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Morphometric analysis of cavernicolous adult Idiophlebotomus asperulus Quate and Fairchild, 1961 female sand flies in Southern Thailand

Published online by Cambridge University Press:  05 November 2024

Kam Sheng Lau
Affiliation:
Faculty of Environmental Management, Prince of Songkla University, Hat Yai, Songkhla 90110, Thailand Health and Environmental Research Centre (HERC), Faculty of Environmental Management, Prince of Songkla University, Hat Yai, Songkhla 90110, Thailand
Md Shahariar Chowdhury
Affiliation:
Faculty of Environmental Management, Prince of Songkla University, Hat Yai, Songkhla 90110, Thailand Health and Environmental Research Centre (HERC), Faculty of Environmental Management, Prince of Songkla University, Hat Yai, Songkhla 90110, Thailand
Chin Hua Chia
Affiliation:
Materials Science Program, Department of Applied Physics, Faculty of Science and Technology, Universiti Kebangsaan Malaysia, Bangi, Selangor 43600, Malaysia
Noodchanath Kongchouy
Affiliation:
Division of Computational Science, Faculty of Science, Faculty of Science, Prince of Songkla University, Hat Yai, Songkhla, Thailand
Jirayu Buatong
Affiliation:
International Centre of Excellence in Seafood Science and Innovation, Faculty of Agro-Industry, Prince of Songkla University, Hat Yai, Songkhla 90110, Thailand
Nattapong Maneeroth
Affiliation:
Health and Environmental Research Centre (HERC), Faculty of Environmental Management, Prince of Songkla University, Hat Yai, Songkhla 90110, Thailand
Pathamet Khositharattanakool
Affiliation:
School of Medicine, Mae Fah Luang University, Chiang Rai 57100, Thailand Biomedical Technology Research Group for Vulnerable Populations, Mae Fah Luang University, Chiang Rai 57100, Thailand
Puckavadee Somwang*
Affiliation:
School of Medicine, Mae Fah Luang University, Chiang Rai 57100, Thailand Biomedical Technology Research Group for Vulnerable Populations, Mae Fah Luang University, Chiang Rai 57100, Thailand
Theerakamol Pengsakul*
Affiliation:
Faculty of Environmental Management, Prince of Songkla University, Hat Yai, Songkhla 90110, Thailand Health and Environmental Research Centre (HERC), Faculty of Environmental Management, Prince of Songkla University, Hat Yai, Songkhla 90110, Thailand
*
Corresponding authors: Theerakamol Pengsakul and Puckavadee Somwang; Emails: theerakamol.p@psu.ac.th and puckavadee.som@mfu.ac.th
Corresponding authors: Theerakamol Pengsakul and Puckavadee Somwang; Emails: theerakamol.p@psu.ac.th and puckavadee.som@mfu.ac.th

Abstract

Sand flies are potential carriers of various diseases that are transmittable to humans and animals. In this study, United States Centers for Disease Control light traps were set up in four tourist caves in the Thai provinces of Surat Thani, Nakhon Si Thammarat, Satun, and Chumphon to capture Idiophlebotomus asperulus sand flies. Over a period of three months, April to June, in 2017, a total of 181 female Idiophlebotomus asperulus sand flies were captured during nightly operations. The sand flies were dissected into 23 external and internal parts to identify their morphological characteristics. Statistical analysis was then conducted on these morphological characteristics, involving both univariate analysis (one-way analysis of variance and the Kruskal–Wallis test) and multivariate analysis (canonical discriminant analysis). Levene’s, the Kolmogorov–Smirnov, and Box’s M tests were used for the preliminary statistical screening of the data. The test results revealed significant morphological differences in the sand flies from the four provinces with regard to their antenna segments 5, palpal segments 3, pharynxes, hindlegs, femurs, and spermathecae. These morphological differences in the southern Thai Idiophlebotomus asperulus sand fly population suggest the possibility that at least three morphologically different populations are found in this region.

Type
Research Paper
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re- use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of Entomological Society of Canada

Introduction

Seventy species of sand flies (Diptera, Psychodidae), which can transmit diseases to humans and animals, have been identified (Pothirat et al. Reference Pothirat, Tantiworawit, Chaiwarith, Jariyapan, Wannasan and Siriyasatien2014). Among the diseases carried by sand flies is leishmaniasis (e.g., Leishmania tropica, L. major, and L. aethiopica), a zoonotic disease with the capacity for cross-transmission between humans and animals (Lemma et al. Reference Lemma, Erenso, Gadisa, Balkew, Gebre-Michael and Hailu2009; Eshetu and Bassa Reference Eshetu and Bassa2016). Although leishmaniasis infections caused by L. martiniquensis have been reported to occur in both the northern and southern regions of Thailand, the infections appear to occur more often in the southern region (Thisyakorn et al. Reference Thisyakorn, Jongwutiwes, Vanichsetakul and Lertsapcharoen1999; Sukmee et al. Reference Sukmee, Siripattanapipong, Mungthin, Worapong, Rangsin and Samung2008; Chusri et al. Reference Chusri, Thammapalo, Silpapojakul and Siriyasatien2014; Osatakul et al. Reference Osatakul, Mungthin, Siripattanapipong, Hitakarun, Kositnitikul, Naaglor and Leelayoova2014). This may be attributed to this region’s abundance of ecotourism locations, such as parks, wildlife sanctuaries, and caves, that provide ideal sand fly breeding grounds. Sand flies, which live in moist environments, can draw blood from vertebrates, including reptiles and mammals, that live in the surrounding area (Apiwathnasorn et al. Reference Apiwathnasorn, Sucharit, Surathin and Deesin1993; World Tourism Organisation 2012). According to the results from a survey of sand fly habitats, it was reported that the various species of sand flies prefer caves over other habitats (Apiwathnasorn et al. Reference Apiwathnasorn, Sucharit, Rongsriyam, Leemingsawat, Kerdpibule and Deesin1989). Taking this into account, this investigation focuses on the cave area in Southern Thailand.

