Good question, increasingly we can judge for ourselves. Go to BOLD (COI barcoding) [0]. Search for "Apidae". That's just one family of bees, in this case the one that includes 27+ (IIRC, probably way off) subspecies of what we know as the honeybee. The important bit is the count in "BINS", e.g. hypothesis of speciation typically based on a single gene, COI.
That's only the specimens that have been sequenced and archived at BOLD. That doesn't include the various other bee families, notably Halictidae, Colletidae, Melittidae, and others roughly all the "sister groups" in the Apoidea [1].
An example of why is this important? The Africanized honeybee, known perhaps from bad horror movies, is characterized (identified) as a hybrid of two species. It can be more or less aggressive (to the point of killing you if you don't GTFO) depending on then nature of its DNA. Hybridization has blurred the limits of the species in many areas, including in the US. Sequencing specimens is the only way to confidently determine which of the species you have, A (friendly bee honey), AB (grumpy bee honey), or B (deadly bee honey) (gross simplification here, not Mendelian).
> The Africanized honeybee, known perhaps from bad horror movies
You're talking about The Swarm (1978), which is absolutely so-bad-it's-good. Fans of Michael Caine will I think in particular find it rewarding, and I was especially impressed with its frankly prescient treatment of the drawbacks inherent in mass insecticide application given that the ongoing research increasingly points to exactly that as the culprit for pollinators disappearing.
Well, you're considerably more likely to run into a wild colony of "Africanized" hybrids than you are a great white shark, for one thing. For another, while I wasn't around at the time, I understand the movie was more made in response to sensationalistic reporting than a cause of it - I might be wrong about that part, though.
That said, my understanding is that A. m. scutellata x A. mellifera hybrids aren't unusually aggressive in nest defense by the standards of social hymenopterans generally, but only by the standard of the European honeybee (A. mellifera). I can't claim close familiarity with the relevant literature on bee hybrids, but from what I have seen, their nest defense behavior seems roughly comparable in aggressiveness to that of many yellowjacket (Vespula, Dolichovespula) species. On the other hand, a wild bee colony is likely to be one or two orders of magnitude greater in size than a wild yellowjacket colony, which means that a comparable level of aggression in nest defense could pose a significantly greater hazard.
Using the figures from the Wikipedia article [1] and its relevant source [2], it looks like A. m. scutellata x A. mellifera are responsible for an average of around 15 human deaths per year since the introduction of A. m. scutellata into Brazil in 1956. So I don't really see that there's very much to worry over here, in any case.
> Well, you're considerably more likely to run into a wild colony of "Africanized" hybrids than you are a great white shark
Are you? They attack rarely (although are thought to have done so fatally a few weeks ago here in NZ) and aren’t even seen usually, but they are close to popular beaches.
Well, according to UFL's International Shark Attack File [1] and the CDC [2] respectively, on average 4.3 humans die worldwide per year of shark attacks, vs. an average 62 humans in the US per year of stings from hymenopterans excluding ants.
Given that the shark attack stats cover a period 25 times as long as that for the bees, wasps, and hornets, I do feel like "considerably" is a fair choice of adjective here.
You’re measuring attacks, I’m talking of being in close proximity.
Probably people die of bee stings more than sharks attacks here in NZ, but those bees certainly aren’t africanised. I suspect most US deaths aren’t all from africanised bees either but that’s going to be hard to prove.
Look into mushroom identification - many little brown mushrooms (LBMs) are differentiated only by careful microscopic analysis of their spores or DNA sequencing. Mushrooms are especially difficult because many of the potentially useful identifying features are only present at certain (short - hours or a day or two) phases of the lifecycle of the fruiting body.
Finally, for those who think genomic/genetic studies are being used inappropriately, consider that while they may seem to me to be, in practice, just another sort of 'data processing' (which they are not - they are often just generalised (or even generalized), and their application to new contexts is not that different to simply applying similar analysis to previous contexts) it is possible, for example, that, for example, the study of the DNA sequences of fungi actually (if you want to make a broader and very broad claim about fungus genomics) might in the future yield, in this particular case, a much more detailed, more reliable (and possibly more objective) classification (if not entirely a direct one) of some of the fungi and their eukaryotes in our immediate neighbourhood.
