Surveillance of avian malaria and related haemoparasites in common terns (Sterna hirundo) on the Atlantic coast of South America.

Haemosporidia (Apicomplexa, Haemosporida) are protozoa that infect vertebrate blood cells and are transmitted by vectors. Among vertebrates, birds possess the greatest diversity of haemosporidia, historically placed in 3 genera: Haemoproteus, Leucocytozoon and Plasmodium, the causative agent of avian malaria. In South America, existing data on haemosporidia are spatially and temporally dispersed, so increased surveillance is needed to improve the determination and diagnosis of these parasites. During the non-breeding season in 2020 and 2021, 60 common terns (Sterna hirundo) were captured and bled as part of ongoing research on the population health of migratory birds on the Argentinian Atlantic coast. Blood samples and blood smears were obtained. Fifty-eight samples were screened for Plasmodium, Haemoproteus and Leucocytozoon, as well as for Babesia parasites by nested polymerase chain reaction and by microscopic examination of smears. Two positive samples for Plasmodium were found. The cytochrome b lineages detected in the present study are found for the first time, and are close to Plasmodium lineages found in other bird orders. The low prevalence (3.6%) of haemoparasites found in this research was similar to those reported for previous studies on seabirds, including Charadriiformes. Our findings provide new information about the distribution and prevalence of haemosporidian parasites from charadriiforms in the southernmost part of South America, which remains understudied.

Characterization and diversity of Babesia sp. YLG, a new member of the Peircei group infecting Mediterranean yellow-legged gulls (Larus michahellis).

Avian infecting piroplasms are largely under-studied compared to other hemoparasites, and this paucity of information has blurred our phylogenetic and biological comprehension of this important group as a whole. In the present study, we detected and characterized Babesia from yellow-legged gull (Larus michahellis) chicks from a colony in southern France. Based on morphological and molecular characterizations, a new Babesia species belonging to the Peircei group, a clade of avian-specific piroplasms, was identified. Due to the complexity of species delineations and the low number of parasites characterized in this clade to date, a species name was not yet attributed; we refer to it for now as Babesia sp. YLG (Yellow-Legged Gull). High prevalence (85% and 58% in 2019 and 2020, respectively) and high parasitemia (up to 20% of parasitized erythrocytes) were recorded in chicks, without any obvious clinical signs of infection. Although the 16 isolates examined had identical 18S rRNA gene sequences, six genetic variants were described based on partial cox1 sequencing, with evidence of chicks co-infected by two variants. Transmission of Babesia sp. YLG via the soft tick Ornithodoros maritimus is discussed.

The New Human Babesia sp. FR1 Is a European Member of the Babesia sp. MO1 Clade.

In Europe, Babesia divergens is responsible for most of the severe cases of human babesiosis. In the present study, we describe a case of babesiosis in a splenectomized patient in France and report a detailed molecular characterization of the etiological agent, named Babesia sp. FR1, as well as of closely related Babesia divergens, Babesia capreoli and Babesia sp. MO1-like parasites. The analysis of the conserved 18S rRNA gene was supplemented with the analysis of more discriminant markers involved in the red blood cell invasion process: rap-1a (rhoptry-associated-protein 1) and ama-1 (apical-membrane-antigen 1). The rap-1a and ama-1 phylogenetic analyses were congruent, placing Babesia sp. FR1, the new European etiological agent, in the American cluster of Babesia sp. MO1-like parasites. Based on two additional markers, our analysis confirms the clear separation of B. divergens and B. capreoli. Babesia sp. MO1-like parasites should also be considered as a separate species, with the rabbit as its natural host, differing from those of B. divergens (cattle) and B. capreoli (roe deer). The natural host of Babesia sp. FR1 remains to be discovered.

RAP-1a is the main rhoptry-associated-protein-1 (RAP-1) recognized during infection with Babesia sp. BQ1 (Lintan) (B. motasi-like phylogenetic group), a pathogen of sheep in China.

