Tag Archives: take-off angle

Not all aphids get lost

Although aphids are very good at kicking, we know that aphids would not be very good at football as they are very short-sighted (Doring et al., 2008) but does that mean that they are not very good at finding their host plants? There is a common misperception, and not just confined to non-entomologists, that aphids are no more than aerial plankton. In 1924 Charles Elton

Lost 1

whilst on an expedition to Nordaustlandet* (the second largest of the Spitsbergen group and almost entirely covered by ice) reported finding large numbers of aphids, many still alive, later identified as Dilachnus piceae (now known as Cinara piceae) (Elton, 1925).

Lost 2

Cinara piceae the Greater Black Spruce Aphid –big and beautiful.

 

He suggested that the aphids came from the Kola Peninsula, a distance of about 800 miles (almost 1300 km) due to the strong south and south-east winds blowing at the time. He estimated that they would have made the journey within twelve to twenty-four hours. This was regarded as being an example of totally passive migration and used as one of many examples of aerial plankton** (Gislen, 1948). This is, however, probably not giving aphids credit for what they are capable of doing when it comes to flight. Berry & Taylor (1968), who sampled aphids at 610 m above the grounds using aeroplanes, implied that the aphids, although using jet streams, were flying rather than floating (page 718 and page 720) and that they would descend to the ground in the evening and not fly during the night.

Lost 3

Aphids don’t usually fly during the night. (From Berry & Taylor (1968)).

Dixon (1971) interprets this somewhat differently and suggests that the “movement of the air in which it is flying determines the direction of its flight and the distance it will travel” but then goes on to say “after flying for an hour or two aphids settle indiscriminately on plants”. So yes the speed of the air in which the aphid is flying will determine how far it flies in a set time, but as aphids can fly much longer than an hour or two, active flights of from between 7-12 hours have been recorded (Cockbain, 1961), this rather suggests that the aphids are making a “decision” to stop flying and descend from the jet stream. That said, in the words of the great C.G. Johnson “aphids are weak flyers”, they cannot make progress against headwinds of more than 2 km per hour (Johnson, 1954), although Trevor Lewis gives them slightly more power and suggests that the can navigate against winds of up to 3 km per hour (Lewis, 1964).

Whatever the upper limit is, it doesn’t mean that they are powerless when it comes to ‘deciding’ when to stop flying. In the words of Hugh Loxdale and colleagues, “aphids are not passive objects” (Loxdale et al, 1993). Aphidologists, were until the 1980s (Kennedy, 1986), generally somewhat sceptical about the ability of aphids to direct their flight in relation to specific host finding from the air and not just flying towards plants of the right colour (Kennedy et al., 1961), or at all after take-off (Haine, 1955). The general consensus now, is that aphids control the direction of their flight in the boundary layer*** but that it is determined by the wind at higher altitudes (Loxdale et al., 1993).   Whilst we are discussing viewpoints, another point of debate is on whether aphids migrate or not. Loxdale et al., (1993) state that “migration can be viewed ecologically as population redistribution through movement, regardless of whether deliberate of uncontrolled or from the behavioural viewpoint of a persistent straightened-out movement affected by the animal’s own locomotory exertions or by its active embarkation on a vehicle”. In the case of aphids the vehicle could be the wind. Under both definitions, aphids can be defined as undertaking migrations. Long-distance migration by aphids is defined as being greater than 20 km and short-distance (local) migration being less than this (Loxdale et al., 1993). Long-distance migration is likely to be the exception rather than the rule with most aphids making local flights and not venturing out of the boundary layer, sometimes travelling distances no more than a few hundred metres (Loxdale et al., 1993).

There are different types of winged aphids (morphs) and these show different angles of take-off and rates of climb.  In Aphis fabae for example, which host –alternates between spindle and bean, the gynoparae which migrate from the secondary host to the primary host, have a steeper angle of take-off and climb more rapidly than the alate exules which only disperse between the secondary host plants (David & Hardie, 1988).

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http://influentialpoints.com/Images/Rhopalosiphum_padi_emigrant_alate_departing_from_primary_host_c2013-05-21_11-25-12ew.jpg

The gynoparae are thus much more likely to end up in the jet stream and be carried longer distances, with, of course, a greater chance of getting lost (Ward et al., 1998). The alate exules however, may only land in the next field or even in the same one, and easily find a new host plant (Loxdale et al., 1993). These differences between the morphs of host alternating aphids are also seen in the bird cherry-oat aphid Rhopalosiphum padi (Nottingham et al., 1991).  Once safely air-borne, the aphids then have another set of problems to overcome.

