We analyzed 4.4 million @Team_eBird records to find out why tropical birds live in narrow slices of mountainside

You won’t BELIEVE what we found

Out today in #ScienceResearch

science.org/doi/10.1126/sc…

w/ @StrimasMackey & @EliotITMiller

But first the backstory.

As you travel up or down a tropical mountain, you will find very different species in each elevational zone. Way more so than on temperate zone mountains. This species turnover explains why tropical mountains are Earth’s hottest biodiversity hotspots

We began studying this puzzle 15 yrs ago in tropical Andes

Want to find different tanagers, antpittas, or hummingbirds? Move 500 m up or downslope. Exciting! And puzzling! Forests often look similar and birds have wings. Why don’t they live in broader elevational ranges?

So why do tropical birds live in narrow slices of mountainside?

People usually point to climate. It’s hot in the lowlands and cool in the mountains. Maybe birds live only within the elevations that are just right for them - their Goldilocks zone

Dan Janzen described how this might come to be in his famous “Why mountain passes are taller in the tropics” article

The low temp seasonality of tropical mountains means species only experience a narrow range of temps & might evolve specialized thermal physiology to these temps

For example, researchers documented cases where species inhabited narrow ranges on mountains with lots of species but broader ranges on mountains with fewer species (& esp when close relatives were absent), and argued that interspecific competition explained these patterns

We wanted to measure the relative importance of these two hypotheses.

We took a comparative approach & analyzed forest species’ elevational ranges in regions that differ in their temperature seasonality (Janzen hypothesis) and regional species richness (competition hypothesis)

Problem: Defining forest species’ elevational ranges within regions is hard

Solution: use @ebird data (the 4.4 million records bit)

We came up with a frequency-based method to define ranges using eBird checklists that met stringent filtering criteria

We then asked whether mean elevational range size within regions was better predicted by temperature seasonality (Janzen hypothesis) or by regional species richness (competition hypothesis)

And found....

that regional species richness is a strong predictor of mean elevational range size, consistent with competition hypothesis

Regional species richness also correlated with variation in elevational range sizes for species that live in multiple regions

To illustrate these patterns, we compare W (Choco) & E (Amazon) slopes of tropical Andes at the equator
Similar temp seasonality & mountain height
Tons of species in both, but even more on Amazon slope
And, correspondingly, narrower elevational ranges on the Amazon slope

So how might more species lead to narrow elevational ranges?

There are many possible mechanisms. To begin to shed some light, we looked at pairwise competition between elevational replacements, the mechanism originally highlighted as pointing to a role for competition

We asked whether species exhibit competitive release in allopatry for 52 natural experiments in Neotropics, using eBird data to define competitive release in elevational & environmental space

We used this comparative approach to avoid cherry-picking particular cases

And…we find competitive release around half the time

We find evidence that pairwise competition limits the elevational ranges of species like Black-faced Anthrush Formicarius analis (photo credit: Luiz Matos, ML68863331)

and for Scale-crested Pygmy-Tyrant Lophotriccus pileatus (photo credit: Pablo Ortega, ML321152491)

and for Phaethornis hermits, Campephilus woodpeckers, Spizaetus hawk-eagles and many more

credits: Peter Hawrylyshyn ML69744221, Fernando Burgalin Sequeria ML179056551, Nailson Júnior ML367075101, Pablo Ortega ML443711351

check out the supporting information for figures that I think are pretty cool for each comparison

So we find many examples of competitive release, suggesting competitive exclusion in sympatry. But also plenty of examples of natural experiments where we find no evidence for competition

What gives?

Can we explain why we see competitive release sometimes but not others?

Yes, we can - we find that behavior matters (but relative elevational position does not - i.e. competition not more important at warm limit)