Phlebotomine Sand-flies PDF

Summary

This PDF document describes the Phlebotomine sand-flies, including their morphology and life cycle. It details the medically important species, their role in transmitting leishmaniasis and other viruses, and their external morphology.

Full Transcript

5
Phlebotomine sand-flies
(Phlebotominae)

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 94 Phlebotomine sand-flies (Phlebotominae)

There are approaching 1000 species of sand-flies in six genera, within
the subfamily Phlebotominae of the family Psychodidae. Species in three
genera – Phlebotomus, Lutzomyia and Sergentomyia – suck blood from
vertebrates; the former two are the more important as they contain dis-
ease vectors. The genus Phlebotomus occurs only in the Old World, from
southern parts of the northern temperate areas, mainly the Mediterranean
region, to central Asia, and in tropical areas, but there are not many species
in sub-Saharan Africa or South-east Asia and none in the Pacific area. Most
Phlebotomus species inhabit semiarid and savannah areas in preference to
forests. Lutzomyia species are found only in the New World, and, by con-
trast, occur mainly in forested areas of Central and South America.
Sergentomyia species are also confined to the Old World, being found
mainly in the Indian subregion, sub-Saharan Africa and Asia. Although a
few species bite people they are not vectors.
Adult flies are often called sand-flies because of their colour. However,
this can be confusing because in some parts of the world the small biting
midges of the family Ceratopogonidae (Chapter 6) and black-flies (Simuli-
idae, Chapter 4) are called sand-flies. The medically most important species
include Phlebotomus papatasi, P. sergenti, P. argentipes, P. ariasi, P. perniciosus
and species in the Lutzomyia longipalpis and L. flaviscutellata complexes.
In both the Old and New Worlds sand-flies are vectors of leishmaniasis
and viruses responsible for sandfly fever, and in the Andes the bacterium
Bartonella bacilliformis, causing bartonellosis (Carrión’s disease).

5.1 External morphology
Adults of Phlebotomus and Lutzomyia are difficult to distinguish, but as the
former genus is found only in the Old World and the latter in the New
World this is not a problem.
Adult phlebotomine sand-flies are readily recognized by their minute
size (1.5–3.5 mm in length), hairy appearance, relatively large black eyes
and their long and stilt-like legs (Plate 6). The only other blood-sucking
flies which are as small as this are some species of biting midges (Cer-
atopogonidae), but these have non-hairy wings and differ in many other
details (Chapter 6). Phlebotomine sand-flies have the head, thorax, wings
and abdomen densely covered with long hairs. The 16-segmented anten-
nae are long and composed of small bead-like segments having short hairs;
antennae are similar in both sexes. The mouthparts are short and inconspic-
uous and adapted for blood-sucking, but only females bite. At their base is
a pair of five-segmented maxillary palps which are relatively conspicuous
and droop downwards.
Wings are lanceolate in outline and quite distinct from the wings of other
biting flies. The Phlebotominae can be distinguished from other subfami-
lies of the family Psychodidae, which they may superficially resemble, by
their wings. In sand-flies the wings are held at an angle of about 40! over

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 Life cycle 95

Figure 5.1 Adult male phlebotomine sand-fly showing genital claspers
at end of abdomen, and a diagrammatic representation of the double
branching of wing vein 2.

the body when the fly is at rest or blood-feeding, whereas in non-biting psy-
chodid flies they are folded, roof-like, over the body or flat. Wing venation
also differs. In phlebotomine sand-flies, but not in the other subfamilies
of Psychodidae, vein 2 branches twice, although this may not be apparent
unless most of the hairs are rubbed from the wing veins (Fig. 5.1).
The abdomen is moderately long and in the female more or less rounded
at the tip. In males it terminates in a prominent pair of genital claspers (Fig.
5.1) which give the end of the abdomen an upturned appearance.
Identification of adult phlebotomine sand-flies to species is difficult and
usually necessitates the examination of internal structures, such as the
arrangement of the teeth on the cibarial armature, the shape of the sper-
matheca in females, and in males the structure of the external genitalia
(terminalia).