Babesia sp. BQ1 (Lintan) is one of the parasites isolated from infected sheep in China that belongs to the B. motasi-like phylogenetic group. The rhoptry-associated-protein 1 (rap-1) locus in this group consists of a complex organization of 12 genes of three main types: 6 rap-1a variants intercalated with 5 identical copies of rap-1b and a single 3' ending rap-1c gene. In the present study, transcription analysis performed by standard RT-PCR demonstrated that the three different rap-1 gene types and the four rap-1a variants were transcribed by the parasite cultivated in vitro. Peptides, specific for each rap-1 type gene, were selected in putative linear B-epitopes and used to raise polyclonal rabbit antisera. Using these sera, the same expression pattern of RAP-1 proteins was found in parasites cultivated in vitro or collected from acute infection whereas only RAP-1a67 was detectable in merozoite extracts. However, ELISA performed with recombinant RAP-1a67, RAP-1b or RAP-1c and sera from infected sheep demonstrated that RAP-1a67 is the main RAP-1 recognized during infection, even if some infected sheep also recognized RAP-1b and/or RAP-1c.

Stimulation and quantification of Babesia divergens gametocytogenesis.

BACKGROUND: Babesia divergens is the most common blood parasite in Europe causing babesiosis, a tick-borne malaria-like disease. Despite an increasing focus on B. divergens, especially regarding veterinary and human medicine, the sexual development of Babesia is poorly understood. Development of Babesia sexual stages in the host blood (gametocytes) plays a decisive role in parasite acquisition by the tick vector. However, the exact mechanism of gametocytogenesis is still unexplained. METHODS: Babesia divergens gametocytes are characterized by expression of bdccp1, bdccp2 and bdccp3 genes. Using previously described sequences of bdccp1, bdccp2 and bdccp3, we have established a quantitative real-time PCR (qRT-PCR) assay for detection and assessment of the efficiency of B. divergens gametocytes production in bovine blood. We analysed fluctuations in expression of bdccp genes during cultivation in vitro, as well as in cultures treated with different drugs and stimuli. RESULTS: We demonstrated that all B. divergens clonal lines tested, originally derived from naturally infected cows, exhibited sexual stages. Furthermore, sexual commitment was stimulated during continuous growth of the cultures, by addition of specific stress-inducing drugs or by alternating cultivation conditions. Expression of bdccp genes was greatly reduced or even lost after long-term cultivation, suggesting possible problems in the artificial infections of ticks in feeding assays in vitro. CONCLUSIONS: Our research provides insight into sexual development of B. divergens and may facilitate the development of transmission models in vitro, enabling a more detailed understanding of Babesia-tick interactions.

Rhoptry-associated protein (rap-1) genes in the sheep pathogen Babesia sp. Xinjiang: Multiple transcribed copies differing by 3' end repeated sequences.

Sheep babesiosis occurs mainly in tropical and subtropical areas. The sheep parasite Babesia sp. Xinjiang is widespread in China, and our goal is to characterize rap-1 (rhoptry-associated protein 1) gene diversity and expression as a first step of a long term goal aiming at developing a recombinant subunit vaccine. Seven different rap-1a genes were amplified in Babesia sp. Xinjiang, using degenerate primers designed from conserved motifs. Rap-1b and rap-1c gene types could not be identified. In all seven rap-1a genes, the 5' regions exhibited identical sequences over 936 nt, and the 3' regions differed at 28 positions over 147 nt, defining two types of genes designated α and ß. The remaining 3' part varied from 72 to 360 nt in length, depending on the gene. This region consists of a succession of two to ten 36 nt repeats, which explains the size differences. Even if the nucleotide sequences varied, 6 repeats encoded the same stretch of amino acids. Transcription of at least four α and two ß genes was demonstrated by standard RT-PCR.

Strong conservation of rhoptry-associated-protein-1 (RAP-1) locus organization and sequence among Babesia isolates infecting sheep from China (Babesia motasi-like phylogenetic group).

