BA602809.pdf


 Su: Successful Invader 765

HOW TO BECOME A SUCCESSFUL INVADER§

NAN-YAO SU
Department of Department of Entomology & Nematology, Fort Lauderdale Research & Education Center, 

 University of Florida, Davie, Florida 33314; E-mail: nysu@ufl.edu

§Summarized from a presentation and discussions at the “Native or Invasive - Florida Harbors Everyone” 
Symposium at the Annual Meeting of the Florida Entomological Society, 24 July 2012, Jupiter, Florida.

ABSTRACT

Most invasive species hitchhike on human transportation, and their close associations with 
human activity increase their chances of uptake. Once aboard, potential invaders have to 
survive the journey, and those with traits such as being a general feeder or tolerance to a 
wide range of environmental conditions tend to survive the transportation better. Similar 
traits are generally considered to also aid their establishment in new habitats, but stud-
ies showed that the propagule pressure, not any of the species-specific traits, is the most 
important factor contributing to their successful establishment. Higher propagule pressure, 
i.e., repeated invasions of larger numbers of individuals, reduces Allee effects and aids the 
population growth of invasive species in alien lands. Coined as the invasive bridgehead ef-
fect, repeated introduction also selects a more invasive population that serves as the source 
of further invasions to other areas. Invasive species is the consequence of homogenocene 
(our current ecological epoch with diminished biodiversity and increasing similarity among 
ecosystems worldwide) that began with the Columbian Exchange of the 15th century and 
possibly the Pax Mongolica of the 13-14th century. Anthropogenic movement of goods among 
major cities will only accelerate, and the heightened propagule pressure will increase the 
number of invasive species for as long as the current practices of global commercial activi-
ties continue.

Key Words: propagule pressure, invasive bridgehead effect, homogenocene, Columbian Ex-
change

RESUMEN

 
La mayoría de las especies invasoras entran los países conjuntamente con el transporte 
humano y sus estrechas asociaciones con las actividades humanas aumentan sus posibilida-
des de admisión. Una vez a bordo, los invasores potenciales tienen que sobrevivir el viaje y 
las species con características tales como ser un consumidor general o una tolerancia a una 
amplia gama de condiciones ambientales tienden a sobrevivir el transporte mejor. También, 
por lo general se considera que las características similares ayudan su establecimiento en 
nuevos hábitats, pero los estudios muestran que la presión de propágulos, no unas de las 
características específicas de la especie, es el factor más importante que contribuye a su esta-
blecimiento exitoso. Mayor presión de propágulos, es decir, repetidas invasiones de un mayor 
número de individuos, reduce los efectos de Allee y ayuda en el crecimiento de la población 
de las especies invasoras en paises exóticos. Llamado como el efecto invasivo de la cabeza de 
puente, la introducción repetida también selecciona una población más invasiva que sirve 
como una fuente para más invasiones a otras áreas. Las especies invasoras son la consecuen-
cia de homogenocene (nuestra época ecológica actual con la disminución de la biodiversidad 
y el aumento de similitud entre los ecosistemas en todo el mundo), que comenzó con el 
Intercambio Colombiano del siglo 15 y posiblemente la Pax Mongolica del siglo 13 al 14. El 
movimiento antropogénico de mercancía entre las principales ciudades seguirá aceleraran-
dose, y la elevada presión de propágulos aumentará el número de especies invasoras por el 
tiempo que las prácticas actuales de actividades comerciales globales continúen.

Palabras Clave: presión de propágulos, efecto invasivo de la cabeza de puente, homogenoce-
ne, Intercambio Colombiano

Of the over 12,500 insect species found in Flor-
ida in 1995, 988 (7.9%) were listed as “non-na-
tive” species (Frank & McCoy 1995), but not all of 
them are considered “invasive.” Invasive species 

are defined as the non-native “pest” species, i.e., 
those that adversely affect environment, economy 
and human health (Anonymous 1999). Pest sta-
tus is determined primarily by human value and 



766 Florida Entomologist 96(3) September 2013

perception. Following its successful introduction 
to control cacti (Opuntia spp.) (Caryophyllales: 
Cactaceae) in Australia in 1925, for example, the 
moth Cactoblastis cactorum Berg (Lepidoptera: 
Pyralidae) was intentionally introduced to sev-
eral Caribbean islands in 1957 (Frank & McCoy 
1995) to control Opuntia weeds. By 1989, C. cac-
torum had spread to the Florida Keys where it 
became a “pest” because it began to attack two 
cati, O. spinosissima Martyn (Mill.) and O. triac-
antha (Willdenow), which are considered to have 
value because they are designated rare (Habeck 
& Bennett 1990).