I've also got to say that for the same reason, I don't have a lot of confidence in the 'fungal genomic analysis' thing in particular, because, on the whole, it seems to me to be so easily manipulated.
I occasionally use iNaturalist to help identify plants and fungus while out on hikes. The community there has a ton of specialists and it is extremely common to get messages like this on observations that are months old. Here is one I got this morning about a random mushroom I took a picture of in the woods of Indiana:
Russula sanguinea was described from a European mushroom and therefore probably isn't here in North America at all. The name has been applied to many red Russula in N. A. adding to the confusion. Out west where it may be sorted it is being called Russula rhodocephala which itself is a lookalike for Russula americana but under different trees according to Danny Miller here [1]. Mushroomexpert's Kuo and Mycoquebec say that a lookalike under oaks in the east is Russula tenuiceps or R. sanguinaria under conifers/pines, but it is probably a group of species, and also not the same as the European one in the case of R. sanguinaria. We are trying to downvote these identifications for this reason. Hopefully, any people interested in identifying mushrooms will pitch in and help to vote any Russula that is being called Russula sanguinea in the eastern US back to genus level anyway, but we are concerned with a few other species too. Read fungee's journal post here [2]. Check out the master list here [3]. Another thing that is daunting for Russula ID, there are well over a hundred known red Russula in the east, many are not named yet, and, if they are, the name is not in use.
I dabbled in mycology and identifying mushrooms is super hard, probably one of the hardest taxonomy things. I wouldn’t want to be the expert in that field getting asked all the time with a single iPhone photo.
/r/mycology had to say stop posting “please identify this mushroom” because it was so common. I’d imagine its easier with insects. And you don’t have as many people who care because they aren’t trying to eat them as often.
I still like to ID random bugs I find in my house and backyard and it’s always a probability exercise.
Those tree identification apps by taking a photo never work. I used it at a UofT garden where every tree was labelled and it got it wrong every time. So even the ML is way off.
I read genomic data collected for phylogenetic analysis of non-hymenopteran species the way I do, I don't expect to find a single specimen of that species that I haven't seen somewhere else, either within my own field of study or any other. It is possible that some new species of hymenopteran may be found from genomic data, and that this newly discovered species will then become a member of the Hymenoptera, but it would probably not be of that group we currently consider. That's the thing: the current state of the hymenopteran phylogeny is that although the species of hymenopteran I consider most closely related to each other has been found in multiple specimens from multiple populations, they are a diverse group, with many examples of them from multiple regions. That's the kind of thing we would expect to see from a modern, large-scale genome analysis, but that is not how I see it.
> I dabbled in mycology and identifying mushrooms is super hard, probably one of the hardest taxonomy things.
There are a lot of mushrooms that are very easy to identify, and learning edible mushrooms is imho a lot easier than learning edible plants. But if you pick up mushrooms at random then yeah, it's generally extremely difficult.
I mean out of the 2,000 mushrooms in North America, there are all of 20 or 30 that are seriously poisonous. So it doesn't take all that long to learn the most harmful ones. Especially since you don't even need to know whether or not a mushroom is harmful, only if it looks vaguely like one of the harmful ones.
Yes, and this even applies to vertebrates and can sometimes work in reverse. I was part of a team of research divers that did fish counts in California. This was in the early 00's so in several instances genetic research found that seemingly identical fish were different species depending on region. In one case groups of fish that looked quite different turned out to be the same species. Very frustrating when you are putting in so much work underwater!
That whole experience made me very skeptical of citizen-science projects once I knew how much training was required to do good work. While they are a great compliment to professional research they are no replacement (though often funders are treating citizen science as just that).
Yes. And to make it even more confusing, there are often plants/animals that have wildly varying appearance but are actually the same species: e.g. great danes/chihuahuas or cabbage/broccoli
