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Factors affecting host plant selection in alfalfa aphids

Published online by Cambridge University Press:  24 March 2023

Andja Radonjić Open the ORCID record for Andja Radonjić [Opens in a new window] ,
Ivana Jovičić Open the ORCID record for Ivana Jovičić [Opens in a new window] ,
Ivana Lalićević  and
Olivera Petrović-Obradović Open the ORCID record for Olivera Petrović-Obradović [Opens in a new window]
Andja Radonjić*
Affiliation:
Faculty of Agriculture, University of Belgrade, Nemanjina 6, 11080 Belgrade, Serbia
Ivana Jovičić
Affiliation:
Institute of Pesticides and Environmental Protection, Banatska 31b, 11080 Belgrade, Serbia
Ivana Lalićević
Affiliation:
Tamiš Research and Devalopment Institute, Ltd. Novoseljanski put 33 Street, 26000 Pančevo, Serbia
Olivera Petrović-Obradović
Affiliation:
Faculty of Agriculture, University of Belgrade, Nemanjina 6, 11080 Belgrade, Serbia
*
Author for correspondence: Andja Radonjić, Email: avucetic@agrif.bg.ac.rs
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Abstract

Alfalfa (Medicago sativa L.) hosts several species of aphid, Acyrthosiphon pisum (Harris), Aphis craccivora Koch and Therioaphis trifolii (Monell). The preference of the aphids of alfalfa plants for dense assemblies or individual plants, as well as for healthy or infested plants, was investigated in the field as in the laboratory. Years of field research have revealed the specific preferences of all three species of aphid. A. pisum and T. trifolii are most commonly found in alfalfa crops, while A. craccivora is mostly found on alfalfa weeds. Also, a single species of aphid alone is usually present on a plant. In order to determine the reason for this clear preference and to establish whether at the very beginning, i.e. at the stage of choosing a host, aphid species distance themselves from each other, we tested the effect of the volatiles of healthy and infested plants on their attractiveness to aphids. A. craccivora is repelled by the volatiles of dense crops and plants previously infested with one of the other two species. A. pisum and T. trifolii choose a dense assembly of plants, repelled by the volatiles of plants previously infested with A. craccivora. A. pisum displays the weakest competitive traits, and A. craccivora the strongest. This research showed that competition between aphid species does not occur only when they find themselves on the same plant at the same time, fighting for resources, but also in the choice of plant, in order to avoid later competition.

Keywords

Acyrthosiphon pisumalfalfaaphidsAphis craccivoracompetitionhost plant selectionTherioaphis trifolii
Type
Research Paper
Information
Bulletin of Entomological Research , Volume 113 , Issue 4 , August 2023 , pp. 439 - 448
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Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press

Introduction

Under natural conditions, one plant species often hosts several species of aphids that occupy the same or different niche at the same or different times (Gianoli, Reference Gianoli2000; van Veen et al., Reference van Veen, Brandon and Godfray2009; Liu et al., Reference Liu, Kang, Tan, Fan, Tian and Liu2020). Insect species that feed on one plant share the resources of that plant even when they are located on different plant organs or their parts. While feeding in the phloem, aphids release salivary secretions that are easily dispersed via the plant juices, so the whole plant, as well as the insects present on it, receive information about the presence and feeding of the aphids (Petersen and Sandström, Reference Petersen and Sandström2001). In addition, plant resources are limited, so the aphid species that develop on one plant are most often in some form of competition, but it is not excluded that they have a neutral or positive effect on each other (Müller and Steiner, Reference Müller and Steiner1991; Petersen and Sandström, Reference Petersen and Sandström2001). Insect feeding not only leads to a change in the nutritional value of a plant but is also reflected in a change in volatile organic compounds (VOCs) (Arimura et al., Reference Arimura, Matsui and Takabayashi2009). However, it is not only the feeding of insects that causes changes in VOCs. Abiotic factors (Gouinguené and Turlings, Reference Gouinguené and Turlings2002), as well as other biotic factors such as the communal life of plants (Ninkovic et al., Reference Ninkovic, Dahlin, Vucetic, Petrovic-Obradovic, Glinwood and Webster2013), bring about changes in the odor profiles of plants. All these changes are registered by aphids and generate a reaction. Sometimes such changes increase the attractiveness of plants to the aphids (Rajabaskar et al., Reference Rajabaskar, Wu, Bosque-Pérez and Eigenbrode2013), and sometimes they reduce it (Dahlin et al., Reference Dahlin, Vucetic and Ninkovic2015).

