Studies
on the mosquito populations from Coimbatore, Tamil Nadu, India
K. Manimegalai
Department of Zoology, Avinashilingam University for Women,
Coimbatore, Tamil Nadu 641043, India
Email: manijeysu@gmail.com
Date of publication (online): 26 June 2010
Date of publication (print): 26 June 2010
ISSN 0974-7907 (online) | 0974-7893 (print)
Editor: R. Ramanibai
Manuscript details:
Ms
# o2304
Received
03 September 2009
Final
revised received 26 May 2010
Finally
accepted 27 May 2010
Citation: Manimegalai, K. (2010). Studies on the mosquito
populations from Coimbatore, Tamil Nadu, India. Journal of Threatened Taxa 2(6): 961-969.
Copyright: © K. Manimegalai 2010. Creative Commons
Attribution 3.0 Unported License. JoTT allows unrestricted use of this
article in any medium for non-profit purposes, reproduction and distribution by
providing adequate credit to the authors and the source of publication.
Author Details: K. Manimegalai is a Reader specializing in mosquito
populations, taxonomy based on morphometry and geometry using modern tools like
wing shape analysis, PCR studies and other biotechnological studies.
Acknowledgements: I
thank Dr. M. Arunachalam for his help in data analysis.
Abstract: Mosquito prevalence was studied in three areas of Coimbatore
City, Tamil Nadu viz., North Coimbatore, Gandhipuram and Kavundampalayam. Culex quinquefasciatus, C. pseudovishnu, C. gelidus and Armigeres subalbatus are prevalent in the study area. Results indicated that C. quinquefasciatus was the predominant species in North Coimbatore followed by C. pseudovishnu, whereas A. subalbatus was the predominant species both
in Gandhipuram and Kavundampalayam areas.
Keywords:Armigeres subalbatus, Culex pseudovishnu, Culex quinquefasciatus, Coimbatore
City, Diptera, Gandhipuram, meterological parameters, population dynamics.
INTRODUCTION
Diptera represents one of the
largest orders of insects with more than 85,000 species including a large
number of disease vectors. Prominent among these are mosquitoes, which are placed under the
suborder Nematocera and family Culicidae. More than 3100 species of mosquitoes belonging to 34 genera
have been recorded under three subfamilies, namely, Anophelinae, Culicinae and
Toxorhynchitinae (Knight & Stone 1977). Among insect pests mosquitoes are considered “Public Enemy
Number One” for humans owing to their biting and blood feeding habits and their
role as vectors of diseases including filariasis, malaria, yellow fever, dengue
fever and Japanese encephalitis (WHO 1996).
The most important disease
transmitting and nuisance causing mosquitoes belong to the genera Anopheles, Culex, Aedes,
Mansonia, Haemogogus, Sabithes and Psorophora. In India, the various species of Anopheles, Culex, Aedes and Mansonia are important as carriers of
diseases. Malaria, Filariasis,
Japanese Encephalitis (JE), Dengue fever and Dengue Haemorrhagic Fever (DHF)
are the major mosquito borne diseases in India (William 2000).
Culex spp. occurin all climatic zones ranging from forest to semi desert zones. Altitude does
not seem to limit distribution, since they are observed at elevations of 2770
to 5500 m in India and also in mines at depths of 1,250m below the sea level
(Bhat 1975; Renapurkar et al. 2001). At lower elevations, C. quinquefasciatus populations occur in high numbers
with relatively little seasonal variation, although high numbers are found
during the third quarter of the year. In contrast at middle (≈ 600-1000 m) and high elevations (≈ 1300-1500m)
mosquito densities are much lower with well pronouncedseasonal variations (Lapointe 2000).
Urbanization is a continuous
process in developing countries like India and this has naturally led to
aggregation of population. Further, due to rapid industrialization, large numbers of labourers
migrate from rural to urban areas in search of job opportunities. This has resulted in the development of
many slums with no proper sanitary and waste waterdisposal arrangements. Due to
unplanned town expansions, the peripheral areas of towns bordering villages
have become semi-urbanized and this process continues unchecked. The results are environmental changes
including the creation of water bodies highly conducive for the breeding of
mosquitoes. The increasing
breeding potential of these ubiquitous mosquitoes can thus be attributed to the
development process (Rajagopalan & Das 1988).
