Gone gorilla

Humans and lowland gorillas (Gorilla gorilla gorilla) share many features, including strong social bonds among members of their group.  Lowland gorillas differ from humans in that one male (the silverback) dominates the group, which is composed of several females and their offspring. Some mature males are unable to attract females and may be consigned to a solitary existence.  The silverback male mates with females in his group, and may allow other females to join.  However, if a female joins a new group with an unweaned child, there is a high probability that the silverback will kill the child, as a way of getting the female into estrous more quickly, so that he can be the father of more future children.


A group of gorillas ranges over the landscape. Credit: Céline Genton CNRS/University of Rennes

The Odzala-Kokoua National Park in the Republic of Congo is home to several thousand lowland gorillas. Nelly Ménard and Pascaline Le Gouar (in affiliation with the ECOBIO laboratory CNRS/University of Rennes) have been studying two populations of these gorillas for over 20 years, and have identified and collected long-term data on 593 individuals from the two populations in their study. Working with their student, Alice Baudouin, and several other researchers, they documented that about 22% of the individuals were suffering from a yaws-like disease – an infectious skin disease caused by the bacterium Treponema pallidum pertenue.

FA2 + E2 ; pian ; GR ; Sergio

A mother carries her infected infant. Credit: Ludovic Bouquier CNRS/University of Rennes

Females may disperse from their social group several times over the course of their lifetime.  Factors influencing the decision to disperse include availability of a higher quality silverback, reduction of predation, and avoiding inbreeding, resource competition and disease.  Given the prevalence and conspicuousness of yaws, the researchers suspected that these highly intelligent animals would use a variety of cues to inform them of whether they should disperse and which group they should attempt to join.  They expected that females should leave diseased silverbacks for healthy ones, that they should leave groups with numerous diseased individuals and immigrate into groups with healthy individuals, and that diseased females would be less likely to leave their group. Other factors influencing a gorilla’s decision might include group size, group age and whether she had an unweaned infant in her care.


Silverback gorilla viewed from the mirador (observation post). Credit: Céline Genton CNRS/University of Rennes.

Because they considered so many variables, the researchers used their dataset to construct models of the probability of emigration (leaving the group) and immigration (entering a new group).  The research team categorized each breeding group based on the age of the oldest offspring: young (oldest offspring less than 4 years), juvenile (<7.5 years), mature (<11 years) and senescent (< 14 years). Female gorillas were more likely to emigrate if their group had numerous infected individuals (graph a below) and if the silverback was severely infected (graph b). They were also more likely to leave an older breeding group, perhaps understanding that the silverback would be losing effectiveness in the near future (graph c).  Lastly, females with unweaned infants were very unlikely to leave a group (graph d), presumably unwilling to accept the risk that their infant might starve or be killed if they attempted to join a new group.


Probability an adult female emigrates from her group in relation to (a) number of severely diseased individuals within her group, (b) presence of severe lesions on the silverback, (c) age of the breeding group, and (d) presence of an unweaned infant.  Dotted lines (in graph a) and bars (in graphs b, c and d) indicate 95% confidence intervals.

The research team did a similar analysis of factors associated with female gorillas immigrating into a new breeding group.


Probability an adult female immigrates into a group in relation to (a) age of group, (b) presence of severely diseased individuals, and (c) group size. Bars (in graph a and b) and dotted lines (graph c) indicate 95% confidence intervals.


They discovered that females were much more likely to join younger groups which had younger silverbacks (graph a).  In addition, females tended to join groups without any severely diseased individuals (graph b).  They were also attracted to smaller groups (graph c).

Based on these data, it is clear that disease strongly influences female dispersal decisions.  Females were much more likely to disperse from breeding groups with numerous infected individuals, and strongly avoided groups with more than two diseased individuals. This is not surprising, given how conspicuous these skin lesions are, particularly in the facial regions.  Contrary to expectation, female disease status (infected or not) did not influence female dispersal tendency. The researchers suggest that dispersal might not be particularly costly to the female (assuming she does not have an unweaned infant) because the home range of social groups overlap broadly so it is easy to move from one group to another, and food is also plentiful throughout the range.

Many features of a gorilla’s social environment influence its dispersal decisions. Because diseased females are as likely to disperse as healthy females, the disease pathogen may be more easily spread into previously uninfected gorilla populations.  On the other hand,  dispersing female avoidance of diseased populations has the effect of quarantining the diseased populations. The researchers hope to get a better understanding of the mechanisms of female appraisal of their social environment, so they can predict changes in the prevalence of this pathogen.

note: the paper that describes this research is from the journal Ecology. The reference is Baudouin, A., S. Gatti, F. Levrero, C. Genton, R. H. Cristescu, V. Billy, P. Motsch, J.-S. Pierre, P. Le Gouar, and N. Ménard. 2019. Disease avoidance, and breeding group age and size condition the dispersal patterns of western lowland gorilla females. Ecology 100(9): e02786. 10.1002/ecy.2786.  Thanks to the Ecological Society of America for allowing me to use figures from the paper. Copyright © 2019 by the Ecological Society of America. All rights reserved.

It’s all happening at the ecotone

In an effort to make order out of the chaos of existence, scientists often resort to classifying stuff.  To make order of the natural world, ecologists classify different regions of the world into distinct biomes – large geographical areas with characteristic groups of organisms adapted to that particular environment.  Familiar examples of terrestrial biomes are tropical forests, temperate grasslands and desert, and in the aquatic world examples include open ocean, coral reefs and rivers. But what happens at ecotones, where two or more biomes come together? Research has shown that ecotones can be biodiversity hotspots, as the diverse habitats attract many different species, and may also attract edge specialists – species that are particularly adapted to conditions on the border between the two biomes.


Sara Weinstein collects data at the ocean to land ecotone. Credit: Anand Varma.

Sara Weinstein’s graduate research explored the ecology and transmission of raccoon roundworm, Baylisascaris procyonis, a widespread raccoon parasite that causes severe disease in other animals (including humans).  She was dissecting raccoons to study infection patterns and as she describes “it would have been a waste of perfectly good raccoon guts to not also examine the rest of the parasite community.”  This examination would allow her to determine whether the generalization that ecotones are biodiversity hotspots for terrestrial and aquatic organisms also applies to the much more murky world of gut parasites.


A raccoon poses next to a culvert. Credit: SB Weinstein.

Working with four other researchers, Weinstein compiled a database of published accounts of gastrointestinal parasites from surveys of 256 raccoon populations.  They then used this database to classify parasites as either core or satellite.  Core parasites are locally abundant, common over a large region and can occupy a broad ecological niche.  Satellite parasites are rare, restricted to a small portion of a region and have narrow ecological niches.


Microphallus sp. – a group of relatively rare satellite trematodes collected from a raccoon gut. Credit: SB Weinstein.

Weinstein and her colleagues found that the data divided raccoon gut parasites into two distinct groups.


Top graph. Parasite frequency across raccoon populations. Most parasite genera were found in less than 10% of the raccoon populations.  Dashed line indicates 30% cutoff between satellite and core genera.  Bottom graph. Proportion of raccoons infected with each parasite  in relation to range-wide prevalence.  Larger data points indicate more populations surveyed for a given parasite.


