- Author: Kathy Keatley Garvey
Postdoctoral researcher Nick Saleh of the Santiago Ramirez lab, UC Davis Department of Evolution and Ecology, will present a live talk, coupled with a question-and-answer session, on "All About Social Behavior in Bees (Especially Orchid Bees)" from 2 to 3 p.m. on Zoom. Access the Zoom link here.
The event is free and geared for families, said spokesperson Tabatha Yang, education and outreach coordinator for the Bohart Museum of Entomology.
- There are around 200 species of orchid bees.
- Orchid bee males make species-specific perfumes from fragrances collected from a variety of sources (including, but not limited to orchids).
- Orchid bees are hugely important pollinators in the neotropical region.
- Orchid bees are corbiculate bees, the group which also contains honey bees, bumblebees, and stingless bees.
- Orchid bees have typically been considered solitary bees, but we now know they can have a diversity of simple social behaviors.
"I am broadly interested in the mechanistic basis of behavioral evolution in animals, especially insects, in the context of social and sexual communication," Saleh says on his website. "Much of my research has investigated the evolution of social behavior in orchid bees, using them as a model system to examine transitions from solitary to social life-histories. I take an integrative approach to research, utilizing behavioral, transcriptomic, genomic, and chemical data to understand how socially sensitive physiology and communication systems evolve and function."
Orchid bees, distributed throughout South and Central America, are easily distinguished by their brilliant metallic coloration, primarily green, gold and blue.
“Euglossine--or orchid--bees constitute a diverse group of conspicuous insect pollinators from tropical America,” Santiago told the crowd at the 2018 UC Davis Bee Symposium in his talk, The Evolution and Chemical Ecology of Orchid Bees. "Male euglossine bees do not produce their own pheromones, but instead gather and accumulate perfume compounds from orchid flowers, fungi, and other resources, to subsequently present to females during courtship display.” Santiago was named a Chancellor's Fellow in January 2020, a five-year fellowship award.
Due to the COVID-19 pandemic, the 10th annual UC Davis Biodiversity Museum program is all virtual this year via webinars and pre-recorded presentations, and takes place throughout the month of February. The science-based event traditionally occurs on only one day--the Saturday of Presidents' Weekend, when families and friends gather on campus to learn first-hand about the UC Davis museums and collections.
This year's biodiversity event is featuring 12 museums or collections:
- Anthropology Museum
- Arboretum and Public Garden
- Bohart Museum of Entomology
- Botanical Conservatory
- California Raptor Center
- Center for Plant Diversity
- Häagen-Dazs Honey Bee Haven
- Nematode Collection
- Marine Invertebrate Collection
- Museum of Wildlife and Fish Biology
- Paleontology Collection
- Phaff Yeast Culture Collection
For more information and the schedule, access these two formats on the UC Davis Biodiversity program website: (1) live talks and demonstrations and (2) pre-recorded talks and activities. Information on the biodiversity museum events also appear on social media, including Facebook, Instagram, and Twitter, @BioDivDay.
To help support the Biodiversity Museum event, contributions are being accepted through a month-long crowdfunding campaign program at https://crowdfund.ucdavis.edu/project/24310.
Resource:
"Can Scents Create New Species? Sounds Like Orchid Bee Evolution" (Feature story on research of Santiago Ramirez on the College of Biological Sciences website, Jan. 13, 2020)
- Author: Kathy Keatley Garvey
Apis mellifera scutellata, a honey bee subspecies from southern and eastern Africa, “first made the news in 1957 when swarms escaped from an experimental breeding program in Brazil,” said population biologist Erin Calfee, lead author of “Selection and Hybridization Shaped the Rapid Spread of African Honey Bee Ancestry in the Americas,” published in PLOS Genetics.
The invasive bees expanded their range 300 to 500 kilometers a year, breeding with the European honey bees (Apis mellifera), also non-natives, and arriving in southern California in 1994.
“If we want to understand what makes a very fit honey bee, we should study scutellata-European hybrid honey bees, because in less than 50 years they've outcompeted other honey bees across most of the Americas,” said Calfee, who studies with major professor Graham Coop and collaborator Santiago Ramirez, both of the Department of Evolution and Ecology. The trio collaborated with María Alejandra Palacio and Marcelo Agra from the National Institute of Agricultural Technology (INTA) in Balcarce, Argentina.