The sand fly genus Idiophlebotomus can be distinguished by the insects’ parameres, which are single, bifurcated, and covered with scales. However, Idiophlebotomus asperulus Quate and Fairchild, 1961, Idiophlebotomus pholetor Quate and Fairchild, 1961, Idiophlebotomus erebicolus Quate, 1965, Idiophlebotomus longiforceps Wang et al., 1974, Idiophlebotomus frondifer Lewis and Lane, 1976, Idiophlebotomus wellingsae Lewis and Dyce, 1983, Idiophlebotomus dispar Lewis, 1987, and Idiophlebotomus boucheti Léger and Pesson, 1994 exhibit a single paramere on the male reproductive organ (Ilango Reference Ilango2010; Léger et al. Reference Léger, Depaquit and Gay2014). These species may have similar external characteristics but are incapable of breeding even with sibling species. This circumstance gives rise to taxonomy problems. Although an approach for the general identification of sand fly gender is currently lacking, in the context of medical entomology, more emphasis should be placed on efforts to successfully identify the females of the species. Recently, Buatong et al. (Reference Buatong, Dvorak, Thepparat, Thongkhao, Koyadun, Siriyasatien and Pengsakul2022) identified female sand flies located in cavernicolous localities in four provinces in Southern Thailand based on morphology. Morphological variations often stem from evolutionary processes associated with random events, particularly those affecting populations, including the founder effect or genetic drift (Vignon et al. Reference Vignon, Zhou, McIntosh, Correa, Westley and Jacquin2023).

Sand fly classification calls for expertise and experience in morphology (Nzelu et al. Reference Nzelu, Cáceres, Arrunátegui-Jiménez, Lañas-Rosas, Yañez-Trujillano and Luna-Caipo2015). For the most part, sand fly classification entails the use of a microscope for the scrutiny of the insect’s head and genitalia (Galati Reference Galati, Rangel and Shaw2010; Maneeroth et al. Reference Maneeroth, Noonanant, Thongkhao and Pengsakul2020). The close similarity of some sand fly species or groups can complicate the classification process (Kumar et al. Reference Kumar, Srinivasan and Jambulingam2012). The standard procedure for sand fly classification, presented in 1979, requires additional preclassification studies regarding the characteristics to be considered during classification (Lewis Reference Lewis1979). An approach that sidesteps these issues is the morphometric analysis of each species (Campbell et al. Reference Campbell, Sokal and Rohlf1970; Gebre-Michael and Medhin Reference Gebre-Michael and Medhin1997; Godoy et al. Reference Godoy, Galati, Cordeiroestrela, De Souza, Dos Santos, De Sousa and Rangel2014).

Previous studies have identified a variety of sand fly species inhabiting the caves of Southern Thailand (Maneeroth et al. Reference Maneeroth, Noonanant, Thongkhao and Pengsakul2020). The emphasis of our research is on the morphometric analysis of the physical characteristics of the adult female sand fly Idiophlebotomus asperulus found in the limestone caves of Southern Thailand.

Materials and methods

Sample collection

Sand fly population samples for this investigation were sourced from limestone caves located in Southern Thailand (Fig. 1) during the rainy season, April–June, in 2017 (Table 1). Five Centers for Disease Control (United States of America) light traps (John W. Hock, Co., Florida, United States of America) were installed inside each cave. The light traps were positioned 1.0–1.5 m from the ground and remained operational from dawn to dusk – specifically, from 06:00 to 18:00 local time. The procedures used to collect and prepare specimens for this study are certified by the Institutional Animal Care and Use Committee, Prince of Songkla University, Hat Yai, Songkhla, Thailand (Reference no. 2561-10-021).

Figure 1. Map of Southern Thailand showing the localities where the specimens were collected in Chumphon, Surat Thani, Nakhon Si Thammarat, and Satun provinces.