There were eight taxa (genera) that were found in more than 40% of raccoon populations. In contrast there were 51 genera that were found in fewer than 30% of raccoon populations, with the vast majority of these found in fewer than 10% of raccoon populations in the survey (top graph on left).  The eight common taxa – core parasites – also tended to be present in more individuals within each population than did the 51 less common genera of satellite parasites (bottom graph on left).


Having defined core and satellite parasites, the researchers then did a thorough analysis of the gut contents of 180 raccoon collected by trappers and animal control agents in Santa Barbara County between 2012 – 2015. They hypothesized that the prevalence of core parasites should not be overly affected by ecotones.  In contrast, satellite parasites should increase in ecotones, because ecotones provide unique environmental conditions that would be suitable to some of the less common species in the parasite community.


In Santa Barbara County, Weinstein and her colleagues identified four core parasites and nine satellite parasites within the population, with a mean of 2.24 parasite species per raccoon. Racoons nearer to the marine ecotone harbored more parasite species than did raccoons more distant from the marine ecotone, a result of much greater richness of satellite species (left graph below). The story was very different for the freshwater ecotone.  Overall, parasite richness was relatively constant in relation to distance from the freshwater ecotone.  There were actually fewer core parasites but more satellite parasites near the freshwater ecotone (right graph below).


Left graph. Total parasite richness (orange line) in relation to distance from shore.  Satellites (orange fill) increased in abundance near the shore, while core parasites (maroon line) were steady. Right graph. Total parasite richness in relation to distance from freshwater.

Why did core parasite richness decline near the freshwater ecotone?  Weinstein and her colleagues believe that diet may play an important role.  For example, the core parasites Atriotaenia procyonis and Physoloptera rara were more common in raccoons far from freshwater, probably because racoons are infected by these two parasites as a result of eating terrestrial (but not aquatic) insect species that are intermediate hosts for these two parasite species.  As it turns out, these intermediate insect hosts prefer upland habitats that tend to be located relatively distant from the freshwater ecotone.

Increased abundance of rare parasites at ecotones has important implications for human health.  Several emerging infectious diseases, such as lyme disease, yellow fever and Nipoh virus are associated with ecotones. Habitat development by the expanding human population is causing increased habitat fragmentation, creating more ecotones, and potentially increasing the prevalence of these and other, equally unfriendly, parasites.

note: the paper that describes this research is from the journal Ecology. The reference is Weinstein, S. B., J. C. Van Wert, M. Kinsella, V. V. Tkach, and K. D. Lafferty. 2019. Infection at an ecotone: cross-system foraging increases satellite parasites but decreases core parasites in raccoons. Ecology 100(9):e02808. 10.1002/ecy.2808.  Thanks to the Ecological Society of America for allowing me to use figures from the paper. Copyright © 2019 by the Ecological Society of America. All rights reserved.


Forest canopy fixes nitrogen shortage

The two billion hectares of forest canopy remaining on our planet are ideal habitat for nitrogen fixing microorganisms that can convert N2 to ammonia.


View of the forest canopy at the research site. Credit: D. Stanton.

The forest canopy tends to be nutrient-poor because there is no access to nutrients that accumulate in the soils on the forest floor, and rainfall can leach away any nutrients that do accumulate in the canopy from atmospheric deposition. So if you are a microbe, and you want to enjoy the view from the canopy, it is to your advantage to be able to fix atmospheric nitrogen so you can build essential molecules such as proteins and ATP.

As I mentioned in a previous post (Nitrogen continues to confound convention) both phosphorus (P) and molybdenum (Mo) are essential nutrients for biological nitrogen fixation.  Daniel Stanton and his colleagues hypothesized that nitrogen fixation in the canopy might be limited by the availability of P and Mo, so they designed a series of experiments to explore the role of these nutrients at the San Lorenzo Canopy Crane in San Lorenzo National Park in the Republic of Panama.  The crane provides about 1 ha of canopy access to non-acrophobic ecologists.


The crane at the research site: Credit: D. Stanton.

In one experiment, Stanton and his colleagues filled thin nylon stockings with vermiculite to form 40 cm long cylinders of 4 cm diameter.  Each cylinder was then soaked in either pure water (control), a molybdenum (Mo) compound, a phosphorus (P) compound, or a combination of Mo and P,  thus establishing four treatments. They attached each of these stockings to five different trees and allowed them to reside in the canopy for six months, to be colonized by microorganisms.


Nylon stockings treated with nutrients (or untreated controls) and affixed to branches in the canopy. Credit: D. Stanton.

The researchers measured the rate of nitrogen fixation by cutting a 50 cm2 rectangle from the area of densest growth on each stocking, and incubating it (along with the colonizing microorganisms) in a closed bottle that they had inoculated with heavy nitrogen (15N).  They then measured how much 15N the colonizers took up during a 12 hr incubation period.


Samples incubating for 12 hr to measure the rate of nitrogen fixation. Credit: D. Stanton.

The most common colonizers were nitrogen fixing filamentous cyanobacteria. These cyanobacteria fixed nitrogen at a somewhat (but not statistically significant) higher rate with Mo addition and at a much higher rate with P addition, and even more so with Mo + P addition.


Nitrogen fixation rates for each experimental treatment. C = control.  Note that the y-axis is logarithmic, so these differences in fixation rates are substantial.  Non-overlapping lowercase letters above the bars indicate significant differences between the means.

Nitrogen fixation is complex and costly.  Part of the complexity arises because nitrogenase, the enzyme that catalyzes the reaction, cannot tolerate oxygen.  To deal with this problem, cyanobacteria have evolved heterocysts, which are specialized anaerobic cells where nitrogen fixation occurs.  How does nutrient addition influence heterocyst abundance and function?

There are actually two aspects to this story.  One finding is that Mo addition had no effect on heterocyst abundance, while P addition had a pronounced effect.


Heterocyst frequency for each experimental treatment.

A second aspect is that Mo addition had a pronounced effect on the efficiency of nitrogen fixation.  For one analysis the researchers compared the nitrogen fixation rate per heterocyst for the phosphorus addition treatments either without or with Mo addition (in other words, they compared the P added treatment to the Mo + P treatment). Nitrogen fixation rates were much higher in the Mo + P treatments.  So while Mo does not increase heterocyst abundance, it does dramatically increase heterocyst fixation efficiency.


Quantity of N fixed per heterocyst per day in relation to absence (left bar) or presence (right bar) of Mo.  P was added for both treatments.  Dark horizontal lines are the median values, quartile range is represented by top and bottom of each box, and the whiskers represent the range of values for each treatment.

Phosphorus acts by markedly increasing the overall cyanobacterial growth.  It increases the amount of cyanobacteria that colonizes the canopy and also increases heterocyst density per filament. In contrast molybdenum’s effect is more nuanced as it increases the efficiency of the nitrogen fixation reaction without having any (obvious) effect on cyanobacterial structure.