“Compared to European-adapted honey bees, African bees preferentially forage for pollen (vs. nectar) and store little honey for winter,” said Calfee. “Foraging behavior is one of many traits that distinguish African and European honey bees and may contribute to a natural climatic range limit for Africanized honey bees, which spread rapidly out of Brazil in the 1950s and today dominate across tropical (but not temperate) regions in the Americas.”
“We find that natural selection has favored African scutellata ancestry at some of the same regions of the genome in both North and South America,” said Calfee. “This beneficial genetic variation from A. m. scutellata could be used to breed more resilient honey bees, for example with higher Varroa mitetolerance. In contrast, it doesn't look like the European ancestry was that important to the invasion's success.”
Despite their rapid move from Brazil, “today African mitochondria and traits are not widely observed in Northern California or, at their southern limit, in southern Argentina, despite having plenty of time for the invasion to reach these latitudes,” Calfee said. “Before this study no one had done a thorough genomic study of the outcome of this invasion in either North or South America, and the expected range limit and impact of scutellata ancestry on U.S. agriculture was especially uncertain.”
"This study provides the first detailed analysis of how scutellata ancestry varies with climatic variable, and therefore, future breeding studies can use the existing genetic variation along these clines to breed bees optimized for different climates,” Ramirez said.
“Scutellata-European honey bees have a number of desirable traits for bee breeding in light of current honey bee declines, including higher overall genetic diversity and resilience to Varroa mites and toxins,” the UC Davis doctoral student said. “But they are also known for being much more defensive than most European honey bees.” European colonists brought Apis mellifera to what is now the United States in 1662.
Their study found:
- Bee populations that reached California traveled five times the distance out of Brazil as bees in Argentina, but the two hybrid zones have nearly the same latitude. “This is pretty strong evidence that reaching cooler climates has blocked the further spread of scutellata ancestry. It also implies that their future range limit may be very sensitive to climate change,” Calfee says.
- Scutellata-European hybrid honey bee populations are very genetically variable. Looking at the hybrid zones in California and Argentina, we find the scutellata-to-European ancestry transition happens over hundreds of kilometers. “Seeing this much variation in their ancestry proportions, we can expect lots of variation in important traits, like defensive behaviors and Varroa mite tolerance,” Calfee said. “This also suggests there is a very blurry line between so-called ‘Africanized' and ‘non-Africanized' honey bees, and beekeepers should be very skeptical about using these labels, especially when based on mtDNA alone, to predict traits.”
- “Possibly our most surprising result is that we don't see a big drop in genetic diversity, or bottleneck,” Calfee said, “as we move further away from Brazil. Because the invasion was so rapid, and spread across thousands of kilometers, we would expect only a few of the scutellata haplotypes to make it all the way to California, but the bees in California have similar diversity to the bees in Argentina. This means that large populations of scutellata-European hybrid honey bees made it all the way to the ends of the invasion and they were perhaps even more successful than we'd first imagined.”
- “We see these wide hybrid zones, and we would expect most traits to have similarly wide clines,” Calfee related. “We see this with wing length, which increases as we move into higher latitudes and African scutellata ancestry goes down. But many traits we couldn't measure in this study because they can only be measured on colonies, not individual bees. I would be very curious to go out and measure the defensive behaviors of feral colonies across these hybrid zones and see if defense also has a smooth transition matching the changes we see in ancestry composition. For now, we don't really know how defensive honey bees are with intermediate scutellata ancestry, but we'd expect them to vary a lot, and overlap with what we see in European bees.”
“It would be great to combine our data with more behavioral mapping studies to see if we can uncover which traits are driving the selection patterns we see in the genome,” Calfee commented “For example, scutellata-European hybrid honey bees defend their colonies from Varroa mite infection by removing infected brood and biting or ‘grooming' Varroa mitesoff of adult bees. These traits are potentially really important in the wild because Varroa mites are a common problem contributing to honey bee declines. But most genetic mapping studies have been done in European bees, so we currently don't know which regions of the genome underlie these beneficial behaviors in scutellata-European hybrid honey bees.”
Scutellata-European hybrid honey bees are known for their defensive behaviors. In comparison with European honey bees, they defend their colonies in greater numbers, stinging predators and pursuing intruders at greater distances. That defense behavior resulted in news media sensationalizing them as "killer bees." Calfee said she was never stung. “That's mostly because bees sting only to defend their colonies, not when out foraging on flowers.” Calfee collected freely foraging honey bees. “We did find some feral nests in utility poles and trees in Argentina,” she said, “and we sampled bees from the entrances, but thankfully, we didn't disturb any of these colonies enough to elicit a defense response.”