5.2 Life cycle
The minute eggs (0.3–0.4 mm) are more or less ovoid in shape and usually
brown or black, and careful examination under a microscope reveals that
they are patterned, as shown in Figure 5.2. Some 30–70 eggs are laid singly
at each oviposition. They are thought to be deposited in small cracks and
holes in the ground, at the base of termite mounds, in cracks in masonry, on
stable floors, in poultry houses, amongst leaf litter and in between buttress-
roots of forest trees, etc. The type of oviposition site presumably varies
greatly according to species.
Although eggs are not laid in water they require a microhabitat with high
humidity. They are unable to withstand desiccation and hatch after 4–20

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 96 Phlebotomine sand-flies (Phlebotominae)

Figure 5.2 Egg of a phlebotomine sand-fly showing mosaic-type pat-
tern, and a larva with matchstick hairs and caudal setae.

days, although hatching may likely be delayed in cooler weather. Larvae are
mainly scavengers, feeding on organic matter such as fungi, decaying forest
leaves, semi-rotting vegetation, animal faeces and decomposing bodies of
arthropods. Although some species, especially of the genus Phlebotomus,
occur in semiarid areas, the actual larval habitats must have a high degree
of humidity. Larvae may be able to survive by migrating to drier areas if
their breeding places are temporarily flooded.
There are four larval instars. The mature larva is 3–6 mm long and has a
well-defined black head which is provided with a pair of small mandibles;
the body is white or greyish and 12-segmented (Fig. 5.2). Ventrally the
abdominal segments have small pseudopods, but the most striking feature
is the presence on the head and all body segments of conspicuous thick
bristles with feathered stems, which in many species have slightly enlarged
tips. They are called matchstick hairs and identify larvae as those of phle-
botomine sand-flies. In most species the last abdominal segment bears two
pairs of conspicuous long hairs called the caudal setae. First-instar larvae
have two single bristles, not two pairs.
Larval development is usually complete after 20–30 days’ duration
depending on species, temperature and availability of food. In temperate
areas and arid regions species may overwinter as diapausing fully grown
larvae. Prior to pupation the larva assumes an almost erect position in the
habitat, the skin then splits open and the pupa wriggles out. The larval skin
is not completely cast off but remains attached to the end of the pupa. The
presence of this skin, with its characteristic two pairs of caudal bristles, aids
in the recognition of the phlebotomine pupa. The pupal shape is as shown
in Figure 5.3. Adults emerge from the pupae after about 6–13 days. The life
cycle, from oviposition to adult emergence, is 30–60 days, but extends to
several months in some species with diapausing larvae. In temperate areas
adults die off in late summer or autumn and species overwinter as lar-
vae, with the adults emerging the following spring. It is usually extremely

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 Life cycle 97

Figure 5.3 Pupa of a phlebotomine sand-fly with larval skin still
attached.

difficult to find larvae or pupae of sand-flies, and relatively little is known
about their biology and ecology.

5.2.1 Adult behaviour
Both sexes feed on plant juices and sugary secretions but females in addi-
tion suck blood from a variety of vertebrates, including livestock, dogs,
urban and wild rodents, snakes, lizards and amphibians; a few species
feed on birds. Females of many Phlebotomus species in the Old World and
Lutzomyia species in the New World bite mammals, including humans. Bit-
ing is usually restricted to crepuscular and nocturnal periods but people
may be bitten during the day in darkened rooms, or in forests during over-
cast days. Most species feed out of doors (exophagic) but some species also
feed indoors (endophagic). A few species are autogenous, that is they can
lay eggs without blood-feeding.
Adults are weak fliers and usually disperse 100 metres or less from their
breeding places. Consequently biting is often very localized. However,
adults of at least some species have been known to fly up to 2.2 km over a
few days. When close to a host sand-flies may have a characteristic hopping
type of flight, so that there may be several short flights and landings before
females settle on a host. Even a light wind inhibits flight activities and
biting. Because of their very short mouthparts sand-flies are unable to bite
through clothing.
During the day adult sand-flies rest in sheltered, dark and humid sites,
but on dry surfaces, such as on tree trunks, on ground litter and foliage of
forests, in animal burrows, termite mounds, tree-holes, rock fissures, caves,
cracks in the ground and inside human and animal habitations. Species that
commonly rest in houses (endophilic) before or after feeding on humans
are often referred to as domestic or peridomestic species. Examples are

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 98 Phlebotomine sand-flies (Phlebotominae)

Phlebotomus papatasi in the Mediterranean area, P. argentipes in India and
the Lutzomyia longipalpis complex in South America.
In temperate areas of the Old World sand-flies are seasonal and adults
occur only in the summer months. In tropical areas some species are com-
mon more or less throughout the year, but in other species there may be
well-marked changes in abundance of adults related to the dry and wet
seasons.

5.3 Medical importance

5.3.1 Annoyance
About 70 species are vectors of disease to humans, but apart from their
importance as vectors, sand-flies may constitute a serious, but usually
localized, biting nuisance. In previously sensitized people their bites may
result in severe and almost intolerable irritations, a condition known in the
Middle East as harara.

