Molecular occurrence and genetic diversity of Ehrlichia canis in naturally infected dogs from Thailand.

Canine monocytic ehrlichiosis is cause by Ehrlichia canis resulting in hematologic disorders and severe clinical signs. The aim of this study was to scrutinize the molecular detection and genetic diversity of E. canis based on the trp36 gene in dogs from Thailand's northern and central regions. A total of 120 dogs blood samples were amplified for trp36 gene of E. canis using the polymerase chain reaction (PCR). Forty-seven out of 120 dog blood samples (39.16%, 47/120) were positive for E. canis the trp36 DNA with 790 bp of PCR amplicon size. The factor significantly associated with E. canis infection is animal housing status (p < 0.05). Sequence and phylogenetic analysis showed that E. canis trp36 gene of Thailand isolates was clustered into 1st clade with similarity ranging from 95.65 to 100% together with the US genogroup. The 14 haplotypes of the trp36 gene shown in TCS network exhibited that haplotype #1-4 was found in Thailand. The entropy analysis of the trp36 gene illustrated 751 polymorphic sites and 271 entropy peaks of nucleic and amino acid sequences, respectively. Hence, these findings are crucial for better understanding the epidemiology of Ehrlichia infection and could be helpful for implementing control measures in Thailand.

Ehrlichia canis: Molecular characterization and genetic diversity based on the p28 and trp36 genes.

Ehrlichia canis is a common tick-borne intracellular pathogen causing canine monocytic ehrlichiosis (CME) in dogs worldwide. The aims of this study were to investigate the genetic diversity and antigenicity of E. canis based on the p28 and trp36 genes in dogs in Thailand. The E. canis p28 and trp36 genes were amplified by the polymerase chain reaction (PCR) and cloned for sequencing and bioinformatic analyses. 36% (44/120) of dog blood samples were positive for E. canis DNA consisting of p28 (31%, 14/44) and trp36 (69%, 30/44) genes with 792 and 882 bp of PCR products size, respectively. The E. canis TRP36 from all Thailand sequences exhibited encoded nine amino acids (TEDSVSAPA) with 11 copies of tandem repeats along the sequences. The phylogenetic trees of E. canis, using the p28 and trp36 genes, exhibited that the Thailand isolates fell into two clades and one clade with similarity ranging from 55.95 to 100% and 100%, respectively. The results of diversity analysis revealed 10 and 20 haplotypes of the p28 and trp 36 genes, respectively. The entropy analysis of the p28 and trp36 nucleic acid sequences showed 442 and 1321 high entropy peaks respectively, whereas those of the P28 and TRP36 amino acid sequences showed 477 and 388 high entropy peaks, respectively. For B-cell epitopes analysis, the conserved amino acid of P28 and TRP36 sequences has been also demonstrated. Therefore, the results could be utilized to improve the understanding of phylogenetic relationship, genetic diversity and antigenicity of E. canis Thailand isolates.

Molecular characterization and genetic diversity of Babesia bovis and Babesia bigemina of cattle in Thailand.

Babesia bovis and B. bigemina are the most common tick-borne parasites that cause bovine babesiosis which effects livestock production, leading to economic losses in tropical and subtropical areas of the world. The aims of this study were to determine the molecular detection, genetic diversity and antigenicity prediction of B. bovis based on spherical body protein 2 (sbp-2) gene and B. bigemina based on rhoptry-associated protein 1a (rap-1a) gene in cattle in Thailand. By PCR assay, the molecular detection of B. bovis and B. bigemina infection revealed levels of 2.58% (4/155) and 5.80% (9/155), respectively. The phylograms showed that B. bovis sbp-2 and B. bigemina rap-1a sequences displayed 5 and 3 clades with similarity ranging between 85.53 to 100% and 98.28 to 100%, respectively, when compared within Thailand strain. Diversity analysis of sbp-2 and rap-1a sequences showed 18 and 4 haplotypes, respectively. The entropy analysis illustrated 104 and 7 polymorphic sites of sbp-2 and rap-1a nucleic acid sequences, respectively, while those of sbp-2 and rap-1a amino acid sequences showed 46 and 4 high entropy peaks, respectively. Motifs analysis exhibited the distribution and conservation among sbp-2 and rap-1a sequences. The continuous and discontinuous B-cell epitopes have also been evaluated in this work. Therefore, our findings may be used to ameliorate the understanding inputs of molecular phylogeny, genetic diversity and antigenicity of B. bovis and B. bigemina Thailand stains.

Anaplasma marginale: Molecular discrimination, recombinant expression and characterization of major surface protein 2.

