Taxonomic and evolutionary analysis of Zaprionus indianus
and its colonization of Palearctic and Neotropical regions

Leliane Silva Commar1, Luis Gustavo da Conceição Galego2, Carlos Roberto Ceron3

and Claudia Marcia Aparecida Carareto1

1Departamento de Biologia, Universidade Estadual Paulista “Júlio de Mesquita Filho”,

São José do Rio Preto, SP, Brazil.
2Departamento de Ciências Biológicas, Instituto de Ciências Exatas e Naturais,

Universidade Federal do Triângulo Mineiro, Uberlândia, MG, Brazil.
3Departamento de Química e Ciências Ambientais, Universidade Estadual Paulista

“Júlio de Mesquita Filho”, São José do Rio Preto, SP, Brazil.

Abstract

Zaprionus indianus is a dipteran (Drosophilidae) with a wide distribution throughout the tropics and temperate
Palearctic and Nearctic regions. There have been proposals to reclassify the genus Zaprionus as a subgenus or
group of the genus Drosophila because various molecular markers have indicated a close relationship between
Zaprionus species and the immigrans-Hirtodrosophila radiation within Drosophila. These markers, together with
alloenzymes and quantitative traits, have been used to describe the probable scenario for the expansion of
Zaprionus indianus from its center of dispersal (Africa) to regions of Asia (ancient dispersal) and the Americas (re-
cent dispersal). The introduction of Z. indianus into Brazil was first reported in 1999 and the current consensus is that
the introduced flies came from high-latitude African populations through the importation of fruit. Once in Brazil, Z.
indianus spread rapidly throughout the Southeast and then to the rest of the country, in association with high-
way-based fruit commerce. These and other aspects of the evolutionary biology of Z. indianus are addressed in this
review, including a description of a probable route for this species’ dispersal during its recent expansion.

Key words: alloenzyme, bioinvasion, molecular markers, phylogenetic analysis, quantitative traits.

Received: September 15, 2011; Accepted: February 28, 2012.

Introduction

A little more than 10 years ago, Zaprionus indianus

(Gupta, 1970), a drosophilid belonging to the genus

Zaprionus and the subgenus of the same name, was intro-

duced into Brazil and became a major pest affecting fig pro-

duction (Vilela, 1999) giving rise to its Brazilian common

name of fig fly. Vilela et al. (2001) and Stein et al. (2003)

provided detailed descriptions of the species immediately

after its introduction. Briefly, Z. indianus is approximately

3 mm long, has red eyes and a brown body with longitudi-

nal white bands interspersed with black bands on the back

of the head and thorax. In addition to being a human

commensal, Z. indianus is a generalist species that uses a

variety of endemic and introduced fruits as sites for mating

and oviposition (Lachaise and Tsacas, 1983; Schmitz et al.,

2007). Zaprionus indianus feeds on the bacteria and yeast

found in decomposing fruits, principally on the yeast

Candida tropicalis (Gomes et al., 2003). Based on the vari-

ous locations where this organism has been found, it is be-

lieved that Z. indianus lives on 80 host plants, making this

species the most ecologically diverse drosophilid in the

Afrotropical fauna (Yassin and David, 2010).This genera-

list characteristic is perhaps one of the principal factors

contributing to the success of Z. indianus in tropical and

subtropical regions.

There has been much speculation about the phylogen-

etic position of Z. indianus within the genus and subgenus

Zaprionus (Drosophilidae). This species has aroused great

interest in the Brazilian scientific community because of its

recent introduction and rapid dispersal, first throughout

Brazil and then across a large part of the South American

continent. These and other aspects of the evolutionary biol-

ogy of Z. indianus are addressed in this review, which in-

cludes an attempt to trace a probable route of dispersal for

this species during its recent expansion.

Phylogenetic relationships of the genus Zaprionus

The genus Zaprionus is divided into two subgenera

that are distinguished by their geographic origin: the subge-

Genetics and Molecular Biology, 35, 2, 395-406 (2012)

Copyright © 2012, Sociedade Brasileira de Genética. Printed in Brazil

www.sbg.org.br

Send correspondence to Claudia M.A. Carareto. Departamento de
Biologia, Universidade Estadual Paulista (UNESP), São José Rio
Preto, 15054-000, SP, Brazil. E-mail: carareto@ibilce.unesp.br.

Review Article



nus Anaprionus (Okada, 1990) contains 10 species from the

Oriental biogeographic region (Okada and Carson, 1983;

Wynn and Toda, 1988; Gupta and Gupta, 1991) and the

subgenus Zaprionus comprises 49 essentially Afrotropical

species (Okada and Carson, 1983; Yassin et al., 2008a,b).