Alfalfa is the most important forage legume in the world (Michaud et al., Reference Michaud, Lehman, Rumbaugh, Hanson, Barnes and Hill1988) and one of the most commonly grown crops in Serbia (Katić et al., Reference Katić, Mihailović, Karagić, Vasiljević and Milić2005). Aphids can be serious pests in alfalfa fields (Blackman and Eastop, Reference Blackman and Eastop2000). In addition to fields, alfalfa plants can be found as ruderal weeds alongside roads and ditches, on urban green areas, in parks as well as volunteer alfalfa in other crops (Mueller, Reference Mueller2004). Such plants can also host aphids. Three aphid species, Acyrthosiphon pisum (Harris), Aphis craccivora Koch and Therioaphis trifolii (Monell), develop on alfalfa in Serbia and cause damages to the host plant directly by feeding and indirectly by vectoring plant-pathogenic viruses (Katis et al., Reference Katis, Tsitsipis, Stevens, Powell, Van Emden and Harrington2007; Bol, Reference Bol, Mahy and Van Regenmortel2010; Jovičić et al., Reference Jovičić, Radonjić and Petrović-Obradović2016). In alfalfa fields, the most abundant species is T. trifolii, followed by A. pisum, while A. craccivora occurs rarely in small colonies (Petrović-Obradović and Tomanović, Reference Petrović-Obradović and Tomanović2005; Jovičić et al., Reference Jovičić, Radonjić and Petrović-Obradović2016). All three species can be found in alfalfa crops throughout the growing season, but it was noticed that the highest population density of T. trifolii in alfalfa crops in Serbia was recorded in summer, A. pisum is dominant in spring and A. craccivora is the most abundant in July (Jovičic et al., Reference Jovičić, Radonjić and Petrović-Obradović2016). T. trifolii is most often found on the underside of middle leaves (Jovičić et al., Reference Jovičić, Radonjić and Petrović-Obradović2017a), A. pisum infests the growing tips of lucerne stems (Ryalls et al., Reference Ryalls, Riegler, Moore and Johnson2013), and A. craccivora develops predominantly on the stem, most often in the lower-to-middle portions, while its appearance on the petioles or leaves is rare (Berberet et al., Reference Berberet, Giles, Zarrabi and Payton2009).

By observing and monitoring the appearance of alfalfa aphids, it is possible to notice that certain species, in addition to preferring a particular part of a plant, also prefer plants that live under certain conditions. Alfalfa is grown in dense assemblies, but it is a very common ruderal plant that can be found along roadsides or as a weed amongst other crops. In order to determine whether there is regularity in the appearance of different aphid species on cultivated or weed alfalfa, the aim of our research was to collect as many samples as possible of aphids from alfalfa plants from several localities over the course of several years. In addition, our goal was to determine whether the smell of non-infested plants, as well as that of infested plants, is a factor affecting the presence of aphids on alfalfa. Do aphids decide to land on an alfalfa plant depending on the environment in which the plant lives, as an individual (as a weed) or as a dense (as cultivated) assembly of plants, and is there inter- or intraspecies competition when choosing a host plant, were questions we aimed to answer.

Materials and methods

Field research

In order to examine the presence of the three aphid species (A. craccivora, A. pisum and T. trifolii) on alfalfa plants, sampling was done at different intervals over 10 years (2011–2020). Two categories of alfalfa plants were selected: cultivated plants and alfalfa weeds. The occurrence of aphids in alfalfa fields was studied at 60 localities (82 samples) in the major growing areas in Serbia and at 41 localities (52 samples) with the presence of alfalfa as a volunteer or ruderal weed. Aphids were collected directly from plant stems and leaves and placed in plastic tubes with 70% ethanol. Identification was based on morphological characters examined using a stereomicroscope (Bio-Optica, Type 100), and the keys of Blackman and Eastop (Reference Blackman and Eastop2000).

Laboratory studies

Growing of plants for laboratory research

Alfalfa plants were produced in climatic chambers maintained at 23°C, relative humidity 60%, light 35,000 lx, with a light regime of L16:D8. Alfalfa variety K28 (Institute for Forage Crops, Kruševac, Republic of Serbia) was used for the experiment.

Plants grown for the experiment, as well as those grown to maintain the aphids, were sown in plastic pots (8 × 8 × 8 cm3), ten plants per pot. To test the effect of sparse sowing on the attractiveness of plant aphids, two plants per pot were sown. The pots were uncovered until germination of the plants.

Maintenance of aphid colonies

A laboratory population of A. craccivora, A. pisum and T. trifolii reared on alfalfa plants at insectary of Faculty of Agriculture – University of Belgrade since 2017. In the insectary, the ambient temperature was 23°C, relative humidity 60%, with a light regime of L16:D8.

Each aphid species was kept in a different chamber.

Infestation of plants for olfactory studies

Infestation of plants for the experiment was done by applying ten adult aphids per pot. When the average number of aphids per pot was 100 ± 20, the plants were ready for the experiment. Plants infested by different aphid species were kept in separate chambers to prevent plant–plant interaction of volatiles during the pre-experimental period.