How do these findings influence our understanding of tropical forests in the western hemisphere?  It turns out that episodes of nutrient addition actually happen in nature, courtesy of vast plumes of nutrient-rich rock-derived dust that periodically blow over the Atlantic Ocean from the Sahara desert in western Africa. Preliminary estimates by Stanton and his colleagues indicate that nutrient enrichment from these dust plumes is sufficient to  profoundly increase the rates of nitrogen fixation in tropical forests.  This may require us to reconsider our understanding of how nitrogen cycles within and between ecosystems.

note: the paper that describes this research is from the journal Ecology. The reference is Stanton, D. E., S. A. Batterman, J. C. Von Fischer, and L. O. Hedin. 2019. Rapid nitrogen fixation by canopy microbiome in tropical forest determined by both phosphorus and molybdenum. Ecology 100(9):e02795. 10.1002/ecy.2795. Thanks to the Ecological Society of America for allowing me to use figures from the paper. Copyright © 2019 by the Ecological Society of America. All rights reserved.

Nitrogen continues to confound convention

Ah nitrogen…  It is the most abundant molecule in the air that we breathe (close to 80%), yet plants always seem to be starving for it.  Annually, nitrogen fertilizers are a $75 billion dollar industry. The problem is that the nitrogen gas that we breathe (N2) is very nonreactive, because the two nitrogen atoms are held together by a massively powerful triple bond.  So N2 must be broken down to some other more usable form (such as ammonia) – a process we call nitrogen fixation.  Most nitrogen fixers are microorganisms that live in soils or symbiotically within plants.  Unfortunately, N-fixation is energetically very costly, so even organisms that can fix nitrogen will generally happily use nitrogen compounds from the soil or leaf litter (the layer of fallen leaves above the soil) if they are available, rather than expending enormous energy to fix it for themselves. The general formula for nitrogen fixation (ignoring protons, electrons and energy transfers) is…


A few years ago Scott Morford, Benjamin Houlton and Randy Dahlgren (the first two are co-authors of the present study) stunned the ecological world by identifying a previously unsuspected source of nitrogen – weathering of bedrock such as the mica schist pictured below. This bedrock was formed from seabeds which were rich in organic matter and had a high concentration of nitrogen compounds When the rock breaks down, both carbon and nitrogen compounds leach into the soil. Katherine Dynarski became interested in nitrogen fixation as an undergrad at Villanova University, so it was natural for her to move to the University of California at Davis to begin her graduate work with Morford and Houlton on how nitrogen cycles through ecosystems.


Nitrogen-rich mica schist bedrock. Credit: Katherine Dynarski.

Dynarski got involved in this specific project essentially by accident. She was helping a fellow graduate student collect rocks at adjacent forests on contrasting bedrock (one high-N mica schist, and one low-N basalt), and figured that while she was out there, she might as well measure some N-fixation rates. In leaf litter and the soil below, most N-fixation is done by free-living soil bacteria. Dynarski expected higher N-fixation rates in the litter collected above the N-poor bedrock, reasoning that the microorganisms would need to fix nitrogen from the air, because there was little present in the litter.  In contrast, she expected to find lower N-fixation rates in litter collected above the N-rich bedrock, reasoning that the micro-organisms could save considerable energy by using existing nitrogen that had leached into the soil and leaf litter layer. She was shocked when she ran the samples and found exactly the opposite of her expectation, which led her to develop a more substantial project looking at the relationship between bedrock and N fixing microbes.


Katherine Dynarski conducting gas incubations to measure N-fixation rates in the field. Credit: Scott Mitchell.

Working in northern California and Western Oregon, Dynarski and her colleagues identified sites whose bedrock was low in nitrogen (below 500 parts per million N) or high in nitrogen (above 500 ppm N). The researchers used soil and leaf litter samples from 14 paired sites – high N bedrock with nearby low N bedrock. They analyzed soil and leaf litter samples from each plot for concentration of nitrogen, carbon (C), phosphorus (P) and molybdenum (Mo) – the latter two elements have been shown in other systems to limit the rate of N-fixation.  The researchers also collected samples of underlying bedrock and analyzed N and Mo content of these rocks.

Recall that the conventional paradigm is that microorganisms should have lower N-fixation rates in N-rich environments.  There was negligible N-fixation occurring in the soil, but considerable N-fixation in the leaf litter above.  Thus the conventional prediction was that N-fixation rates would be higher in leaf litter above low-N bedrock. As I mentioned previously, Dynarski found the exact opposite to be true in one site; would this unconventional finding be confirmed by the 14 sites explored in this study?

The answer is yes!  Considerably more N-fixation was detected in leaf litter above high N bedrock than in leaf litter above low N bedrock.


Mean leaf litter N-fixation rates and low-N and High_N bedrock sites.  Error bars are one standard deviation. P = 0.014.

You will notice the large error bars above the graph.  As it turns out, N-fixation rates vary dramatically – even on a very small spatial scale, which is why the researchers took multiple samples from each site. Some sample sites (hotspots) have unusually high rates of N-fixation.  These hotspots are also strongly correlated with high carbon concentration, with greater C in the leaf litter associated with much higher rates of N-fixation.


Litter N-fixation rates in relation to % soil carbon at N-fixation hotspots. Hotspots are defined as having fixation rates greater than 1 kg N per hectare per year.

Dynarski and her colleagues also discovered that, in general, leaf litter above high-N bedrock tended to have more C and P than did leaf litter above low-N bedrock.  Given this finding (along with the hotspot finding) we are now ready to explore the question of why microbes are expending more energy to fix nitrogen in regions where more nitrogen is naturally available.

The researchers considered two hypotheses.  First, it takes N to make N.  N-fixation is catalyzed by N-rich enzymes. It may be that leaf litter above low-N bedrock is too N-poor to provide microbes with enough nitrogen make these enzymes. So the additional nitrogen from high-N bedrock is just enough to allow microbes to produce the N-fixation enzymes.

The second hypothesis is that the litter above low-N bedrock is also low in C, P and Mo, all of which are required for N-fixation. Thus the positive effect of these nutrients overwhelms the negative effect of additional nitrogen on the rate of nitrogen fixation.  According to this hypothesis, the conventional paradigm of high nitrogen availability reducing the rate of N-fixation is correct, but other factors may be equally or more important in natural ecosystems.

Fortunately, this conundrum is easily resolved.  Dynarski and her colleagues took some leaf litter samples and added a small amount of nitrogen to them.  These N-additions significantly reduced N-fixation rates at both low and high bedrock N sites.  Thus environmental N does reduce biological N-fixation, but other factors, such as the availability of other essential nutrients, can overwhelm the inhibitory effect of environmental nitrogen in natural ecosystems


A Douglas fir forest in the Oregon Coast Range, where some of this research was conducted.  Credit: Katherine Dynarski.

The researchers conclude that nitrogen input from bedrock weathering leads to increased C storage and P retention, ultimately enhancing rates of N-fixation. About 75% of Earth’s surface is underlain by rocks with substantial N reservoirs, so we need to continue exploring the effects of weathering bedrock on ecosystem processes and functioning.

note: the paper that describes this research is from the journal Ecology. The reference is Dynarski, K. A., S. L. Morford, S. A. Mitchell, and B. Z. Houlton. 2019. Bedrock nitrogen weathering stimulates biological nitrogen fixation. Ecology 100(8):e02741. 10.1002/ ecy.2741. Thanks to the Ecological Society of America for allowing me to use figures from the paper. Copyright © 2019 by the Ecological Society of America. All rights reserved.