Table 1. The geographic locations and details of the sand fly collection sites, which were caves in Southern Thailand

Sample preparation

A total of 181 female sand flies were collected for the present study. The specimens were euthanised with 95% ethyl acetate and then were transferred to a conical tube containing 70% ethanol. The female sand fly specimens were dissected to separate the head, thorax, wings, and hind legs (Lewis and Lane Reference Lewis and Lane1976; Maneeroth et al. Reference Maneeroth, Noonanant, Thongkhao and Pengsakul2020). The organs were then treated with Hoyer’s medium (Anderson Reference Anderson1954), placed on a glass slide, covered with a coverslip, and placed in a 45 °C oven for seven days. Species identification involved examination of the abdomen, where the genitalia are located, and head, using taxonomic keys (Abonnenc Reference Abonnenc1972; Lewis and Lane Reference Lewis and Lane1976; Léger and Pesson Reference Léger and Pesson1994; Léger et al. Reference Léger, Depaquit and Gay2014; Loyer et al. Reference Loyer, Depaquit and Gay2016). Sand flies identified as Idiophlebotomus asperulus based on their morphological characteristics were then measured using an Olympus CX31 RBSF microscope (Olympus Corp., Tokyo, Japan) connected to an Olympus DP21 camera (Olympus Corp.).

Morphometric analysis

Morphological characteristics of Idiophlebotomus asperulus were measured, based on 23 aspects: (1) ascoid on flagellomere 2 (length of longest ascoid on flagellomere 2), (2) ascoid on flagellomere 3 (length of longest ascoid on flagellomere 3), (3) pharynx length (length of the pharynx), (4) pharynx width (width of the posterior part of the pharynx), (5) pharyngeal armature (length of the teethed area at the posterior end of the pharynx), (6) epipharynx (length from the anterior margin of the clypus to the tip of the labral teeth), (7) femur on hind leg (longest measurement of hind leg femur), (8) tibia on hind leg (longest measurement of hind leg tibia), (9) palpal segment 1 (length of palpal segment 1), (10) palpal segment 2 (length of palpal segment 2), (11) palpal segment 3 (length of palpal segment 3), (12) palpal segment 4 (length of palpal segment 4), (13) palpal segment 5 (length of palpal segment 5), (14) antennal segment 3 (length of antennal segment 3), (15) antennal segment 4 (length of antennal segment 4), (16) antennal segment 5 (length of antennal segment 5), (17) cibarium length (length of cibarium from the chitinous arch at the posterior junction with pharynx, to the anterior junction with the clypus), (18) cibarium width (width of the cibarium measured at the widest part), (19) spermathecae length (length of spermathecae), (20) spermathecae width (width of spermathecae measured at the widest part), (21) head of spermathecae length (length of the teethed area at the posterior end of the pharynx), (22) tarsal segment 1 on hind leg (longest measurement of hind leg tarsal segment 1), and (23) tarsus on hind leg (longest measurement of hind leg tarsus). The morphological results derived from these measurements are displayed in Figure 2. The digital image of the abdomen part of female and male sand fly are shown in Figure 3.

Figure 2. Idiophlebotomus asperulus female: A, antennal segments A3 to A5; B, spermathecae; C, pharynx; D, cibarium; E, epipharynx; F, palpal segment 1 to 5; and G, hindleg.

Figure 3. The abdomen of sand flies: A, spermathecae in a female sand fly and B, styles of a male sand fly.

Statistical analyses

Univariate analysis

The missing data for the morphological characters were imputed through the mean substitution of each individual group, with a total sample size of 147. Following an assessment of the normality distribution, a descriptive statistical analysis was carried out to compute the mean and standard deviation. A one-way analysis of variance and a post hoc test using Tukey’s pairwise test, with a significance level of P < 0.05, were used to compare the mean of the morphological characters among specimens according to the four provinces. Before the tests, homogeneity of variances was verified by way of Levene’s test and normality distribution was verified by way of the Kolmogorov–Smirnov test, with a significance level of P > 0.05. A nonparametric analysis with the Kruskal–Wallis test was performed for the morphological characters that did not meet the assumption of normality (P < 0.05).

Multivariate analysis

Z-score transformation was conducted for all the raw data to ensure the feasibility of the morphological characters for multivariate analysis. Box’s M test was used to assess the morphological characteristics for the multivariate assumption of covariance matrix equality. Following its verification, the data were scrutinised using canonical discriminant analysis. The canonical discriminant score was applied to generate a graph, and the canonical discriminant function was used to group the findings. The significance of the discriminant function was calculated by means of Wilk’s lambda and the Chi-square statistic. The results from the canonical discriminant analysis were confirmed via leave-one-out cross validation. A confusion matrix was then used to gradually regroup the data by excluding one specimen over time. The remaining grouped data was then used to identify that specimen.

Results

Four populations, amounting to a total of 147 individual Id. asperulus, were used in the present study, and the multivariate analysis of the 23 morphological characters is tabulated in Table 2. Nine of the 23 morphological characters met the one-way analysis of variance assumptions, and nine morphological characteristics with statistically significant differences among the Id. asperulus populations were identified. They were the ascoid on flagellomere 3 (F = 12.1, P < 0.05), pharynx width (F = 43.93, P < 0.05), the epipharynx ( F = 28.71, P < 0.05), palpal segment 4 (F = 9.523, P < 0.05), palpal segment 5 (F = 12.49, P < 0.05), antennal segment 3 (F = 23.01, P < 0.05), antennal segment 4 (F = 32.74, P < 0.05), spermathecae length (F = 45.92, P < 0.05), and spermathecae width (F = 28.69, P < 0.05).