For all experiments, alfalfa plants in stage 5 (early flowering) were used.

Olfactory bioassay

To study the behavioral responses of aphids to the volatiles of non-infested and infested plants, a two-way olfactometer consisting of two stimulus zones, arms (length 4 cm) directly opposite to each other connected by a neutral central zone (2.5 × 2.5 cm2) separating them, was used (Ninkovic et al., Reference Ninkovic, Dahlin, Vucetic, Petrovic-Obradovic, Glinwood and Webster2013). Both ends of the olfactometer were connected by plastic tubes to containers holding test plants. Airflow was provided by a vacuum pump and circulated over non-infested and infested plants, carrying their odor into the olfactometer arms and further on into the central zone, which was connected by a tube to the vacuum pump. Airflow in the olfactometer was set to 180 ml min−1.

Apterous viviparous females of all three species were taken from the colonies by random sampling and transferred to Petri dishes. To prevent the dehydration of individuals, Petri dishes were lined with damp filter paper. They were left to adjust to the conditions in the laboratory for 2 h before the start of the experiment. Individual aphids were inserted into the olfactometer through an opening in the upper side. After a 10-min adaptation period, the movement of the aphids in the arena of the olfactometer was monitored and their positions were recorded every 3 min during the 30 min of the experiment (ten positions). The number of repetitions for each test was 18–20 (one aphid = one repetition). Prior to each insect test, the olfactometer was rotated by 180° to avoid positional bias. After each test, the olfactometer was cleaned with 96% ethanol. The experiments were conducted in a dark room with the discrete light above olfactometer.

The response of A. craccivora, A. pisum and T. trifolii was tested on a combination of non-infested and infested plants, plants infested by different aphid species, as well as on individual plants and grouped plants. Twenty-one different treatment arrangements were designed.

We compared the following aphid preferences for: (i) individual plants (two potted plants) vs. a plant in a group (ten potted plants), (ii) non-infested plants vs. plants infested with A. craccivora, (iii) non-infested plants vs. plants infested by T. trifolii, (iv) non-infested plants vs. plants infested with A. pisum, (v) plants infested with A. pisum vs. plants infested with T. trifolii, (vi) plants infested by A. craccivora vs. plants infested with T. trifolii, and (vii) plants infested with A. pisum vs. plants infested with A. craccivora.

Data analysis

Wilcoxon's test for paired samples (StatSoft, 2011), with a significance level of P ≤ 0.05, was used to compare the number of aphid visits to each olfactometer arm.

Results

Field research

Presence of aphids in cultivated alfalfa

In the period from 2011 to 2020, a total of 82 samples were collected from 60 localities with alfalfa grown in Serbia. A single species of aphid was found in 47 samples (57.32%). A. pisum alone was found in the largest number (24 samples or 29.27%), in slightly fewer samples, T. trifolii (20 samples or 24.39%), while A. craccivora alone was found in three samples (3.66%).

Two species of aphid were found in a total of 26 samples (31.71%). A. pisum + T. trifolii in 15 samples (18.29%), A. pisum + A. craccivora in five samples (6.09%), and A. craccivora + T. trifolii in six samples (7.32%).

The total number of samples in which all three species of plant aphid were found was nine (10.96%) (table 1).

Table 1. Location of the sampling sites, geographical coordinates, dates of sampling, and collected aphid species on cultivated alfalfa (Serbia, 2011–2020)

Ap, A. pisum; Ac, A. craccivora; Tt, T. trifolii.

Alfalfa as a volunteer or ruderal weed

Out of a total of 52 samples from alfalfa weeds, A. craccivora alone was found in 49 (94.23%). The other two species were not found on their own. T. trifolii was found together with A. craccivora in three samples, which is 5.77% of the total number of infested weed alfalfa plants (table 2).

Table 2. Location of the sampling sites, geographical coordinates, dates of sampling, and collected aphid species on alfalfa as a volunteer or ruderal weed (Serbia, 2011–2020)

Ap, A. pisum; Ac, A. craccivora; Tt, T. trifolii.

Laboratory bioassay

Test of aphid preferences according to the density of plant assembly

Tests of species preference for plants growing in dense or thinned assemblies showed that A. craccivora prefers a thinned assembly (Z = 2.18, P = 0.029, N = 17), while A. pisum and T. trifolii prefer a dense assembly of plants (Z = 3.147, P = 0.0016, N = 17; Z = 2.38, P = 0.017, N = 16) (fig. 1).

Figure 1. Aphid olfactory responses to volatiles of thinned or dense assemblies of alfalfa plants. Asterisks indicate significant preferences. *P < 0.05, **P < 0.01, Wilcoxon's matched pair test.