Tropical trophic cascade slows decomposers

In the rough and tumble natural world, consumers such as lions, lady bugs, llamas and lizards get most of the press, while producers such as peas, pumpkins and phytoplankton come in a close second.  Consumers earn their name because they get their energy from consuming other organisms, while producers produce their own energy (using photosynthesis or chemosynthesis) from inorganic molecules.  Often ignored in this ecosystem structural scheme are decomposers, which get their energy from breaking down the tissue of dead organisms.  They should not be ignored.  Much of the energy transferred through ecosystems passes through decomposers.

One reason they are overlooked is that most decomposers are tiny. Some of the largest decomposers are detritivores, which actually eat the dead materials (detritus), in contrast to other microbial decomposers such as bacteria and fungi.  Shredders are detritivores commonly found in streams and rivers; these aquatic insects eat portions of dead leaves and, in the process, shred them into much smaller pieces that energize other decomposers. Many researchers had noted that shredders were relatively rare in tropical streams, in part because there are many other larger consumers in the ecosystem that are willing to eat dead leaves and any shredders associated with them. Thus Troy Simon and his colleagues expected that shredders, such as the caddisfly, Phylloicus hansoni, would play, at best, a minor role in the streams they studied in the Northern Range Mountains in Trinidad.


A typical headwater stream located in the Northern Range mountains of Trinidad. Waterfalls in the uppermost reaches of these streams act as a barrier to the upstream movement of guppies, but not killifish and crabs, which can move over land during periods of heavy rain. Credit: Joshua Goldberg.

We will discuss interactions between several species in these aquatic systems.  Trees are important producers as they shed leaves into the streams; these leaves are broken down by shredders such as the aforementioned caddisflies and also microbial decomposers.   The major consumers are omnivorous crabs, Eudaniela garmani, which eat leaves and caddisflies (and many other items), and two fish species. Killifish, Anablepsoides hartii, eat caddisflies, other invertebrates and also the occasional small fish (including fish eggs).


Hart’s killifish (Anablepsoides hartii) are primarily insectivorous and major consumers of leaf‐shredding caddisflies. Credit: Pierson Hill.

Guppies, Poecilia reticulata, are much smaller than killifish, maxing out at 32 mm long in comparison to the killifish maximum length of 100 mm.  But guppies are much more omnivorous, feeding on leaves, leaf-shredding insects and even killifish eggs and larvae.


Male (left) and female (right) Trinidadian guppy (Poecilia reticulata). Guppies are omnivorous, feeding broadly on detritus as well as plant and animal prey, including young killifish. Credit: Pierson Hill.

Amazingly, killifish can disperse over land, as can crabs (less amazingly).  This allows them to bypass barrier waterfalls during wet periods, which results in them being the only large consumer species above waterfalls in many Trinidad streams.  Guppies lack killifish dispersal abilities, so they are often confined to stream reaches below significant waterfalls.  These species, and their consumption patterns are highlighted in the figure below.


Diagram of the two detrital-based food webs.  Above the waterfall is the KC reach, named after its two important consumers, killifish and crabs.  Below the waterfalls is the KCG reach, named after its three important consumers, killifish, crabs and guppies. Arrows show direction of energy flow within the ecosystem.

Simon and his colleagues wanted to know how interactions among all of these species influenced the rate of leaf decomposition.  The researchers constructed identical-size leaf packs of recently fallen leaves of the Guarumo tree, Cercropia peltata, and attached them to copper wire frames within each reach of the stream.  They periodically harvested a subset of the packs and measured the amount of decomposition by drying and weighing the leaves, and comparing this weight to the starting weight of the leaf pack.  In addition, they collected all invertebrates > 1 mm long from each leaf pack and identified them to species or genus.

To control the consumers involved in each interaction, Simon and his colleagues constructed underwater electric exclosures which created an electric field that convinced all fish and crabs to exit (and stay out) within 30 seconds of being turned on, but did not influence invertebrates in any detectable way.  Killifish are active day and night, guppies only during the day, and the researchers believed that crabs were active primarily at night. The researchers set up four treatments: control (C) with 24 hour access to consumers, experimental (E) with 24 hour exclusion of consumers, day-only exclusion (D) and night-only exclusion (N).  The researchers expected that the day-only exclusion treatments would selectively exclude guppies, while night-only exclusion would selectively exclude crabs. They then placed the leaf packs into each exclosure, turned on the current, and ran the experiment for 29 days.  Five replicates of each treatment were done above and below the waterfalls.


Electric exclosures established in the stream. Leaf packs were tied to the copper frame and periodically harvested over the 29 days of the experiment. Rectangular tiles shown in treatment frames were part of a separate study. Credit: Troy N. Simon.

We’re finally ready for some data.  The two graphs on the left represent the downstream reach below the waterfalls, where killifish, crabs and guppies are naturally present (KCG).  The two graphs on the right represent the upstream reach above the falls, where only killifish and crabs are naturally present.  There was no evidence in the downstream reach that excluding consumers influenced decomposition rates (top left graph).  However, when consumers were present (C treatment) in the upstream reach, decomposition rates were reduced by about 40% in comparison to treatments when consumers were partially (D and N) or completely (E) excluded (top right graph).


Mean (+SE) for (a,b) decay rate of Cecropia peltata leaves (percentage of mass lost per day) and (c,d)  biomass of Phylloicus hansoni (milligrams of dry mass per gram of Cecropia). 24-hour treatments allow full macroconsumer access [control (C)] or completely exclude macroconsumers [electric (E)]. Twelve-hour treatments exclude access to either diurnally active [day (D)] or nocturnally active [night (N)] macroconsumers. Different letters above the bars indicate statistically significant differences between the treatments.

The two bottom graphs above look at the biomass of the caddisfly, Phylloicus hansoni, which was easily the most abundant macroinvertebrate within the leaf packs.  There was no significant difference in caddisfly abundance below the waterfall regardless of treatment (bottom left graph above).  Above the waterfalls, caddisfly abundance was severely depressed in the controls (C) where killifish were free to feed on them (bottom right graph).

One piece of evidence that killifish ate caddisflies and depressed their abundance was that surviving caddisflies were much smaller in the control treatment leaf packs than in any of the experimental treatment leaf packs.  This suggests that  killifish with unimpeded access to caddisflies were picking off the largest individuals.


Mean (+SE) caddisfly length in mm (y-axis) for each treatment, 

These findings support the hypothesis that a trophic cascade prevails in the KC reach, in which killifish eat caddisflies, thereby slowing down decomposition. But in the KCG reach, guppies eat killifish eggs and larvae and compete with them for resources, thereby reducing killifish abundance, and interfering with the establishment of a trophic cascade.

Lastly, the researchers explored whether the same trophic cascade operated in upper reaches but not in lower reaches of other streams in the area. Surveys of six streams indicate a definite “yes” answer, with Cecropia decay rate and caddisfly biomass much lower in the upper reaches.