How do they ‘decide’ when to land? How do they ‘know’ that there are host plants below them? Aphids have two main senses that help them locate their host plants, vision and smell (odour recognition) (Kring, 1972; Döring, 2014). Generally speaking, aphids respond positively to what we perceive as green or yellow light and negatively to blue and red light (Döring & Chittka, 2007) although this is not an absolute rule. Some aphids are known to preferentially choose yellowing leaves (sign of previous infestation) e.g. Black Pecan Aphid Melanocallis caryaefoliae (Cottrell et al., 2009) which indicates a pretty sophisticated host finding suite of behaviours. Aphids in flight chambers will delay landing if presented with non-host odours even in the presence of a green target (Nottingham & Hardie, 1993) and conversely can be attracted to colourless water traps that have been scented with host plant odours (Chapman et al., 1981). Aphids are thus using both visual and olfactory cues to locate their host plants and to ‘decide’ when to descend from the jet stream or boundary layer (Kring, 1972; Döring, 2014). They are not merely aerial plankton, nor are they entirely at the mercy of the winds, they do not deserve to be described as passive (Reynolds & Reynolds, 2009).

Once at ground level and on a potential host plant, aphids go through a complicated suite of behaviours to determine if the host is suitable or not; if the plant meets all the required

Lost 5

From air to plant – how aphids chose their host plants – after Dixon (1973).

 

criteria, then the aphid will start feeding and reproducing. It is interesting to note that although there may be a lot of aphids in the air, the number of plants on the ground that

Lost 6

Settled safely and producing babies 🙂

http://beyondthehumaneye.blogspot.co.uk/2012/06/aphids.html  https://simonleather.files.wordpress.com/2016/04/cd0a4-aphidbirth2small.jpg

 

are infested with them is relatively low, about 10% in a diverse landscape (Staab et al., 2015), although in a crop, the level of infestation can approach 100% (e.g. Carter et al., 1980). The fact that in some cases less than 1% of those that set off will have found a host plant (Ward et al., 1998) is not a problem when you are a member of clone; as long as not all of the members of a clone gets lost the journey has been a success.

They may be small, they may be weak flyers, but enough of them find a suitable host plant to keep the clone alive and kicking; not all aphids get lost.

 

References

Carter, N., Mclean, I.F.G., Watt, A.D., & Dixon, A.F.G. (1980) Cereal aphids – a case study and review. Applied Biology, 5, 271-348.

Chapman, R.F., Bernays, E.A., & Simpson, S.J. (1981) Attraction and repulsion of the aphid, Cavariella aegopodii, by plant odors. Journal of Chemical Ecology, 7, 881-888.

Cockbain, A.J. (1961) Fuel utilization and duration of tethered flight in Aphis fabae Scop. Journal of Experimental Biology, 38, 163-174.

Cottrell, T.E., Wood, B.W. & Xinzhi, N. (2009) Chlorotic feeding injury by the Black Pecan Aphid (Hemiptera: Aphididae) to pecan foliage promotes aphid settling and nymphal development. Environmental Entomology, 38, 411-416

David, C.T. & Hardie, J. (1988) The visual responses of free-flying summer and autumn forms of the black bean aphid, Aphis fabae, in an automated flight chamber. Physiological Entomology, 13, 277-284.

Dixon, A.F.G. (1971) Migration in aphids. Science Progress, Oxford, 59, 41-53.

Dixon, A.F.G. (1973) Biology of Aphids, Edward Arnold, London.

Döring, T.F. & Chittka, L. (2007) Visual ecology of aphids – a classcial review on the role of colours in host finding. Arthropod-Plant Interactions, 1, 3-16.

Döring, T., Hardie, J., Leather, S.R., Spaethe, J., & Chittka, L. (2008) Can aphids play football? Antenna, 32, 146-147.

Döring, T. (2014) How aphids find their host plants, how they don’t. Annals of Applied Biology, 165, 3-26.

Elton, C.S. (1925) The dispersal of insects to Spitsbergen. Transactions of the Entomological Society of London, 73, 289-299.

Gislen, T. (1948) Aerial plankton and its conditions of life. Biological Reviews, 23, 109-126.

