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Distribution of Aedes albopictus (Diptera, Culicidae) in southwestern Pacific countries, with a first report from the Kingdom of Tonga

Laurent Guillaumot1*, Reynold Ofanoa2, Lucien Swillen3, Narendra Singh4, Hervé C Bossin5 and Francis Schaffner6

Author Affiliations

1 Institut Pasteur de Nouvelle Calédonie, 9–11 Avenue Paul Doumer, Association Pasteur International Network ,Nouvelle-caledonie, Noumea, BP 61, 98845, New Caledonia

2 Ministry of Health, Nuku’alofa, Kingdom of Tonga

3 Retired WHO Technical Officer, Tontouta, New Caledonia

4 Secretariat of the Pacific Community, Suva, Fiji

5 Institut Louis Malardé, Papeete, Tahiti, French Polynesia

6 Institute of Parasitology, University of Zurich, Zurich, Switzerland

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Parasites & Vectors 2012, 5:247  doi:10.1186/1756-3305-5-247


The electronic version of this article is the complete one and can be found online at: http://www.parasitesandvectors.com/content/5/1/247


Received:5 October 2012
Accepted:31 October 2012
Published:6 November 2012

© 2012 Guillaumot et al.; licensee BioMed Central Ltd.

This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Background

Aedes (Stegomyia) albopictus is currently one of the most notorious globally invasive mosquito species. Its medical importance is well documented, and its fast expansion throughout most continents is being monitored with concern. It is generally assumed that its expansion through the Western Pacific island countries has not progressed since its establishment in Fiji in 1989. However, the current status of Ae. albopictus in the Pacific region is largely unknown.

Findings

According to data from the literature and our own observations, Ae. albopictus is currently present in the following countries of the southern Pacific region: Papua New Guinea, Solomon Islands, Fiji, and the Kingdom of Tonga, where it was first detected in July 2011. It is absent from New Caledonia and French Polynesia where routine entomological surveillance is carried out, and was not detected during entomological work in 2007, either on the Cook Islands or on the Wallis and Futuna Islands. The species was not reported from American Samoa in 2004, but it is mentioned as probably present in Vanuatu. This is the first report of Ae. albopictus in Tonga.

Conclusions

The introduction and establishment of Ae. albopictus in Tonga was expected due to the geographical proximity of this country to Fiji where the species is strongly established. The pathway of introduction is unknown. The expansion of Ae. albopictus in the Pacific region poses an increasing threat to public health given the role this mosquito plays as primary vector of emerging infectious diseases such as Chikungunya fever.

Keywords:
Aedes albopictus; Vector; Distribution; Pacific islands; Tonga; Introduction

Background

The “Asian tiger mosquito” Aedes (Stegomyia) albopictus (Skuse, 1895) is nowadays the most notorious invasive Culicidae. From its native range in Asia, the species has spread throughout the Americas, Europe and Africa, mainly via international trade in used tires [1]. Its capacity to transmit a large number of arboviruses is well documented. Although less efficient than Aedes aegypti for the dengue viruses transmission, it was responsible for large dengue epidemics in Japan in 1942–1945 [2], for the DEN-1 outbreak in Hawaii in 2001 [3] and for the DEN-2 outbreaks in La Reunion in 1977–78 and 2004 [4,5]. Being the sole vector of the severe chikungunya epidemic in La Reunion and other islands of the Indian Ocean in 2005–06 [6], Ae. albopictus was also responsible for a chikungunya outbreak in Italy in 2007 [7] as well as for local chikungunya and dengue transmissions in Southern France in 2010 [8]. Aedes albopictus is suspected to play a prominent role in outbreaks of these two diseases in Central Africa [9] and in addition, it is a potential vector of many other arboviruses, including yellow fever, as can be deduced from laboratory experiments [10,11]. Although the species efficiently transmits the dog heartworm Dirofilaria immitis[12], it is a poor vector of human filariasis [13].