(Top) Mean (+SE) decay rate for Cecropia peltata
leaves (percentage of mass lost per day) and (b) caddisfly biomass (milligrams of dry mass per gram of Cecropia) in the landscape study (n = 6 streams). Different letters above bars indicate statistically significant differences  between treatments.

Surveys of each stream indicated that killifish were much more abundant in the upper reaches where guppies were not found, but guppies were much more prevalent in the lower reaches than were killifish.  These findings indicate that this detrital-based trophic cascade, with killifish eating caddisflies and thereby slowing down decomposition, is a general pattern in the upper reaches of these tropical streams.  However, Simon and his colleagues caution us that different streams will have different groups of organisms playing different ecological roles.  Thus the presence of detrital-based trophic cascades will depend on the particulars of which species are present and how abundant they are in a particular stream.

note: the paper that describes this research is from the journal Ecology. The reference is Simon, T. N., A. J. Binderup, A. S. Flecker, J. F. Gilliam, M. C. Marshall, S. A. Thomas, J. Travis, D. N. Reznick, and C. M. Pringle. 2019. Landscape patterns in top-down control of decomposition: omnivory disrupts a tropical detrital-based trophic cascade. Ecology 100(7):e02723. 10.1002/ecy.2723. Thanks to the Ecological Society of America for allowing me to use figures from the paper. Copyright © 2019 by the Ecological Society of America. All rights reserved.


Hot ants defend plants from elephants

I’ve lost a lot of sleep over ants.  As a spider researcher, I often placed ants on spiderwebs to lure my spiders out of their underground retreats and onto their webs. The problem was that these harvester ants (Pogonmyrmex species) were fierce, so to minimize damage to myself, I was forced to capture them in the very early morning, when they and (alas) I were very sluggish.

acacias_thorn copy

Swollen thorn (domatia) that serves as living quarters for acacia ants. Credit: T. Palmer.

Todd Palmer has worked with ants for many years, including research on ant-plant mutualisms in which acacia trees provide domatia (swollen thorns) as ant living quarters and extrafloral nectaries as ant food, while ants provide protection from herbivores such as elephants, kudus and steenboks.

Similar to my efforts with ants and spiders, Palmer wanted to reduce ant-induced damage to himself and his colleagues, so he often took advantage of early morning ant sluggishness for purposes of manipulating acacia trees. On the other hand, if he wanted to study aggressive responses, he learned that mid-day was best. Recognizing the daily patterns of ant activity got Palmer, Ryan Tamashiro (Palmer’s undergraduate research student) and Patrick Milligan (Palmer’s graduate student) thinking about how these different levels of activity would influence herbivores, many of which tend to be most active during dawn and dusk when temperatures are low and ants are relatively sluggish.

Elephant side

Elephants are major herbivores that can cause enormous damage to acacia trees. Credit: T. Palmer.

Four species of ants live in domatia on branches of Acacia drepanolobium, the dominant tree species at Mpala Research Centre in Laikipia, Kenya.

Acdr habitat

A grove of Acacia drepanolobium. Credit: T. Palmer.

In order of relative abundance, the ant species are Crematogaster mimosae (52%), C. sjostedti (18%), Tetraponera penzigi (16%) and C. nigriceps (15%).  Previous research showed that C. mimosae and C. nigriceps are the two most effective acacia defenders.

Cnigriceps copy

Crematogaster nigriceps on an acacia tree. Credit: T. Palmer.

Ants are poikilotherms, whose body temperature, and presumably their activity levels, fluctuate with environmental temperature.  As these ants live in acacia branches, the first order of business became to determine how branch temperature fluctuated with time of day during the 21 days of data collection.  Not surprisingly, branch temperature peaked at mid-day, and was lowest at dawn and dusk (temperatures were not measured during the night).

TamashiroFig S!

Variation in branch surface temperature with time of day. Horizontal bars are median values; boxes are first and third quartiles.

Tamashiro, Milligan and Palmer next asked how ant activity level related to branch temperature.  Different ant species don’t get along so well, so each tree hosted only one ant species.  For each tree surveyed, the researchers counted the number of ants that passed over a 5 cm branch segment during a 30 second time period (they did this twice for each tree),  The researchers discovered a strong correlation between branch surface temperature and baseline ant activity, with C. mimosae and C. nigriceps showing greatest activity levels at all temperatures, which increased sharply at higher temperatures.

TamashiroFig 1a

Ant activity levels in relation to branch surface temperature. Shaded areas are 95% confidence intervals for each species.

Do higher temperatures cause a stronger aggressive response to predators or other disturbances? Tamashiro and his colleagues tested this by rapidly sliding a gloved hand over a 15 cm segment of a branch three times and then resting the gloved hand on the branch for 30 s.  They then removed the glove and counted the number of ants that had swarmed onto the glove.  Again, C. mimosae and C. nigriceps showed the strongest aggressive response, which increased sharply with temperature

TamashiroFig 1b

Aggressive swarming by ants in relation to branch surface temperature. Shaded areas are 95% confidence intervals for each species.

While a gloved hand is a nice surrogate for predators, the researchers wanted to know how the ants would respond to a real predator, and whether the response was temperature dependent.  At the same time, they wanted to determine whether the predator would change its behavior in response to changes in ant defensive behavior at different temperatures.  They used eight somali goats (Capra aegagrus hircus) as their predators, and C. mimosae as the focal ant species for these trials.

Cpl. Paula M. Fitzgerald, USMC - United States Department of Defense

Somali goats in Ali Sabieh, Djibouti. Credit: Cpl. Paula M. Fitzgerald, USMC – United States Department of Defense.

The researchers chose eight trees of similar size for their experiment, and removed ants from four of the trees by spraying them with a short-lived insecticide, and preventing ant recolonization by spreading a layer of ultra-sticky solution (Tanglefoot) around the based of each treated tree.  Goats were allowed to feed for five minutes.


Number of bites (top graph) and time spent feeding (bottom graph) by goats in relation to branch surface temperature. Shaded area is 95% confidence interval.

Tamashiro and his colleagues measured the number of bites taken (top graph) and the amount of time spent feeding (bottom graph) at different branch temperatures.  Both measures of goat feeding were not influenced by branch temperature if there were no ants on the trees (blue lines and points).  But if ants were present (red lines and points), goat feeding decreased sharply with increasing branch temperature, presumably reflecting more aggressive ant defense of the plants.

These findings have important implications for acacia trees, which are a critical species in the sub-Saharan ecosystem.  Previous research has shown that elephant damage is strongly influenced by the number of swarming ants on a particular tree; a greater number of swarming ants are associated with less elephant damage. Many vertebrate browsers feed throughout the day, but may feed preferentially at dawn and dusk, when temperatures are cooler and ant-defense is weakest. Browsing is particularly problematic for acacia saplings, which are usually attacked by small-bodied vertebrates such as steenbok, which forage primarily at night when ants are least active.  Thus the effectiveness of ant defense may be compromised by mismatches between vertebrate activity periods and ant activity periods.

note: the paper that describes this research is from the journal Ecology. The reference is Tamashiro, R. A., P. D. Milligan, and T. M. Palmer. 2019. Left out in the cold: temperature-dependence of defense in an African ant–plant mutualism. Ecology 100(6): e02712. 10.1002/ecy.2712 . Thanks to the Ecological Society of America for allowing me to use figures from the paper. Copyright © 2019 by the Ecological Society of America. All rights reserved.