Chassagnard and Tsacas (1993) classified the species of the

subgenus Zaprionus into two groups, inermis and armatus,

with the latter comprising three subgroups: armatus,

tuberculatus and vittiger. Recent phylogenetic revisions

using molecular and morphological characters have shown

Zaprionus s.s. species to be monophyletic, but both species

groups to be polyphyletic (Yassin et al., 2008a). Based on

these recent phylogenetic findings, a new classification of

the subgenus Zaprionus has been proposed and includes a

redefinition of the boundaries of the armatus and inermis

species groups. The vittiger subgroup was upgraded to the

level of a species group and the tuberculatus subgroup was

transferred from the armatus to the inermis group (Yassin

and David, 2010). Zaprionus indianus was included in the

armatus group and vittiger subgroup (now group) by Chas-

sagnard (1996), as mentioned above. Gupta (1970) pro-

posed the epithet indianus for the species, probably because

the type specimen used for identification came from India;

he was probably unaware of the distribution of the species

throughout the entire Afrotropical region (Vilela et al.,

2001). This was not, however, the only misunderstanding

related to the identification of this species. Tsacas (1985)

reviewed all of the problems concerning the nomenclature

of Z. indianus and pointed out that synonymous species

names include Z. inermis (Séguy, 1983), Z. paravittiger

(Goodbole and Vaidya, 1972) and Z. collarti (Tsacas,

1980). He also noted that Z. vittiger (Coquillet, 1901) can

easily be misidentified as Z. indianus.

The genus Zaprionus has also been the subject of

much discussion regarding its proper phylogenetic position

within the Drosophilidae. The first attempt to establish

phylogenetic relationships within this family was by

Throckmorton (1962, 1975). Using biogeographic, ana-

tomical and behavioral data, Throckmorton (1975) charac-

terized the Drosophilidae as a paraphyletic group and con-

sidered Zaprionus to be a subgenus of Drosophila within

the immigrans-Hirtodrosophila radiation. Throckmorton’s

classification was criticized because he did not use the con-

cept of monophyly. Other researchers proposed new phylo-

genetic relationships among drosophilids. For example,

Grimaldi (1990) used cladistic analysis to construct a phy-

logenetic tree for Drosophila and related genera based on

217 morphological characteristics of 120 representative

species. In this phylogeny, the subgenera Hirtodrosophila,

Scaptomyza, Idyomia and Zaprionus were excluded from

the genus Drosophila. Despite the fact that mitochondrial

DNA analyses by De Salle (1992) corroborated Grimaldi’s

proposal, the majority of phylogenies that were constructed

thereafter based on molecular markers conflicted with these

authors proposals and frequently placed species of

Zaprionus within the genus Drosophila.

Three of the early molecular phylogenies included

species from Zaprionus on a branch between the subgenera

Drosophila and Sophophora of the genus Drosophila.

These phylogenies were constructed using the gene se-

quences of the alcohol dehydrogenase enzyme (Adh) (Tho-

mas and Hunt, 1993), copper/zinc superoxide dismutase

(Kwiatowski et al., 1994) or the two concatenated gene se-

quences (Cu/Zn Sod and Adh; Russo et al., 1995). The great

majority of phylogenetic analyses, however, link species of

the genus Zaprionus to the subgenus Drosophila. Based on

ribosomal RNA sequences from 72 species of

Drosophilidae, Pelandakis and Solignac (1993) placed the

species of Zaprionus (Z. inermis, Z. sepsoides, Z. capensis,

Z. taronus and Z. lineosus) in a single clade within the sub-

genus Drosophila, in close proximity to the immigrans and

repleta groups. Kwiatowski and Ayala (1999) subse-

quently used sequences of the genes Adh, Sod and Gpdh to

place Zaprionus in the same clade as D. immigrans. Other

analyses produced similar results, placing Zaprionus close

to D. immigrans but not within the same clade. This is the

case for the study by Powell and De Salle (1995), who ana-

lyzed mitochondrial and ribosomal sequences as well as

morphological and behavioral data. It is also true for the

study by Remsen and De Salle (1998) who, in addition to

the data used by Powell and De Salle (1995), analyzed nu-

cleotide sequences of the genes Adh and Sod. In contrast,

the phylogenetic analysis by Tatarenkov et al. (1999),

which used four nuclear markers (Ddc, Sod, Adh and

Gpdh), placed Zaprionus (as well as Scaptomyza) in a posi-

tion that formed a sister clade with the virilis and repleta

groups. In this study, Tatarenkov et al. (1999) proposed for

the first time that the taxon Zaprionus should be considered

a subgenus of the genus Drosophila.

More recent studies, such as those of Robe et al.

(2005), which analyzed the nuclear genes alpha methyl

dopa (amd) and mitochondrial cytochrome oxidase II

(COII), and Da Lage et al. (2007), which used sequences of

the gene Amyrel, placed Zaprionus within the immigrans-

Hirtodrosophila radiation of the subgenus Drosophila, thus

corroborating Throckmorton’s original proposal of 1975.

At the same time, a study using the Amyrel gene, the COII

gene and morphological characteristics has linked

Zaprionus to the tumiditarsus group, which is basically

classified as part of the subgenus Drosophila (Yassin,

2007).