Table 2. A comparison of the means and standard deviations of the morphometric characteristics of female Idiophlebotomus asperulus. The significant P-values were based on the results of the analysis of variance (*) and Kruskal–Wallis (§) test

Note: The various superscript alphabets are the subgroups of the Tukey’s pairwise test.

fII, ascoid on flagellomere 2; fIII, ascoid on flagellomere 3; Ph.L, pharynx length; Ph.W, pharynx width; Ph.A, pharyngeal armature; Epi, epipharynx; Fem, femur on hind leg; Tib, tibia on hind leg; Palp 1, palpal segment 1; Palp 2, palpal segment 2; Palp 3, palpal segment length of palpal segment 3; Palp 4, palpal segment 4; Palp 5, palpal segment 5; A3, antennal segment 3; A4, antennal segment 4; A5, antennal segment 5; Ci.L, cibarium length; Ci.W, cibarium width; Sperm.L, spermathecae length; Sperm.W, spermathecae width; Sperm.Hea, head of spermathecae length; Tar.1, tarsal segment 1 on hind leg; and Tar, tarsus on hind leg.

The Tukey’s pairwise post hoc analysis indicated two major subgroups – the Surat Thani and Chumphon subgroup and the Nakhon Si Thammarat and Satun subgroup – for seven of the morphological characteristics – specifically, for pharynx length, femur on hind leg, tibia on hind leg, antennal segment 3, antennal segment 4, antennal segment 5, and tarsal segment 1 on hind leg. The Surat Thani and Chumphon subgroup exhibited significantly different morphologies for the ascoid on both flagellomeres 2 and 3, pharynx width, pharyngeal armature, epipharynx, femur on hind leg, cibarium width, spermathecae width, and head of spermathecae length. More specifically, the average ascoids on flagellomeres 2 and 3 were considerably shorter in the Surat Thani subgroup than in any of the other three subgroups. Also, the measurements for pharynx width, pharynx armature, femur on hind leg, and cibarium width derived from specimens in the Chumphon subgroup differed markedly from those derived from specimens from the other provinces. The average spermathecae length (Sperm.L) was significantly longer in the Nakhon Si Thammarat subgroup (M = 60.83, standard deviation = 6.58) than in populations from the other provinces (Surat Thani subgroup: M = 48.52, standard deviation = 5.53, P < 0.05; Satun subgroup: M = 46.11, standard deviation = 6.82, P < 0.05; and Chumphon subgroup: M = 47.15, standard deviation = 5.90, P < 0.05). Because no discernible differences were observed in the palpal segment 1 and cibarium length of the samples collected from the four provinces, these characteristics were excluded from the concluding stage of the morphometric multivariate analysis.

The canonical discriminant analysis multivariate analysis results of the Id. asperulus sample populations gave rise to three different classification functions. The main characteristics in the structure matrix were pharynx widths, femur on hind leg, antennal segment 5, and spermathecae length (Table 3). Functions 1 and 2 were used for the canonical discriminant analysis, with Function 1 accounting for 58.4% of the variance (chi-square = 432.647, multivariate analysis of variance test yields Wilk’s Lambda = 0.041, df = 693, P < 0.001), and Function 2 accounting for 31.24% of the variance. The scattered plot of the discriminant scores for Functions 1 and 2, with a convex hull, are shown in Figure 4. The morphological characters pharynx width, femur on hind leg, and spermathecae length presented high scores in Function 1, whereas the significantly negative score for spermathecae length in Function 2 indicates a greater length than in specimens from the other provinces. Spermathecae length was therefore construed to be a significant indicator of variation. By looking into Function 3, three significantly positive score characters were identified (epipharynx, palpal segment 5, and spermathecae length); however, these characters do not differ among sand fly populations captured in Satun and Surat Thani provinces. The canonical discriminant analysis analysis revealed that the morphological characters of sand fly populations from Satun and Surat Thani provinces are closely related and the sand fly populations from Chumphon and Nakhon Si Thammarat provinces are distinct from the other provinces. The group classification equation categorised 79% of the sand fly populations accurately. According to the scatter plot of discriminant scores, with regard to the two functions, the populations of Id. asperulus in two locations are close to each other. The confusion matrix analysis (Table 4), based on the canonical discriminant analysis results, revealed that 97.3% of the originally grouped cases and 88.4% of the cross-validated grouped cases are accurately classified.