Olfactory response of A. craccivora to non-infested and infested plants

Non-infested plants and plants previously infested with its own species were chosen equally by A. craccivora (Z = 0.166, P = 0.87, N = 17). Also, in the attractiveness test of plants infected with A. pisum and T. trifolii, A. craccivora showed no statistically significant attraction to any of the infested plants (Z = 0.26, P = 0.79, N = 19). It showed a statistically significant preference for plants infested with its own species relative to plants infested with A. pisum or T. trifolii (Z = 2.68, P = 0.007, N = 18; Z = 2.16, P = 0.031, N = 2.16). However, between non-infested plants and plants infested by the other two species, it statistically significantly more often selected healthy plants: A. pisum (Z = 2.13, P = 0.03, N = 17) and T. trifolii (Z = 3.172, P = 0.0015, N = 17) (fig. 2).

Figure 2. A. craccivora olfactory responses to volatiles of non-infested (healthy) or infested alfalfa plants. Asterisks indicate significant preferences. *P < 0.05, **P < 0.01, Wilcoxon's matched pair test.

Olfactory response of A. pisum to non-infested and infested plants

In the selection test between plants previously infested with A. pisum and non-infested plants, A. pisum chose more infested plants, however not statistically significantly (Z = 1.72, P = 0.08, N = 18). It did not differentiate between non-infested and T. trifolii-infested plants (Z = 0.11, P = 0.91, N = 18), nor between plants infested with A. pisum and T. trifolii (Z = 1.05, P = 0.29, N = 19). When choosing between A. craccivora-infested and non-infested plants, it was statistically significantly attracted more to non-infested plants (Z = 2.07, P = 0.038, N = 16). In all other combinations where on the one side there were plants infested with A. craccivora, it statistically significantly chose the other side, plants infested with A. pisum (Z = 1.99, P = 0.046, N = 16), plants infested with T. trifolii (Z = 3.05, P = 0.002, N = 19) (fig. 3).

Figure 3. A. pisum olfactory responses to volatiles of non-infested (healthy) or infested alfalfa plants. Asterisks indicate significant preferences. *P < 0.05, **P < 0.01, Wilcoxon's matched pair test.

Olfactory response of T. trifolii to non-infested and infested plants

In the test of choice between non-infested plants and plants previously infested with its own species, T. trifolii did not show a statistically significantly preference for either side (Z = 1.29, P = 0.19, N = 16). In all combinations in which A. craccivora-infested plants were on one side, it chose the other side: non-infested plants (Z = 3.74, P = 0.0001, N = 19), T. trifolii (Z = 2.69, P = 0.007, N = 16), A. pisum (Z = 2.66, P = 0.007, N = 16). In the selection test between a non-infested plant and one infested with A. pisum, non-infested plants were chosen (Z = 2.58, P = 0.009, N = 16), and between T. trifolii and A. pisum, it chose T. trifolii (Z = 3.32, P = 0.0009, N = 19) (fig. 4).

Figure 4. T. trifolii olfactory responses to volatiles of non-infested (healthy) or infested alfalfa plants. Asterisks indicate significant preferences. *P < 0.05, **P < 0.01, Wilcoxon's matched pair test.

Discussion

Our field research indicates that the presence of three aphid species on alfalfa plants depends on the conditions in which the plants are grown (cultivated or weed), as well as on the physiological status of the plant, i.e. whether a plant is non-infested or infested by aphids. Laboratory research has shown that the reason for this specific preference may be plant odors.

Analyzing the presence of aphids on plants collected in the field, it was noticed that each of the three observed species had a clear preference for plants with either a dense assembly or for plants that grow as weeds. A. pisum and T. trifolii were predominantly found in crops. In contrast to these two species, the presence of A. craccivora was very rarely registered in alfalfa crops, while on ruderal alfalfa weeds it was found alone in over 94% of the infested samples. These results are consistent with several studies showing that A. pisum and T. trifolii form dense colonies in alfalfa crops and are significant pests of cultivated alfalfa (Barberet et al., Reference Barberet, Arnold and Soteres1983; Sunnucks et al., Reference Sunnucks, Driver, Brown, Carver, Hales and Milne1997; Julier et al., Reference Julier, Bournoville, Landre, Ecalle and Carre2004; Pons et al., Reference Pons, Núñez, Lumbierres and Albajes2005; Rakhshani et al., Reference Rakhshani, Ebadi and Mohmmadi2010; Ryalls et al., Reference Ryalls, Riegler, Moore and Johnson2013; Grez et al., Reference Grez, Zaviezo and Gardiner2014; Ximenez-Embun et al., Reference Ximenez-Embun, Zaviezo and Grez2014). Also, A. craccivora is often not considered a significant pest of cultivated alfalfa because it occurs in small numbers with irregular distribution in the field (Pons et al., Reference Pons, Lumbierres and Albajes2009, Reference Pons, Lumbierres, Comas, Madeira and Stary2013; Ryalls et al., Reference Ryalls, Riegler, Moore and Johnson2013). It is interesting that A. craccivora is often found in the yellow water traps placed in alfalfa crops, but very rarely on plants, which means that it crosses fields, but rarely lands in dense crops (Jovičić et al., Reference Jovičić, Radonjić and Petrović-Obradović2017b).