A. marginale's major surface protein 2 (MSP2) is an immunodominant protein that is encoded by a multigene family. Phylogenetic analysis revealed that the msp2 sequence Thailand strain was clustered in third clade, with similarity values between 90.4 and 100%. The haplotype diversity showed 10 haplotypes of the msp2 genes. The entropy analysis of the nucleic and amino sequences revealed 289 and 117 high entropy peaks, respectively. Interestingly, one predicted allele belonging to MHC-II represented the hypervariable region (HVR) of MSP2. A. marginale's recombinant MSP2 (rAmMSP2), which has a molecular weight of 42 kDa, was examined in SDS-PAGE. Antigenicity of rAmMSP2 (42 kDa) and AmMSP2 (36 kDa) showed the conserved epitopes. The distribution of AmMSP2 on infected erythrocytes' membrane and outside was demonstrated by immunofluorescence detection. Therefore, the rMSP2 could be utilized in the establishment of immunodiagnostic tools and vaccine approaches for the monitoring of anaplasmosis.

Molecular genetic diversity and bioinformatic analysis of Leucocytozoon sabrazesi based on the mitochondrial genes cytb, coxI and coxIII and co-infection of Plasmodium spp.

Leucocytozoon sabrazesi is an intracellular haemoprotozoan parasite responsible for leucocytozoonosis, which is transmitted by insect vectors and affects chickens in tropical and subtropical areas in many countries. It causes huge economic losses due to decreased meat and egg production. In the present study, we used nested PCR to determine the genetic diversity of L. sabrazesi based on the cytb, coxI, coxIII and concatenated genes in chickens in Thailand. In addition, we found co-infections between L. sabrazesi and Plasmodium spp. (P. gallinaceum or P. juxtanucleare) in chickens that were not identified by microscopic examination of blood smears. The phylogenetic analysis indicated that L. sabrazesi cytb and coxIII genes were conserved with similarity ranging from 99.9 to 100% and 98 to 100%, respectively whereas the coxI gene was diverse, with similarities ranging from 97 to 100%. These findings ascertained the nucleotide analysis of the cytb, coxI, coxIII and concatenated sequences in which 4, 8, 10 and 9 haplotypes were found, respectively. In addition, it was found that the large number of synonymous substitutions and conservative amino acid replacements in these mitochondrial genes occurred by non-synonymous substitution. The evolutionary analysis of the Ka/Ks ratio supported purifying selection and the negative values of both Fu's Fs and Tajima's D indicate selective sweep especially for the coxI gene. The entropy and Simplot analysis showed that the genetic variation in populations of Plasmodium spp. was higher than in Leucocytozoon. Hence, the nucleotide sequences of three mitochondrial genes could reflect the evolutionary analysis and geographic distribution of this protozoan population that switches hosts during its life cycle.

Title: Diversité génétique moléculaire et analyse bioinformatique de Leucocytozoon sabrazesi basée sur les gènes mitochondriaux cytb, coxI et coxIII et la co-infection avec Plasmodium spp. Abstract: Leucocytozoon sabrazesi est le parasite hémoprotozoaire intracellulaire responsable de la leucocytozoonose, qui est transmise par des insectes vecteurs et affecte les poulets dans les zones tropicales et subtropicales de nombreux pays. Il provoque d'énormes pertes économiques en raison de la diminution de la production de viande et d'œufs. Dans la présente étude, nous avons utilisé la PCR nichée pour déterminer la diversité génétique de L. sabrazesi sur la base des gènes cytb, coxI, coxIII et concaténés chez des poulets en Thaïlande. De plus, nous avons trouvé des co-infections entre L. sabrazesi et Plasmodium spp. (P. gallinaceum ou P. juxtanucleare) chez des poulets, qui n'ont pas été identifiées par l'examen microscopique de frottis sanguins. L'analyse phylogénétique a indiqué que les gènes cytb et coxIII de L. sabrazesi étaient conservés avec une similarité allant respectivement de 99,9 à 100 % et de 98 à 100 %, alors que le gène coxI était diversifié, avec des similarités allant de 97 à 100 %. Ces découvertes ont confirmé l'analyse des nucléotides des séquences cytb, coxI, coxIII et concaténées dans lesquelles 4, 8, 10 et 9 haplotypes ont été trouvés, respectivement. De plus, il a été constaté que le grand nombre de substitutions synonymes et de remplacements conservateurs d'acides aminés dans ces gènes mitochondriaux se produisaient par substitution non synonyme. L'analyse évolutive du rapport Ka/Ks a soutenu la sélection purificatrice et les valeurs négatives des Fs de Fu et D de Tajima indiquent un balayage sélectif, en particulier pour le gène coxI. L'entropie et l'analyse Simplot ont montré que la variation génétique de la population de Plasmodium spp. était plus élevée que pour Leucocytozoon. Par conséquent, les séquences nucléotidiques de trois gènes mitochondriaux pourraient refléter l'analyse évolutive et la répartition géographique de cette population de protozoaires qui changent d'hôte au cours de leur cycle de vie.