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. 2023 Dec 18;151(2):213–219. doi: 10.1017/S0031182023001336

Typing of Leishmania isolates from vectors and leporids of the Madrid (Spain) outbreak

Anna Fernández-Arévalo 1,*,, Estela González 2,*,, Cristina Ballart 1,3, Inés Martín-Martín 2, Silvia Tebar 1, Carme Muñoz 4,5,6,, Maribel Jiménez 2,7,, Ricardo Molina 2,7,, Montserrat Gállego 1,3,7,
PMCID: PMC10941034  PMID: 38105582

graphic file with name S0031182023001336_figAb.jpg

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Keywords: Leishmania, outbreak, Spain, typing

Abstract

In 2009, a large outbreak of leishmaniasis, associated with environmental changes, was declared near Madrid (Spain), in which Phlebotomus perniciosus was the vector, whereas the main reservoirs were hares and rabbits. Analysis of isolates from humans, vectors and leporids from the focus identified the Leishmania infantum ITS-Lombardi genotype. However, multilocus enzyme electrophoresis (MLEE), the reference technique for Leishmania typing, and sequencing of the hsp70 gene, a commonly used marker, were not performed. In the present study, 19 isolates from P. perniciosus (n = 11), hares (n = 5) and rabbits (n = 3) from the outbreak area, all characterized as ITS-Lombardi in previous studies, were analysed by MLEE and hsp70 sequencing. The hsp70 results confirmed that all the analysed strains are L. infantum. However, by MLEE, 4 different zymodemes of L. infantum were identified based on variable mobilities of the NP1 enzyme: MON-34 (NP1100, n = 11), MON-80 (NP1130, n = 6), MON-24 (NP1140, n = 1) and MON-331 (NP1150, n = 1). The relative frequency of these zymodemes does not correspond to their usual occurrence in Spain. Moreover, MON-34 and MON-80 were found in P. perniciosus, hares and rabbits for the first time. These findings continue to provide insights into the outbreak and call for further studies with a higher number of strains.

Introduction

Leishmaniasis is a parasitological disease with worldwide distribution (World Health Organization, 2010). In the Mediterranean area, the disease is autochthonous, although imported cases are also found (Berriatua et al., 2021; Fernández-Arévalo et al., 2022; Van der Auwera et al., 2022). In Spain, the incidence reported for 2018 was 0.65 cases/100 000 habitants (Centro Nacional de Epidemiología, 2019), and in 2017 the estimated incidence rate was 0.86 for visceral leishmaniasis (VL), 1.04 for cutaneous leishmaniasis (CL) and 0.12 for mucocutaneous leishmaniasis, with an estimated underreporting of 14.7–20.2% for VL and 50.4–55.1% for CL (Humanes-Navarro et al., 2021). VL and CL are the main clinical manifestations in the country, but occasionally atypical CL or mucosal presentations are also diagnosed (Aliaga et al., 2003; Fernández Martínez et al., 2019). Although prevalence is higher in certain regions and seasons, the disease is present in most of Spain and cases are reported throughout the year (Fernández Martínez et al., 2019). The parasite responsible for autochthonous cases is Leishmania infantum, the principal domestic reservoir is the dog, and the main vectors are Phlebotomus perniciosus and Phlebotomus ariasi sand flies (Jiménez et al., 1995; Gállego et al., 2001; Martín-Sánchez et al., 2004; Berriatua et al., 2021). Phlebotomus langeroni has also been incriminated as a vector (Sáez et al., 2018) and different domestic and wild animals have been suspected or confirmed to be reservoirs (Azami-Conesa et al., 2021; Cardoso et al., 2021; Martín-Sánchez et al., 2021).

In 2009, the largest outbreak of leishmaniasis due to L. infantum ever detected in Europe was declared in Fuenlabrada, in the southwest Madrid region (Spain) (Arce et al., 2013). At its peak (2010–2014), more than 600 human cases were reported (Dirección General de Salud Pública – Consejería de Sanidad de la Comunidad de Madrid, 2015; Fernández Martínez et al., 2019) and asymptomatic carriers were also detected (Molina et al., 2020). The great majority of the patients were immunocompetent adults living in the area who presented cutaneous forms of the disease (Arce et al., 2013; Carrillo et al., 2013). However, children and immunocompromised individuals were also affected, and VL cases and rare clinical manifestations were observed, as well as a high susceptibility of the immigrant population born in Sub-Saharan Africa (Arce et al., 2013; Gomez-Barroso et al., 2015; Horrillo et al., 2015). Demographic and environmental changes, such as the construction of a vast green park connecting different urban zones, favoured the proliferation of P. perniciosus, hares (Lepus granatensis) and rabbits (Oryctolagus cuniculus), which were incriminated as reservoirs, and led to the outbreak (Molina et al., 2012; Carrillo et al., 2013; Jiménez et al., 2014; González et al., 2021).

Over the years, the leishmaniasis cases, reservoirs, vectors and parasites associated with the outbreak have been extensively investigated. However, few studies have characterized the parasites beyond species level. Two studies used the internal transcriber spacer (ITS) to type 3 and 4 strains isolated from hares and rabbits, respectively (Molina et al., 2012; Jiménez et al., 2014). All strains shared the ITS sequence of the strain MHOM/ES/87/Lombardi (AJ000295), this strain corresponding to zymodeme MON-24 of L. infantum (Chicharro et al., 2013). Similar results were obtained for 6 DNA samples and 67 isolates from sand flies when ITS2 was tested (Jiménez et al., 2013; González et al., 2017). In another study, 31 human isolates related to the outbreak were characterized by ITS and haspb (k26) markers (Chicharro et al., 2013). All strains were identified as ITS-Lombardi, but when combined with the haspb (k26) results, 4 different genotypes were detected, L-920 being the most prevalent. Given this background, the aim of the present study was to dig deeper into the characterization of non-human strains from the leishmaniasis outbreak using multilocus enzyme electrophoresis (MLEE), the technique most extensively used in epidemiological studies of leishmaniasis foci and the gold standard recommended by the WHO for this purpose (World Health Organization, 2010). Additionally, strains were also analysed by PCR-sequencing of the heat shock protein 70 (hsp70), one of the main markers used for Leishmania characterization (Fernández-Arévalo et al., 2022; Van der Auwera et al., 2022).