Laboratory research has confirmed the predictability noted in the field and emphasizes the importance of plant odor as a signal aphids need in their search for a host plant. All plant species have a specific VOC that they emit under natural conditions (Ahmed et al., Reference Ahmed, Darshanee, Khan, Zgang and Liu2019). Plants release a variety of different volatile compounds that provide aphids with information that allows them to discriminate between host and non-host plants (Webster, Reference Webster2012). However, when growing together, plants change their odor profiles as they adapt to each other, so the smell of a plant differs depending on whether it lives alone or in a community with other individuals. These are small differences, but the aphids can detect them (Ninkovic et al., Reference Ninkovic, Rensing, Dahlin and Markovic2019), and our research confirms this theory. But what could be the reason for one species of aphid to prefer alfalfa plants that live in a dense assembly, while another prefers solitary plants? We can look for reasons in the biology of the species. Under the climatic conditions of Serbia, A. pisum and T. trifolii are holocyclic, while A. craccivora is predominantly anholocyclic. All three are monoecious. Perhaps the fact that a sexual generation must be formed and eggs laid directs T. trifolii and A. pisum toward dense assemblies of plants where the possibility of finding individuals of the same species and laying eggs to overwinter is greater than on solitary plants.

Herbivore-induced plant volatiles (HIPVs), which the plant emits when an insect is feeding, are different from basic VOCs. When insects feed on plants, the production of VOCs increases, and qualitative changes occur. The host plant selection of herbivores varies depending on quantitative and qualitative changes in the odor of the host plants (Ahmed et al., Reference Ahmed, Darshanee, Khan, Zgang and Liu2019).

The results of our field research clearly show that different species of aphid avoid each other in most cases, i.e. they are most often found alone on plants. This is particularly pronounced in A. craccivora, which was rarely found in cultivated crops in combination with one of the other two species, and in weed alfalfa it was almost always alone. Only in slightly more than 5% of the samples was it found in combination with T. trifolii. A single species of aphid was found in cultivated alfalfa in more than half of the analyzed samples. Two species together were found in 31% of cases, of which the dominant combination was A. pisum + T. trifolii. Laboratory research is consistent with fieldwork because it has shown that each species responds in a specific way to changes in the VOCs caused by one of the three species tested. HIPV are species-specific (McCormick et al., Reference McCormick, Unsicker and Gershenzon2012), so all three species, in most cases, avoided plants previously infested with another species. All three species always showed a statistically significantly preference for non-infested plants over plants infested with another species. Between non-infested plants and plants infested with their own species, the aphids made no distinction. It is as if induced plant volatiles of their own species are not recognized as a change in the scent of the host plant. Interestingly, A. pisum did not react to the changes caused by the feeding of T. trifolii. Although it is known that the harmfulness of T. trifolii on alfalfa is increased through the secretion of toxic saliva, which strongly affects the physiology of the plant (Berg and Boyd, Reference Berg and Boyd1984) and thus changes in its odor profile, A. pisum did not recognize these changes. On the other hand, T. trifolii avoided plants already infested with A. pisum. As we have already mentioned, A. pisum is dominant during spring, while T. trifolii is most abundant during summer (Jovičić et al., Reference Jovičić, Radonjić and Petrović-Obradović2016). T. trifolii is a species that inhabits plants at a time when A. pisum is already present and tries to avoid already infested plants. In contrast, A. pisum, as the species already established on plants when T. trifolii arrives, seems to have no cause to recognize odors that arise after T. trifolii infestation.