The distribution of Ae. albopictus across the Pacific Island Countries and Territories (PICTs) is patchy. Several islands of the Northern hemisphere like Taiwan and the Japanese islands are part of its native area. However, it is not present on other Northern Pacific islands like Yap in the Federated States of Micronesia, despite continuous traffic of passengers and goods including tires from the neighboring Guam where Ae. albopictus is abundant. In Yap, the local Stegomyia species Aedes hensilli seems to prevent its establishment [14], possibly echoing John Belkin’s 1962 statement: “Aedes albopictus does not occur in the South Pacific. It is unlikely that it will become established, for it does not seem to be able to compete with other members of the scutellaris group” [15]. Indeed, an intentional introduction of Ae. albopictus on a Tuamotu atoll in an attempt to displace the local filariasis vector Aedes polynesiensis failed [13]. Eventually, Ae. albopictus was reported in Papua New Guinea in 1970[16], in The Solomon Islands in 1979 [17], but only in 1989 in another South Pacific country, namely Fiji [18]. No other introduction has been reported in any other South Pacific island country since then.

A list published in 1995 [19] to which various authors are referring mentions its presence in 11 countries/territories of this region. We assume this is/was not substantiated since (1) the sources are not mentioned, (2) except for the countries previously mentioned, we were unable to find any ancient or recent corroborating data in the literature, and (3) most of the reports do not match our observations.

Here, we describe and discuss the situation with regard to Ae. albopictus in all PICTs of the southern hemisphere, and we report the first finding of the species in the Kingdom of Tonga (Figure 1).

thumbnailFigure 1. Map of the South Pacific Ocean. Modified from WHO with permission.

Findings

The overall situation in the PICTs is summarized in Table 1 and more details are given below, except for countries where Ae. albopictus is known to have been established for a long time (Fiji, Papua New Guinea, Solomon Islands).

Table 1. Status of Aedes albopictus in the 17 South Pacific island countries and territories

    In New Caledonia
, the species is currently absent. Routine mosquito surveillance, aiming at monitoring dengue and chikungunya vector populations and detecting invasive species around ports of entry (harbor and airport), is carried out using regular larval and adult collections (sticky ovitraps, [20], BG Sentinel® traps, Biogents, Germany) in urban and rural areas. Overall, up to 23,000 mosquitoes are identified annually. Aedes albopictus has never been recorded, either on the mainland or on the Loyalty Islands (Institut Pasteur of New Caledonia – IPNC annual reports, unpublished).

    In French Polynesia
, the species is currently absent. Mosquito sampling is frequently conducted for research or surveillance purposes on several archipelagoes (Society Islands, Tuamotu and Marquesas). Sampling is mostly done using ovitraps and BG Sentinel® traps. Aedes albopictus has not been detected so far.

    On Wallis and Futuna Islands
, entomological investigations were carried out by IPNC during a dengue outbreak in 2002 and 2003, and entomological records were updated and extended to the Horne group (Futuna and Alofi islands) in August 2007, supporting that Ae. albopictus was absent. A total of 3,918 mosquitoes, collected at all stages and in all types of environments including larval sampling in tires and other artificial and natural containers, were identified during these surveys. The prevalent mosquito species was Ae. polynesiensis, and a small population of Ae. aegypti was found in the main village. No Ae. albopictus specimens were found, either on Wallis island or on the Futuna and Alofi islands (IPNC reports, unpublished). However, no field data are available for the last 5 years.

    On Cook Islands
, the species was absent in 2007 during the last field investigation on the main island Rarotonga. A training workshop for vector surveillance and control was conducted there in collaboration with the Secretariat of the Pacific Community in September 2007. This entomological training included adult mosquito field trapping (CDC light trap and BG Sentinel® traps) and immature collection targeting container breeding species in both rural and urban settings across the island. The identified dominant species were Ae. polynesiensis and Ae. aegypti. No Ae. albopictus specimen was found. No field data are available for the last 5 years.

A survey conducted in 2004 in

    American Samoa
[21] only reported Ae. aegypti and Ae. polynesiensis. Thus, it can be assumed that Ae. albopictuswas absent from this country up to 2004. The situation is unknown regarding the 7 other countries, namely
    Kiribati, Nauru, Niue, Pitcairn, Western Samoa, Tokelau and Tuvalu
for which, to the best of our knowledge, no studies, unpublished or otherwise or papers have considered the presence of Ae. albopictus.

Regarding

    Vanuatu
, no recent specific publications have been found, but according to WHO entomologist (Dr. Chang Moh Seng, personal communication, 2011), the species probably is currently present but this needs to be confirmed.