Materials and methods

Strains

Nineteen strains previously isolated from sand flies and leporids captured at different locations during the leishmaniasis outbreak area of Fuenlabrada (Spain) between 2011 and 2014 were selected for analysis. Eleven of them were isolated from 11 field-captured P. perniciosus in 2012 (n = 4), 2013 (n = 4) and 2014 (n = 3). The sand flies specimens had been captured in 4 collecting stations placed in institutional facilities: 3 located in the municipality of Fuenlabrada, in the border zone of the green park, (ATE-station n = 3, BOS-station n = 3, JIC-station n = 3) and 1 in the central area of the park in the municipality of Leganés (POL-station n = 2) (González et al., 2017). The other 8 strains were isolated from colony specimens of P. perniciosus used in direct xenodiagnosis of hares and rabbits. Five of them were isolated from 3 hares living in the park captured in 2011/12 and 3 were obtained from 3 rabbits captured in the border zone in 2013 (Molina et al., 2012; Jiménez et al., 2014). All the isolates had been previously characterized by ITS sequencing as the Lombardi type (Molina et al., 2012; Jiménez et al., 2013, 2014; González et al., 2017).

The strains were thawed and cultured in Schneider's insect medium supplemented with 20% fetal bovine serum and 1% sterile human urine until the exponential growth phase (Fernández-Arévalo et al., 2022).

Hsp70 gene sequencing

DNA from the cultured strains was obtained by the QIAmp DNA Mini Kit (Qiagen) following the manufacturer's instructions. Amplification was done using previously described primers and cycling conditions (Van der Auwera et al., 2013; Fernández-Arévalo et al., 2022). PCR products were enzymatically purified using EXOSAP-IT (Affymetrix USB) and double-strand sequenced by the Sanger method at the Scientific and Technologic Centres of the University of Barcelona. The obtained sequences were edited using MEGA X software (Kumar et al., 2018).

MLEE

Protein extracts were obtained from mass cultures as previously described (Piarroux et al., 1994). The strains were analysed by MLEE using a panel of 15 enzymes [malate dehydrogenase (MDH) E.C 1.1.1.37, malic enzyme (ME) EC 1.1.1.40, isocitrate dehydrogenase (ICD) EC 1.1.1.42, phosphogluconate dehydrogenase (PGD) EC 1.1.1.44, glucose-6-phosphate dehydrogenase (G6PD) EC 1.1.1.49, glutamate dehydrogenase (GLUD) EC 1.4.1.3, NADH diaphorase (DIA) EC 1.6.2.2, nucleoside phosphorylase purine (NP) − 1 and 2 − EC 2.4.2.1, glutamate oxaloacetate transaminase (GOT) − 1 and 2 − EC 2.6.1.1, phosphoglucomutase (PGM) EC 2.7.5.1, fumarate hydratase (FH) 4.2.1.2, mannose phosphate isomerase (MPI) EC 5.3.1.8 and glucose phosphate isomerase (GPI) EC 5.3.1.9] (Rioux et al., 1990). The samples were run on starch gel and revealed under suitable conditions for each enzyme. Migration distances were manually measured and compared with those of the marker strains (Supplementary Table S1) to assign the corresponding electromorphs and zymodemes. Once all enzyme mobilities were determined, the strains were tested again with a second batch of protein extract to confirm the results. The isoelectric focusing technique was also used to confirm the NP1 mobility (Piarroux et al., 1994).

Results

Analysis of the hsp70 gene showed that all the analysed strains shared the same genotype, presenting the main sequence reported for L. infantum strains (GenBank accession numbers OQ747159–OQ747177). Neither SNPs nor heterozygous positions were detected.

The strains produced different MLEE patterns. All of them shared an electrophoretic mobility (EM) of 104 for the MDH enzyme (MDH104) and an EM of 100 for the other enzymes except NP1 (EM: 100, 130, 140, 150). Thus, NP1 was the only enzyme associated with enzymatic polymorphisms in Leishmania strains from the outbreak. NP1100 was observed in 11 out of the 19 strains, which were therefore identified as L. infantum zymodeme MON-34. Six strains shared NP1130 (MON-80), whereas NP1140 was observed in 1 strain (MON-24), and NP1150 in the remaining strain (MON-331; also known as GR-19 and MON-24 var NP1150) (Table 1).

Table 1.

Results of MLEE Leishmania infantum characterization related to host, location and year of isolation

Zymodeme Original host Locationa Year WHO code
MON-24 (n = 1) Phlebotomus perniciosus JIC station 2013 IPER/ES/2013/LEMSJIC1FF4
MON-34 (n = 11) Phlebotomus perniciosus ATE station 2012 IPER/ES/2012/LEMATE1FL2
2013 IPER/ES/2013/LEMATE1FL6
2014 IPER/ES/2014/LEMATE1FL8
BOS station 2012 IPER/ES/2012/LEMBOS1FL1
JIC station 2012 IPER/ES/2012/LEMSJIC1FF1
POL station 2013 IPER/ES/2013/LEMPOL2FL21
Oryctolagus cuniculus Border zone 2013 IPER/ES/2013/LEMC6
Lepus granatensis Park 2012 IPER/ES/2012/LEML34BX
IPER/ES/2012/LEML34DX
IPER/ES/2012/LEML40AX
IPER/ES/2012/LEML40BX
MON-80 (n = 6) Phlebotomus perniciosus BOS station 2013 IPER/ES/2013/LEMBOS1FL10
2014 IPER/ES/2014/LEMBOS1FL32
JIC station 2014 IPER/ES/2014/LEMSJIC1FF19
POL station 2012 IPER/ES/2012/LEMPOL2FL7
Oryctolagus cuniculus Border zone 2013 IPER/ES/2013/LEMC17
Lepus granatensis Park 2011 IPER/ES/2011/LEML1D18
MON-331 (n = 1) Oryctolagus cuniculus Border zone 2013 IPER/ES/2013/LEMC3
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a