The most pronounced competitive traits were shown by A. craccivora, which in all combinations avoided plants previously infested with one of the other two species, while the other two species avoided plants infested with A. craccivora. A. craccivora is present on plants throughout vegetation but is most numerous during the summer (Jovičić et al., Reference Jovičić, Radonjić and Petrović-Obradović2016), which means that the time of its most intensive development on plants coincides with the time when the other two species appear in large numbers. Although it is a very polyphagous species (Mehrparvar et al., Reference Mehrparvar, Madjdzadeh, Mahdavi Arab, Esmaeilbeygi and Ebrahimpour2012), it recognizes the odors of healthy host plants (Pettersson et al., Reference Pettersson, Karunaratne, Ahmed and Kumar1998), even different varieties of the same plant species (Diabate et al., Reference Diabate, Deletre, Murungi, Fiaboe, Wesonga and Martin2019), so it is not surprising that it recognizes the odor of infested plants and avoids them. On the other hand, it has a huge reproductive potential that is reflected in the fact that in alfalfa under optimal conditions one generation develops in 6–9 days, and a single female produces over 80 larvae (Berberet et al., Reference Berberet, Giles, Zarrabi and Payton2009). The feeding of such dense colonies of A. craccivora leads to a change in the odor profile of plants, which is confirmed by studies of the behavior of ladybugs which efficiently find infested plants (Fouad, Reference Fouad2021). Our research shows that these changes have a repellent effect on T. trifolii and A. pisum, which is in line with research showing that changes in VOCs that are attractive to natural enemies (Vučetić et al., Reference Vučetić, Dahlin, Petrović-Obradović, Glinwood, Webster and Ninkovic2014) are repellent to aphids (Dahlin et al., Reference Dahlin, Vucetic and Ninkovic2015).

Competition between different species of aphid and even individuals of the same species when overbreeding occurs is known and studied (Müller and Steiner, Reference Müller and Steiner1991). However, most research deals with competition at the level of population development (Müller and Godfray, Reference Müller and Godfray1997; Petersen and Sandström, Reference Petersen and Sandström2001; Portha and Detrain, Reference Portha and Detrain2004). Our research differs in that we investigated the initial phase, i.e. the search for a host plant and the reaction of different species of aphid to already infested plants. Plant odor is an equally important signal for oligophagous species such as A. pisum and T. trifolii and polyphagous species like A. craccivora.

Acknowledgments

This study was funded by the Ministry of Education, Science and Technological Development of the Republic of Serbia (Grant Nos. 451-03-47/2023-01/200116 and, 451-03-47/2023-01/200214 and 451-03-47/2023-01/200054).

Conflict of interest

The authors declare no conflict of interest.