Table 3. The structure matrix of the morphometric features of female Idiophlebotomus asperulus chosen using canonical discriminant analysis. The samples were collected from tourist caves in four provinces, namely, Surat Thani, Nakhon Si Thammarat, Satun, and Chumphon, in Southern Thailand

fII, ascoid on flagellomere 2; fIII, ascoid on flagellomere 3; Ph.L, pharynx length; Ph.W, pharynx width; Ph.A, pharyngeal armature; Epi, epipharynx; Fem, femur on hind leg; Tib, tibia on hind leg; Palp 1, palpal segment 1; Palp 2, palpal segment 2; Palp 3, palpal segment length of palpal segment 3; Palp 4, palpal segment 4; Palp 5, palpal segment 5; A3, antennal segment 3; A4, antennal segment 4; A5, antennal segment 5; Ci.L, cibarium length; Ci.W, cibarium width; Sperm.L, spermathecae length; Sperm.W, spermathecae width; Sperm.Hea, head of spermathecae length; Tar.1, tarsal segment 1 on hind leg; and Tar, tarsus on hind leg.

Figure 4. The canonical discriminant analysis results of the measured characteristics of Idiophlebotomus asperulus collected from Chumphon (black), Nakhon Si Thammarat (teal), Satun (red), and Surat Thani (blue).

Table 4. The leave-one-out cross-validation of all the samples used in the canonical discriminant analysis of the morphological characteristic measurements of Idiophlebotomus asperulus collected from tourist caves in four provinces, namely, Surat Thani, Satun, Chumphon, and Nakhon Si Thammarat, in Southern Thailand

Discussion

The findings derived through the present study reveal variations in terms of internal and external morphological features among sand fly populations in Southern Thailand. These morphological variations likely stem from the environmental conditions in which the insects exist (Thongsripong et al. Reference Thongsripong, Green, Kittayapong, Kapan, Wilcox and Bennett2013). It is debatable whether caves with more resources are endowed with greater biological complexity than are caves with fewer resources. Local climate and ecology also may influence morphological change, which may occur in the form of a genetic drift or directional selection. Some studies have suggested that larval development is limited to an area within the maximum flight distance of adult sand flies (Claborn Reference Claborn2010) and that the poor flying ability of sand flies restricts their maximum flying distance to no more than 100 m (Killick-Kendrick Reference Killick-Kendrick1999). Based on this, sand fly populations may be restricted to each local area, and genetic differences may occur not only among different species but also among populations of the same species in different areas (Belen et al. Reference Belen, Alten and Aytekin2004).

Differences in sand fly morphological features can be attributed to the geographical locations of the caves, which influence habitat environmental factors, such as temperature, physical barriers, precipitation, latitude, and altitude, and the abundance and distribution of vertebrate hosts. The Idiophlebotomus sand fly species feeds on the blood of mammals, reptiles, and amphibians living in caves (Srisuton et al. Reference Srisuton, Phumee, Sunantaraporn, Boonserm, Sor-Suwan and Brownell2019; Toontong et al. Reference Toontong, Sunantaraporn, Tiawsirisup, Pengsakul, Boonserm and Phumee2022). The highest temperature of any of the present study’s sand fly sampling sites was recorded as 29 °C in Chumphon, and the lowest was recorded as 25.9 °C in Nakhon Si Thammarat. According to Rafatbakhsh-Iran et al. (Reference Rafatbakhsh-Iran, Salehzadeh, Nazari, Zahirnia, Davari, Latifi and Chamanpara2016), the density of sand fly populations is influenced by relative humidity. The relative humidity of the sampling sites ranges between 75 and 90%. The findings of Rafatbakhsh-Iran et al.’s (Reference Rafatbakhsh-Iran, Salehzadeh, Nazari, Zahirnia, Davari, Latifi and Chamanpara2016) study, which was conducted in central Morocco, showed that higher environmental temperatures promote increases in sand fly populations, which may explain why the more female sand flies were collected from Chumphon than from the other three sampling locations. The results from our investigation show that density of sand fly populations is affected by temperature in the four caves. This suggests the sand fly has less capacity to adapt to cave environments with lower temperatures.

The present study’s results indicate a certain degree of variability in the sand fly pharynx. This morphological feature presents a possible approach for sand fly classification. However, the two morphological characteristics with low variations in the populations of sand flies investigated are the posterior segment of the pharynx (pharynx width, pharynx length) and the width of the cibarium. Based on appearance, it was difficult to differentiate the pharynx, antennal segment 3, and ascoid among P. argentipes, P. annandalei, and P. glacus, which share similar habitats and external morphology (Ilango Reference Ilango2010). This could be due to the fact that the samples for this study were collected from near the cave’s entrances, where the environment is similar to that above ground. Cave entrances typically experience daily fluctuations in sunlight and temperature, which support the growth of green plants (Lee et al. Reference Lee, Meisinger, Aubrecht, Kovacik, Saiz-Jimenez, Baskar and Bell2012). The use of these areas by animals to eat, sleep, or nest means cave entrances are appropriate food-source locations for sand flies.

Conventional morphometrics is a cost-effective method for the characterisation and classification of organisms (Bhat et al. Reference Bhat, Mir, Farooq, Manzoor, Hami and Allie2022). In the present study, a statistical morphometric analysis was performed to identify variations in the interior and exterior morphology of Id. asperulus sand fly populations that live in the caves of Southern Thailand that are visited by tourists. Sand fly morphology can be used to identify comparable species or to detect changes in sand fly populations. Additionally, it can be used to monitor sand fly populations for improved management and prevention of leishmaniasis.

