Sequencing of hsp70 for discernment of species from the Leishmania (Viannia) guyanensis complex from endemic areas in Colombia

Incriminating leishmaniases vectors in Colombia: An overview and roadmap for future research

A major challenge in defining the vector status of phlebotomine sand flies is selecting the appropriate criteria. Vectors can be graded by importance, with successful transmission as the highest grade. Potential vectors are often identified based on high frequency in transmission foci, anthropophily, and more recently by identification of DNA in field samples. However, a species' ability to transmit a pathogen depends not only on its intrinsic biology of sand fly-Leishmania interactions but also on ecological parameters, which are rarely evaluated. This study aimed to analyze the literature data describing characteristics of Colombian sand flies related to their role as vectors of Leishmaniinae parasites. Based on information contained in scientific publications using combinations of five criteria, sand fly species were graded into five levels, and 26 species were considered as potential or proven leishmaniasis vectors in Colombia. Levels one to four refer to potential or suspected status, while level five denotes proven vectors. Studying vectors in a regional context is crucial because species' behaviors vary with environmental and ecological conditions, meaning a species may be a key vector in one area but not in another. A better understanding of vector-parasite interactions will aid in developing innovative control strategies and formulating significant epidemiological perspectives.

Novel duplex TaqMan-based quantitative PCR for rapid and accurate diagnosis of Leishmania (Mundinia) martiniquensis and Leishmania (Mundinia) orientalis, responsible for autochthonous leishmaniasis in Thailand

The World Health Organization has recently declared Thailand a leishmaniasis hotspot in Southeast Asia due to the continuous increase in new symptomatic and asymptomatic cases over the years. This emerging parasitic disease is known to be caused by two autochthonous species of Leishmania belonging to the newly described subgenus Mundinia, namely L. martiniquensis and L. orientalis. In Thailand, clinical cases due to L. martiniquensis typically present with visceral leishmaniasis, whereas L. orientalis mainly causes localized cutaneous leishmaniasis. Although Leishmania species confirmation is essential for clinical diagnosis and treatment planning, the availability of highly accurate and rapid diagnostic methods remains limited. In this study, we developed a duplex TaqMan quantitative PCR assay using newly designed species-specific primers and probes based on sequences from the nucleotide and genome databases of Leishmania spp. retrieved from GenBank. The duplex qPCR assay was optimized to specifically amplify the internal transcribed spacer 1 (ITS1) of L. martiniquensis and the heat shock protein 70 (type I) intergenic region (HSP70-I IR) of L. orientalis with high amplification efficiencies. The performance of the optimized duplex qPCR was evaluated by analyzing 46 DNA samples obtained from cultures, and clinical and insect specimens, consistent with the results of the previously validated 18S rRNA-qPCR and ITS1-PCR. The duplex qPCR could detect both species of Leishmania at a limit of detection of one copy per reaction and did not cross-amplify with other pathogen DNA samples. Standard curves of the singleplex and duplex assays showed good linearity with excellent amplification efficiency. Using conventional ITS1-PCR and plasmid sequencing as a reference standard assay, the duplex qPCR showed diagnostic sensitivity and specificity of 100% and positive and negative predictive values of 100% for both Leishmania species with a perfect level of agreement (kappa = 1.0). The novel duplex TaqMan-based qPCR has shown to be a rapid, cost-effective, and highly accurate diagnostic tool for the simultaneous detection and identification of two autochthonous Leishmania spp. in a variety of clinical and entomological samples. This will greatly facilitate early diagnosis, treatment monitoring, and surveillance, especially in leishmaniasis-endemic areas where sequencing-based diagnosis is not routinely available.

Validation of Oxford nanopore sequencing for improved New World Leishmania species identification via analysis of 70-kDA heat shock protein

BACKGROUND

Leishmaniasis is a parasitic disease caused by obligate intracellular protozoa of the genus Leishmania. This infection is characterized by a wide range of clinical manifestations, with symptoms greatly dependent on the causal parasitic species. Here we present the design and application of a new 70-kDa heat shock protein gene (hsp70)-based marker of 771 bp (HSP70-Long). We evaluated its sensitivity, specificity and diagnostic performance employing an amplicon-based MinION™ DNA sequencing assay to identify different Leishmania species in clinical samples from humans and reservoirs with cutaneous leishmaniasis (CL) and visceral leishmaniasis (VL). We also conducted a comparative analysis between our novel marker and a previously published HSP70 marker known as HSP70-Short, which spans 330 bp.

METHODS

A dataset of 27 samples from Colombia, Venezuela and the USA was assembled, of which 26 samples were collected from humans, dogs and cats affected by CL and one sample was collected from a dog with VL in the USA (but originally from Greece). DNA was extracted from each sample and underwent conventional PCR amplification utilizing two distinct HSP70 markers: HSP70-Short and HSP70-Long. The subsequent products were then sequenced using the MinION™ sequencing platform.

RESULTS

The results highlight the distinct characteristics of the newly devised HSP70-Long primer, showcasing the notable specificity of this primer, although its sensitivity is lower than that of the HSP70-Short marker. Notably, both markers demonstrated strong discriminatory capabilities, not only in distinguishing between different species within the Leishmania genus but also in identifying instances of coinfection.

CONCLUSIONS

This study underscores the outstanding specificity and effectiveness of HSP70-based MinION™ sequencing, in successfully discriminating between diverse Leishmania species and identifying coinfection events within samples sourced from leishmaniasis cases.

Pathogens, reservoirs, and vectors involved in the transmission of vector-borne and zoonotic diseases in a Colombian region

The ecology of vector-borne diseases (VBDs) is an important system of great complexity, which involves the knowledge about the pathogens and animal species entailed in maintaining transmission cycles in a given locality, including those that act as vectors and reservoirs for the transmitted pathogens. To understand the ecology of some VBDs, we studied vectors, reservoirs, and pathogens of different VBDs, including dengue, leishmaniasis, Chagas disease, malaria, Zika, and chikungunya in the municipality of La Mesa, Cundinamarca, Colombia, a locality close to the capital, Bogotá. Vectors and mammals were sampled in urban and rural areas between May and August 2019. Molecular analyses were performed for the detection of pathogens in mammals and vectors, and of blood-meal sources in insects. Several vectors and mammals collected in this study have been involved in pathogen transmission cycles or may have a potential role in them. The findings of this study suggest that in the municipality of La Mesa, there are both vector and potential reservoir species, which are or could be implicated in the maintenance of the cycles of vector-borne diseases such as leishmaniasis and Chagas disease. Although arbovirus infections, such as dengue, are reported in the municipality, arbovirus presence was not detected. These findings highlight the importance of ongoing surveillance of vectors and associated control operations in La Mesa, of relevance to other locations where vectors and animal hosts also occur.