Leishmania sp. infection in dogs from Florianópolis, Santa Catarina, SC, Brazil

The aim of the present study was to investigate the occurrence of Leishmania sp. infection in dogs (N = 491) living in the municipality of Florianópolis, Santa Catarina (SC), Brazil, which was considered a disease-free region for visceral leishmaniasis until 2011, when autochthonous cases of canine disease were notified. Seroprevalence in this population was assessed by ELISA (0.4%; 2/491) and IFAT (4.09%; 24/491). Only one dog exhibited seroreactivity in both serological methods, comprising a total of 25 (5.3%) seroreagent animals. Leishmania sp. DNA, obtained from a sample of whole blood of this animal, was amplified by both conventional and Real-Time PCR. Sequencing of the amplified DNA and, thereby, determination of the Leishmania species involved, was not possible. Our results suggest the necessity of a thorough epidemiological investigation in Florianópolis. (AU).O objetivo do presente estudo foi pesquisar a ocorrência de infecção por Leishmania sp. em cães (N = 491) domiciliados no município de Florianópolis, Santa Catarina, considerada uma região indene para leishmaniose visceral até o ano de 2011, quando foram notificados casos autóctones da doença canina. A soroprevalência na população foi avaliada por ELISA (0,4%; 2/491) e RIFI (4,09%; 24/491). Somente um cão apresentou sororeatividade em ambos os métodos soro-lógicos, totalizando 25 (5,3%) animais sororeagentes. O DNA de Leishmania sp., obtido de uma amostra do sangue total desse animal, foi amplificado por PCR convencional e PCR em Tempo Real. Não foi possível realizar o sequenciamento do DNA amplificado e, deste modo, determinar a espécie de Leishmania envolvida. Os nossos resultados sugerem a necessidade de uma investigação epidemiológica minuciosa em Florianópolis. (AU)

Canine leishmaniasis: Genome-wide analysis and antibody response to Lutzomyia longipalpis saliva.

The anti-inflammatory properties of sand fly saliva favor the establishment of the Leishmania infantum infection. In contrast, an antibody response against Lutzomyia longipalpis saliva is often associated with a protective cell-mediated response against canine visceral leishmaniasis. Genetic studies may demonstrate to what extent the ability to secrete anti-saliva antibodies depends on genetic or environmental factors. However, the genetic basis of canine antibody response against sand fly saliva has not been assessed. The aim of this study was to identify chromosomal regions associated with the anti-Lu. longipalpis salivary IgG response in 189 dogs resident in endemic areas in order to provide information for prophylactic strategies. Dogs were classified into five groups based on serological and parasitological diagnosis and clinical evaluation. Anti-salivary gland homogenate (SGH) IgG levels were assessed by Enzyme-Linked Immunosorbent Assay (ELISA). Genomic DNA was isolated from blood samples and genotyped using a SNP chip with 173,662 single nucleotide polymorphism (SNP) markers. The following linear regression model was fitted: IgG level = mean + origin + sex + age + use of a repellent collar, and the residuals were assumed as pseudo-phenotypes for the association test between phenotypes and genotypes (GWA). A component of variance model that takes into account polygenic and sample structure effects (EMMAX) was employed for GWA. Phenotypic findings indicated that anti-SGH IgG levels remained higher in exposed and subclinically infected dogs than in severely diseased dogs even in regression model residuals. Five associated markers were identified on chromosomes 2, 20 and 31. The mapped genes included CD180 (RP105) and MITF related to the rapid activation of B lymphocytes and differentiation into antibody-secreting plasma cells. The findings pointed to chromosomal segments useful for functional confirmation studies and a search for adjuvant molecules of the anti-saliva response

Anti-<i>Lu</i>. <i>longipalpis</i> SGH IgG levels (ELISA Units) in the sera of dogs relative to the clinical response.

<p>IgG levels were measured by ELISA. I—uninfected dogs, II—exposed dogs, III—infected dogs, IV—diseased dogs and V—severely diseased dogs. Anti–SGH IgG levels decreased with the severity of canine leishmaniasis before (A) and after (B) adjustment in the linear regression model (residual). The phenotypic variation of anti-SGH IgG levels was maintained after adjustment.</p

Proportion of positive results in the parasitological and serological diagnosis and clinical and biochemical findings of each clinical group.

<p>Proportion of positive results in the parasitological and serological diagnosis and clinical and biochemical findings of each clinical group.</p

Position, frequency, and significance of significantly associated SNPs and positional candidate genes potentially associated with the phenotypes.