Vacation’s changing tides

Cindy and I and our dog (Cheyanne) recently returned from a two+ week vacation at North Carolina’s Outer Banks.  We stayed in Avon, which is about eight miles north of the iconic Cape Hatteras lighthouse in a large house with a great ocean view.  We got a large house, because we thought our kids might join us, but it turns out that one disadvantage of kids getting older is that their lives become more complex.  Anyhow, several friends stayed with us for a few days, and a grand time was had by all.


Cheyanne and I ponder the ocean’s vastness. Credit: Cindy Miller

But the point of this post is the trip home.  On Friday, we packed everything into our car, including Cheyanne, and began the eight-hour drive back to our home in Radford, VA.  At Rodanthe (about 15 miles north), traffic just stopped.  We sat in our car for a few minutes, disembarked, and spoke with many people walking by, who told us that the road (NC12) was flooded and covered with sand.  We had heard rumors of flooding, but since the sun was out and the wind relatively calm, we assumed that was all in the past.  Apparently the flooding was so bad that a motor home and the boat it was towing got totally caught up in the sand and water, and was wedged so efficiently that they could not even be towed out until serious excavation happened. That was not going to happen until Saturday.


Moving the dunes off of the road. Credit: Cindy Miller.

Saturday at 6 PM we got the call that the road was open and we could head home.  We repacked the car, re-experienced Cheyanne’s baleful look, and set out, with an ETA of 3 AM at the earliest.  Alas the high tide came in, water breached the dunes, and a very kind police officer knocked on our window, imploring us to return to Avon and wait for a better day.  Cheyanne gave him a baleful look, but we obeyed.


Reconstituted dunes.  Notice the tire tracks left by earth-moving machines. Credit: Cindy Miller.

The next morning we set out again; by now we could pack a car in just a few minutes.  Our peanut butter on toast dinner of the previous night had left us a bit peckish, so we stopped off for some pastries and cappuccinos. We headed north once again and this time we were able to pass through the Rodanthe flood, and several others along the way.  The water level was high, but our car had good ground clearance and our escape was relatively uneventful, but done at sub-breakneck speed.


Riding away through Rodanthe’s rising tides. Credit: Cindy Miller.


Why was this happening?  The weather was beautiful – no rain, no wind and sunny skies.  It just doesn’t get any nicer than this at the Outer Banks.  As it turns out, there were two provocateurs.  First, there was subtropical storm Melissa several hundred miles to our east, passing harmlessly out to sea, but increasing sea levels.  Second, there was almost a full moon, which also tends to increase sea levels.  But that’s it!

That shouldn’t be enough.  In past years those two events might cause waves to crash to the dunes with increased vigor, but would not cause them to breach the dunes and spill onto the roads.  But those were past years, and now is the present, and sea levels along the North Carolina coast have risen by about one foot in the past 50 years.  Here are some data from Wilmington, NC – about 150 miles south of Avon.


Rising sea levels measured at Wilmington, North Carolina. Credit: National Oceanic and Atmospheric Administration and SeaLevelRise.org

You should note two things.  First, there is substantial year-to-year variation in sea levels. Second, rates of sea level rise are accelerating.  Scientists at the National Oceanic and Atmospheric Administration and the US Army Corps of Engineers expect this trend to continue.  Here is the prognosticated change in sea levels between now and 2050 at Oregon Inlet (just a few miles north of Rodanthe).


Forecast sea level change between 2016 and 2050. Credit: National Oceanic and Atmospheric Administration, U. S. Army Corps of Engineers and SeaLevelRise.org

This is very bad.  I’ve been vacationing at the Outer Banks for about 25 years; it has become a part of who I am.  I don’t want to give up on this spectacular part of the world, but we must act.  We cannot continue sticking our heads in the sand (which we can now oftentimes find on NC12), pretending that climate change is a construct of the liberal press or elite intelligentsia.

The first step in dealing with a problem is acknowledging that it exists. Climate change is here, and its impact is increasing. An estimated 50 million climate change refugees around the globe are being forced to abandon their homes. More will follow, including our neighbors from North Carolina’s Outer Banks. For their sake, and ours, let’s acknowledge the problem, and focus our resources, energies and talents to reducing the damage in the short term, and dealing with the causes of climate change over the next decades and centuries.

Mystifying trophic cascades

Within ecosystems, trophic cascades may occur when one species, usually a predator, has a negative effect on a second species (its prey), thereby having a positive effect on its prey’s prey. Today’s example considers the interaction between a group of predators (including several fish species, a sea snail and a sea star) their prey (the sea urchin Paracentrotus lividus) and sea urchin prey, which comprise numerous species of macroalgae that attach to the shallow ocean floor. These predators can negatively affect sea urchin populations either by eating them (consumptive effects), or by scaring them so they forage less efficiently (nonconsumptive effects). If sea urchins are less abundant or less aggressive foragers, the net indirect effect of a large population of fish, sea snails and sea stars will be an increase in macroalgal abundance.

Maldonado Halo

A large sea urchin grazing in a macroalgal community.  Notice the white halo surrounding the urchin, indicating that it has grazed all of the algae within that region. Credit: Albert Pessarrodona.

Many humans enjoy eating predatory fish, and we have overfished much of the ocean’s best fisheries including the shallow temperate rocky reefs (4 – 12 m deep) in the northwest Mediterranean Sea. Removing these predators has caused sea urchin populations to explode, overgrazing their favorite macroalgal food source, and ultimately leading to the formation of urchin barrens – large areas with little algal growth, low productivity and a small nondiverse assemblage of invertebrates and vertebrates.


A sea urchin barrens whose macroalgae have been overgrazed by sea urchins. Credit: Albert Pessarrodona

Albert Pessarrodona became interested in this trophic cascade after years of diving in the Mediterranean. He noticed that in Marine Protected Areas, predatory fish abound and there are few visible urchins and lots of macroalgae. In nearby unprotected areas where fishing is permitted, urchins graze out in the open brazenly, and urchin barrens are common. He also wondered whether a second variable – sea urchin size – might play a role in this dynamic. Were large sea urchins relatively immune from predation by virtue of their large size and long spines, allowing them to forage out in the open even if predators were relatively common?


Interactions investigated in this study.  (a) Predators consume either small (left) or large (right) sea urchins (consumptive effects). (b) Sea urchins eat macroalgae. (c) Predators scare small or large sea urchins, reducing their foraging efficiency (nonconsumptive effects). (d) Predatory fish indirectly increase macroalgal abundance.

Pessarrodona and his research team used field and laboratory experiments to explore the relationship between sea urchin size and their survival and behavior in high-predator-risk and low-predator-risk conditions. High-risk was the Medes Islands Marine Reserve, which has had no fishing since 1983 and boasts a large, diverse assemblage of predatory fish, while low-risk was the nearby Montgri coast, which has a similar habitat structure, but allows fishing. The researchers tethered 40 urchins of varying sizes to the sea bottom (about 5m deep) in each of these regions, left them for 24 hours, and then collected the survivors to compare survival in relation to body size in high and low-risk conditions. They discovered that large urchins were much less likely to get eaten than were small urchins, and that the probability of getting eaten was substantially greater in the high-risk site.


