- Author: Kathy Keatley Garvey
“I got two phone calls almost simultaneously on my two cell phones, so I thought this could not be a prank, but I am still in disbelief,” said Leal, a UC Davis distinguished professor in the Department of Molecular and Cellular Biology, and former professor and chair of the Department of Entomology (now Entomology and Nematology)
The caller: The National Academy of Sciences (NAS)
The message: You've been elected a member of the National Academy of Sciences, the highest honor a scientist can achieve.
"Members are elected to the National Academy of Sciences in recognition of their distinguished and continuing achievements in original research,” a spokesperson related. “Membership is a widely accepted mark of excellence in science and is considered one of the highest honors that a scientist can receive. Current NAS membership totals approximately 2,400 members and 500 international members, of which approximately 190 have received Nobel prizes."
“As they say, many deserving and few lucky ones," Leal commented. "Bruce Hammock told me many years ago that when he was elected to NAS, he looked around and saw many deserving colleagues. Now I understand that feeling very well. It is a tremendous and humbling honor. I hope an imposter syndrome does not kick in.”
Hammock, a UC Davis distinguished professor who holds a joint appointment with the Department of Entomology and Nematology, was elected a NAS member in 1999.
They are the only UC Davis entomologists who are NAS members.
Leal: World Leader in His Field
Leal, a native of Brazil and educated in Brazil, Japan and the United States, joined the UC Davis Department of Entomology in 2000. In 2013, he accepted a position with the Department of Molecular and Cellular Biology. "Walter is an internationally recognized entomologist and a world leader in his field for his groundbreaking and transformative research in insect olfaction and chemical ecology,” Hammock said. “He is truly a renaissance man. He chaired our entomology department from 2006 to 2008, and under his tenure, our department was ranked No. 1 in the country. I've long admired (1) his rigorous fundamental research programs supported by National Science Foundation, National Institutes of Health, and the U.S. Department of Food and Agriculture, and other agencies, (2) how he tackles and solves multiple challenging problems in insect olfaction and chemical ecology, (3) his grasp of how to organize and moderate highly successful worldwide research webinars (4) his generosity in helping other succeed and (4) his finely honed sense of humor."
Leal solves entomological problems spanning agriculture, human health, and welfare. He translates pheromone technology to agriculturists and serves as a principal investigator for the Pacific Southwest Regional Center of Excellence for Vector-Borne Diseases (affiliated with the Centers for Disease Control and Prevention). He holds more than 20 patents.
“Walter has been exceptionally conscientious, active, and generous in professional service at UC Davis,” Hammock pointed out. "In August of 2021, he achieved a ‘first' for international science communication when he organized and led the extraordinary virtual conference ‘Insect Olfaction and Taste in 24 Hours Around the Globe.' I especially applaud him for elucidating the mode of action of the insect repellent DEET, developed in 1946 and known as ‘the gold standard of repellents.' Its mode of action remained an enigma for six decades until Walter's discovery. In researching the neurons in mosquito antennae sensitive to DEET, he isolated the first DEET-sensitive odorant receptor, paving the way for the development of better repellents.”
May Berenbaum, professor and head, Department of Entomology, University of Illinois-Urbana-Champaign, National Medical of Science Laureate, NAS member, and editor of the Proceedings of the National Academy of Sciences, earlier wrote that “Dr. Leal is indisputably a world leader in the field of insect chemical ecology whose work over the course of his long and distinguished career has transformed basic knowledge of insect olfactory mechanisms and inspired innovative practical applications for sustainable management of insects of importance in agriculture and human health. He has contributed significantly to the current understanding of the structure and function of every component of olfaction, including receptors, binding proteins, and degrading enzymes, revising classic paradigms along the way. No textbook and no course on insect chemical communication could be considered complete without mentioning his landmark research achievements.”
'Just Like in a Honey Bee Colony'
Leal recently was named the 2024 recipient of the UC Davis Academic Senate's Distinguished Research Award, and will present a lecture on “Just Like in a Honey Bee Colony--It Takes a Team in the UC Davis Hive to Win an Award” at the Academic Senate's Faculty Distinguished Research Award Lecture Lunch on Tuesday, May 7 from noon to 1 p.m. in the UC Davis Conference Center.
Leal is the first UC Davis faculty member to receive the Academic Senate's trifecta of awards: outstanding teaching, public service, and research. Leal received the Academic Senate's 2020 Distinguished Teaching Award for Undergraduate Teaching, and the 2022 Distinguished Scholarly Public Service Award.
Among Leal's many honors: Fellow of the Entomological Society of America (2009), American Association for the Advancement of Science (2005), and the National Academy of Inventors (2019). He was elected a trustee of the Royal Entomological Society in February 2024.
Leal holds a Ph.D. in applied biochemistry from the University of Tsukuba, Japan, with subsequent postdoctoral training in entomology and chemical ecology at the National Institute of Sericultural and Entomological Science (NISES) and Cornell University, respectively. He was the first non-Japanese person to earn tenure at Japan's Ministry of Agriculture, Forestry, and Fisheries.

- Author: Kathy Keatley Garvey
It's early morning, Aug. 20. A lady beetle is snacking on aphids on our native milkweed plant (where the monarchs are supposed to be, but aren't!). And then, apparently satiated, LB climbs a twig to the top of her Mt. Everest, looks around, unfolds her wings, and takes off.