Doubts about the phylogenetic relationships of

drosophilids are not restricted to the genus Zaprionus. A

phylogenetic reconstruction by van der Linde and Houle

(2008) combined 117 trees to produce a “supertree” that

corroborated the paraphyly of the genus Drosophila and

placed Zaprionus among species of the immigrans-

tripunctata radiation, which is currently the most accepted

position. These results support a new classification for the

396 Commar et al.



genus Zaprionus in which it is a subgenus of the genus

Drosophila or even a group within the subgenus

Drosophila. However, to understand the evolutionary rela-

tionships of the genus Zaprionus better it is necessary to

perform complementary analyses that use a larger number

of molecular markers and morphological characteristics.

Nevertheless, most studies indicate that the diversification

of Zaprionus occurred after the origin of the subgenus

Sophophora, making Zaprionus more related to the subge-

nus Drosophila than to Sophophora. However, the exact

phylogenetic relationship between Zaprionus (and other

drosophilids) and the genus Drosophila is still a matter for

speculation.

Evolution and geographic distribution of the genus
Zaprionus

The genus Zaprionus is currently believed to have

arisen in the Oriental region (Okada, 1981) relatively re-

cently, during the Late Miocene (~10 million years ago), as

compared to the origin of the subgenus Drosophila (~ 60

MYA) (Yassin et al., 2008a). Using mitochondrial (COII)

and nuclear (Amyrel) markers and a reconstruction of his-

torical biogeography, Yassin et al. (2008a) proposed that

immediately after its origin in the East, during the Quater-

nary (~7 MYA), an ancestral lineage of the subgenus

Zaprionus colonized Africa via a maritime route from the

islands of the Indian Ocean. Thereafter, most of the mor-

phological and ecological diversification of the subgenus

took place in West Africa during the cyclic climatic chan-

ges of the Quaternary. In this analysis, the authors adopted

the Chassagnard and Tsacas (1993) classification of the

subgenus Zaprionus. However, as commented above, the

groups and subgroups have been redefined in the light of a

more recent phylogenetic analysis (Yassin and David,

2010). In order to provide an overview of the diversifica-

tion of the subgenus in tropical Africa, in this discussion we

have followed strictly the description by Yassin et al.

(2008a), although it is important to note that the

tuberculatus subgroup was transferred from the armatus to

the inermis group and the vittiger subgroup (from the

armatus group) was upgraded to species level. In short, the

two groups of the subgenus Zaprionus evolved in tropical

Africa: the inermis group, which evolved first in the islands

of the Indian Ocean (6.9 � 0.8 MYA) but with many inde-

pendent dispersal events between the African continent and

these islands, especially during the Pleistocene, and the

armatus group, which appeared later (4.4 � 0.9 MYA) in

Central Africa, during the Early Pliocene. This diversifica-

tion of the subgenus Zaprionus in Africa and the islands of

the Indian Ocean occurred in parallel with the evolution of

the species of the subgroup melanogaster of the group

melanogaster in the genus Drosophila (Lachaise et al.,

1988; Lachaise and Silvain, 2004). Recently, three dis-

tantly related Afrotropical species (Z. indianus, Z.

tuberculatus and Z. ghesquierei) became invasive and have

been found in the Palearctic region (Chassagnard and

Kraaijeveld, 1991). Zaprionus indianus is the most wide-

spread species of the genus and occurs over a broad range

on four continents (Asia, Africa and the Americas).

Ecological, ethological and evolutionary features
shared between Zaprionus and Drosophila and
genomic invasion by transposable elements

The similarities between species of the genus

Zaprionus and species of the subgroup melanogaster in

terms of their evolutionary characteristics and their ecolog-

ical diversity have been highlighted in evolutionary studies

(de Setta et al., 2009, 2011). As mentioned above, the ori-

gin of the subgenus Zaprionus dates back to the Late Mio-

cene (~7 MYA) in tropical Africa (Yassin et al., 2008a),

and the species included in this subgroup originated be-

tween 4.3 and 6.9 MYA. Interestingly, the subgroup

melanogaster arose at the same time and in the same geo-

graphic region. The subgroup melanogaster diversified in

tropical Africa from a proto-melanogaster lineage that mi-

grated from the East about 17-20 MYA. In West Africa, the

complexes erecta and yakuba evolved approximately 13-

15 and 8-15 MYA, respectively, and the complex

melanogaster, the origin of the lineages that gave rise to D.

melanogaster on one side and to the subcomplex simulans

on the other, emerged about 2-3 MYA. This subcomplex

produced D. simulans, D. sechellia and D. mauritiana, ap-

parently from the same diversification event, only about

400,000 years ago (Lachaise et al., 1988; Lachaise and

Silvain, 2004). This superposition of time and place of ori-

gin and diversification allows for evolutionary studies in-

volving the comparison of genetic, morphological and

behavioral data. Some of the studies done have involved the

analysis of sequences of transposable elements (e.g., mari-

ner, Hosimary, gypsy, copia and micropia) in species of the

two groups (Maruyama and Hartl, 1991; Lawrence and

Hart1, 1992; Brunet et al., 1994, 1999; Jordan and McDon-

ald, 1998; Heredia et al., 2004; de Almeida and Carareto,

2006; Ludwig and Loreto, 2007; Ludwig et al., 2008; Vidal

et al., 2009; de Setta et al., 2009, 2011; Deprá et al., 2010).