Probability of being eaten in relation to sea urchin size (cm) in high-risk (blue line) and low-risk (green line) habitats.

Pessarrodona and his colleagues followed this up by investigating whether the relatively predation-resistant large urchins were less fearful, and thus more likely to forage effectively, even in high-risk sites. Previous studies showed that sea urchins can evaluate risk using chemical cues given off by other urchins injured in a predatory attack, or given off by the actual predators. To explore the relationship between these cues and sea urchin behavior, the researchers put either large or small sea urchins into partitioned tanks with an injured sea urchin. Water flowed from one partition to the other, so the experimental sea urchins received chemical cues from the injured urchins. They also had a group of sea urchins placed in similar tanks without any injured sea urchins as controls. The experimental sea urchins were given seagrass to feed on, and the researchers calculated feeding rates based on how much food remained after seven days.

Small sea urchins were not deterred by the presence of an injured urchin (left graph below), while large sea urchins drastically reduced their feeding rates in response to the presence of an injured urchin (middle graph). This was startling as it flew in the face of the commonsense expectation that small sea urchins (most susceptible to predation) should be most fearful of predator cues. The researchers repeated the experiment (under slightly different conditions) placing an actual predator (a fearsome sea snail) on the other side of the partition. Again, large urchins showed drastically reduced foraging rates (right graph below).


Sea urchin responses to predation risk cues in the laboratory. When exposed to injured urchins – symbolized as having a triangle cut out – (A) small urchins did not reduce their grazing rate, while (B) large urchins drastically curtailed grazing. (C) When exposed to a predatory snail on the other side of a partition, large urchins sharply curtailed grazing. n.s = no significant difference, **P<0.01.

It turns out that large sea urchins are the critical players in this trophic cascade because they do much more damage to algal biomass than do the smaller urchins (we won’t go through the details of that research). The question then becomes how this plays out in natural ecosystems. Do consumptive and non-consumptive effects of predators in high-risk sites reduce sea urchin abundance and reduce the foraging levels of large sea urchins so that macroalgal cover is greatly enhanced? Pessarrodona and his colleagues surveyed high-risk and low-risk sites for sea urchin density and algal abundance. They set up 45 quadrats (40 X 40 cm) at each site, measured each sea urchin’s diameter, and estimated the abundance of each type of algae by harvesting a 20 X 20 cm subsample from each quadrat and drying and weighing the sample.

The findings were striking. Small and large sea urchins were much less abundant at high-risk sites than at low-risk sites (left graph below). At the same time, macroalgae were much more abundant at high-risk sites than at low-risk sites (right graph below).


(Left graph) Density of small and large sea urchins in high-risk and low-risk habitats. (Right graph) Biomass of macroalgae of different growth structures in high-risk and low-risk habitats. Canopy algae are taller than 10 cm, while turf algae are lower stature. Codium algae are generally not grazed by sea urchins. **P<0.01, ***P<0.001.


Summary of interactions.  Arrow width indicates relative importance.

To summarize this system, predators reduce small sea urchin abundance by eating them (consumptive effects), and reduce large sea urchin foraging by intimidating them (nonconsumptive effects). The net indirect effect of predators on macroalgae is a function of these two effects. Large sea urchins are the major macroalgae consumers, but, of course, large sea urchins develop from small sea urchins.

The $64 question is why large sea urchins fear predators so much, while small (more vulnerable) urchins do not. The quick answer is that we don’t know. One possibility is that small sea urchins may be bolder in risky environments since they are more vulnerable to starvation (have fewer reserves), and also have lower reproductive potential since they are likely to die before they get large enough to reproduce. In contrast, large sea urchins can survive many days without food because of their large reserves. In addition, large urchins are close to sexual maturity, and thus may be unwilling to accept even a small risk to their well-being, which could interfere with them achieving reproductive success.

note: the paper that describes this research is from the journal Ecology. The reference is Pessarrodona, A.,  Boada, J.,  Pagès, J. F.,  Arthur, R., and  Alcoverro, T. 2019.  Consumptive and non‐consumptive effects of predators vary with the ontogeny of their prey. Ecology  100( 5):e02649. 10.1002/ecy.2649. Thanks to the Ecological Society of America for allowing me to use figures from the paper. Copyright © 2019 by the Ecological Society of America. All rights reserved.

Fast living vs. slow and steady

Fast living makes headlines, as evidenced by such notables as Freddie Mercury, Paul Walker and Lamar Odom.  Unfortunately the first two are dead while Odom was narrowly brought back from a near-death experience – all were victims of their fast life styles.  Like humans, some birds live fast and die young, while others live slow, but may survive to relatively ripe old ages.

Pic 2

The tiny rifleman (Acanthisitta chloris), reintroduced in Tiritiri Matangi, New-Zealand.  This endangered bird feeds on insects that it gleans from tree trunks.  It often has two clutches of 2-5 young per year. Credit: Simon Ducatez.

Simon Ducatez studied invasive cane toads with Rick Shine in Australia, and became interested in why some species were more likely than others to successfully invade new habitat.  The problem for answering that question is that most invasions are not studied until after the invasive species becomes established; by that time it may be too late to identify exactly what factors were responsible for the successful invasion. On his first visit to New-Zealand in 2016, Ducatez discovered ecosanctuaries – enclosed wildlife reserves where invasive predators are eliminated, and native animals (mostly birds) are introduced. He realised that these introductions could provide invaluable information on why species thrive or fail to become established in a new environment. At about the same time, a colleague drew his attention to a database developed by the Lincoln Park Zoo (LPZ) in Chicago, Illinois, which contains data on hundreds of intentional release events (translocation attempts), including information on the survival and reproduction of the released individuals. Analyzing how a species life history could affect the survival and reproduction of these voluntarily introduced populations would provide answers useful for restoration biologists who wish to return native species to habits where they were now extinct, and to ecologists who want to identify the factors promoting biological invasions.

Pic 7

The relatively massive and flightless south island takahe (Porphyrio hochstetteri), reintroduced in New-Zealand.  This bird was thought to be extinct but was rediscovered in 1948 and has benefited from active restoration programs. Credit: Simon Ducatez.

Life history traits are adaptations that influence growth, survivorship and reproduction of individuals of a particular species.  For each species in the LPZ dataset, Ducatez and Shine used the bird literature to gather data on body mass and four life history traits: maximum lifespan, clutch size, number of clutches per year, and age at first reproduction. They then used a statistical procedure – principle components analysis – which described each species based on their life history strategy.  Fast life styles were associated with small bodies, short lifespans, large clutch size and number, and early reproduction.  Slow life styles were associated with large bodies, long lifespans, small clutch size and number, and delayed reproduction. Ducatez and Shine then asked a simple question based on 1249 translocation events in the LPZ dataset – how do fast life style birds perform in comparison to slow life style birds following translocation?

It turns out that slow life style birds are much better at surviving translocation than are fast life style birds, at least when measured in the short term (one week) and the medium term (one month).