‘JIC’, ‘BOS’ and ‘ATE’ are the codes used to identify the collecting stations placed in the border zone of the park in the municipality of Fuenlabrada, and ‘POL’ the code the collecting station placed in the centre of the park in the municipality of Leganés.

No correlations were apparent between the zymodeme and host, year or location (Table 1, Fig. 1). The only MON-24 strain was isolated from a P. perniciosus specimen in 2013. MON-34 and MON-80 zymodemes were found in rabbits, hares and sand flies from all collecting stations and in all years. Finally, the zymodeme MON-331 was detected in 1 rabbit. If the strains are grouped according to the collecting station and animal reservoir of origin, ‘JIC-station’, ‘POL-station’ and ‘rabbits’ present the most diversity, as each strain in these groups belonged to a different zymodeme. In contrast, all ‘ATE-station’ strains were MON-34 (Fig. 1).

Figure 1.

Figure 1.

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Distribution of Leishmania infantum zymodemes and hosts analysed in the leishmaniasis outbreak from Madrid region (Spain). Each circle represents 1 strain coloured according to its zymodeme. POL (placed in the municipality of Leganés), JIC, BOS and ATE (in the municipality of Fuenlabrada) are sand flies collecting stations where L. infantum strains were isolated from P. perniciosus. Rabbits were captured all around the perimeter of the Bosquesur park (marked with a dotted line) while hares were captured inside the park. The map image was taken from Google Earth (https://earth.google.com).

Discussion

In an unexpected outbreak in an endemic area, identification of the aetiological agent gains importance. Human leishmaniasis can be caused by about 20 of the 56 Leishmania species described (Akhoundi et al., 2016) and in the current context of globalization and climate change, the presence of imported species cannot be ruled out. In the leishmaniasis outbreak in Fuenlabrada, although part of the immigrant population was highly affected (Arce et al., 2013; Gomez-Barroso et al., 2015), the causative species was promptly identified as the autochthonous L. infantum (Chicharro et al., 2013).

When performing characterization studies within the L. donovani complex, and specifically for L. infantum strains, one of the major obstacles is the low intraspecific diversity (Maurício, 2018; Fernández-Arévalo et al., 2020). Different techniques have been used for the intraspecific analysis of L. infantum, including MLEE, multilocus microsatellite typing, multilocus sequence typing (MLST), randomly amplified polymorphic DNA, PCR-RFLP, and PCR-sequencing (Toledo et al., 2002; Ferroglio et al., 2006; Montoya et al., 2007; Aït-Oudhia et al., 2011; Van der Auwera and Dujardin, 2015). Depending on the technique and genetic markers used, a different resolution of genetic diversity is achieved. For instance, microsatellite typing provides extremely variable results, whereas single gene PCR-sequencing or PCR-RFLP techniques often show limited diversity (Van der Auwera and Dujardin, 2015). Accordingly, the 19 studied strains from the outbreak were genetically identical by both hsp70 and ITS sequencing. The hsp70 marker is very reliable for Leishmania species identification, but its resolution is too low to perform intraspecies characterization within the Leishmania donovani complex (Fernández-Arévalo et al., 2020). The ITS region can differentiate strains below the species level, and it has been correlated with the geographical origin. Evidence for this is the distinction of the Lombardi genotype from the ITS-A genotype, which is also common in the area. However, in L. infantum or L. donovani complex strains, ITS shows a lower degree of polymorphism than in other complexes, not being sufficiently resolving for outbreak studies (Kuhls et al., 2005; Fernández-Arévalo et al., 2022). Sequencing results can be improved in terms of resolution and robustness by a MLST approach (Kuhls and Mauricio, 2019). However, the lack of such studies in the area, together with the absence of a consensus scheme providing sufficient resolution for L. infantum sensu stricto strains from the same geographical origin, hinders, in this case, an integrative understanding of the results. As a side note, it may be interesting to mention that a recent study based on complete maxicircle coding regions, which could be considered kind of MLST, detected 2 distinct L. infantum populations among humans in the Madrid region, in almost perfect agreement with ITS typing (Solana et al., 2022).

MLEE offers an intermediate and manageable level of discrimination for these species (Fernández-Arévalo et al., 2022) and it has been extensively used in epidemiological studies to assess the geographical distribution of isolates and clinical presentations, and to elucidate vectors, and reservoirs (Pratlong et al., 2004; Montoya et al., 2007; Aït-Oudhia et al., 2011; Haouas et al., 2012). However, nowadays, this methodology is falling out of use. The requirement of mass culture of the strains and its manual and laborious protocol make it a costly and time-consuming technique, limiting its use to specific situations. MLEE is not the most suitable technique for inferring taxonomy, as it relies on phenotypic traits that may not be consistent with genetics. But, when applied for L. infantum intraspecific typing, MLEE can provide valuable information on reservoirs and vectors, allowing comparison between foci, and providing data to fill epidemiological gaps. Here lies the interest in using MLEE to characterize the strains isolated from the vectors and reservoirs implicated in the leishmaniasis outbreak in Madrid.