Just by looking at them, you cannot tell if a honey bee has African scutellata ancestry, she said. “There are subtle differences in body size--scutellata are slightly smaller and have shorter wings--but there's also a lot of variation between individual bees. So we didn't actually know what percent scutellata ancestry our samples had until we got the sequencing results back. It was pretty exciting to see such a beautiful cline in ancestry in the data!”
Her motivation for the research? “I wanted to study the genomics of scutellata-European hybrid honey bees because they are this story of the incredible potential, but also limitations, of adaptation,” said Calfee, who holds a bachelor's degree in history from Brown University, magna cum laude, and expects to receive her doctorate in population biology from UC Davis in May of 2021. She grew up in Davis, coincidentally with a feral bee colony living in an almond tree in her backyard.
“What made scutellata-European hybrid bees such a successful genetic mixture, and also, what's stopped them from getting all the way to Canada? A lot of work has already been done on these bees and why they might be more fit than European honey bees, especially in the tropics. For example, we know that they are adapted to warmer climates, have higher resilience against Varroa mites and pesticides and overall much higher genetic diversity. What's really useful about taking a population genetics approach is that the most important selection pressures will naturally leave the largest detectable genomic signatures.”
“I also wanted to compare the genetic outcomes between the bees that spread north to California and those that spread south to Argentina. Because these bee populations split early in the invasion out of Brazil, they give us two sources of information about the range limits and which genetic regions are important to the incredible success of the invasion. It's a unique opportunity to have large-scale natural replication like this.”
In their collaboration with the Argentina scientists, they sought to compare the outcomes of the invasions in California to South America. “We only had a rough idea of where the hybrid zones were from previous studies based on mitochondria surveys or just a few bees,” Calfee related. “So we sampled very long transects, hundreds of kilometers, in both California and Argentina, netting individual bees.”
“Luckily for us, the hybrid zones ended up being very wide and hard to miss! We sequenced the genomes of hundreds of bees across these transects and determined how the proportions of scutellata vs. Europeanancestry changes with latitude. Because these hybrid bees are recent genetic mixtures of African A. m. scutellata and European bee subspecies, we were able to infer the patchwork of scutellata vs. European ancestry across their genomes and look for regions of the genome with an overabundance of one ancestry, a sign that natural selection has favored that ancestry.”
The project was funded in part by the Pollinator Partnership and North American Pollinator Protection Campaign. The study took several years, from planning to publication, but the all the sampling was done in 2018.
The abstract:
Recent biological invasions offer ‘natural' laboratories to understand the genetics and ecology of adaptation, hybridization, and range limits. One of the most impressive and well-documented biological invasions of the 20th century began in 1957 when Apis mellifera scutellata honey bees swarmed out of managed experimental colonies in Brazil. This newly-imported subspecies, native to southern and eastern Africa, both hybridized with and out-competed previously-introduced European honey bee subspecies. Populations of scutellata-European hybrid honey bees rapidly expanded and spread across much of the Americas in less than 50 years. We use broad geographic sampling and whole genome sequencing of over 300 bees to map the distribution of scutellata ancestry where the northern and southern invasions have presently stalled, forming replicated hybrid zones with European bee populations in California and Argentina. California is much farther from Brazil, yet these hybrid zones occur at very similar latitudes, consistent with the invasion having reached a climate barrier. At these range limits, we observe genome-wide clines for scutellata ancestry, and parallel clines for wing length that span hundreds of kilometers, supporting a smooth transition from climates favoring scutellata-European hybrid bees to climates where they cannot survive winter. We find no large effect loci maintaining exceptionally steep ancestry transitions. Instead, we find most individual loci have concordant ancestry clines across South America, with a build-up of somewhat steeper clines in regions of the genome with low recombination rates, consistent with many loci of small effect contributing to climate-associated fitness trade-offs. Additionally, we find no substantial reductions in genetic diversity associated with rapid expansions nor complete dropout of scutellata ancestry at any individual loci on either continent, which suggests that the competitive fitness advantage of scutellata ancestry at lower latitudes has a polygenic basis and that scutellata-European hybrid bees maintained large population sizes during their invasion. To test for parallel selection across continents, we develop a null model that accounts for drift in ancestry frequencies during the rapid expansion. We identify several peaks within a larger genomic region where selection has pushed scutellata ancestry to high frequency hundreds of kilometers past the present cline centers in both North and South America and that may underlie high-fitness traits driving the invasion.