Haine, E. (1955) Aphid take-off in controlled wind speeds. Nature, 175, 474-475

Johnson, C.G. (1951) The study of wind-borne insect populations in relation to terrestrial ecology, flight periodicity and the estimation of aerial populations. Science Progress, 39, 41-62.

Johnson, C.G. (1954) Aphid migration in relation to weather. Biological Reviews, 29, 87-118

Kennedy, J. S., Booth, C. O. & Kershaw, W. J. S. (1961). Host finding by aphids in the field III Visual attraction. Annals of Applied Biology, 49, 1-21.

Kring, J.B. (1972) Flight behavior of aphids. Annual Review of Entomology, 17, 461-492.

Lewis, T. (1964) The effects of shelter on the distribution of insect pests. Scientific Horticulture, 17, 74-84

Loxdale, H. D., Hardie, J., Halbert, S., Foottit, R., Kidd, N. A. C. &Carter, C. I. (1993).The relative importance of short-range and long-range movement of flying aphids. Biological Reviews of the Cambridge Philosophical Society, 68, 291-312.

Nottingham, S.F., Hardie, J. & Tatchell, G.M. (1991) Flight behaviour of the bird cherry aphid, Rhopalosiphum padi. Physiological Entomology, 16, 223-229.

Reynolds, A.M. & Reynolds, D.R. (2009)  Aphid aerial desnsity profiles are consistent with turbulent advection amplifying flight behaviours: abandoning the epithet ‘passive’. Proceedings of the Royal Society B, 276, 137-143.

Staab, M., Blüthgen, N., & Klein, A.M. (2015) Tree diversity alters the structure of a tri-trophic network in a biodiversity experiment Oikos, 124, 827-834.

Ward, S.A., Leather, S.R., Pickup, J., & Harrington, R. (1998) Mortality during dispersal and the cost of host-specificity in parasites: how many aphids find hosts? Journal of Animal Ecology, 67, 763-773.

 

Post script

Political and geographic borders are not factors that deter aphid migrants, Wiktelius (1984) points out that aphids regularly make the journey across the Baltic in both directions to and from Sweden.

Wiktelius, S. (1984) Long range migration of aphids into Sweden. International Journal of Biometeorology, 28, 185-200.

 

*Elton refers to it as North-East Land

** Johnson (1951) objects to this terminology in no uncertain terms. That said, as there are records of non-winged aphids being caught by aircraft (Kring, 1972), it does suggest that there may be some accidental migration going on.

*** The UK Met Office defines the boundary layer as “that part of the atmosphere that directly feels the effect of the earth’s surface” and goes on to say that depending on local conditions it can range in depth from a few metres to several kilometres.

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Filed under Aphidology, Aphids

Not all aphids take the same risks

In 1970 an entomologist working on the black bean aphid, Aphis fabae, at Rothamsted Experimental Station (as it then was),  noted that he could categorise the winged individuals as either migrants, flyers or non-flyers; the former flying before they reproduced, the second flying after they reproduced and the final category, never flying (Shaw, 1970).  To describe this phenomenon he used the phrase “migratory urge” a term previously only used in the ornithological literature.

A few years later a group of PhD students in Tony Dixon’s lab at the University of East Anglia started dissecting aphids and counting their ovarioles, finding that unlike most other insects, ovariole number was variable within a species and not related to adult weight (Dixon & Dharma, 1980; Wellings et al., 1980; Leather, 1983).  Generally speaking, in insects, including aphids, the heavier they are, the more fecund they are, although in some instances this is not always true (Leather, 1988).

Ovarioles Fig 1

Figure 1 taken from http://www.aphidsonworldsplants.info/Cloning_Experts_3.htm

Ovarioles Fig 2

Figure 2 What aphid ovarioles really look like Dombrovsky  et al. BMC Research Notes 2009 2:185   doi:10.1186/1756-0500-2-185

What we found then (Wellings et al., 1980), and later (Leather et al., 1988), was that aphids with wings (alatae) even those from the same clone, had much more variability in the number of ovarioles contained within them than those without wings (apterae) (Leather et al., 1988), and that the more ovarioles an aphid contained the more fecund it was, although as mentioned earlier the number of ovarioles appeared to be independent of weight (Leather & Wellings, 1981).

So what does this have to do with migratory urge in Aphis fabae? In the early 1980s Keith Walters was working on migration in cereal aphids (Sitobion avenae and Rhopalosiphum padi) and discovered, that as with Aphis fabae these two species also produced alatae with different flight attributes (Walters & Dixon, 1983).  Building on what we in our group had discovered about ovarioles, Keith was able to show that the degree of migratory urge in aphids was determined by the number of ovarioles they contained. The greater the number of ovarioles the more reluctant they were to take flight (Figure 3ab).