The use of MLEE to type L. infantum has shown that strains zymodemes in humans may belong to viscerotropic, dermotropic or both (Pratlong et al., 2004). In the canine reservoir, zymodeme MON-1 is predominant and few others have been isolated, giving rise to the suspicion of anthroponotic transmission cycles in some foci (Aït-Oudhia et al., 2011). MON-1 is also the main zymodeme identified in isolates from other reservoir hosts, such as cats, foxes, rats, horses and even rabbits (Gállego et al., 2001; Martín-Sánchez et al., 2004; Campino et al., 2006; Díaz-Sáez et al., 2014). In contrast, greater variation has been observed in strains isolated from sand flies (Gállego et al., 2001; Martín-Sánchez et al., 2004). In the strains included in the present study, MLEE analysis revealed 4 different zymodemes (MON-24, MON-34, MON-80 and MON-331), which vary from each other by a single enzyme (NP1). Except for MON-331, these zymodemes are commonly found in the Madrid region, as well as in the rest of Spain and the Mediterranean basin (Jiménez et al., 1995; Chicharro et al., 2003, 2013; Pratlong et al., 2013). Nevertheless, the frequency of the zymodemes detected here differs from what is usually found in Spain. None of the strains analysed belonged to MON-1, the predominant L. infantum zymodeme, which may be found in ITS-Lombardi strains. Moreover, only a single strain was identified as MON-24, the second most frequent human L. infantum zymodeme including in the area of the outbreak (Jiménez et al., 1995; Chicharro et al., 2003, 2013), where it was isolated from a P. perniciosus. Other studies carried out in the Mediterranean basin have identified MON-24 in strains from cases of human VL and CL and canine leishmaniasis, as well as from sand flies (Gállego et al., 2001; Martín-Sánchez et al., 2004; Campino et al., 2006; Haouas et al., 2012). Surprisingly, the most prevalent zymodeme in our study was MON-34 (11/19 strains), followed by MON-80 (6/19 strains), both detected in hares, rabbits and sand flies captured at all the collection points. According to the literature, zymodeme MON-34 has been isolated in human CL and VL cases and in animals (dogs and racoons), but it has not been reported in sand flies until now (Jiménez et al., 1995; Harrat et al., 1996; Gállego et al., 2001; Martín-Sánchez et al., 2004; Montoya et al., 2007; Pratlong et al., 2013; Fernández-Arévalo et al., 2022). MON-80 is less frequent in Spain, and it has been isolated mainly in humans with VL and CL throughout its distribution range (Gállego et al., 2001; Chicharro et al., 2003; Martín-Sánchez et al., 2004; Campino et al., 2006; Pratlong et al., 2013). To the best of our knowledge, only 1 study in North Africa has reported MON-80 in dogs (Benikhlef et al., 2009), and no previous reports describe it in sand flies, although it has been demonstrated experimentally that P. perniciosus could be a potential vector in the outbreak area (Remadi et al., 2018). Therefore, this is the first time that MON-34 and MON-80 strains have been isolated from P. perniciosus and leporids.

Regarding the zymodeme MON-331, found here in a rabbit, only 1 strain has been described before (GR-19, MON-24 var NP1150), in an HIV-positive human with VL (Martín-Sánchez et al., 2004). Although rare, NP1150 has been detected in other zymodemes of the L. donovani complex in isolates from Kenia, Sudan and China (Pratlong et al., 2013).

Unfortunately, no human isolates from this outbreak have been typed by MLEE. Only 1 study has characterized human strains from the Fuenlabrada outbreak (Chicharro et al., 2013), using ITS and haspb (k26) as molecular markers, also identifying 4 strain types (by haspb (k26)) that shared the ITS-Lombardi sequence. There is no apparent correlation between the isoenzymes and ITS sequences. Besides MON-34, MON-80 and MON-331, reported here, ITS-Lombardi has been described in MON-1, MON-24 and MON-27 strains (Chicharro et al., 2013; Fernández-Arévalo et al., 2022), whereas ITS sequence types other than Lombardi have been observed in MON-1, MON-24 and MON-34 strains (Kuhls et al., 2005; Chicharro et al., 2013; Fernández-Arévalo et al., 2022). As far as we know, there is no correlation between haspb (k26) and MLEE either. Based on the available data, it seems that human, reservoir and vector strains from the Fuenlabrada outbreak are similar, but it is not possible to ascertain any relationship between them.

According to MLEE background records, it is likely that the human strains from the outbreak could correspond to MON-34, MON-80 and MON-24. Regarding clinical manifestations, all these zymodemes have been detected in immunocompetent and immunocompromised individuals with VL and CL (Jiménez et al., 1995; Gállego et al., 2001; Chicharro et al., 2003; Martín-Sánchez et al., 2004; Pratlong et al., 2013), cases of which were also reported in the outbreak (Arce et al., 2013; Carrillo et al., 2013; Horrillo et al., 2015). However, despite providing data of unquestionable interest, it is unlikely that MLEE would be performed in human samples due to the performance drawbacks mentioned above.

When gathering all the available information about L. infantum in the Fuenlabrada outbreak, various questions arise. On one hand, the typing results reflect a certain homogeneity among the strains involved, although they belong to different zymodemes, and the strain types found are not new or exclusive to the area, which casts doubt on the emergence and transmission of a specific strain type as the detonator of the outbreak. On the other hand, the strains isolated from P. perniciosus in the area have shown higher virulence in the transmission of L. infantum to hamsters in ex vivo tests with experimentally infected P. perniciosus and in in vivo studies with the hamster and mouse model (Domínguez-Bernal et al., 2014; Martín-Martín et al., 2015; Mas et al., 2021). However, the strains do not seem to cause disease in leporids (Molina et al., 2012; Jiménez et al., 2014), nor were they found in local dogs, and some exhibit less virulent behaviour in canine cells (Mas et al., 2020). It remains uncertain if there was a selection of these strain types in the leporid reservoir or if they were simply the strain types present in the area at the onset of the outbreak, which arose from the interaction between large populations of vectors, reservoirs and humans. Furthermore, it is unknown if these strains are circulating among leporids in other endemic regions.