5.3.2 Leishmaniasis
Leishmaniasis is a term used to describe a number of closely related dis-
eases caused by about 20 distinct species, subspecies and strains of Leishma-
nia parasites in approximately 90 countries. The three main clinical forms
are cutaneous, mucocutaneous and visceral leishmaniasis. A fourth, less
common form is diffuse cutaneous leishmaniasis, while post-kala-azar der-
mal leishmaniasis is caused by Leishmania donovani donovani following cure
of the initial visceral form. The epidemiology of leishmaniasis is complex,
involving not only different parasite species but different strains of para-
sites and different reservoir hosts.
Basically amastigote parasites ingested by female sand-flies with a
blood-meal multiply in the gut and develop into promastigotes, which
are elongate, have a flagellum and attach to the mid-gut or hind-gut wall
and multiply rapidly. Many, however, are voided when the fly defecates.
After further development the survivors migrate to the anterior part of
the mid-gut and then to the fore-gut. Here some parasites become meta-
cyclic forms. Four to twelve days after the sand-fly has taken an infec-
tive blood-meal the metacyclic forms are found in the mouthparts, and
are introduced into a new host during feeding. Infective flies often probe
more often than uninfected flies, thus maximizing transmission of para-
sites during blood-feeding. Previous feeding by females on sugary sub-
stances, mostly obtained from plants, is essential not only for the survival
of the sand-fly but also for the development of the parasites to the infective
form.
Most types of leishmaniasis are zoonoses. The degree of involvement
of humans varies greatly from area to area. The epidemiology is largely
determined by the species of sand-flies, their ecology and behaviour, the

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 Medical importance 99

availability of a wide range of non-human hosts, and also by the species and
strains of Leishmania parasites. In some areas, for example, sand-flies will
transmit infections almost entirely among wild or domesticated animals,
with little or no human involvement, whereas elsewhere animals may be
important reservoir hosts of infection for humans. In India the disease
may be transmitted between people by sand-flies, with animals taking no
identifiable part in its transmission. The epidemiology of the leishmaniases
is complex, and only simplified accounts are given below.

Cutaneous leishmaniasis (CL)
In the Old World, CL is known also as oriental sore. It occurs mainly
in arid areas of the Middle East to north-western India and central Asia,
in North Africa and various areas in East, West and southern Africa. The
principal parasites are Leishmania major, transmitted mainly by Phlebotomus
papatasi, and Le. tropica, transmitted by P. sergenti. Leishmania major is usually
zoonotic and in most of its range gerbils (e.g. Rhombomys opimus) are the
reservoir hosts; Le. tropica occurs in densely populated areas and humans
appear to be the main reservoir hosts. In the New World, CL is found mainly
in forests from Mexico to northern Argentina, and is caused by Leishmania
braziliensis, Le. amazonensis and Le. mexicana. Rodents and dogs appear to
be reservoir hosts. Vectors include Lutzomyia wellcomei and L. flaviscutellata.

Mucocutaneous leishmaniasis (ML) (espundia)
A severely disfiguring disease found from Mexico to Argentina. It is mainly
caused by Leishmania braziliensis. Dogs may be reservoir hosts. Lutzomyia
wellcomei is an important vector.

Diffuse cutaneous leishmaniasis (DCL)
A form that causes widespread cutaneous nodules or macules over the
body. It is confined to Venezuela and the Dominican Republic and the
highlands of Ethiopia and Kenya. In South America the parasite is Le. ama-
zonensis transmitted by Lutzomyia flaviscutellata and spiny rats (Proechimys
species) are reservoir hosts. In Ethiopia and Kenya the parasite is Le.
aethiopica, transmitted by Phlebotomus pedifer and P. longipes, with rock
hyraxes (Procavia capensis) as reservoir hosts.

Visceral leishmaniasis (VL)
Often referred to as kala-azar. It is caused by Leishmania donovani donovani
in most areas of its distribution, such as India, Bangladesh, Sudan, East
Africa and Ethiopia. Among the vectors are P. argentipes and P. orientalis.
Rodents, wild cats and genets (Genetta genetta) may be reservoir hosts. In
the Mediterranean basin, Iran and central Asia, including northern and
central China, Leishmania donovani infantum is the parasite, and the vec-
tors include P. ariasi and P. perniciosus. Dogs and foxes (Vulpes vulpes) are

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 100 Phlebotomine sand-flies (Phlebotominae)

reservoir hosts. Visceral leishmaniasis also occurs sporadically in Central
and South America, where the parasite is Leishmania donovani infantum (Le.
chagasi of some authors), transmitted by species in the Lutzomyia longipalpis
complex.