<p>Position, frequency, and significance of significantly associated SNPs and positional candidate genes potentially associated with the phenotypes.</p

Principal component analysis (PCA) showing the genetic relationship between the sampled breeds and the grouping of the first two main components (C1 and C2) in three homogeneous sets and three heterogeneous sets.

<p>Labrador Retriever (black), Italian Greyhound (goldenrod), Cocker Spaniel (pink), Rottweiler (blue), German Shepherd Dog (forest green), Belgian Shepherd Dog (red), White Swiss Shepherd Dog (orange), and Golden Retriever (yellow).</p

Canine leishmaniasis: Genome-wide analysis and antibody response to <i>Lutzomyia longipalpis</i> saliva

<div><p>The anti-inflammatory properties of sand fly saliva favor the establishment of the <i>Leishmania infantum</i> infection. In contrast, an antibody response against <i>Lutzomyia longipalpis</i> saliva is often associated with a protective cell-mediated response against canine visceral leishmaniasis. Genetic studies may demonstrate to what extent the ability to secrete anti-saliva antibodies depends on genetic or environmental factors. However, the genetic basis of canine antibody response against sand fly saliva has not been assessed. The aim of this study was to identify chromosomal regions associated with the anti-<i>Lu</i>. <i>longipalpis</i> salivary IgG response in 189 dogs resident in endemic areas in order to provide information for prophylactic strategies. Dogs were classified into five groups based on serological and parasitological diagnosis and clinical evaluation. Anti-salivary gland homogenate (SGH) IgG levels were assessed by Enzyme-Linked Immunosorbent Assay (ELISA). Genomic DNA was isolated from blood samples and genotyped using a SNP chip with 173,662 single nucleotide polymorphism (SNP) markers. The following linear regression model was fitted: IgG level = mean + origin + sex + age + use of a repellent collar, and the residuals were assumed as pseudo-phenotypes for the association test between phenotypes and genotypes (GWA). A component of variance model that takes into account polygenic and sample structure effects (EMMAX) was employed for GWA. Phenotypic findings indicated that anti-SGH IgG levels remained higher in exposed and subclinically infected dogs than in severely diseased dogs even in regression model residuals. Five associated markers were identified on chromosomes 2, 20 and 31. The mapped genes included <i>CD180</i> (<i>RP105</i>) and <i>MITF</i> related to the rapid activation of B lymphocytes and differentiation into antibody-secreting plasma cells. The findings pointed to chromosomal segments useful for functional confirmation studies and a search for adjuvant molecules of the anti-saliva response.</p></div

Canine leishmaniasis: Genome-wide analysis and antibody response to Lutzomyia longipalpis saliva

The anti-inflammatory properties of sand fly saliva favor the establishment of the Leishmania infantum infection. In contrast, an antibody response against Lutzomyia longipalpis saliva is often associated with a protective cell-mediated response against canine visceral leishmaniasis. Genetic studies may demonstrate to what extent the ability to secrete anti-saliva antibodies depends on genetic or environmental factors. However, the genetic basis of canine antibody response against sand fly saliva has not been assessed. The aim of this study was to identify chromosomal regions associated with the anti-Lu. longipalpis salivary IgG response in 189 dogs resident in endemic areas in order to provide information for prophylactic strategies. Dogs were classified into five groups based on serological and parasitological diagnosis and clinical evaluation. Anti-salivary gland homogenate (SGH) IgG levels were assessed by Enzyme-Linked Immunosorbent Assay (ELISA). Genomic DNA was isolated from blood samples and genotyped using a SNP chip with 173,662 single nucleotide polymorphism (SNP) markers. The following linear regression model was fitted: IgG level = mean + origin + sex + age + use of a repellent collar, and the residuals were assumed as pseudo-phenotypes for the association test between phenotypes and genotypes (GWA). A component of variance model that takes into account polygenic and sample structure effects (EMMAX) was employed for GWA. Phenotypic findings indicated that anti-SGH IgG levels remained higher in exposed and subclinically infected dogs than in severely diseased dogs even in regression model residuals. Five associated markers were identified on chromosomes 2, 20 and 31. The mapped genes included CD180 (RP105) and MITF related to the rapid activation of B lymphocytes and differentiation into antibody-secreting plasma cells. The findings pointed to chromosomal segments useful for functional confirmation studies and a search for adjuvant molecules of the anti-saliva response