- Author: Kathy Keatley Garvey
Distributed throughout South and Central America, orchid bees are easily distinguished by their brilliant metallic coloration, primarily green, gold and blue, says researcher Santiago Ramirez, an assistant professor in the UC Davis Department of Evolution and Ecology.
He'll discuss "The Evolution and Chemical Ecology of Orchid Bees" at the fourth annual UC Davis Bee Symposium: Keeping Bees Healthy on Saturday, March 3 in the UC Davis Conference Center. His talk begins at 10:15 a.m.
“Insects rely more on chemical signals than on any other sensory modality to find, identify, and choose mates,” Ramirez points out. “Euglossine--or orchid--bees constitute a diverse group of conspicuous insect pollinators from tropical America. Male euglossine bees do not produce their own pheromones, but instead gather and accumulate perfume compounds from orchid flowers, fungi, and other resources, to subsequently present to females during courtship display.”
"They are extremely charismatic organisms," he says.
"Male-gathered perfumes are stereotyped, species-specific, and divergent among closely related taxa, suggesting that they play a key role in maintaining, and possibly originating, reproductive isolation among lineages."
Ramirez says that “Most insects rely on chemical signals (semiochemicals) to gain precise information on the location, identity, and quality of potential mates. Despite the ubiquity and importance of semiochemicals across the insect phylogeny, the underlying genetic and molecular mechanisms that control signal chemistry and signal detection remain poorly understood. Moreover, whether insect sex semiochemicals mediate reproductive isolation, speciation, and lineage diversification remains surprisingly unexplored given the vast diversity and ecological dominance of insects on Earth.”
His research involves integrating diverse techniques from multiple disciplines, including behavioral ecology, chemical ecology, population genetics, functional genomics, and neuroethology “to answer specific questions about the genetic basis, function, and evolution of chemosensory communication in arguably one of the most important groups of insect pollinators in the American tropics.”
Ramirez received his bachelor's degree in biology, with honors, from the Universidad de los Andes (Colombia) in 2001, and his doctorate in organismic and evolutionary biology from Harvard University in 2008. He served as a postdoctoral fellow at UC Berkeley from 2008 to 2012 before joining the UC Davis faculty in 2013.
The symposium is sponsored by the UC Davis Honey and Pollination Center, Robert Mondavi Institute of Wine and Food Science, and the UC Davis Department of Entomology and Nematology.
Keynote speaker at the symposium is noted bee scientist/professor/author Tom Seeley of Cornell University, Ithaca, N.Y., who will speak on "Darwinian Beekeeping."
The daylong event "is designed for beekeepers of all experience levels, including gardeners, farmers and anyone interested in the world of pollination and bees," said Amina Harris, director of the Honey and Pollination Center. "In addition to our speakers, there will be lobby displays featuring graduate student research posters, the latest in beekeeping equipment, books, honey, plants, and much more."
To register, access the Honey and Pollination Center website. For more information, contact Amina Harris at aharris@ucdavis.edu or Liz Luu at luu@caes.ucdavis.edu.
- Author: Kathy Keatley Garvey
Heaven scent?
Orchid bee researcher Santiago Ramirez, an assistant professor in the UC Davis Department of Evolution and Ecology, will discuss his work on Sunday, May 7 at the third annual UC Davis Bee Symposium in the UC Davis Conference Center on Alumni Drive. He'll speak at 10:45 a.m. on “The Evolution and Chemical Ecology of Orchid Bees.”
The all-day symposium, sponsored by the UC Davis Honey and Pollination Center and the UC Davis Department of Entomology and Nematology, begins at 9 a.m. with registration and a continental breakfast. Amina Harris, director of the Honey and Pollination Center, and Neal Williams, assistant professor, UC Davis Department of Entomology and Nematology, will welcome the crowd. Registration for the event continues today through Wednesday, May 3.
Orchid bees, distributed throughout South and Central America, are easily distinguished by their brilliant metallic coloration, primarily green, gold and blue.
“Insects rely more on chemical signals than on any other sensory modality to find, identify, and choose mates,” Ramirez points out. “Euglossine--or orchid--bees constitute a diverse group of conspicuous insect pollinators from tropical America. Male euglossine bees do not produce their own pheromones, but instead gather and accumulate perfume compounds from orchid flowers, fungi, and other resources, to subsequently present to females during courtship display.”