References

Ahmed, N, Darshanee, HLC, Khan, IA, Zgang, Z-F and Liu, T-X (2019) Host selection behavior of the green peach aphid, Myzus persicae, in response to volatile organic compounds and nitrogen contents of cabbage cultivars. Frontiers in Plant Science 10, 79.CrossRefGoogle ScholarPubMed
Arimura, G, Matsui, K and Takabayashi, J (2009) Chemical and molecular ecology of herbivore-induced plant volatiles: proximate factors and their ultimate functions. Plant and Cell Physiology 50, 911923.CrossRefGoogle ScholarPubMed
Barberet, RC, Arnold, DC and Soteres, KM (1983) Geographical occurrence of Acyrthosiphon pisum (Harris), and Therioaphis maculate (Buckton) (Homoptera: Aphididae). Journal of Economic Entomology 76, 10641068.CrossRefGoogle Scholar
Berberet, RC, Giles, KL, Zarrabi, AA and Payton, ME (2009) Development, reproduction, and within-plant – infestation patterns of Aphis craccivora (Homoptera: Aphididae) on Alfalfa. Environmental Entomology 38, 17651771.CrossRefGoogle ScholarPubMed
Berg, G and Boyd, MEJ (1984) Insects in Lucerne: A Guide to Identification and Control of Insects in Lucerne. Carrum Downs, Victoria, Australia: Grassland Society of Victoria.Google Scholar
Blackman, RL and Eastop, VF (2000) Aphids on the World's Crops. An Identification and Information Guide, 2nd Edn. London, UK: Natural History Museum, 466p.Google Scholar
Bol, JF (2010) Alfalfa mosaic virus. In Mahy, BWJ and Van Regenmortel, MHV (eds), Desk Encyclopedia of Plant and Fungal Virology. Oxford, UK: Elsevier and Academic Press, pp. 8591.Google Scholar
Dahlin, I, Vucetic, A and Ninkovic, V (2015) Changed host plant volatile emissions induced by chemical interaction between unattacked plants reduce aphid plant acceptance with intermorph variation. Journal of Pest Science 88, 249257.CrossRefGoogle Scholar
Diabate, S, Deletre, E, Murungi, KL, Fiaboe, KKM, Wesonga, J and Martin, T (2019) Behavioural response of alate Aphis craccivora Koch (Homoptera: Aphididae) to volatiles from different cowpea cultivars. Journal of Applied Entomology 143, 659669.CrossRefGoogle Scholar
Fouad, HA (2021) Responses of the predatory species, Coccinella undecimpunctata L. (Coleoptera: Coccinellidae), to the volatiles from its prey, Aphis craccivora Koch. and Vicia faba plant. Egyptian Journal of Biological Pest Control 31, 76.CrossRefGoogle Scholar
Gianoli, E (2000) Competition in cereal aphids (Homoptera: Aphididae) on wheat plants. Environmental Entomology 29, 213219.CrossRefGoogle Scholar
Gouinguené, SP and Turlings, TCJ (2002) The effects of abiotic factors on induced volatile emissions in corn plants. Plant Physiology 129, 12961307.CrossRefGoogle ScholarPubMed
Grez, AA, Zaviezo, T and Gardiner, MM (2014) Local predator composition and landscape affects biological control of aphids in alfalfa fields. Biological Control 76, 19.CrossRefGoogle Scholar
Jovičić, I, Radonjić, A and Petrović-Obradović, O (2016) Alfalfa aphids (Hemiptera: Aphididae) and coccinellid predators in Serbia: seasonal abundance. Acta Zoologica Bulgarica 68, 581587.Google Scholar
Jovičić, I, Radonjić, A and Petrović-Obradović, O (2017a) Spotted alfalfa aphid, Therioaphis trifolii (Monell) (Hemiptera: Aphididae): pest on alfalfa in Serbia. Plant Doctor 45, 384390.Google Scholar
Jovičić, I, Radonjić, A and Petrović-Obradović, O (2017b) Flight activity of aphids as potential vectors of viral infection of alfalfa in Serbia. Pesticides and Phytomedicine 32, 173179.CrossRefGoogle Scholar
Julier, B, Bournoville, R, Landre, B, Ecalle, C and Carre, S (2004) Genetic analysis of lucerne (Medicago sativa L.) seedling resistance to pea aphid (Acyrthosiphon pisum Harris). Euphytica 138, 133139.CrossRefGoogle Scholar
Katić, S, Mihailović, V, Karagić, P, Vasiljević, P and Milić, D (2005) Growing and use of alfalfa and clover. Plant Doctor 33, 483491.Google Scholar
Katis, NI, Tsitsipis, JA, Stevens, M and Powell, G (2007) Transmission of plant viruses. In Van Emden, HF and Harrington, R (eds), Aphids as Crop Pests. London: CABI Publishing, pp. 353390.CrossRefGoogle Scholar
Liu, F-H, Kang, Z-W, Tan, X-L, Fan, Y-L, Tian, H-G and Liu, T-X (2020) Physiology and defense responses of wheat to the infestation of different cereal aphids. Journal of Integrative Agriculture 19, 14641474.CrossRefGoogle Scholar
McCormick, AC, Unsicker, SB and Gershenzon, J (2012) The specificity of herbivore-induced plant volatiles in attracting herbivore enemies. Trends in Plant Science 17, 303310.CrossRefGoogle Scholar
Mehrparvar, M, Madjdzadeh, SM, Mahdavi Arab, N, Esmaeilbeygi, M and Ebrahimpour, E (2012) Morphometric discrimination of black legume aphid, Aphis craccivora Koch (Hemiptera: Aphididae), populations associated with different host plants. North-Western Journal of Zoology 8, 172180.Google Scholar
Michaud, R, Lehman, WF and Rumbaugh, MD (1988) World distribution and historical development. In Hanson, AA, Barnes, DK and Hill, RR (eds), Alfalfa and Alfalfa Improvement. Agronomy Monograph vol 29. Madison, Wisconsin, USA: American Society of Agronomy, Crop Science Society of America, Soil Science Society of America, pp. 2591.Google Scholar
Mueller, S (2004) Seed production issues for genetically enhanced alfalfa. In: Proceedings, National Alfalfa Symposium, 14–15 December, 2004, San Diego, CA, UC Cooperative Extension, University of California, Davis 95616.Google Scholar
Müller, CB and Godfray, HCJ (1997) Apparent competition between two aphid species. Journal of Animal Ecology 66, 5764.CrossRefGoogle Scholar
Müller, PF and Steiner, H (1991) Mutual influence between aphids on a joint host plant. Beiträge zur Entomologie 41, 265270.Google Scholar
Ninkovic, V, Dahlin, I, Vucetic, A, Petrovic-Obradovic, O, Glinwood, R and Webster, B (2013) Volatile exchange between undamaged plants: a new mechanism affecting insect orientation in intercropping. PLoS ONE 8, e69431.CrossRefGoogle ScholarPubMed
Ninkovic, V, Rensing, M, Dahlin, I and Markovic, D (2019) Who is my neighbor? Volatile cues in plant interactions. Plant Signaling & Behavior 14, 1634993.CrossRefGoogle ScholarPubMed
Petersen, MK and Sandström, JP (2001) Outcome of indirect competition between two aphid species mediated by responses in their common host plant. Functional Ecology 15, 525534.CrossRefGoogle Scholar
Petrović-Obradović, O and Tomanović, Ž (2005) Aphids: pests of alfalfa and clover. Plant Doctor 33, 534538.Google Scholar
Pettersson, J, Karunaratne, S, Ahmed, E and Kumar, V (1998) The cow-pea aphid, Aphis craccivora, host plant odours and pheromones. Entomologia Experimentalis et Applicata 88, 177184.CrossRefGoogle Scholar
Pons, X, Núñez, E, Lumbierres, B and Albajes, R (2005) Epigeal aphidophagous predators and the role of alfalfa as a reservoir of aphid predators for arable crops. European Journal of Entomology 102, 519525.CrossRefGoogle Scholar
Pons, X, Lumbierres, B and Albajes, R (2009) Heteropterans as aphid predators in inter-mountain alfalfa. European Journal of Entomology 106, 369378.CrossRefGoogle Scholar
Pons, X, Lumbierres, B, Comas, J, Madeira, F and Stary, P (2013) Effects of surrounding landscape on parasitism of alfalfa aphids in IPM crop system in Northern Catalonia. BioControl 58, 733744.CrossRefGoogle Scholar
Portha, S and Detrain, C (2004) Local population dynamics of two co-existing birch aphid species: competition or intrinsic cycles of abundance? Belgian Journal of Zoology 134, 8588.Google Scholar
Rajabaskar, D, Wu, Y, Bosque-Pérez, NA and Eigenbrode, SD (2013) Dynamics of Myzus persicae arrestment by volatiles from potato leafroll virus-infected potato plants during disease progression. Entomologia Experimentalis et Applicata 148, 172181.CrossRefGoogle Scholar
Rakhshani, H, Ebadi, R and Mohmmadi, AA (2010) Population dynamics of alfalfa aphids and their natural enemies, Isfahan, Iran. Journal of Agricultural Science and Technology 11, 505520.Google Scholar
Ryalls, JMW, Riegler, M, Moore, BD and Johnson, SN (2013) Biology and trophic interactions of lucerne aphids. Agricultural and Forest Entomology 15, 335350.CrossRefGoogle Scholar
Statistica (Data Analysis Software System) v. 10 (2011) StatSoft, Inc., Tulsa, OK, USA.Google Scholar
Sunnucks, P, Driver, F, Brown, WV, Carver, M, Hales, DF and Milne, WM (1997) Biological and genetic characterisation of morphologicaly similar Therioaphis trifolii (Hemiptera: Aphididae) with different host utilization. Bulletin of Entomological Research 87, 425436.CrossRefGoogle Scholar
van Veen, FJF, Brandon, CE and Godfray, HCJ (2009) A positive trait-mediated indirect effect involving the natural enemies of competing herbivores. Oecologia 160, 195205.CrossRefGoogle ScholarPubMed
Vučetić, A, Dahlin, I, Petrović-Obradović, O, Glinwood, R, Webster, B and Ninkovic, N (2014) Volatile interaction between undamaged plants affects tritrophic interactions through changed plant volatile emission. Plant Signaling & Behavior 9, e29517.CrossRefGoogle ScholarPubMed
Webster, B (2012) The role of olfaction in aphid host location. Physiological Entomology 37, 1018.CrossRefGoogle Scholar
Ximenez-Embun, MG, Zaviezo, T and Grez, A (2014) Seasonal, spatial and diel partitioning of Acyrthosiphon pisum (Hemiptera: Aphididae) predators and predation in alfalfa fields. Biological Control 69, 17.CrossRefGoogle Scholar
Figure 0