The lack of comparable characterization studies hampers a global understanding of the situation. To fully determine the epidemiological characteristics of the Fuenlabrada outbreak and the circulating strains in the region, more comprehensive studies with a higher number of isolates from humans, vectors and reservoirs from a range of L. infantum endemic regions are needed, as well as more robust and discriminative techniques.

Supporting information

Fernández-Arévalo et al. supplementary material

Fernández-Arévalo et al. supplementary material

Acknowledgements

The authors wish to thank Dr Francine Pratlong and Patrick Lami for their help with queries and for assigning a MON-code to the zymodeme with NP1150. The participating UB and ISGlobal investigators are part of the GREPIMER group (Grup de Recerca en Patología Importada i Malaties Emergents i Re-emergents) recognized by the Agència de Gestió d'Ajuts Universitaris i de Recerca (AGAUR, 2017 SGR 924 and 2021 SGR 01562). ISGlobal research was supported by the Tropical Disease Cooperative Research Network (RICET) (RD12/0018/0010) and by CIBER -Consorcio Centro de Investigación Biomédica en Red- (CB 2021), Instituto de Salud Carlos III, Ministerio de Ciencia e Innovación and Unión Europea – NextGenerationEU. We acknowledge support from the grant CEX2018-000806-S funded by MCIN/AEI/ 10.13039/501100011033, and support from the Generalitat de Catalunya through the CERCA Program.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0031182023001336

Data availability statement

Sequences are available in GenBank under accession numbers OQ747159-OQ747177.

Author's contributions

Conceptualization: Anna Fernández-Arévalo, Estela González, Montserrat Gállego, Maribel Jiménez and Ricardo Molina. Investigation: Anna Fernández-Arévalo, Estela González, Cristina Ballart, Inés Martín-Martín, Silvia Tebar and Montserrat Gállego. Formal analysis and interpretation: Anna Fernández-Arévalo, Estela González, Montserrat Gállego, Carme Muñoz, Maribel Jiménez and Ricardo Molina. Writing – original draft preparation: Anna Fernández-Arévalo, Estela González, Montserrat Gállego, Carme Muñoz, Maribel Jiménez and Ricardo Molina; Writing – review and editing: all authors. Final approval: all authors.

Financial support

This research received no specific grant from any funding agency, commercial or not-for-profit sectors.

Competing interests

None.

Ethical standards

Not applicable.