Certain species-specific characteristics are of-
ten regarded as traits that render some species 
more “invasive.” These include, among others, 
high dispersal ability (better survival of transpor-
tation), association with human activity (increas-
ing opportunities for migration), ecological com-
petence (better survival in a new environment), 
rapid and/or placid reproduction (e.g., sexual 
and asexual reproduction), and rapid population 
growth. The usefulness of the list of such “inva-
sive” traits has been questioned because many 
species with these traits have never become in-
vasive (Kolar & Lodge 2001). These traits may be 
“necessary” instead of “sufficient,” but they still 
serve as the guide to understand the likelihood of 
a species to become invasive.

STEPS TOWARD SUCCESSFUL INVASION AND ES-
TABLISHMENT

Uptake and Migration

Most cases of species invasions are human-
mediated. Living organisms extend their ranges 
naturally, but natural extension of most species 
occurs less frequently and at much shorter dis-
tances than anthropogenic events. Because most 
invasive species hitchhike on human transpor-
tation, a close association with human activity 
increases their chances of uptake. Cockroaches, 
rodents and some termite species tend to live near 
human habitat and are frequently transported. 
The Formosan subterranean termite, Copto-
termes formosanus Shiraki (Isoptera: Rhinoter-
mitidae), for example, tends to infest man-made 
structures (hence the common name in its native 
China is “house termite”), and is one of the most 
widely distributed subterranean termites (Rust & 
Su 2012). The West Indies powderpost termite, 
Cryptotermes brevis Walker (Isoptera: Kaloter-
mitidae), often hitchhikes in wooden furniture or 
picture frames (and thus nicknamed “furniture 
termite”), and is found in more regions in the 
world than any other termite species.

Once aboard, the stowaway has to survive the 
journey (Fig. 1). General feeders that can tolerate 
a wider range of temperature and humidity tend 
to survive better during the transportation, but 

some species may create conditions suitable for 
their survival. Incipient colonies of C. formosa-
nus, for example, may seal off the nest after tun-
neling into wet wood, and create moist conditions 
in their food source to survive the journey.

Surviving in a New Environment: Propagule Pressure

Species-specific traits that better serve for 
survival during transportation (i.e., generalist 
feeders, and tolerance to a wide range of environ-
mental conditions) are usually considered to aid 
the invaders to survive in new environment. Co-
lautti et al. (2006) who studied 14 invasive char-
acteristics (i.e., features associated with invasive 
species), however, found that propagule pressure 
was the only consistent predictor of invasive-
ness. Physiological tolerance and body size did 
not have any effect on a species’ ability to invade 
a foreign land. Propagule pressure is defined as 
the measure of the total number of individuals 
being introduced, and is the function of the num-
ber of introduction events and the mean number 
of introduced individuals per event (Lockwood et 
al. 2005) (Fig. 1). Generally speaking, more intro-
duction events with more individuals per event 
increase the propagule pressure and hence the 
chance of successful establishment (Colautti et 
al. 2006). Propagule pressure is affected by inva-
sion pathways that are closely associated with 
human activities. Using the mitochondrial DNA 
sequences, Yang et al. (2012) examined the inva-
sion pathways of the fire ant, Solenopsis invicta 

Fig. 1. Steps for a species to become a successful in-
vader in alien lands.



 Su: Successful Invader 767

Buren (Hymenoptera: Formicidae), into China 
and showed that this species was most likely im-
ported from Austin, Texas, which also ranked the 
highest in exporting goods to China. The frequent 
traffic of goods from Austin to China apparently 
increased the propagule pressure and aided its 
successful invasion.

Population Growth and Allee Effect

The notion that density dependent factors gov-
ern the upper limit of population size goes back 
as far as Malthus and forms the backdrop for 
natural selection. However, low population den-
sity during the early stage of species establish-
ment may also inhibit population growth due to 
infrequent intra-species encounters. Coined the 
“Allee effect,” this principle was demonstrated in 
a series of studies using goldfish (Allee 1931; Al-
lee & Bowen 1932) during the time when most 
ecologists were focusing on the adverse effects of 
overcrowding and competition on individual sur-
vival. Overcrowding increased individual com-
petition and mortality thus inhibits population 
growth, but according to the Allee effect, under-
crowding also deters population growth due to 
these aggregation-related consequences. Mecha-
nisms contributing to the Allee effect may include 
mate limitation, cooperative defense, cooperative 
feeding, and environmental alternation through 
aggregation. Leung et al. (2004), for example, 
used prediction models to study zebra mussel 
invasions in 1,589 inland lakes of Michigan and 
found that models that included the Allee effect 
were better in predicting its invasion. Due to the 
Allee effect, higher propagule pressure increases 
the probability for invasive species to establish in 
a new environment, and to increase its population 
(Fig. 1).