Table 1. Location of the sampling sites, geographical coordinates, dates of sampling, and collected aphid species on cultivated alfalfa (Serbia, 2011–2020)

Figure 1

Table 2. Location of the sampling sites, geographical coordinates, dates of sampling, and collected aphid species on alfalfa as a volunteer or ruderal weed (Serbia, 2011–2020)

Figure 2

Figure 1. Aphid olfactory responses to volatiles of thinned or dense assemblies of alfalfa plants. Asterisks indicate significant preferences. *P < 0.05, **P < 0.01, Wilcoxon's matched pair test.

Figure 3

Figure 2. A. craccivora olfactory responses to volatiles of non-infested (healthy) or infested alfalfa plants. Asterisks indicate significant preferences. *P < 0.05, **P < 0.01, Wilcoxon's matched pair test.

Figure 4

Figure 3. A. pisum olfactory responses to volatiles of non-infested (healthy) or infested alfalfa plants. Asterisks indicate significant preferences. *P < 0.05, **P < 0.01, Wilcoxon's matched pair test.

Figure 5

Figure 4. T. trifolii olfactory responses to volatiles of non-infested (healthy) or infested alfalfa plants. Asterisks indicate significant preferences. *P < 0.05, **P < 0.01, Wilcoxon's matched pair test.