Ovarioles Fig 3a

Figure 3a Relationship between number of ovarioles and time to take-off (minutes) in Sitobion avenae  (Drawn from data in Walters & Dixon, 1983).

Ovarioles Fig 3b

Figure 3b Relationship between number of ovarioles and time to take-off (minutes) in Rhopaloisphum padi  (Drawn from data in Walters & Dixon, 1983).

 He also found that the fewer the number of ovarioles, the steeper the angle of take-off was (Figure 4) i.e. aphids with few ovarioles climbed faster and more steeply and were thus more likely to end  up higher in the air, and thus more likely to travel further than those

Ovarioles Fig 4

Figure 4 Relationship between number of ovarioles and angle of take-off (degrees) in Rhopalosiphum padi (drawn from data in Walters & Dixon, 1983).

taking off at a shallower angle.  He also showed that resistance to starvation was greater in those aphids with fewer ovarioles and that they could also fly for longer periods of time.  Given that alatae of Aphis fabae also have a variable number of ovarioles, 6-12 (Leather et al., 1988), we can see that this fits in very well with Shaw’s classification of migrants, flyers and non-flyers.

This is yet another great example of the flexibility (plasticity) of the aphid clone.  By producing offspring that have different flight capabilities and propensities, the clone is able to hedge its bets in times of adversity; alate aphids in many aphid species are produced in response to crowding and/or poor nutritional quality (Dixon, 1973).  This deterioration in living conditions could be very local i.e. restricted to the plant on which the aphid is feeding or its immediate neighbours, slightly more widespread, i.e. at a field scale or at a much more widespread landscape scale.  Given that long distance aphid migration is very costly (only a tiny proportion survive, Ward et al, 1998) the best option is to spread the risk between the members of your clone.  Those individuals with more ovarioles and greater potential fecundity make the low risk short-distance hops (trivial flights), but take the chance that the next door plant might be just as bad as the one left behind and also within easy reach of natural enemies, but with a higher chance of arriving and reproducing.

Ovarioles Fig 5

A risk taking aphid!

 

At the other end of the scale, those clone members with fewer ovarioles and reduced potential fecundity make the long distance migratory flights, with the risk of not finding a suitable host plant in time, but with the chance that if they do, it will be highly nutritious and natural enemy-free.  A really good example of not putting all your eggs in one basket and yet again a demonstration of what fantastic insects aphids are 😉

 

References

Dixon, A.F.G. (1973) Biology of Aphids Edward Arnold, London.

Dixon, A.F.G. & Dharma, T.R. (1980) Number of ovarioles and fecundity in the black bean aphid, Aphis fabae. Entomologia Experimentalis et Applicata, 28, 1-14.

Leather, S.R. (1983) Evidence of ovulation after adult moult in the bird cherry-oat aphid, Rhopalosiphum padi. Entomologia experimentalis et applicata, 33, 348-349.

Leather, S. R. (1988). Size, reproductive potential and fecundity in insects: Things aren’t as simple as they seem. Oikos 51: 386-389.

Leather, S.R. & Welllings, P.W. (1981) Ovariole number and fecundity in aphids. Entomologia experimentalis et applicata, 30, 128-133.

Leather, S.R., Wellings, P.W., & Walters, K.F.A. (1988) Variation in ovariole number within the Aphidoidea. Journal of Natural History, 22, 381-393.

Shaw, M.J.P. (1970) Effects of population density on the alienicolae of Aphis fabae Scop.II The effects of crowding on the expression of migratory urge among alatae in the laboratory. Annals of Applied Biology, 65, 197-203.

Walters, K.F.A. & Dixon, A.F.G. (1983) Migratory urge and reproductive investment in aphids: variation within clones. Oecologia, 58, 70-75.

Ward, S.A., Leather, S.R., Pickup, J., & Harrington, R. (1998) Mortality during dispersal and the cost of host-specificity in parasites: how many aphids find hosts? Journal of Animal Ecology, 67, 763-773.

Wellings, P.W., Leather , S.R., & Dixon, A.F.G. (1980) Seasonal variation in reproductive potential: a programmed feature of aphid life cycles. Journal of Animal Ecology, 49, 975-985.

 

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Filed under Aphidology, Aphids