References

  1. Aït-Oudhia K, Harrat Z, Benikhlef R, Dedet JP and Pratlong F (2011) Canine Leishmania infantum enzymatic polymorphism: a review including 1023 strains of the Mediterranean area, with special reference to Algeria. Acta Tropica 118, 80–86. [DOI] [PubMed] [Google Scholar]
  2. Akhoundi M, Kuhls K, Cannet A, Votýpka J, Marty P, Delaunay P and Sereno D (2016) A historical overview of the classification, evolution, and dispersion of Leishmania parasites and sandflies. PLOS Neglected Tropical Diseases 10, e0004349. [DOI] [PMC free article] [PubMed] [Google Scholar]
  3. Aliaga L, Cobo F, Mediavilla JD, Bravo J, Osuna A, Amador JM, Martín-Sánchez J, Cordero E and Navarro JM (2003) Localized mucosal leishmaniasis due to Leishmania (Leishmania) infantum clinical and microbiologic findings in 31 patients. Medicine 82, 147–158. [DOI] [PubMed] [Google Scholar]
  4. Arce A, Estirado A, Ordobas M, Sevilla S, García N, Moratilla L, de la Fuente S, Martínez A, Pérez A, Aránguez E, Iriso A, Sevillano O, Bernal J and Vilas F (2013) Re-emergence of leishmaniasis in Spain: community outbreak in Madrid, Spain, 2009 to 2012. Eurosurveillance 18, 20546. [DOI] [PubMed] [Google Scholar]
  5. Azami-Conesa I, Gómez-Muñoz MT and Martínez-Díaz RA (2021) A systematic review (1990–2021) of wild animals infected with zoonotic leishmania. Microorganisms 9, 1101. [DOI] [PMC free article] [PubMed] [Google Scholar]
  6. Benikhlef R, Aoun K, Bedoui K, Harrat Z and Bouratbine A (2009) First identifications of Leishmania infantum MON-80 in the dog in Algeria and Tunisia. Revue de Médicine Vétérinaire 160, 464–466. [Google Scholar]
  7. Berriatua E, Maia C, Conceição C, Özbel Y, Töz S, Baneth G, Pérez-Cutillas P, Ortuño M, Muñoz C, Jumakanova Z, Pereira A, Rocha R, Monge-Maillo B, Gasimov E, van der Stede Y, Torres G and Gossner CM (2021) Leishmaniases in the European Union and neighboring countries. Emerging Infectious Diseases 27, 1723–1727. [DOI] [PMC free article] [PubMed] [Google Scholar]
  8. Campino L, Pratlong F, Abranches P, Rioux J-A, Santos-Gomes G, Alves-Pires C, Cortes S, Ramada J, Cristovão JM, Afonso MO and Dedet JP (2006) Leishmaniasis in Portugal: enzyme polymorphism of Leishmania infantum based on the identification of 213 strains. Tropical Medicine and International Health 11, 1708–1714. [DOI] [PubMed] [Google Scholar]
  9. Cardoso L, Schallig H, Persichetti MF and Pennisi MG (2021) New epidemiological aspects of animal leishmaniosis in Europe: the role of vertebrate hosts other than dogs. Pathogens (Basel, Switzerland) 10, 307. [DOI] [PMC free article] [PubMed] [Google Scholar]
  10. Carrillo E, Moreno J and Cruz I (2013) What is responsible for a large and unusual outbreak of leishmaniasis in Madrid? Trends in Parasitology 29, 579–580. [DOI] [PubMed] [Google Scholar]
  11. Centro Nacional de Epidemiología (2019) Enfermedades de declaración obligatoria. Casos notificados por comunidades autónomas y tasas por 100.000 habitantes. España 2018. Datos definitivos (06/05/2019). Instituto de Salud Carlos III. https://www.isciii.es/QueHacemos/Servicios/VigilanciaSaludPublicaRENAVE/EnfermedadesTransmisibles/Documents/INFORMES/INFORMES RENAVE/RENAVE_cierre_EDO_2018.pdf
  12. Chicharro C, Jiménez MI and Alvar J (2003) Iso-enzymatic variability of Leishmania infantum in Spain. Annals of Tropical Medicine and Parasitology 97, S57–S64. [DOI] [PubMed] [Google Scholar]
  13. Chicharro C, Llanes-Acevedo P, García E, Nieto J, Moreno J and Cruz I (2013) Molecular typing of Leishmania infantum isolates from a leishmaniasis outbreak in Madrid, Spain, 2009 to 2012. Eurosurveillance 18, 20545. [DOI] [PubMed] [Google Scholar]
  14. Díaz-Sáez V, Merino-Espinosa G, Morales-Yuste M, Corpas-López V, Pratlong F, Morillas-Márquez F and Martín-Sánchez J (2014) High rates of Leishmania infantum and Trypanosoma nabiasi infection in wild rabbits (Oryctolagus cuniculus) in sympatric and syntrophic conditions in an endemic canine leishmaniasis area: epidemiological consequences. Veterinary Parasitology 202, 119–127. [DOI] [PubMed] [Google Scholar]
  15. Dirección General de Salud Pública – Consejería de Sanidad de la Comunidad de Madrid (2015) Leishmaniasis en la Comunidad de Madrid. Documentos Técnicos de Salud Pública 63. http://www.madrid.org/bvirtual/BVCM017837.pdf
  16. Domínguez-Bernal G, Jiménez M, Molina R, Ordóñez-Gutiérrez L, Martínez-Rodrigo A, Mas A, Cutuli MT and Carrión J (2014) Characterisation of the ex vivo virulence of Leishmania infantum isolates from Phlebotomus perniciosus from an outbreak of human leishmaniosis in Madrid, Spain. Parasites and Vectors 7, 499. [DOI] [PMC free article] [PubMed] [Google Scholar]
  17. Fernández-Arévalo A, El Baidouri F, Ravel C, Ballart C, Abras A, Lachaud L, Tebar S, Lami P, Pratlong F, Gállego M and Muñoz C (2020) The Leishmania donovani species complex: a new insight into taxonomy. International Journal for Parasitology 50, 1079–1088. [DOI] [PubMed] [Google Scholar]
  18. Fernández-Arévalo A, Ballart C, Muñoz-Basagoiti J, Basarte L, Lobato G, Arnau A, Abras A, Tebar S, Llovet T, Lami P, Pratlong F, Alsina M, Roe E, Puig L, Muñoz C and Gállego M (2022) Autochthonous and imported tegumentary leishmaniasis in Catalonia (Spain): aetiological evolution in the last four decades and usefulness of different typing approaches based on biochemical, molecular and proteomic markers. Transboundary and Emerging Diseases 69, 1404–1418. [DOI] [PubMed] [Google Scholar]
  19. Fernández Martínez B, Gómez Barroso D and Cano Portero R (2019) La leishmaniasis en España: evolución de los casos notificados a la Red Nacional de Vigilancia Epidemiológica desde 2005 a 2017 y resultados de la vigilancia de 2014 a 2017. Boletin Epidemiológco Semanal 27, 15–27. [Google Scholar]