These studies found similarities between the sequences of

transposable elements from the subgenus Zaprionus and

from certain species of the subgroup melanogaster that

were greater than the similarities between species of the

same species group. In addition, these elements do not oc-

cur in other species of the group melanogaster. The studies

cited above indicate that these elements were involved in

instances of horizontal transfer between the species of the

two genera.

The sharing of transposable elements via horizontal

transfer requires spatial, temporal and ecological overlap.

Drosophilids are saprophagic species that develop in de-

composing plant material, including fruits, leaves and

flowers, as well as fungi. Species of the group

melanogaster tend to use decomposing fruits, flowers and

Colonization by Zaprionus indianus 397



other plant parts as substrates for feeding and mating; spe-

cies of the genus Zaprionus also mate on flowers and fruits

(Markow and O’Grady, 2006, 2008) and feed on this mate-

rial and on microorganisms involved in decomposition.

These microorganisms are eliminated in the feces and de-

posited at mating sites and on the surfaces of eggs (Bakula,

1969; Gilbert, 1980). This environment is thus rich in po-

tential vectors for the horizontal transfer of transposable el-

ements such as symbiotic bacteria (Hotopp et al., 2007),

viruses (Fraser et al., 1996) and parasites such as ticks

(Gilbert, 2010), mites (Houck et al., 1991) and wasps

(Yoshiyama et al., 2001).

In addition to their shared ecological characteristics,

the historic and contemporary geographic coexistence be-

tween species of the subgroup melanogaster and the subge-

nus Zaprionus suggests that these two groups of species

passed through a period that allowed the transfer of trans-

posable elements during their diversification. The invasive

potential of various species of both groups, such as D.

melanogaster (David and Capy, 1988), D. simulans

(Hamblin and Veuille, 1999), D. malerkotliana (Vogl et al.,

2003), D. ananassae (Val and Sene, 1980) and Zaprionus

indianus (Gupta, 1970) may have promoted horizontal

transfer events (for a detailed review, see Carareto, 2011).

Intercontinental colonization by Zaprionus indianus

Zaprionus indianus probably originated in Africa

(Tsacas et al., 1981, 1985; David et al., 2006a,b; Yassin et

al., 2008a,b) and can be considered one of the most suc-

cessful colonizing species of its genus. The rapid geo-

graphic expansion of this species has led to many hypothe-

ses on the processes involved in this invasion. Yassin et al.

(2008b) studied the distribution of mitochondrial haplo-

types of the COI and COII genes in 23 geographically dis-

tinct populations of Z. indianus and detected two phylogen-

etic lineages. Lineage 1 included three African populations,

which supported the African origin of this species. A dis-

tinct phylogenetic pattern was observed in lineage II. The

Atlantic populations (of the Americas and the island of Ma-

deira) were closer to the ancestral African populations than

to those of the East (Madagascar, Middle East and India),

indicating that Z. indianus underwent two independent ra-

diations: an older radiation in which it spread from East Af-

rica to the East, and a more recent radiation in which it

spread to the West (via the Atlantic). The various hypothe-

ses explaining the two great invasions (Old World, Asia;

New World, Americas) are described below.

The colonization of Asia

The colonization of Asia may have occurred only 30

years ago (David et al., 2006a), based on the description by

Gupta (1970) using type specimens from India, or it may

have occurred centuries ago (Karan et al., 2000). This pro-

cess is not well documented and some authors even claim

that Z. indianus is endemic to India (Gupta, 1970) and Paki-

stan (Shakoori and Butt, 1979). However, Z. indianus has

not been recorded in nearby Sri Lanka (Karan et al., 2000).

Zaprionus indianus has been found in the Comoro Islands,

the Canary Islands and Madagascar (Chassagnard and Tsa-

cas, 1993), as well as in Saudi Arabia (Amoudi et al., 1991;

1993a,b) and in other parts of the Palearctic region (Chas-

sagnard and Kraaijeveld, 1991).

The few records of Z. indianus in Asia include studies

of quantitative traits and alloenzyme polymorphisms. In In-

dian populations, the sizes of the body, thorax and wings

are reduced at higher temperatures (Karan et al., 1999), and

various quantitative (weight, body and wing size) and re-

productive (number of ovarioles) traits increase with lati-

tude. The quantitative traits (wing, thorax and body size)

also increase with altitude (Karan et al., 2000). The geo-

graphical characteristics (latitude and longitude) are not se-

lective factors themselves, but they may be related to some

form of climatic selection (Karan et al., 2000). Thus, these

data provide indirect evidence of the action of natural selec-

tion, probably driven by variation in temperature. Various

authors have suggested that increased body size may im-

prove flying ability (Stalker, 1980; David et al., 1994;

Azevedo et al., 1998).