Range Expansion and Invasive Bridgehead Effect

Many species do not establish in alien lands 
despite being frequently transported by man, be 
it intentionally or accidentally (Lockwood et al. 
2005). The frequent anthropogenic movement 
of these species may act as a process to select a 
particular population that is more invasive than 
others. Once established, the selected population, 
instead of the populations in the native land, may 
become the source of further invasions to other re-
gions and range expansion (Fig. 1). This phenom-
enon was termed “invasive bridgehead effect” by 
Lombaert et al. (2010) who tracked the invasive 
pathways of the Asian ladybeetle, Harmonia axy-
ridis (HA) by analyzing the microsatellite genetic 
variation among its populations worldwide. There 
have been repeated attempts to release H. axyri-
dis as the biological control agent against aphids 
since early 1900s, but all failed. Since 1988, H. 

axyridis has been found unexpectedly in multiple 
areas. Some of these populations were eventu-
ally successful in the control of soybean aphids, 
but others became nuisance pests due to their 
unpleasant odors when they overwinter indoors 
in large numbers. A genetic study by Lombaert 
et al. (2010) showed that H. axyridis from its na-
tive Asia established its bridgehead in eastern 
U.S. in 1988, from which it was later introduced 
to South America, South Africa and Europe. The 
study of S. invicta invasive pathways to China of-
fers another example of bridgehead effect (Yang 
et al. 2012). A comparison of the genetic varia-
tions among 27 populations of S. invicta (10 in 
China and 17 in the U.S.) showed that most popu-
lations in China appeared to have originated from 
Wuchuan in southwest Guangdong Province, P.R. 
China, in which this ant species first established, 
and served as the bridgehead population to other 
populations in China.

HOMOGENOCENE

The process of successful establishment by in-
vasive species as shown in Fig. 1 is part of a larger 
trend of “homogenocene” which was termed by 
Samways (1999) to characterize our current eco-
logical era as an epoch with diminished biodiver-
sity and increasing similarity among ecosystems 
worldwide. Homogenocene results from anthro-
pogenic movement of organisms worldwide, and 
most attribute its beginning to the “Columbian 
Exchange,” i.e. the large scale exchange of goods, 
and macro- and microorganisms following the 
1492 voyage of Christopher Columbus to the New 
World (Mann 2011). Connection of 2 once-sepa-
rated Hemispheres prompted the movements of 
numerous organisms, but before the Columbian 
Exchange, there was another dramatic connec-
tion of 2 largely separated worlds during the Pax 
Mongolica via the Silk Road.

Pax Mongolica: 13th-14th Century

Following a series of wars waged through most 
of the 11th century, Genghis Khan and his descen-
dents built the largest continuous empire in hu-
man history that stretched from the Pacific Ocean 
to the Caspian Sea and today’s Moscow. The Mon-
gol Empire was partitioned into 4 branches, and 
despite political tensions and constant squabbles 
among them, trade routes were kept open, and 
exchanges of goods, people, and ideas changed the 
lives of those inhabited within the Mongol Em-
pire and the neighboring nations. The Silk Road 
(started in the Han dynasty, 206 BCE – 220 CE) 
was reopened as the main land route connecting 
China with Europe. The Maritime Silk Road con-
nected China through SE Asia, the Indian Ocean, 
the Arabian Sea, the Persian Gulf, and the Red 



768 Florida Entomologist 96(3) September 2013

Sea to East Africa. Through these networks of 
trade routes, a global commerce flourished for 
the first time in human history, and productiv-
ity and populations of nations within the trade 
zone grew rapidly (Abu-Lughod 1989). The Yum 
system (a series of relay stations at every 32-40 
km along the major routes to supply fresh horses 
and other travel accommodations) that was origi-
nally established to secure communication among 
Mongol troops, provided vital needs for traveling 
merchants, and the trade routes were manned by 
Mongol soldiers for safe passage. Chinese silk, 
exotic spices, Indian cotton, sugar and new crops 
such as carrots, turnips and buckwheat were in-
troduced to Europe by merchants from the East.