Rhoptry-associated-protein 1 (RAP-1) is considered as a potential vaccine candidate due to its involvement in red blood cell invasion by parasites in the genus Babesia. We examined its value as a vaccine candidate by studying RAP-1 conservation in isolates of Babesia sp. BQ1 Ningxian, Babesia sp. Tianzhu and Babesia sp. Hebei, responsible for ovine babesiosis in different regions of China. The rap-1 locus in these isolates has very similar features to those described for Babesia sp. BQ1 Lintan, another Chinese isolate also in the B. motasi-like phylogenetic group, namely the presence of three types of rap-1 genes (rap-1a, rap-1b and rap-1c), multiple conserved rap-1b copies (5) interspaced with more or less variable rap-1a copies (6), and the 3' localization of one rap-1c. The isolates Babesia sp. Tianzhu, Babesia sp. BQ1 Lintan and Ningxian were almost identical (average nucleotide identity of 99.9%) over a putative locus of about 31 Kb, including the intergenic regions. Babesia sp. Hebei showed a similar locus organization but differed in the rap-1 locus sequence, for each gene and intergenic region, with an average nucleotide identity of 78%. Our results are in agreement with 18S rDNA phylogenetic studies performed on these isolates. However, in extremely closely related isolates the rap-1 locus seems more conserved (99.9%) than the 18S rDNA (98.7%), whereas in still closely related isolates the identities are much lower (78%) compared with the 18S rDNA (97.7%). The particularities of the rap-1 locus in terms of evolution, phylogeny, diagnosis and vaccine development are discussed.

Sequence and organization of the rhoptry-associated-protein-1 (rap-1) locus for the sheep hemoprotozoan Babesia sp. BQ1 Lintan (B. motasi phylogenetic group).

Babesiosis is a frequent infection of animals worldwide by tick borne pathogen Babesia, and several species are responsible for ovine babesiosis. Recently, several Babesia motasi-like isolates were described in sheep in China. In this study, we sequenced the multigenic rap-1 gene locus of one of these isolates, Babesia sp. BQ1 Lintan. The RAP-1 proteins are involved in the process of red blood cells invasion and thus represent a potential target for vaccine development. A complex composition and organization of the rap-1 locus was discovered with: (1) the presence of 3 different types of rap-1 sequences (rap-1a, rap-1b and rap-1c); (2) the presence of multiple copies of rap-1a and rap-1b; (3) polymorphism among the rap-1a copies, with two classes (named rap-1a61 and rap-1a67) having a similarity of 95.7%, each class represented by two close variants; (4) polymorphism between rap-1a61-1 and rap-1a61-2 limited to three nucleotide positions; (5) a difference of eight nucleotides between rap-1a67-1 and rap-1a67-2 from position 1270 to the putative stop site of rap-1a67-1 which might produce two putative proteins of slightly different sizes; (6) the ratio of rap-1a copies corresponding to one rap-1a67, one rap-1a61-1 and one rap-1a61-2; (7) the presence of three different intergenic regions separating rap-1a, rap-1b and rap-1c; (8) interspacing of the rap-1a copies with rap-1b copies; and (9) the terminal position of rap-1c in the locus. A 31kb locus composed of 6 rap-1a sequences interspaced with 5 rap-1b sequences and with a terminal rap-1c copy was hypothesized. A strikingly similar sequence composition (rap-1a, rap-1b and rap-1c), as well as strong gene identities and similar locus organization with B. bigemina were found and highlight the conservation of synteny at this locus in this phylogenetic clade.

A novel chicken lung epithelial cell line: characterization and response to low pathogenicity avian influenza virus.