MATERIALS AND METHODS
Coimbatore is located at the
foothills of the Western Ghats a mega biodiversity hotspot. It is the third largest city in Tamil
Nadu located at 10050’-11002’N & 76056’-77001’E. The city has an average elevation of
442m above the mean sea level. The
total area of Coimbatore City is 1287km2 with a population of
9,40,000 (Census of India 2001).
The Sanganoor Canal originates in
the Western Ghats, (Kuridimalai Hills) and flows from west to east entering
Coimbatore at the Coimbatore-Mettupalayam Road and flows for about 10km within
the city. It is a major open
drainage system which has intricate linkage with the
storm water supply, domestic sewage and industrial effluent disposal.
Gandhipuram is a commercial
neighbourhood located at the heart of the city, while Kavundampalayam and North
Coimbatore are located on the Mettupalayam Road. These highly populated residential areas with open drainage
were selected for the study.
Fortnightly collections of adult
mosquitoes were made from November 1999 to October 2001 using mosquito sweep
nets. Collected mosquitoes were
anaesthetized using chloroform, examined under stereo binocular microscope
(Carl Zeiss stemi dv4) and sorted. Identification is based on Christophers (1933) and Barraud (1934).
During the study period
meteorological parameters such as temperature, relative humidity and rainfall
were also recorded. Daily
meteorological data were collected from the Meteorological Department, Tamil
Nadu Agriculture University, Coimbatore.
Statistical analysis
Meteorological factors and mosquito
population estimates were subjected to correlation and multiple regression
analyses. Data were also subjected
to Canonical Correspondence Analysis (CCA) to study the pattern of variation in
the populations and summarize multivariate data in scatter diagram. A canonical ordination technique was
used to explain the patterns of variation in mosquito species with the
environmental variables by combining regular ordination with aspects of
regression (Jongman et al. 1987). In the present study population data for mosquito species was assessed
along with environmental variables such as maximum and minimum temperature (0C),
relative humidity (%) at 0722hr and at 1422hr, and rainfall (mm). CCA was carried out using the software
PAST (Palaeontological Statistics Software package for education and data
analysis, a free ware).
RESULTS
Population Studies
During the study period 13 species
were recorded in the three localities of North Coimbatore, Gandhipuram and
Kavundampalayam. Of these four species Culex. quinquefasciatus,
C. pseudovishnu, C. gelidus and Armigeres subalbatus were recorded throughout the period of two years while nine
species C. vishnu, C. tritaeniorhynchus, C. bitaeniorhynchus, A.
albopictus, A. vittatus, A. aegypti, A. vexans, A. subpictus and A. vagus were recorded less frequently and
only during certain periods.
Culex quinquefasciatus was the predominant species in
North Coimbatore and showed a trend of increase in February 2000 (34) with a
peak in October 2001 (42). Maximum number of C. pseudovishnu wererecorded in November 1999 and January 2000 (30). Population of A. subalbatus peaked in July 2001 (20). Compared to North Coimbatore the population of C. quinquefasciatus was less in Gandhipuram (Figs.
1-10). Population of A. subalbatus peaked in January 2000 (42) and
moderate numbers were recorded during March 2000 (26), February 2000 (19),
October 2000 and September 2001 (18).
Observations made in
Kavundampalayam area showed that maximum number of C. quinquefasciatus was in May 2000 (18) and the
minimum in August 2000 (4), February and April 2001 (4). However, A. subalbatus registered high densities in March
2000 (47) and in February 2001 (39). A comparative analysis of the four species in the three localities of
North Coimbatore, Gandhipuram and Kavundampalayam indicated that C. quinquefasciatus was the predominant species in
North Coimbatore followed by C. pseudovishnu, whereas A. subalbatus was the predominant species in both Gandhipuram and
Kavundampalayam areas.
Statistical Analysis
Correlation and regression analysis
showed no relationship between mosquito populations and meteorological
parameters when data were subjected to area-wise correlation analysis (Table
1). Population
of C. quinquefasciatusfrom Gandhipuram were found to decrease with increasing maximum
temperature (31.890C). C. pseudovishnu in Gandhipuram
showed a similar trend, with a decrease in population density with an increase
in maximum temperature. The
relationship between the mosquito population of A. subalbatus from North Coimbatore and maximum
temperature was more pronounced. Among the four species of mosquitoes, C. pseudovishnu in North Coimbatore and A. subalbatus in Gandhipuram showed an increase in population density with a
decrease in minimum temperature (21.750C) and a significant negative
correlation was observed between these two parameters. Study of mosquito population in
relation to humidity (0722hr) indicated that numbers of C. pseudovishnu from North Coimbatore showed a
positive relationship with humidity. A similar positive correlation with humidity was recorded for A. subalbatus in Gandhipuram and C. pseudovishnu and A. subalbatus from Gandhipuram. Of the four species observed, C. quinquefasciatus numbers in North Coimbatore showed
a positive correlation with rainfall. For the other areas, rainfall had no significant effect on mosquito
populations. Numbers of C. gelidus were not found to be significantly
associated with environmental variables.