Conclusion

The present study identified 23 morphological characteristics of sand fly, 14 of which had high variation. These highly varied characteristics were the ascoid on antennal segment 4, the ascoid on antennal segment 5, the epipharynx, the femur on hindleg, the tibia on hindleg, palpal segment 2, palpal segment 3, palpal segment 4, palpal segment 5, antennal segment 3, cibarium length, spermathecae length, tarsal segment 1 on hindleg, and tarsus on hindleg. None of the species exhibited low-variation characteristics. Canonical discriminant analysis indicated that, for the most part, morphology differences among the four sand fly populations in each study area occurs within eight characteristics: the longest ascoid on antennal segment 5; palpal segment 2, 3, and 5; the lengths of antennal segments 3 and 4; cibarium; and the width of the spermathecae. Low variations were detected for two sand fly morphology characteristics, the pharynx and cibarium. Therefore, morphological comparisons facilitate the detection of comparable sand fly species and changes within populations when monitoring sand fly populations to reduce leishmaniasis incidence.

Acknowledgements

The authors thank the Office of Disease Prevention and Control, Region 11 Nakhon Si Thammarat province, Thailand, for fieldwork support, and the Faculty of Environmental Management, Prince of Songkla University, for providing laboratory workspace and equipment. This article had been reviewed by language proofreading by Grammarproofing.com. This research was supported by Postdoctoral Fellowship from Prince of Songkla University, and the Program Management Unit for Human Resources and Institutional Development, Research and Innovation [grant number B16F630071]. The research by Mae Fah Luang University has received funding support from the National Science, Research and Innovation Fund (NSRF), 2023 (grant no. 662A07010).

Author contributions

Conceptualisation: T.P. and P.S.; methodology: K.L., M.C., C.C., N.K., J.B., N.M., P.K., P.S., and T.P.; validation: K.L., N.K., J.B., and T.P.; resources: N.K., N.M., P/K., P.S., and T.P.; writing – original draft preparation: K.L., T.P., and J.B.; writing – review and editing: K.L., M.C., C.C., N.K., J.B., N.M., P.K., P.S., and T.P.; supervision: T.P. and C.C; project administration: T.P. All authors have read and agreed to the published version of the manuscript.

Competing interests

The authors declare that they have no conflicts of interest.