  20. Ferroglio E, Romano A, Trisciuoglio A, Poggi M, Ghiggi E, Sacchi P and Biglino A (2006) Characterization of Leishmania infantum strains in blood samples from infected dogs and humans by PCR-RFLP. Transactions of the Royal Society of Tropical Medicine and Hygiene 100, 636–641. [DOI] [PubMed] [Google Scholar]
  21. Gállego M, Pratlong F, Fisa R, Riera C, Rioux JA, Dedet JP and Portús M (2001) The life-cycle of Leishmania infantum MON-77 in the Priorat (Catalonia, Spain) involves humans, dogs and sandflies; also literature review of distribution and hosts of L. infantum zymodemes in the Old World. Transactions of the Royal Society of Tropical Medicine and Hygiene 95, 269–271. [DOI] [PubMed] [Google Scholar]
  22. Gomez-Barroso D, Herrador Z, San Martín JV, Gherasim A, Aguado M, Romero-Maté A, Molina L, Aparicio P and Benito A (2015) Spatial distribution and cluster analysis of a leishmaniasis outbreak in the south-western Madrid region, Spain, September 2009 to April 2013. Eurosurveillance 20, 1–10. [DOI] [PubMed] [Google Scholar]
  23. González E, Jiménez M, Hernández S, Martín-Martín I and Molina R (2017) Phlebotomine sand fly survey in the focus of leishmaniasis in Madrid, Spain (2012–2014): seasonal dynamics, Leishmania infantum infection rates and blood meal preferences. Parasites and Vectors 10, 368. [DOI] [PMC free article] [PubMed] [Google Scholar]
  24. González E, Molina R, Iriso A, Ruiz S, Aldea I, Tello A, Fernández D and Jiménez M (2021) Opportunistic feeding behaviour and Leishmania infantum detection in Phlebotomus perniciosus females collected in the human leishmaniasis focus of Madrid, Spain (2012–2018). PLoS Neglected Tropical Diseases 15, 1–12. [DOI] [PMC free article] [PubMed] [Google Scholar]
  25. Haouas N, Chaker E, Chargui N, Gorcii M, Belhadj S, Kallel K, Aoun K, Akrout FM, Ben Said M, Pratlong F, Dedet JP, Mezhoud H, Lami P, Zribi M, Azaiez R and Babba H (2012) Geographical distribution updating of Tunisian leishmaniasis foci: about the isoenzymatic analysis of 694 strains. Acta Tropica 124, 221–228. [DOI] [PubMed] [Google Scholar]
  26. Harrat Z, Pratlong F, Belazzoug S, Dereure J, Deniau M, Rioux JA, Belkaid M and Dedet JP (1996) Leishmania infantum and L. major in Algeria. Transactions of the Royal Society of Tropical Medicine and Hygiene 90, 625–629. [DOI] [PubMed] [Google Scholar]
  27. Horrillo L, San Martín JV, Molina L, Madroñal E, Matía B, Castro A, García-Martínez J, Barrios A, Cabello N, Arata IG, Casas JM and Ruiz Giardin JM (2015) Atypical presentation in adults in the largest community outbreak of leishmaniasis in Europe (Fuenlabrada, Spain). Clinical Microbiology and Infection 21, 269–273. [DOI] [PubMed] [Google Scholar]
  28. Humanes-Navarro AM, Herrador Z, Redondo L, Cruz I and Fernández-Martínez B (2021) Estimating human leishmaniasis burden in Spain using the capture-recapture method, 2016–2017. PLoS ONE 16, e0259225. [DOI] [PMC free article] [PubMed] [Google Scholar]
  29. Jiménez M, Ferrer-Dufol M, Cañavate C, Gutiérrez-Solar B, Molina R, Lagun F, López-Vélez R, Cercenado E, Daudén E, Blazquez J, de Guevara CL, Gómez J, de la Torre J, Barros C, Altes J, Serra T and Alvar J (1995) Variability of Leishmania (Leishmania) infantum among stocks from immunocompromised, immunocompetent patients and dogs in Spain. FEMS Microbiology Letters 131, 197–204. [DOI] [PubMed] [Google Scholar]
  30. Jiménez M, González E, Iriso A, Marco E, Alegret A, Fúster F and Molina R (2013) Detection of Leishmania infantum and identification of blood meals in Phlebotomus perniciosus from a focus of human leishmaniasis in Madrid, Spain. Parasitology Research 112, 2453–2459. [DOI] [PubMed] [Google Scholar]
  31. Jiménez M, González E, Martín-Martín I, Hernández S and Molina R (2014) Could wild rabbits (Oryctolagus cuniculus) be reservoirs for Leishmania infantum in the focus of Madrid, Spain? Veterinary Parasitology 202, 296–300. [DOI] [PubMed] [Google Scholar]
  32. Kuhls K and Mauricio I (2019) Phylogenetic studies. In Clos J (ed.), Leishmania. Methods in Molecular Biology. New York, NY: Humana Press, pp. 9–68. doi: 10.1007/978-1-4939-9210-2_2 [DOI] [PubMed] [Google Scholar]
  33. Kuhls K, Mauricio IL, Pratlong F, Presber W and Schönian G (2005) Analysis of ribosomal DNA internal transcribed spacer sequences of the Leishmania donovani complex. Microbes and Infection 7, 1224–1234. [DOI] [PubMed] [Google Scholar]
  34. Kumar S, Stecher G, Li M, Knyaz C and Tamura K (2018) MEGA X: molecular evolutionary genetics analysis across computing platforms. Molecular Biology and Evolution 35, 1547–1549. [DOI] [PMC free article] [PubMed] [Google Scholar]
  35. Martín-Martín I, Jiménez M, González E, Eguiluz C and Molina R (2015) Natural transmission of Leishmania infantum through experimentally infected Phlebotomus perniciosus highlights the virulence of Leishmania parasites circulating in the human visceral leishmaniasis outbreak in Madrid, Spain. Veterinary Research 46, 138. [DOI] [PMC free article] [PubMed] [Google Scholar]
  36. Martín-Sánchez J, Gramiccia M, Di Muccio T, Ludovisi A and Morillas-Márquez F (2004) Isoenzymatic polymorphism of Leishmania infantum in southern Spain. Transactions of the Royal Society of Tropical Medicine and Hygiene 98, 228–232. [DOI] [PubMed] [Google Scholar]
  37. Martín-Sánchez J, Torres-Medina N, Morillas-Márquez F, Corpas-López V and Díaz-Sáez V (2021) Role of wild rabbits as reservoirs of leishmaniasis in a non-epidemic Mediterranean hot spot in Spain. Acta Tropica 222, 1–9. [DOI] [PubMed] [Google Scholar]