Clines related to alloenzyme polymorphisms are gen-

erally attributed to greater or lesser stability of the variants,

depending on the temperature (Hedrick, 1983; Parkash and

Sharma, 1993; Parkash and Yadav, 1993a). Thermo-

resistant variants would be at advantage in environments

with a higher ambient temperature (low latitudes and alti-

tudes), and thermosusceptible variants would be at advan-

tage in environments with lower temperatures (higher lati-

tudes and altitudes). Environments with significant

temperature variation during the year could support popu-

lations with variants of both types or with greater than ex-

pected heterozygosity resulting from balanced selection

(Parkash and Sharma, 1993; Parkash and Yadav, 1993a).

Studies of different alloenzyme markers in Indian

populations of Z. indianus have found that the markers

show latitudinal clinal variation, including, for example,

polymorphisms of the alloenzymes ACPH, esterases and

MDH (Parkash and Sharma,1993), Acph-1S, Acph-1F,

Mdh-1F, AoS, AdhF, Est-1 and 2 and �-GpdhF (Parkash and

Yadav, 1993b;Yadav and Parkash, 1993a; Parkash et al.,

1994) and the allele AdhF (Yadav and Parkash, 1993b). Ad-

ditionally, Parkash et al. (1992) found a significant increase

in the frequency of the AdhF allele with increasing latitude

while Yadav and Parkash (1993b) found that this variant in-

creases tolerance to higher ethanol concentrations.

The clinal variation found in some Asian populations

of Z. indianus is indicative of older colonization. The de-

tails of this colonization have been completely lost. How-

ever, the association of this drosophilid with altered

environments and evidence that the recent colonization of

the Americas probably occurred through the intercontinen-

tal transport of fruits (David et al., 2006b; Yassin et al.,

398 Commar et al.



2009a; Galego and Carareto, 2010a), it is likely that the col-

onization of Asia occurred in a similar way during the great

navigations at the end of the Middle Ages or beginning of

the Modern period (15th century) that involved the trading

of spices and other products between the East and West.

There are still questions, however, regarding the dispersal

of Z. indianus in the Palearctic regions through the interna-

tional fruit trade. For example, while in the Americas the

dispersion of this species was extremely rapid (in approxi-

mately six years from São Paulo to Florida), it took more

than 40 years for the species to spread from India to Egypt.

The population in Egypt seems to be very recent in origin,

more recent than December 2002 (Yassin et al., 2009a).

This population may have come from a natural expansion

from tropical Africa, through the Nile valley, or perhaps

through trade in fruits from East Africa or Asia. Analyses of

the polymorphisms of chromosomal inversions have shown

that the populations in Alexandria (Egypt) are more closely

related to Indian populations (Gupta and Kumar, 1987)

than to African or Brazilian ones (Ananina et al., 2007). In

addition, quantitative analyses of alloenzymes and RAPD

have revealed low genetic variability in the Egyptian popu-

lations, a characteristic of recently introduced populations

(Yassin et al., 2009b).

The colonization of the Americas

Vilela (1999) was the first to report the presence of Z.

indianus in South America; the species was found in per-

simmons (Diospyros kaki, Ebenaceae) from Santa Isabel in

São Paulo city in the state of São Paulo, Brazil. At the same

time, the species was also collected at other locations in this

state (Ribeirão Preto, São José do Rio Preto, and Valinhos)

and in the Federal District (Vilela et al., 2001). Two hy-

potheses for the introduction of this species into Brazil

were initially proposed by these authors. The less likely hy-

pothesis was that some specimens had escaped from the

drosophilid stocks at the Drosophila Species Resource

Center in Austin, Texas, USA. The second hypothesis was

that the introduction occurred directly through the air trans-

port of contaminated foods from Africa to São Paulo.

A third hypothesis, proposed by Galego and Carareto

(2007) as part of an analysis of esterase polymorphism, was

that the introduction occurred through maritime transport

in the Port of Santos (this port is a likely site, considering its

commercial importance for Brazil: one quarter of all the

products imported by Brazil passes through this port). Ac-

cording to the Food and Agriculture Organization (FAO,

1997) the global fruit market increased by 13% in the pe-

riod 1985-1995. The volume of fruit transported and the

special requirements for preservation mean that most of the

fruit trade involves transport by sea (França and Gondin,

1999). According to data from the Brazilian Institute of

Fruits (IBRAF, 2000-2001), Brazil imports mainly apples,

cherries, grapes, kiwi, nectarines, peaches, pears and

plums. Brazilian imports showed a significant increase

from the 1970s to the 1990s, including imports from the

African continent. Brazil currently has bilateral trade

agreements with most countries in Africa (Ministério de

Relações Exteriores, 2007), especially South Africa, from

where it imports ores and agricultural products, including

grapes (Ministério do Desenvolvimento, 2007). The impor-

tance of the fruit trade for the dissemination of this species

in Brazil was initially suggested by Tidon et al. (2003).

Galego and Carareto (2007) suggested that after its intro-

duction, Z. indianus spread throughout the state of São

Paulo principally via the highway-based fruit trade.