Avian influenza virus (AIV) infections of the chicken occur via the respiratory route. Unlike ducks which are considered as a natural AIV reservoir, chickens are highly susceptible to AIV infections and do not possess the RIG-I pattern recognition receptor involved in triggering the antiviral interferon response. To study the chicken innate immune response to AIV in the respiratory tract, we established an epithelial cell line (CLEC213) from lung explants of white leghorn chickens. CLEC213 cells exhibited a polyhedral morphology and formed cohesive clusters bound through tight junctions as assessed by electron microscopy. Expression of E-cadherin but not vimentin could be detected as expected for cells of epithelial origin. In addition, CLEC213 cells showed characteristics similar to those of mammalian type II pneumocytes, including the presence of intracytoplasmic vacuoles filled with a mucopolysaccharide material, alkaline phosphatase activity, transcription of chicken lung collectins genes (cLL and SPA), and some intracytoplasmic lamellar-like bodies. CLEC213 cells showed a constitutive expression level of TLR3 and TLR4 and were responsive to stimulation with the respective agonists, poly (I:C) and LPS: between 4h and 24h after treatment, a strong increase in the expression of IFN-α, IFN-ß and IL-8 genes could be detected. Furthermore, CLEC213 cells supported efficient growth of the low pathogenicity avian influenza virus H6N2 (A/duck/France/05057a/2005) in the presence or the absence of trypsin in the culture media. At 4h post-infection, the H6N2 virus induced highly elevated levels of expression of IFN-α and IL-8, moderately elevated levels of LITAF, TGF-ß4 and CCL5. However, an increase of IFN-ß gene expression could not be detected in response to AIV infection. In conclusion, like mammalian type II pneumocytes, CLEC213 are able to mount a robust cytokine and chemokine immune response to microbial patterns and viral infection. We hypothesize that they could derive from lung atrial granular cells. The involvement of such type of lung epithelial cells in the respiratory tract defence of the chicken can thus be further studied.

Cloning, expression and functional characterization of chicken CCR6 and its ligand CCL20.

Chemokines are key molecules that drive migration of lymphoid and myeloid cells toward organs in basal as well as inflammatory conditions. By recruiting immature dendritic cells to the mucosal surfaces, CCL20 acts in the very early events leading to the development of a specific immune response. In order to characterize dendritic cells in birds and better understand their role in the initiation of immune responses against pathogens of economic as well as human health relevance, we have cloned and expressed chicken CCL20 (chCCL20) and its specific receptor chCCR6. chCCL20 has 51% identity (60% similarity) with human CCL20, while the chicken receptor and its human counterpart display nearly 55% identity (and up to 70% similarity). chCCL20 and its specific receptor chCCR6 mRNAs are mainly expressed in bone marrow, secondary lymphoid organs and in the mucosal surfaces, in particular lungs and intestine. Both receptor and chemokine are functionally active when expressed as genuine or tagged proteins in mammalian expression systems, that is chCCR6 is mainly located at the cell surface within lipid rafts like its human counterpart. And secondly, both human and chicken chemokines were able to drive the migration of either chicken or human CCR6-transfected cells.

Differential modulation of beta-defensin gene expression by Salmonella Enteritidis in intestinal epithelial cells from resistant and susceptible chicken inbred lines.

beta-Defensins are important components of innate immunity in mucosal tissue, a major entry site for several pathogens. These small cationic peptides possess antimicrobial activity against various microorganisms including Salmonella. Two chicken inbred lines, 6 and 15I, diverge phenotypically with respect to levels of Salmonella Enteritidis intestinal carriage and to level of gene expression of two beta-defensins, AvBD1 and AvBD2. The cellular source of these two defensins in the intestinal tissue has not previously been explored. Therefore embryonic intestinal cells were isolated from both chicken lines. Primary intestinal cell cultures expressed epithelial specific markers (villin and E-cadherin) and differentially expressed two beta-defensin genes AvBD1 and AvBD2 according to chicken line. Furthermore, S. Enteritidis interfered with AvBD2 expression only in the cells from the susceptible line 15I. Our embryonic cell culture model demonstrated that intestinal epithelium express beta-defensin antimicrobial peptides that may play a role in immunoprotection against Salmonella Enteritidis.