  38. Mas A, Martínez-Rodrigo A, Orden JA, Viñals LM, Domínguez-Bernal G and Carrión J (2020) A further investigation of the leishmaniosis outbreak in Madrid (Spain): low-infectivity phenotype of the Leishmania infantum BOS1FL1 isolate to establish infection in canine cells. Veterinary Immunology and Immunopathology 230, 110148. [DOI] [PubMed] [Google Scholar]
  39. Mas A, Martínez-Rodrigo A, Orden JA, Molina R, Jiménez M, Jiménez MÁ, Carrión J and Domínguez-Bernal G (2021) Properties of virulence emergence of Leishmania infantum isolates from Phlebotomus perniciosus collected during the human leishmaniosis outbreak in Madrid, Spain. Hepatic histopathology and immunological parameters as virulence markers in the mouse model. Transboundary and Emerging Diseases 68, 704–714. [DOI] [PubMed] [Google Scholar]
  40. Maurício IL (2018) Leishmania taxonomy. In Bruschi F and Gradoni L (eds), The Leishmaniases: Old Neglected Tropical Diseases. Cham: Springer, pp. 15–30. doi: 10.1007/978-3-319-72386-0_2 [DOI] [Google Scholar]
  41. Molina R, Jiménez MI, Cruz I, Iriso A, Martín-Martín I, Sevillano O, Melero S and Bernal J (2012) The hare (Lepus granatensis) as potential sylvatic reservoir of Leishmania infantum in Spain. Veterinary Parasitology 190, 268–271. [DOI] [PubMed] [Google Scholar]
  42. Molina R, Jiménez M, García-Martínez J, San Martín JV, Carrillo E, Sánchez C, Moreno J, Alves F and Alvar J (2020) Role of asymptomatic and symptomatic humans as reservoirs of visceral leishmaniasis in a Mediterranean context. PLoS Neglected Tropical Diseases 14, 1–16. [DOI] [PMC free article] [PubMed] [Google Scholar]
  43. Montoya L, Gállego M, Gavignet B, Piarroux R, Rioux JA, Portús M and Fisa R (2007) Application of microsatellite genotyping to the study of a restricted Leishmania infantum focus: different genotype compositions in isolates from dogs and sand flies. American Journal of Tropical Medicine and Hygiene 76, 888–895. [PubMed] [Google Scholar]
  44. Piarroux R, Trouvé V, Pratlong F, Martini A, Lambert M and Rioux JA (1994) The use of isoelectric focusing on polyacrylamide gel for the enzymatic analysis of ‘Old World’ Leishmania species. Transactions of the Royal Society of Tropical Medicine and Hygiene 88, 475–478. [DOI] [PubMed] [Google Scholar]
  45. Pratlong F, Rioux JA, Marry P, Faraut-Gambarelli F, Dereure J, Lanotte G and Dedet JP (2004) Isoenzymatic analysis of 712 strains of Leishmania infantum in the south of France and relationship of enzymatic polymorphism to clinical and epidemiological features. Journal of Clinical Microbiology 42, 4077–4082. [DOI] [PMC free article] [PubMed] [Google Scholar]
  46. Pratlong F, Lami P, Ravel C, Balard Y, Dereure J, Serres G, El Baidouri F and Dedet J-P (2013) Geographical distribution and epidemiological features of Old World Leishmania infantum and Leishmania donovani foci, based on the isoenzyme analysis of 2277 strains. Parasitology 140, 423–434. [DOI] [PubMed] [Google Scholar]
  47. Remadi L, Jiménez M, Chargui N, Haouas N, Babba H and Molina R (2018) The vector competence of Phlebotomus perniciosus for Leishmania infantum zymodemes of Tunisia. Parasitology Research 117, 2499–2506. [DOI] [PubMed] [Google Scholar]
  48. Rioux JA, Lanotte G, Serres E, Pratlong F, Bastien P and Perieres J (1990) Taxonomy of Leishmania. Use of isoenzymes. Suggestions for a new classification. Annales de Parasitologie Humaine et Comparée 65, 111–125. [DOI] [PubMed] [Google Scholar]
  49. Sáez VD, Morillas-Márquez F, Merino-Espinosa G, Corpas-López V, Morales-Yuste M, Pesson B, Barón-López S, Lucientes-Curdi J and Martín-Sánchez J (2018) Phlebotomus langeroni Nitzulescu (Diptera, Psychodidae) a new vector for Leishmania infantum in Europe. Parasitology Research 117, 1105–1113. [DOI] [PubMed] [Google Scholar]
  50. Solana JC, Chicharro C, García E, Aguado B, Moreno J and Requena JM (2022) Assembly of a large collection of maxicircle sequences and their usefulness for Leishmania taxonomy and strain typing. Genes 13, 1070. [DOI] [PMC free article] [PubMed] [Google Scholar]
  51. Toledo A, Martín-Sánchez J, Pesson B, Sanchiz-Marín C and Morillas-Márquez F (2002) Genetic variability within the species Leishmania infantum by RAPD. A lack of correlation with zymodeme structure. Molecular and Biochemical Parasitology 119, 257–264. [DOI] [PubMed] [Google Scholar]
  52. Van der Auwera G and Dujardin JC (2015) Species typing in dermal leishmaniasis. Clinical Microbiology Reviews 28, 265–294. [DOI] [PMC free article] [PubMed] [Google Scholar]
  53. Van der Auwera G, Maes I, De Doncker S, Ravel C, Cnops L, Van Esbroeck M, Van Gompel A, Clerinx J and Dujardin JC (2013) Heat-shock protein 70 gene sequencing for Leishmania species typing in European tropical infectious disease clinics. Eurosurveillance 18, 20543. [DOI] [PubMed] [Google Scholar]
  54. Van der Auwera G, Davidsson L, Buffet P, Ruf M-T, Gramiccia M, Varani S, Chicharro C, Bart A, Harms G, Chiodini PL, Brekke H, Robert-Gangneux F, Cortes S, Verweij JJ, Scarabello A, Karlsson Söbirk S, Guéry R, van Henten S, Di Muccio T, Carra E, van Thiel P, Vandeputte M, Gaspari V and Blum J (2022) Surveillance of leishmaniasis cases from 15 European centres, 2014 to 2019: a retrospective analysis. Eurosurveillance 27, 2002028. [DOI] [PMC free article] [PubMed] [Google Scholar]
  55. World Health Organization (2010) Control of the leishmaniasis: report of a meeting of the WHO Expert Commitee on the Control of Leishmaniases, Geneva, 2226 March 2010. Technical report series, 949.

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Fernández-Arévalo et al. supplementary material

Fernández-Arévalo et al. supplementary material

S0031182023001336sup001.docx (291KB, docx)

Data Availability Statement

Sequences are available in GenBank under accession numbers OQ747159-OQ747177.

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