The second and third hypotheses are the most likely

because data from morphological, ecological and genetic

markers indicate that the founding population was quite

large (David et al., 2006a; Ananina et al., 2007; Galego and

Carareto, 2007). However, regardless of how it was intro-

duced, Z. indianus rapidly expanded its range; in little more

than two years after its introduction, this drosophilid was

present in practically all of the Brazilian states. As early as

1999, after the first report, the species was detected in Santa

Catarina (Toni et al., 2001) and other areas of the Brazilian

cerrado and Midwest (Tidon et al., 2003). In 2000, the spe-

cies reached Rio Grande do Sul (Castro and Valente, 2001),

Rio de Janeiro (Loh and Bitner-Mathé, 2005) and Uruguay

(Goñi et al., 2001, 2002). In 2001, the species was recorded

in different locations in Minas Gerais (Kato et al., 2004;

David et al., 2006a), and in 2002 it was found in various

states in the Northeast (Mattos-Machado et al., 2005). The

species reached the state of Tocantins and the north of

Brazil in 2003 (Santos et al., 2003) and was also recorded in

Panama in 2003 (Central America). In 2005, Z. indianus

was recorded in Florida (USA) (van der Linde et al., 2006)

and Argentina (Soto et al., 2006). This rapid and broad geo-

graphic dispersion is indicative of the great ease with which

Z. indianus can colonize new environments. Figure 1

shows the worldwide distribution of Z. indianus (with

Brazil highlighted) and the probable dates of colonization.

Interest in the study of Z. indianus is directly related

to its recent invasion of Neotropical regions. Today, this

species is considered to be semi-cosmopolitan (Vilela,

1999; Tidon et al., 2003; Silva et al., 2005a,b). This rapid

expansion, in addition to the scarcity of information on Z.

indianus until the last ten years, has motivated dozens of re-

searchers to investigate the invasion by this species. Many

of the studies that have investigated this invasion have used

markers such as quantitative characteristics, alloenzyme

polymorphisms, mitochondrial DNA, ecological analysis

and even complete genome sequencing.

Variation in quantitative traits can be a good indicator

of the amount of genetic variability in a species and can re-

veal the potential phenotypic plasticity of the species and

its ability to exploit niches. Loh and Bitner-Mathé (2005)

detected significant variation in wing size and form in pop-

ulations of Z. indianus in Rio de Janeiro. David et al.

(2006a) analyzed three quantitative characteristics (wing

Colonization by Zaprionus indianus 399



size, thorax size and number of sternopleural bristles) in

African, Indian and Brazilian populations of Z. indianus

and found clinal variation in the Indian populations that

was less marked in the African populations and not de-

tected in the Brazilian populations; however, the Brazilian

populations showed significant interlineage differences.

Based on these data, the authors suggested that the

propagules that colonized Brazil were quite numerous and

contained sufficient genetic variability to prevent a possi-

ble “bottleneck” effect. The authors also suggested that the

colonization was quite recent, which would explain the lack

of clinal variation in the quantitative traits. Analysis of the

average body size of Brazilian Z. indianus suggested that

South Africa was the probable origin of the founder pro-

pagules (David et al., 2006a). This conclusion regarding

the African origin of the Brazilian populations was sup-

ported by the lack of significant differences between popu-

lations from these two geographic regions (David et al.,

2006a). Chromosomal inversions also support the hypothe-

sis of an African origin for the founder propagules of Z.

indianus (Ananina et al., 2007). Only inversion In(II)A,

one of the most frequent in Indian populations (Gupta and

Kumar, 1987), was detected in Brazilian populations, but at

a very low frequency. Ananina et al. (2007) also showed

that Brazilian populations contained five other inversions

not detected in Indian populations. The high rate of inver-

sion polymorphisms, along with the fact that they are rarely

shared with Indian populations, indicates that the founder

propagules were quite numerous and that they did not stem

from the latter populations.

In various drosophilids, the colonization of a new en-

vironment leads to an increase in genome size through en-

hanced transposition of transposable elements (Biemont

and Vieira, 2005). The size of the Z. indianus genome as es-

timated by flow cytometry ranges from 0.601 pg in Indian

populations to 0.630 pg in African populations and

0.635 pg in Brazilian populations (Nardon et al., 2005). Ac-

cording to these authors the smaller genome size of Indian

populations suggests a possible Asiatic origin for this

drosophilid. Among the different markers studied to date,

genome size is the only one that suggests a non-African ori-

gin for Z. indianus; however, the smaller genome size of the

Indian populations may be the results of a recent bottleneck

during occupation of the Palearctic region (Yassin et al.,

2008b). At any rate, these data indicate that the Brazilian

and African populations have a similar genome size, which

again supports the idea that the founding Brazilian popula-

tions were of African origin.