Footnotes

Subject editor: Lisa Lumley

References

Abonnenc, E. 1972. Les phlébotomes de la région Éthiopienne (Diptera: psychodidae). Memoires de la ORSTOM [Sandflies of the Ethiopian region (Diptera: psychodidae). ORSTOM Memoirs]. Paris Office de la Recherche Scientifiique et Technique Outre-Mer, 55: 1289.Google Scholar
Anderson, L.E. 1954. Hoyer’s solution as a rapid permanent mounting medium for bryophytes. Bryologist, 57: 242244.CrossRefGoogle Scholar
Apiwathnasorn, C., Sucharit, S., Rongsriyam, Y., Leemingsawat, S., Kerdpibule, V., Deesin, T., et al. 1989. A brief survey of Phlebotominae sand flies in Thailand. Southeast Asian Journal of Tropical Medicine and Public Health, 20: 429432.Google ScholarPubMed
Apiwathnasorn, C., Sucharit, S., Surathin, K., and Deesin, T. 1993. Anthropophilic and zoophilic phlebotomine sand flies (Diptera, Psychodidae) from Thailand. Journal of the American Mosquito Control Association, 9: 135137.Google ScholarPubMed
Belen, A., Alten, B., and Aytekin, A.M. 2004. Altitudinal variation in morphometric and molecular characteristics of Phlebotomus papatasi populations. Medical and Veterinary Entomology, 18: 343350.CrossRefGoogle ScholarPubMed
Bhat, K.A., Mir, R.A., Farooq, A., Manzoor, M., Hami, A., Allie, K.A., et al. 2022. Advances in nematode identification: a journey from fundamentals to evolutionary aspects. Diversity, 14: 536. https://doi.org/10.3390/d14070536.CrossRefGoogle Scholar
Buatong, J., Dvorak, V., Thepparat, A., Thongkhao, K., Koyadun, S., Siriyasatien, P., and Pengsakul, T. 2022. Phlebotomine sand flies in Southern Thailand: entomological survey, identification of blood meals and molecular detection of Trypanosoma spp. Insects, 13: 197.CrossRefGoogle ScholarPubMed
Campbell, R.C., Sokal, R.R., and Rohlf, F.J. 1970. Biometry: the principles and practice of statistics in biological research. Journal of the Royal Statistical Society: Series A (General), 133: 102.CrossRefGoogle Scholar
Chusri, S., Thammapalo, S., Silpapojakul, K., and Siriyasatien, P. 2014. Animal reservoirs and potential vectors of Leishmania siamensis in Southern Thailand. Southeast Asian Journal of Tropical Medicine and Public Health, 45: 1319.Google ScholarPubMed
Claborn, D. 2010. The biology and control of leishmaniasis vectors. Journal of Global Infectious Diseases, 2: 127.CrossRefGoogle ScholarPubMed
Eshetu, E. and Bassa, A.A.T. 2016. The public health significance of leishmaniasis: an overview. Journal of Natural Sciences Research, 6: 4857.Google Scholar
Galati, E. 2010. Phlebotominae (Diptera, Psychodidae) classification, morphology, terminology and adult identification. In Brazilian Sand Flies. Edited by Rangel, E. and Shaw, J.. Springer, Cham, Switzerland.Google Scholar
Gebre-Michael, T. and Medhin, G. 1997. Morphometric separation of females of Phlebotomus (Phlebotomus) duboscqi and P. (P.) bergeroti (Diptera: Psychodidae). Journal of Medical Entomology, 34: 383386.CrossRefGoogle ScholarPubMed
Godoy, R.E., Galati, E.A.B., Cordeiroestrela, P., De Souza, N.A., Dos Santos, T.V., De Sousa, L.C., and Rangel, E.F. 2014. Comparative study of the phlebotomine sand fly species (Diptera: Psychodidae: Phlebotominae) of the genera Nyssomyia Barretto, 1962, Bichromomyia Artemiev, 1991, and Migonemyia Galati, 1995, vectors of American cutaneous leishmaniasis in Brazil. Zootaxa, 3838: 501517.CrossRefGoogle ScholarPubMed
Ilango, K. 2010. A taxonomic reassessment of the Phlebotomus argentipes species complex (Diptera: Psychodidae: Phlebotominae). Journal of Medical Entomology, 47: 115.CrossRefGoogle Scholar
Killick-Kendrick, R. 1999. The biology and control of phlebotomine sand flies. Clinics in Dermatology, 17: 279289.CrossRefGoogle ScholarPubMed
Kumar, N.P., Srinivasan, R., and Jambulingam, P. 2012. DNA barcoding for identification of sand flies (Diptera: Psychodidae) in India. Molecular Ecology Resources, 12: 414420.CrossRefGoogle ScholarPubMed
Lee, N.M., Meisinger, D.B., Aubrecht, R., Kovacik, L., Saiz-Jimenez, C., Baskar, S., et al. 2012. Caves and karst environments. In Life at Extremes: Environments, Organisms and Strategies for Survival. Edited by Bell, E.M.. CABI, Wallingford, United Kingdom.Google Scholar
Léger, N., Depaquit, J., and Gay, F. 2014. Idiophlebotomus padillarum n. sp. (Diptera Psychodidae), a new sand fly species from Palawan (Philippines). Acta Tropica, 132: 5156.CrossRefGoogle Scholar
Léger, N. and Pesson, B. 1994. Phlébotomes du Sulawesi: description de Phlebotomus (Idiophlebotomus) Boucheti n. sp. (Diptera: Psychodidae). Parasite, 1: 7780.CrossRefGoogle Scholar
Lemma, W., Erenso, G., Gadisa, E., Balkew, M., Gebre-Michael, T., and Hailu, A. 2009. A zoonotic focus of cutaneous leishmaniasis in Addis Ababa, Ethiopia. Parasites & Vectors, 2: 18.CrossRefGoogle ScholarPubMed
Lewis, D.J. 1979. The phebotomine sandflies (Diptera: Psychodidae) of the oriental region in bullentin of the British museum (natural history). Entomology Series, 37: 217343.Google Scholar
Lewis, D.J. and Lane, R.P. 1976. A taxonomic review of Phlebotomus (Idiophlebotomus) (Psychodidae). Systematic Entomology, 1: 5360.CrossRefGoogle Scholar
Loyer, M., Depaquit, J., and Gay, F. 2016. A new cavernicolous sand fly from Cambodia: Idiophlebotomus nicolegerae n. sp. (Diptera: Psychodidae). Acta Tropica, 155: 4350.CrossRefGoogle Scholar
Maneeroth, N., Noonanant, N., Thongkhao, K., and Pengsakul, T. 2020. Morphometric analysis of sand fly (Diptera: Psychodidae: Phlebotominae), Sergentomyia anodontis Quate and Fairchild, 1961, populations in caves of Southern Thailand. Asian Pacific Journal of Tropical Medicine, 13: 415. http://www.apjtm.org/text.asp?2020/13/9/415/290586.Google Scholar
Nzelu, C.O., Cáceres, A.G., Arrunátegui-Jiménez, M.J., Lañas-Rosas, M.F., Yañez-Trujillano, H.H., Luna-Caipo, D.V., et al. 2015. DNA barcoding for identification of sand fly species (Diptera: Psychodidae) from leishmaniasis-endemic areas of Peru. Acta Tropica, 145: 4551.CrossRefGoogle ScholarPubMed
Osatakul, S., Mungthin, M., Siripattanapipong, S., Hitakarun, A., Kositnitikul, R., Naaglor, T., and Leelayoova, S. 2014. Case report: recurrences of visceral leishmaniasis caused by Leishmania siamensis after treatment with amphotericin B in a seronegative child. American Journal of Tropical Medicine and Hygiene, 90: 4042.CrossRefGoogle Scholar
Pothirat, T., Tantiworawit, A., Chaiwarith, R., Jariyapan, N., Wannasan, A., Siriyasatien, P., et al. 2014. First isolation of Leishmania from northern Thailand: case report, identification as Leishmania martiniquensis and phylogenetic position within the Leishmania enriettii complex. PLOS Neglected Tropical Diseases, 8: e3339. https://doi.org/10.1371/journal.pntd.0003339.CrossRefGoogle ScholarPubMed
Rafatbakhsh-Iran, S., Salehzadeh, A., Nazari, M., Zahirnia, A.H., Davari, B., Latifi, M., and Chamanpara, P. 2016. Ecological aspects of the predominant species of Phlebotominae sand flies (Diptera: Psychodidae) in Hamadan, Iran. Zahedan Journal of Research in Medical Sciences, 18: e5994.Google Scholar
Srisuton, P., Phumee, A., Sunantaraporn, S., Boonserm, R., Sor-Suwan, S., Brownell, N., et al. 2019. Detection of Leishmania and Trypanosoma DNA in field-caught sand flies from endemic and non-endemic areas of leishmaniasis in Southern Thailand. Insects, 10: 238. https://doi.org/10.3390/insects10080238.CrossRefGoogle ScholarPubMed
Sukmee, T., Siripattanapipong, S., Mungthin, M., Worapong, J., Rangsin, R., Samung, Y., et al. 2008. A suspected new species of Leishmania, the causative agent of visceral leishmaniasis in a Thai patient. International Journal for Parasitology, 38: 617622.CrossRefGoogle Scholar
Thisyakorn, U., Jongwutiwes, S., Vanichsetakul, P., and Lertsapcharoen, P. 1999. Visceral leishmaniasis: the first Indigenous case report in Thailand. Transactions of the Royal Society of Tropical Medicine and Hygiene, 93: 2324.CrossRefGoogle ScholarPubMed
Thongsripong, P., Green, A., Kittayapong, P., Kapan, D., Wilcox, B., and Bennett, S. 2013. Mosquito vector diversity across habitats in central Thailand endemic for dengue and other arthropod-borne diseases. PLOS Neglected Tropical Diseases, 7: e2507. https://doi.org/10.1371/journal.pntd.0002507.CrossRefGoogle ScholarPubMed
Toontong, P., Sunantaraporn, S., Tiawsirisup, S., Pengsakul, T., Boonserm, R., Phumee, A., et al. 2022. First report of anuran Trypanosoma DNA in flat-tailed house geckos (Reptilia: Gekkonidae) collected from Southern Thailand: no evidence as a reservoir for human trypanosomatids. Pathogens, 11: 247. https://doi.org/10.3390/pathogens11020247.CrossRefGoogle ScholarPubMed
Vignon, M., Zhou, M., McIntosh, A.R., Correa, C., Westley, P.A., Jacquin, L., et al. 2023. Trait variation in a successful global invader: a large-scale analysis of morphological variance and integration in the brown trout. Biological Invasions, 25: 6591677.CrossRefGoogle Scholar
World Tourism Organisation. 2012. Annual Report 2011. United Nations Tourism, Madrid, Spain.Google Scholar
Figure 0