Association between life style as measured by principle component analysis (PC1 on X-axis) and survival (proportion of translocated individuals still alive on Y-axis). The left graph is survival to one week, while the right graph is survival to one month. 

In contrast, following translocation fast life style birds are more likely to attempt breeding and successfully breed than are slow life style birds.


Association between life style and probability of attempting breeding (left graph) and successfully breeding (right graph).

Ducatez and Shine suggest that both restoration biologists and invasion ecologists could use these findings to address major questions in their respective fields.  Restoration biologists wishing to return native species to previously occupied habitat might adopt different approaches based on a species life style. Species with fast life styles suffer from low survival, so restoration biologists should focus on promoting survival by controlling predators or provisioning extra food. Species with slow life styles suffer from low reproductive success, so conservation managers might consider providing extra nest boxes or other resources that promote successful breeding.


A successful foraging event for an Atlantic puffin (Fratercula arctica), reintroduced in Maine, USA. Credit: Simon Ducatez.

This research informs invasion ecologists that the same trait can have opposite effects on the likelihood that a biological invasion will actually happen.  Thus a slow life style species is more likely to survive moving to a novel habitat, but is unlikely to breed successfully once it gets there.  In contrast a fast life style species is less likely to survive the move, but if it does survive, it may be more likely to successfully reproduce. How this plays out in actual biological invasions is yet to be determined, but at least we now have a better grasp on what factors we should be examining.

note: the paper that describes this research is from the journal Conservation Biology. The reference is Ducatez, S. and Shine, R. (2019), Life‐history traits and the fate of translocated populations. Conservation Biology, 33: 853-860. doi:10.1111/cobi.13281. Thanks to the Society for Conservation Biology for allowing me to use figures from the paper. Copyright © 2019 by the Society for Conservation Biology. All rights reserved.

Spiders eat spiders sometimes

In human society, a guild is an association of craftsmen or merchants that work together to achieve a common goal. For example, 14thcentury Paris boasted over 350 different guilds, including drapiers (cloth makers), knife-makers, locksmiths, helmet-makers and harness-polishers. Ecological guilds are similar to human guilds, in that members of the same guild depend on the same resources for survival. But members of the same ecological guild are  different species, each of which uses a similar resource, or group of resources.  As we shall now discover, as in human guilds, members of ecological guilds don’t always get along very well.

A guild is part of a food web, which is a summary of the feeding relationships within a community.  Israel Leinbach, Kevin McCluney and John Sabo were interested in one particular part of a food web – the relationship between a large wolf spider (Hogna antelucana), a small wolf spider (Pardosa species) and a cricket (Gryllus alogus).  Both spiders are in the same guild, because they obtain their energy from similar sources – insect prey.  This cricket specializes on willow and cottonwood leaves that fall to the ground in the semi-arid floodplain of the San Pedro River in southeast Arizona. Under natural conditions, the researchers observed the large spiders eating both the small spiders and crickets.  However, they never observed the small spider eating the relatively large cricket (which averages 20 times its mass), though small spiders are delighted to eat many other (smaller) insect species.


A large wolf spider subdues and begins to consume a cricket.  Credit: Kevin McCluney.

The researchers argue that even though guild members specialize on similar resources, it is important to consider how other resources might influence the relationships among the species.  During the dry season, water is a critical limiting resource.  As it turns out, large spiders, crickets and small spiders are very different in how much energy and water they contain. From the table below you can see that the small Pardosa spiders are very low in water content, but pack a huge amount of energy into their tiny bodies.  Crickets of both sexes have a high water content, but contain a relatively small amount of energy in their large bodies. Thus small spiders have a much higher energy/water ratio than crickets or large spiders.


Mean (+/- 1 standard error) dry mass, energy, water and energy/water ratio of the three species discussed in this report.

When water is limiting, the large spiders might devote themselves to eating crickets to take advantage of their very high water content. But when water is not limiting, the large spiders would be expected to turn their attention to eating small wolf spiders, which are much dryer, but much higher in energy per unit body mass. The researchers reasoned that providing water to large spiders should increase the rate of intraguild predation (in this case large spiders eating small spiders).


Interactions among the three species when water is limiting (Control – left) and abundant (Experimental – right).  Black arrows are direct effects, while gray arrows show the direction of energy flux).

Leinbach and his colleagues set up a mesocosm experiment using 2 X 2 X 2 meter cages in which they experimentally manipulated community composition and water availability.


Network of cages set up in the San Pedro River floodplain. Credit: Kevin McCluney.

All cages, except controls, received either one large male or female spider, two small spiders (sex unknown) and two crickets (again either male or female). Controls received no large spiders, and were used to establish a baseline survival rate for the two potential prey items (small spiders and crickets). To test for the effects of water availability on predation by large spiders the researchers placed water pillows that held approximately 30 ml of water into half of the enclosures. They predicted that large spiders would primarily eat energy-rich small spiders in cages with water pillows, but prefer water-rich crickets in cages without water pillows. The water pillows had minimal impact on cricket water levels as they got plenty of water from their food (green water-rich leaves)


A large wolf spider sucks water from the water pillow.  Credit: Kevin McCluney.

Leinbach and his colleagues used per capita interaction strength as their quantitative measure of predation effects.  If prey survival was lower in the experimental cages than  in the control, there was a negative interaction strength – indicating that large spiders were eating a particular prey type.  When the researchers provided them with water, large spiders of both sexes ate significantly more small spiders than they did  without water supplements.


Interaction strength (effect of predation) of large spider (Hogna antelucana) on the small spider (Pardosa species).  Both male and female large spiders have significant negative effects on small spiders when water is supplemented (blue bars), but have minimal effects without water supplements (gray bars).

But the story was very different with crickets.  The researchers expected that when supplemented with water, large spiders would bypass the water-rich crickets in favor of the energy-rich small spiders. Surprisingly, instead of crickets in cages with pillows surviving as well as controls, they actually survived better – at least male crickets did. One possible explanation is that spiders may emit odor (or other types of) cues that affect cricket behavior in a negative way, for example by causing them to feed more cautiously and inefficiently. Once the large spiders have killed the small spiders, there may be fewer spiders around to smell up the place, and crickets may feed more efficiently, and thus survive better.


Israel Leinbach searches for spiders and crickets within a cage. Credit Kevin McCluney.

I asked Kevin McCluney if there were any other surprising findings, and he pointed out that large male and female spiders showed very similar consumption patterns.  He expected that females would need more energy because egg production is very energy demanding.  One explanation for this lack of difference is that large male spiders may expend considerable energy wandering around in search of sexually receptive females, and their overall energy needs may be similar to those of females. Balancing the demands of energy, water and sex may be equally demanding for both sexes of large spiders, and may lead to adaptive feeding on different levels of the food chain as environmental conditions shift.

note: the paper that describes this research is from the journal Ecology. The reference is Leinbach, I.,  McCluney, K. E., and Sabo, J. L. 2019. Predator water balance alters intraguild predation in a streamside food web. Ecology 100(4):e02635. 10.1002/ecy.2635. Thanks to the Ecological Society of America for allowing me to use figures from the paper. Copyright © 2019 by the Ecological Society of America. All rights reserved.