Molecular markers have contributed considerably to

understanding the introduction of Z. indianus into the Ame-

ricas. Esterase alloenzymes were the first markers to be

used. Galego et al. (2006) described six loci coding for es-

terases in Z. indianus, four of which encode �-esterases and

two encode �-esterases. Two of these loci, Est-3 (four al-

leles) and Est-2 (two alleles), were polymorphic. This poly-

morphism supports the hypothesis that South America was

colonized by a large number of propagules. Mattos-Ma-

chado et al. (2005) also analyzed polymorphisms at five

alloenzyme loci (Acp, Pgm, Idh, Hk and Est-3) in Brazil-

ian, Asiatic and African populations of Z. indianus and de-

tected a low FST among the Brazilian populations, which

suggested colonization by a single propagule with subse-

quent rapid expansion. Although these authors did not sug-

gest the origin of the propagule, they stated that it probably

included almost all of the polymorphisms that existed in the

ancestral population. An African origin for Z. indianus is

also supported by the analysis of neutral polymorphisms,

which are more appropriate for phylogeographic studies

than alloenzymes, such as the mitochondrial genes COI and

COII (Yassin et al., 2008b; Commar, Ceron, Carareto, un-

published data). Additionally, it has been also reinforced by

analysis of the nuclear gene � esterase-6 (Commar, Ceron,

Carareto, unpublished data).

Biological characteristics of Zaprionus indianus
related to colonization in the Neotropical region

Zaprionus indianus is a generalist species that uses a

variety of domestic and non-domestic fruits as sites for

mating and oviposition (Lachaise and Tsacas 1983;

400 Commar et al.

Figure 1 - Migration routes for Z. indianus involved in its dispersal

throughout the world, based on studies cited in the text. The process that

occurred in Brazil is highlighted.



Schmitz et al., 2007). In Brazil, Z. indianus has adopted a

behavior never seen before among drosophilids, namely,

the colonization of unripe fruits, making them inedible to

humans and causing extensive economic damage (Castro

and Valente, 2001). Although not considered a pest in its

place of origin, the invasion of Brazil by this drosophilid

has resulted in considerable agricultural losses. In 1999, Z.

indianus was responsible for the loss of 40% of the fig har-

vest (Ficus carica) in the main productive region in the

state of São Paulo (Stein et al. 2000). As a result, Z.

indianus was classified as a pest at the time; however, this

behavior must have been a single, one-off event that char-

acterized the introduction of Z. indianus into Brazil (van

der Linde et al., 2006).

Some characteristics of Z. indianus, such as its varia-

tion in body size, are similar to those of populations found

on other continents (Yassin et al., 2009b). Body size may

be related to the success of invading species (Cassey, 2000;

Roy et al., 2002; Fisher and Owens, 2004). The variability

in fly size in a population of Z. indianus in the Nile delta,

which has a Mediterranean climate, was initially attributed

to the highly heterogeneous environment of this region, in-

cluding high temperatures, stress, dehydration and expo-

sure to insecticides (Yassin et al., 2007). Yassin et al.

(2009b) examined this hypothesis by investigating other

populations of the same species living in a completely dif-

ferent and more benign tropical environment, such as close

to the tropics in Brazil, where the climate is wet and humid.

The populations sampled were genetically different from

the Egyptian population, as shown by cytogenetic (Ananina

et al., 2007) and molecular (Yassin et al., 2008b) studies.

The authors showed that contrary to expectation, body size

variability was always very high and similar across popula-

tions and continents. These results suggested that the ele-

vated phenotypic variability in Z. indianus may be an

intrinsic property of this species and may be related to the

ability to use a wide diversity of resources and micro-

habitats.

Other studies that have examined the invasive poten-

tial of Z. indianus have focused on the life cycle (Amoudi et

al., 1991), larval competition (Amoudi et al., 1993a) and

fitness components (Amoudi et al., 1993b) in lineages orig-

inating in Saudi Arabia. Zaprionus indianus is a tropical

species that is easily reared at 31 °C (Amoudi et al., 1991;

Karan et al., 1999; Araripe et al., 2004; Loh et al., 2008) but

is sensitive to cold. The optimal temperature for successful

development of flies from Saudi Arabia is 20-30 °C, with

no development at 35 °C (Amoudi et al., 1991, 1993b).

This sensitivity to variation in temperature is an important

factor in the establishment of this species in varied environ-

ments such as Saudi Arabia, where elevated temperatures

are frequent during the summer.

Alloenzyme studies indicate that the distribution of

genetic variability at the �-esterase 3 locus in Z. indianus is

influenced by natural selection, including selection by in-

secticides and selection stemming from climatic variation

(Galego and Carareto, 2007, 2010b). Plasticity in the distri-

bution of allele frequencies for the Est-3 locus may also

have contributed to the successful spread of this organism,

especially in the American continent, given that esterases

perform multiple essential functions in insects.

Until the end of the 1990s, few studies had examined

the life cycle of Z. indianus. Stein et al. (2003) and Setta

and Carareto (2005) contributed significantly to our under-

standing of the life cycle of Z. indianus populations. These

studies reported a greater longevity than in Z. indianus pop-

ulations of Indian (Bains et al., 1995, 1996) and Saudi Ara-

bian (Amoudi et al., 1991, 1993a) origin. The productivity

of the species was similar to or greater than that of other

drosophilids and the development time was very similar to

that of D. sturtevanti. These results indicated an r-strategy

of environment colonization, which is highly characteristic

of bioinvaders.

