yet the crossovers were error-free and occurred in such a way that the resulting sequence was in frame and domain architecture was preserved. Var exon 1, which encodes the immunologically exposed part of the protein, recombined in up to 0.2% of infected erythrocytes in vitro per life cycle. The high rate of var exon 1 recombination indicates that millions of new antigenic structures could potentially be generated each day in a single infected individual. We propose a model whereby var gene sequence polymorphism is mainly generated during the asexual part of the life cycle.
- Published
- 2014
- Full Text
- View/download PDF
4. Induction of strain-transcending antibodies against Group A PfEMP1 surface antigens from virulent malaria parasites.
- Author
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Ashfaq Ghumra, Jean-Philippe Semblat, Ricardo Ataide, Carolyne Kifude, Yvonne Adams, Antoine Claessens, Damian N Anong, Peter C Bull, Clare Fennell, Monica Arman, Alfred Amambua-Ngwa, Michael Walther, David J Conway, Lalla Kassambara, Ogobara K Doumbo, Ahmed Raza, and J Alexandra Rowe
- Subjects
Immunologic diseases. Allergy ,RC581-607 ,Biology (General) ,QH301-705.5 - Abstract
Sequence diversity in pathogen antigens is an obstacle to the development of interventions against many infectious diseases. In malaria caused by Plasmodium falciparum, the PfEMP1 family of variant surface antigens encoded by var genes are adhesion molecules that play a pivotal role in malaria pathogenesis and clinical disease. PfEMP1 is a major target of protective immunity, however, development of drugs or vaccines based on PfEMP1 is problematic due to extensive sequence diversity within the PfEMP1 family. Here we identified the PfEMP1 variants transcribed by P. falciparum strains selected for a virulence-associated adhesion phenotype (IgM-positive rosetting). The parasites transcribed a subset of Group A PfEMP1 variants characterised by an unusual PfEMP1 architecture and a distinct N-terminal domain (either DBLα1.5 or DBLα1.8 type). Antibodies raised in rabbits against the N-terminal domains showed functional activity (surface reactivity with live infected erythrocytes (IEs), rosette inhibition and induction of phagocytosis of IEs) down to low concentrations (
- Published
- 2012
- Full Text
- View/download PDF
5. Generation of antigenic diversity in Plasmodium falciparum by structured rearrangement of Var genes during mitosis
- Author
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Mihir Kekre, William L Hamilton, Antoine Claessens, Adnan Faizullabhoy, Julian C. Rayner, Thomas D. Otto, and Dominic P. Kwiatkowski
- Subjects
Cancer Research ,Plasmodium ,Erythrocytes ,Protozoan Proteins ,QH426-470 ,Genome ,Biochemistry ,Exon ,Cloning, Molecular ,Homologous Recombination ,Peptide sequence ,Genetics (clinical) ,Genetics ,Gene Rearrangement ,Immune System Proteins ,Nucleic acid sequence ,Chromosome Mapping ,Exons ,Genomics ,Subtelomere ,Antigenic Variation ,3. Good health ,Research Article ,DNA recombination ,Molecular Sequence Data ,Plasmodium falciparum ,Immunology ,Mitosis ,Antigens, Protozoan ,Biology ,Polymorphism, Single Nucleotide ,Parasite Groups ,Antigenic variation ,Humans ,Amino Acid Sequence ,Antigens ,Molecular Biology ,Gene ,Ecology, Evolution, Behavior and Systematics ,Alleles ,Biology and life sciences ,Proteins ,Gene rearrangement ,Sequence Analysis, DNA ,DNA ,DNA, Protozoan ,Gene Expression Regulation ,Parasitology ,Apicomplexa - Abstract
The most polymorphic gene family in P. falciparum is the ∼60 var genes distributed across parasite chromosomes, both in the subtelomeres and in internal regions. They encode hypervariable surface proteins known as P. falciparum erythrocyte membrane protein 1 (PfEMP1) that are critical for pathogenesis and immune evasion in Plasmodium falciparum. How var gene sequence diversity is generated is not currently completely understood. To address this, we constructed large clone trees and performed whole genome sequence analysis to study the generation of novel var gene sequences in asexually replicating parasites. While single nucleotide polymorphisms (SNPs) were scattered across the genome, structural variants (deletions, duplications, translocations) were focused in and around var genes, with considerable variation in frequency between strains. Analysis of more than 100 recombination events involving var exon 1 revealed that the average nucleotide sequence identity of two recombining exons was only 63% (range: 52.7–72.4%) yet the crossovers were error-free and occurred in such a way that the resulting sequence was in frame and domain architecture was preserved. Var exon 1, which encodes the immunologically exposed part of the protein, recombined in up to 0.2% of infected erythrocytes in vitro per life cycle. The high rate of var exon 1 recombination indicates that millions of new antigenic structures could potentially be generated each day in a single infected individual. We propose a model whereby var gene sequence polymorphism is mainly generated during the asexual part of the life cycle., Author Summary Malaria kills >600,000 people each year, with most deaths caused by Plasmodium falciparum. A family of proteins known as P. falciparum erythrocyte membrane protein 1, PfEMP1, is expressed on the surface of infected erythrocytes and plays an important role in pathogenesis. Each P. falciparum genome contains approximately 60 highly polymorphic var genes encoding the PfEMP1 proteins, and monoallelic expression with periodic switching results in immune evasion. Var gene polymorphism is thus critical to this survival strategy. We investigated how var gene diversity is generated by performing an in vitro evolution experiment, tracking var gene mutation in ‘real-time’ with whole genome sequencing. We found that genome structural variation is focused in and around var genes. These genetic rearrangements created new ‘chimeric’ var gene sequences during the mitotic part of the life cycle, and were consistent with processes of mitotic non-allelic homologous recombination. The recombinant var genes were always in frame and with conserved overall var gene architecture, and the recombination rate implies that many millions of rearranged var gene sequences are produced every 48-hour life cycle within infected individuals. In conclusion, we provide a detailed description of how new var gene sequences are continuously generated in the parasite genome, helping to explain long-term parasite survival within infected human hosts.
- Published
- 2014
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