In

    Tonga
, the species has been present, at least since 2011.Aedes albopictus specimens were collected in June 2011 as part of a training workshop held in Tonga’s capital Nuku’alofa, Immature specimens were found coexisting with Ae. aegypti in tires on the waterfront close to the main harbour, and in several types of containers in the locality of Vaiola (Table 2). One adult was captured in a BG Sentinel® trap in Vaiola (Figure 2). Morphological identification was performed using keys and descriptions from Belkin [15]. The risk of misidentification with local Stegomyia species was dealt with using complementary documents [22,23]. Some collected individuals were compared to reference specimens from other areas for further confirmation (i.e. Europe, Reunion Island). Finally, molecular confirmation was established by PCR amplification and sequencing of approximately 460 bp of the mitochondrial cytochrome oxidase I (COI) gene [24]. Sequences obtained for 4 specimens (3 females, 1 male) were >99% identical to corresponding Ae. albopictus GenBank entries. This is the first report of this species in the Kingdom of Tonga.

Table 2. Details of immature mosquito sampling in Tongatapu, 26–30 June 2011

thumbnailFigure 2. Map of Tonga showing the localities where Aedes albopictus was found. Modified from WHO with permission.

A prior larval survey conducted in 2007 on the main island of Tongatapu and in the Vava’u group revealed the presence of 8 species including Ae. aegypti and the local member of the Scutellaris group, Aedes tongae[25]. No Ae. albopictus was found at the time. Aedes albopictus and Ae. tongae can be sorted at larval stage owing to clear taxonomic differences such as the saddle, which is complete on the anal segment of Ae. tongae, but ventrally interrupted in Ae. albopictus[15,26]. This suggests a recent introduction and establishment of Ae. albopictus in Tonga.

Conclusion

Based on literature analyses and our own field investigations, the presence of Ae. albopictus is confirmed in 5 out of 17 countries and territories of the Southern Pacific Ocean (Table 1). The establishment in Tonga is not surprising due to its proximity to Fiji where Ae. albopictus has been present since 1989, and due to the intense sea and air traffic of passengers and goods between these two countries. Although the classical mode of introduction consists of the transfer of eggs through the tire trade, the invasive mosquito could also have been introduced as larvae or even adults transported in trade ships.

Combined with the emergence of mosquito-borne viruses such as chikungunya in the Pacific region [27], the establishment of Ae. albopictus in several PICTs where Ae. aegypti is already present likely increases the risk of arbovirus transmission since the former species colonizes a broader range of habitats, thus increasing the overall vector density. Consequently, regular vector surveillance to detect the introduction of Ae. albopictus into new areas should be conducted regularly in PICTs and, if occurring, appropriate vector control measures should be implemented immediately.

While the hypothesis formulated by Belkin to explain the absence of Ae. albopictus in the south Pacific region might have held true fifty years ago, the situation has dramatically changed with an increase in urbanisation and international trade at levels certainly not predictable at that time. In Fiji and now in Tonga, the presence of local Stegomyia species clearly did not prevent Ae. albopictus from establishing. Undoubtedly, the intensified trade at international and regional level means that many Pacific island countries most likely have encountered Ae. albopictus on multiple occasions. The reason why Ae. albopictus has not established in these islands is not clear. The factors driving the success or failure of the establishment of Ae. albopictus in Pacific island settings are not well understood. The study of Ae. albopictus on islands where it coexists with local Stegomyia species would shed some light on how these species cohabit. The discovery of Ae. albopictus in new PICTs is of great concern as it may be indicative of a slow but ineluctable trend of invasion through the Pacific region like in other areas of the world.

Competing interests

The authors declare having no competing interests.

Authors' contributions

LG carried out the entomological surveillance in New Caledonia, performed the investigations in Wallis and Futuna, Cook Islands and Tonga, and drafted the paper. RO contributed to the field work in Tonga. LS and NS contributed to the field work in Cook Islands and Tonga. HB carried out the entomological surveillance in French Polynesia and edited the manuscript. FS performed the morphological and molecular identification and edited the manuscript. All authors reviewed and approved the final manuscript.

Acknowledgements

The publication of these findings would not have been possible without the financial and/or organisational participation of: the Government of New Caledonia, the Government of French Polynesia, the Environment Agency of Wallis and Futuna, the Ministry of Health of Cook Islands, the Ministry of Health of Tonga, the Secretariat of the Pacific Community, and the French Development Agency. The authors also thank Dr Chang Moh Seng (WHO) for sharing information about Vanuatu, and Prof. A. Mathis for his useful comments and suggestions about the manuscript.

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