Figure 1. Map of Southern Thailand showing the localities where the specimens were collected in Chumphon, Surat Thani, Nakhon Si Thammarat, and Satun provinces.

Figure 1

Table 1. The geographic locations and details of the sand fly collection sites, which were caves in Southern Thailand

Figure 2

Figure 2. Idiophlebotomus asperulus female: A, antennal segments A3 to A5; B, spermathecae; C, pharynx; D, cibarium; E, epipharynx; F, palpal segment 1 to 5; and G, hindleg.

Figure 3

Figure 3. The abdomen of sand flies: A, spermathecae in a female sand fly and B, styles of a male sand fly.

Figure 4

Table 2. A comparison of the means and standard deviations of the morphometric characteristics of female Idiophlebotomus asperulus. The significant P-values were based on the results of the analysis of variance (*) and Kruskal–Wallis (§) test

Figure 5

Table 3. The structure matrix of the morphometric features of female Idiophlebotomus asperulus chosen using canonical discriminant analysis. The samples were collected from tourist caves in four provinces, namely, Surat Thani, Nakhon Si Thammarat, Satun, and Chumphon, in Southern Thailand

Figure 6

Figure 4. The canonical discriminant analysis results of the measured characteristics of Idiophlebotomus asperulus collected from Chumphon (black), Nakhon Si Thammarat (teal), Satun (red), and Surat Thani (blue).

Figure 7

Table 4. The leave-one-out cross-validation of all the samples used in the canonical discriminant analysis of the morphological characteristic measurements of Idiophlebotomus asperulus collected from tourist caves in four provinces, namely, Surat Thani, Satun, Chumphon, and Nakhon Si Thammarat, in Southern Thailand