In addition to commodities and products, 
people and information also flowed through the 
Silk Road. The Venetian merchant, Marco Polo 
traveled with his father and uncle to China (Ca-
thay) and the book of his travel and adventure, 
“The Travel of Marco Polo” introduced Europeans 
to the exotic countries in the east, and stirred 
imagination of many including Christopher Co-
lumbus (Latham 1958). Introduction of Chinese 
innovations such as paper, printing, gunpowder, 
firearms and the magnetic compass were con-
sidered underlying factors for the emergence 
of Renaissance in Europe (Weatherford 2004). 
Through the same trade routes, the pathogen of 
Plague, the bacterium Yersinia pestis (Lehmann 
and Neumann 1896) van Loghem 1944, was also 
brought to Europe by its carrier, the Oriental rat 
flea, Xenopsylla cheopis (Rothschild) (Siphonap-
tera: Pulicidae) on rodents that hitchhiked trade 
ships from the Orient. The disease ravaged Asia 
with an estimated 25 million victims before enter-
ing Europe (Kohn 2008). Between 1347 and 1353, 
Plague killed one third of the European popula-
tion, and profoundly altered the course of Euro-
pean history. The most significant impact of Pax 
Mongolica to homogenocene, however, is that sto-
ries of lands with abundance of gold, treasures, 
and exotic spices flowing through the Silk Road 
led Europeans to the age of discovery, and the Co-
lumbian Exchange.

Columbian Exchange

Columbus’ voyage in 1492 connected 2 Hemi-
spheres and promoted a dramatic and widespread 
exchange of organisms between them. New World 
crops such as maize, potato, tomato, tobacco, 
sweet potato, cacao, vanilla, pineapple, chili pep-
per, peanut, sunflower, and papaya were spread 
to and deeply affected lives of those in the Old 
World. Introduction of maize, potato and sweet po-
tato to China, for example, turned marginal lands 
of mountainous terrains (which were unsuitable 
for cultivating traditional crops such as rice and 
wheat) into productive lands that contributed to 
the doubling of the Chinese population (Mann 

2011) in the Qing dynasty (1644 to 1912). Potato 
was singularly responsible for the population ex-
plosion in Ireland as well as the Great Irish Fam-
ine (1845-1852) when the crops were decimated 
by potato blight. Before the 1500s, there were no 
tomatoes in Italian cuisine, no chocolate in Swit-
zerland, no pineapples in Hawaii, no chili peppers 
in Thai or Indian food, no potatoes in the German 
diet, and no rubber trees in Malaysia. Almost as 
many plant species were also brought from the 
Old to New World, including apple, banana, black 
pepper, coffee, citrus, garlic, onion, peach, soy-
bean, sugarcane, rice, wheat, and watermelon. 
Domesticated animals such as horse, chicken, 
donkey, pig, earthworm, honey bee and silkworm 
were introduced to the New World and changed 
the life style of Native Americans. As with Plague 
during the Pax Mongolica, many infectious dis-
eases including malaria, small pox, chicken pox, 
cholera, leprosy, bubonic plague, yellow fever, ty-
phoid, and measles were also brought from the 
Old to New World. Of these, the most devastating 
was small pox that killed 80-90% of Native Amer-
ican populations (Mann 2011). Columbus’ crews 
who contracted syphilis spread it to European 
populations when some of them later joined the 
Spanish army to invade Italy. Edible plants and 
domestic animals were intentionally introduced, 
but diseases and other organisms were acciden-
tally transferred, and many became invasive, e.g., 
brown rats, zebra mussels, tumbleweed (Salsola 
spp.; Caryophylalles: Amarantaceae), wild oat, 
and ascomycete microfungi (Ophiostoma spp.) 
responsible for Dutch elm disease. Some species 
such as Kudzu that was intentionally introduced 
(to prevent soil erosion) became a pest species, 
while others such as the yeast, Saccharomyces 
bayanus Saccardo, which was accidentally intro-
duced from South America was later used for pro-
ducing lager beer.

CONCLUSION

As shown in Fig. 1, propagule pressure is the 
major factor contributing to the increase of inva-
sive species across the globe. Beginning with Pax 
Mongolica, and later the Columbian Exchange, 
anthropogenic movement of goods among major 
cities has increased over time, and this trend 
will only accelerate. This will heighten propa-
gule pressure to provide more opportunities for 
potential invasive species, and to select for a 
more invasive population within a species. The 
number of invasive species, thus, will only in-
crease for as long as current practices of global 
commercial activities continue. Between cities 
with heavy traffic, a more targeted quarantine/
inspection measure focusing on potential inva-
sive species of the source region may be one so-
lution to intercept their shipments and reduce 
propagule pressure.



 Su: Successful Invader 769

ACKNOWLEDEGMENTS

I would like to thank P. Bardunias and A. Mullins 
(University of Florida) for review of the initial draft of 
this article.

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