Fitness components, such as development time, pro-

ductivity and fertile period are strongly linked to the repro-

ductive biology of a species, with fecundity and productiv-

ity being directly related to the production of ova and

sperm. Araripe et al. (2004) demonstrated that the viability

of male gametes in Z. indianus was temperature-dependent,

such that very low ambient temperatures led to male steril-

ity. If development occurred at 15 °C, all of the males were

sterile. This drastic reduction in reproductive capacity

could explain why Z. indianus is not found in higher lati-

tude regions, as already reported by Chassagnard and

Kraaijeveld (1991) and Goñi et al. (2001, 2002).

We do not know how the species survives periods of

cold, i.e., if there is diapause or if populations are able to re-

cover through reintroduction. One hypothesis suggested by

Danni (1980) involves the formation of islands of heat in

cold regions, as for example in the southern Brazilian city

of Porto Alegre. This phenomenon is associated with ur-

banization. These thermal islands could be used as refuges

by urban insect populations during unfavorable periods.

Oscillations in the frequencies of different species reflect

variations in their tolerance to variable climatic conditions

at a single location. According to Tidon (2006), some

drosophilid species are extremely seasonal and only appear

at particular times of the year. In agreement with this, the

highest frequencies of Z. indianus were recorded during the

seasons with the highest average temperatures (spring and

summer), whereas sightings were lowest during the fall and

winter but increased again in the spring. Such fluctuations

reinforce the invasive capacity of this species (Tidon et al.,

2003). Similar behavior was observedby Silva et al.

(2005a) in three urban parks of Porto Alegre over seven

seasons. In this case, Z. indianus showed the highest fre-

quencies compared to other drosophilids during the seasons

with the highest mean temperatures, but the frequency con-

sistently dropped during autumn and winter to increase

again in the spring. The authors concluded that the ability to

Colonization by Zaprionus indianus 401



live in environments associated with humans and the ca-

pacity to restore high population levels under favorable

conditions contributed to this species expansion and colo-

nization of new areas.

The distribution of Z. indianus across different conti-

nents and its establishment in these areas is related to the

climatic conditions that it encounters. Mata et al. (2010)

used multivariate analysis to show that Z. indianus occu-

pies different niches in Africa, Asia and the Americas such

that the climatic conditions of the area occupied by the orig-

inal population differ from those of areas where it is new,

principally in India. Indeed, populations of Z. indianus in

India established themselves in climates very different

from those of Africa, where the temperatures are more vari-

able and considerably lower in the colder months. The

clinal variation in several characteristics of the Indian pop-

ulations of Z. indianus (Karan et al., 2000) may reflect the

adaptation of these flies to these conditions. Changes in

niche can occur through adaptive responses to new envi-

ronmental conditions in the invaded areas and these

changes may be driven by natural selection for climatic tol-

erance (Mata et al., 2010). In South America, invading Z.

indianus encountered climatic conditions very similar to

their original niche that allowed the rapid establishment

and expansion of this species throughout Brazil.

Studies on the distribution of Z. indianus in Brazil

have shown variation in the abundance of this species

among ecosystems. Tidon et al. (2003) analyzed the abun-

dance of Z. indianus in the cerrado and riverine forests and

found a greater abundance in the cerrado during wet peri-

ods. Ferreira and Tidon (2005) showed that, together with

D. simulans, Z. indianus was the most abundant species in

the urbanized environment of Brasília, the Brazilian capi-

tal. On the other hand, the abundance of this fly in man-

grove forests was higher than in the Atlantic rain forest but

lower than in the cerrado (Tidon et al., 2003) or in urban en-

vironments (Ferreira and Tidon 2005; Silva et al., 2005b).

These results indicate that together with other introduced

Drosophilidae, Z. indianus could be useful as an indicator

of disturbed areas.

In addition to the factors discussed above, the varia-

tion in Z. indianus abundance may also reflect competitive

interactions with other drosophilids. An experimental study

has shown a reduction in the viability of Z. indianus in the

presence of larval waste from D. sturtevanti; on the other

hand, waste from Z. indianus interferes with the viability of

D. simulans and the duration of development in both of

these Drosophila species (Galego and Carareto, 2007).

Thus, competitive interactions between Z. indianus and

other drosophilids may affect the population density of this

species after its introduction into a new environment. Other

factors, such as temperature tolerance and plasticity in the

occupation of niches (involving the use of a wide variety of

plants as food sources) may also be related to this species

invasive success.

Acknowledgments

CMAC and LSC were supported by Conselho Nacio-

nal de Desenvolvimento Científico e Tecnológico (CNPq).

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Creative Commons Attribution License, which permits unrestricted use, distribution, and
reproduction in any medium, provided the original work is properly cited.

406 Commar et al.