5.3.3 Bartonellosis
Bartonellosis, sometimes called Oroya fever or Carrión’s disease, is encoun-
tered in arid mountainous areas of the Andes, mainly in Peru, but also in
Ecuador and Colombia. It is caused by the bacterium Bartonella bacilliformis
and is transmitted by Lutzomyia verrucarum and probably by other Lut-
zomyia species, such as L. colombiana in Colombia. Transmission is possibly
only by contamination of the mouthparts.

5.3.4 Sandfly fevers
Sand-flies transmit the seven viral serotypes responsible for sandfly fevers,
also called papataci fever (sometimes spelt papatasi or pappataci fever),
three-day fever or Phlebotomus fevers. The classical form of the disease
is found in the Mediterranean region, but also extends up the Nile into
Egypt, and from the Middle East to northern India, Pakistan, Afghanistan
and probably China. The most important vector is P. papatasi. Other forms
of the virus in Central and South America are transmitted by Lutzomyia
species such as L. trapidoi.
Female sand-flies become infective 7–10 days after taking a blood-meal.
Infected females lay eggs containing the virus and these eventually give rise
to infected adults. This is an example of transovarial transmission, a phe-
nomenon that is more common in the transmission of various tick-borne
diseases (Chapters 16 and 17). There are probably mammalian reservoir
hosts.

5.4 Control
Although phlebotomine sand-flies are very susceptible to insecticides,
until recently there have been few organized attempts to control them.
However, in most areas where house-spraying has been used to control
Anopheles vectors there have been large reductions in sand-fly populations
followed by interruption of leishmaniasis transmission. When houses in
Kabul, Afghanistan, and in the Peruvian Andes were sprayed with the
pyrethroid lambda-cyhalothrin cutaneous leishmaniasis was reduced by
60% and 54% respectively. In Venezuela spraying houses with lambda-
cyhalothrin substantially reduced the vector (Lutzomyia ovallesi) of cuta-
neous leishmaniasis.
Obviously where sand-flies bite and rest out of doors house-spraying
will have little effect. However, if the outdoor resting sites are known (e.g.
animal shelters, stone walls, tree trunks, termite hills) they can be sprayed

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 Further reading 101

with residual insecticides. Insecticidal fogging of outdoor resting sites may
also give some, but temporary, control of vectors.
Personal protection can be achieved by applying efficient insect repel-
lents such as DEET, piperidene-based ones and 2–5% neem oil. Mesh
screens or nets with very small holes can give protection, but they reduce
ventilation and cause it to be unpleasantly hot in screened houses or
under sand-fly bed-nets. However, such nets, or even mosquito nets with
larger holes, can be impregnated with pyrethroids (e.g. permethrin and
deltamethrin) to give protection against biting for up to 6–12 months. In
Afghanistan and Syria insecticide-treated polyester bed-nets gave good
protection against cutaneous leishmaniasis (Le. tropica transmitted by Phle-
botomus sergenti).
In some countries there is a combined campaign of insecticidal spraying
of houses and the distribution of insecticide-treated bed-nets, a strategy
which targets both Anopheles mosquitoes and sand-flies (see control mea-
sures, Chapter 2).
Control of sand-fly larvae remains impossible because the breeding sites
of most species are unknown.
Because most leishmaniasis transmission involves reservoir hosts, such
as rodents and dogs, attempts have been made to destroy them. In China
leishmaniasis was effectively eliminated in the 1950s by killing dogs, but
although similar culls have been made in parts of Brazil and the Mediter-
ranean region results have been disappointing. Dogs have sometimes been
dipped or sprayed with pyrethroids such as deltamethrin, but repeated
treatments, typically every 2–3 months, are needed. Deltamethrin-treated
collars on dogs, which can remain effective for 8 months, have also given
good, albeit local, control of Le. donovani infantum in Italy and Iran. Trials
in the Mediterranean with a new vaccine against visceral leishmaniasis
have proved promising in protecting dogs, thus reducing the numbers of
reservoir hosts. In Russia and Jordan zoonotic cutaneous leishmaniasis has
been controlled by destroying rodent colonies, but elsewhere results have
not been encouraging.
Insecticide resistance to DDT has been found in P. papatasi and P. argen-
tipes in India, and greater tolerance or resistance to several insecticides,
such as pyrethroids, has been reported in other sand-flies.
In 2005 India, Bangladesh and Nepal signed an agreement to eliminate
visceral leishmaniasis from the Indian subcontinent, mainly by integrated
vector control.

Further reading
Alexander, B. and Maroli, M. (2003) Control of phlebotomine sandflies.
Medical and Veterinary Entomology, 17, 1–18.

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