Canonical Correspondence
Analysis
Distribution of mosquito species in
relation to environmental variables like maximum temperature (0C)
and minimum temperature (0C), relative humidity (%) at 0700hr and at
1400hr and rainfall (mm) were analyzed by ordination based on canonical
correspondence analysis for two years (November 1999 to October 2001) in the
three study areas, North Coimbatore, Gandhipuram and Kavundampalayam (Fig. 10). A positive relationship with humidity
(0722hr) was observed in Gandhipuram for A. subalbatus, and with maximum temperature for C. pseudovishnu and C. gelidus in North Coimbatore. Most of the clusters are clumped together in the base, showing the low
importance of seasons (Fig. 1). A. subalbatus showed a positive relationship with
humidity (1422hr) in North Coimbatore and also a positive relationship with
humidity (0722hr) in Gandhipuram. In Gandhipuram C. pseudovishnu had a positive relationship with rainfall. C. quinquefasciatus in
Kavundampalayam and North Coimbatore area showed more inclination towards
minimum temperature. Most of the
clusters are clumped together in the base exhibiting the less importance of
seasons (Fig. 10).
Discussion
During the study period, 13 species
were recorded in the three test localities. Of these four species, C. quinquefasciatus, C.
pseudovishnu, C. gelidus and A. subalbatus were recorded throughout the period of two years. However, nine species, viz., C. vishnu, C.
tritaeniorhynchus, C. bitaeniorhynchus, A. albopictus, A. vittatus, A. aegypti,
A. vexans, A. subpictus and A. vagus were recorded less frequently which agrees with the established
fact of seasonal occurrence of mosquitoes (Bosgelmez et al. 1994, 1995).
In the present study C. quinquefasciatus was found to be the predominant
species in North Coimbatore, whereas A. subalbatus was the predominant species in Gandhipuram and Kavundampalayam
closely followed by C. quinquefasciatus. The high prevalence
of A.
subalbatus and Culex species in Gandhipuram and
Kavundamapalayam may be attributed to the presence of open sewage canals and
closeness to Sanganoor channel into which sewage is discharged at various
points in its course. These
polluted waters offer an ideal breeding ground for mosquitoes. Similar observations have been made by
Amerasinghe (1982) who found A. subalbatus breeding commonly in polluted ground water collections as well as
in container habitats like tree holes and bamboo stumps.
Studies on
population dynamics of mosquito species have been undertaken by several
investigators(Alten et al. 2000; Gleiser, et al. 2000; Ahumada et al. 2004; Simsek 2003,
2004). According to Alten et al.
(1997), the highest number of mosquitoes was found during summer and autumn and
less number during winter and early spring. Similar observations were made by
Bosgelmez et al. (1995) who recorded highest numbers of species during early
summer especially in June, with the total number of adults collected increasing
from June to September and decreasing in October. Contrary to this observation in the present investigation highest
numbers were recorded invariably in January to March and October to December which might be due to the prevailing monsoonal
pattern.
Rao et al.
(1981), Dash et al. (1998)and Dixit et al. (2002) observed a low density of C. quinquefasciatus in May and a high density in
February in East Godavari District of Andhra Pradesh. Similar high density had been observed in North Coimbatore
in the month of February in the present study. However, in the other two areas high density was recorded in
November to December. Dhar et al.
(1968) also recorded high densities in November to December.
Population studies on A. subalbatus are meagre. In the present study
peak population was recorded invariably from January to March and population
was comparatively low in May to August in both Gandhipuram and Kavundampalayam. C. pseudovishnu population was abundant in North
Coimbatore area and highest density was recorded in November 1999 and January
2000. In Gandhipuram and
Kavundampalayam low density was observed throughout the study period. According to Joshi & Bansal (1991),C.
pseudovishnu prefers
outdoor habitats where both temperature and relative humidity are high. In the
present study C. pseudovishnu numbers were higher when the temperature was optimum in a range of
29.21 to 29.41 0C and humidity ranging from 89-91 %.
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