The intellectual merit? “Most insects rely on chemical signals (semiochemicals) to gain precise information on the location, identity, and quality of potential mates," Ramirez says. “Despite the ubiquity and importance of semiochemicals across the insect phylogeny, the underlying genetic and molecular mechanisms that control signal chemistry and signal detection remain poorly understood. Moreover, whether insect sex semiochemicals mediate reproductive isolation, speciation, and lineage diversification remains surprisingly unexplored given the vast diversity and ecological dominance of insects on Earth.”
His project involves integrating diverse techniques from multiple disciplines, including behavioral ecology, chemical ecology, population genetics, functional genomics, and neuroethology “to answer specific questions about the genetic basis, function, and evolution of chemosensory communication in arguably one of the most important groups of insect pollinators in the American tropics.”
“This project offers unique training and educational opportunities,” he says. “One postdoctoral researcher, one graduate student, and several undergraduate assistants will receive training in entomology, chemical ecology, population genetics, molecular biology, and neuroethology.”
Ramirez expects the field and laboratory work in South and Central America to “foster greater international cooperation, broadening our impact in the education and training of future scientists from diverse backgrounds. We have a track record of collaborating intimately with museums, public exhibits, filmmakers, botanical gardens, and educational institutions to disseminate our work on euglossine bees and their intricate associations with orchids.”
“They are extremely charismatic organisms and we are currently planning to join forces with a botanical garden to install an interactive exhibit on euglossine bees," he says. "Our research will contribute toward the wider goal of gaining a better understanding of the natural world, including key organisms such as insect pollinators. The results derived from this investigation are likely to be of interest to the general public.”
Ramirez received his bachelor's degree in biology, with honors, from the Universidad de los Andes (Colombia) in 2001, and his doctorate in organismic and evolutionary biology from Harvard University in 2008. He served as a postdoctoral fellow at UC Berkeley from 2008 to 2012 before joining the UC Davis faculty in 2013.
Keynote speaker at the event is Steve Sheppard, Thurber Professor of Apiculture and chair of the Department of Entomology, Washington State University (WSU), Pullman, Wash. His topic is "Bees, Mushrooms and Liquid Nitrogen--What?" Sheppard's research involves improving honey bee health through breeding and alternative treatment approaches. He specializes in population genetics and evolution of honey bees, insect introductions and mechanisms of genetic differentiation.
Among the other speakers:
- Extension apiculturist Elina Niño of the UC Davis Department of Entomology and Nematology will introduce the apprentice-level California Master Beekeepers and present them with pins
- Researcher Maj Rundlöf, International Career Grant Fellow, UC Davis Department of Entomology and Nematology, will discuss “Flowering Crops: A Tricky Treat for Bees”
- Veterinarian Michael Karle of the Mid-Valley Veterinary Hospital, Oakland, will speak on "The New FDA Rule on the Use of Antibiotics in Hives"
- Margaret Lombard, chief executive officer of the National Honey Board, to discuss "Good as Gold: Growing Opportunities for the Small-Scale Honey Producer."
Also included will be a "Lightning Round," with each presentation spanning four to six minutes.
The topics:
- "Bumble Bee Cognition in the Wild" by Felicity Muth, postdoctoral researcher, Department of Biology, University of Nevada, Reno
- "Habitat Planting for Bees," by the Neal Williams' lab, UC Davis Department of Entomology and Nematology
- "Optical Tagging of Bees to Track Individual Movements in colonies" by Stacey Combes, assistant professor, UC Davis Department of Neurobiology, Physiology and Behavior
- "Planet Bee: Citizen Bee Projects" by Debra Tomaszewski, executive director and co-founder of the Bay Area's Planet Bee Foundation
- "Plants and Pesticides: Keeping Bees Healthy with Ornamental Horticulture" by Christine Casey, program representative, Häagen-Dazs Honey Bee Haven, UC Davis
Graduate students throughout California will be showcasing their pollinator-related research in the Graduate Student Poster Competition, a traditional part of the symposium. The winners will be announced at 4:15, at the conclusion of the symposium. Awards are first place, $1000; second place, $750; third, $500; and fourth, $250.
To register for the symposium, access http://honey.ucdavis.edu/events/2017-bee-symposium. Amina Harris can be reached at aharris@ucdavis.edu for further information.