The miracle of flight! The miracle of unpacking what's under those wings. The miracle of seeing it all happen.
"The ladybug is a tiny insect with hind wings four times its size," wrote Joanna Klein in her article,
Ladybugs Pack Wings and Engineering Secrets in Tidy Origami Packages, in the May 18, 2017 edition of The New York Times. "Like an origami master, it folds them up into a neat package, tucking them away within a slender sliver of space between its abdomen and the usually polka-dotted, harder wings that protect it.
"When it is time to take off, it deploys its flying apparatus from beneath its colorful shell-like top wings, called the elytra, in only a tenth of a second. And when it lands, it folds it back in just two. Switching between flying and crawling many times in a day, the ladybug travels vast distances."
Klein called attention to a study published in the May 17, 2017 edition of the Proceedings of the National Academy of Sciences. The authors, she said, detailed "just how the ladybug manages to cram these rigid structures into tiny spaces is a valuable lesson for engineers designing deployable structures like umbrellas and satellites."
It's the work of Kazuya Saito of the Institute of Industrial Science, University of Tokyo, Japan, and his colleagues, Shuhei Nomura, Shuhei Yamamoto, Ryuma Niiyama and Yoji Okabe.
The title? "Investigation of Hindwing Folding in Ladybird Beetles by Artificial Elytron Transplantation and Microcomputed Tomography."
The significance? "Hindwings in ladybird beetles successfully achieve compatibility between the deformability (instability) required for wing folding and strength property (stability) required for flying. This study demonstrates how ladybird beetles address these two conflicting requirements by an unprecedented technique using artificial wings. Our results, which clarify the detailed wing-folding process and reveal the supporting structures, provide indispensable initial knowledge for revealing this naturally evolved optimization system. Investigating the characteristics in the venations and crease patterns revealed in this study could provide an innovative designing method, enabling the integration of structural stability and deformability, and thus could have a considerable impact on engineering science."
The abstract? "Ladybird beetles are high-mobility insects and explore broad areas by switching between walking and flying. Their excellent wing transformation systems enabling this lifestyle are expected to provide large potential for engineering applications. However, the mechanism behind the folding of their hindwings remains unclear. The reason is that ladybird beetles close the elytra ahead of wing folding, preventing the observation of detailed processes occurring under the elytra. In the present study, artificial transparent elytra were transplanted on living ladybird beetles, thereby enabling us to observe the detailed wing-folding processes. The result revealed that in addition to the abdominal movements mentioned in previous studies, the edge and ventral surface of the elytra, as well as characteristic shaped veins, play important roles in wing folding. The structures of the wing frames enabling this folding process and detailed 3D shape of the hindwing were investigated using microcomputed tomography. The results showed that the tape spring-like elastic frame plays an important role in the wing transformation mechanism. Compared with other beetles, hindwings in ladybird beetles are characterized by two seemingly incompatible properties: (i) the wing rigidity with relatively thick veins and (ii) the compactness in stored shapes with complex crease patterns. The detailed wing-folding process revealed in this study is expected to facilitate understanding of the naturally optimized system in this excellent deployable structure."
But back to our little lady beetle in our pollinator garden. It's difficult to catch a lady beetle in flight. They don't fly when you WANT them to, and when they do fly, you and your camera are NOT ready. And when you and your camera ARE ready, all focused and everything, they change their mind or change directions. So, in keeping with our motto, "Don't poke 'em, prod 'em or pin 'em," we waited.
With the morning sun behind her back, LB finally obliged and took flight.
We managed to catch the action with a Nikon Z7 with a Nikon 105mm lens, manually focused: F-stop 16; shutter speed, 1/2500 of a second; and ISO, 5600.
Here's hoping LB will return. She missed a few aphids!



- Author: Kathy Keatley Garvey
It's one of the highest honors a scientist can receive. Members are elected to NAS in recognition of their distinguished and continuing achievements in original research.
Agrawal received his doctorate in population biology in 1999 from UC Davis, working with major professor Richard "Rick" Karban, UC Davis Department of Entomology and Nematology.
"Anurag is an inspiration as a scientist and as a person," Karban said. "I've learned a lot from him."
At Cornell, Agrawal is the James A. Perkins Professor of Environmental Studies in the College of Agriculture and Life Sciences. He researches the ecology and evolution of interactions between wild plants and their insect pests, including aspects of community interactions, chemical ecology, coevolution and the life cycle of the monarch butterfly.
Agrawal is the author of the celebrated book, Monarchs and Milkweed: A Migrating Butterfly, a Poisonous Plant, and Their Remarkable Story of Coevolution, published in 2017 by Princeton University Press. The book won a 2017 National Outdoor Book Award in Nature and Environment and an award of excellence in gardening and gardens from the Council of Botanical and Horticultural Libraries. It was also named one of Forbes.com's 10 best biology books of 2017. Read a review of his Monarchs and Milkweed book from the journal Ecology and read the first chapter here. (You can order the book here.)
As Agrawal said in a Cornell news release, “It's a tremendous honor and totally unexpected. I look forward to representing Cornell and also playing a part in the NAS role of advising the U.S. government on science policy.”
"A key research focus for Agrawal's Phytophagy Lab is the generally antagonistic interactions between plants and insect herbivores," according to the Cornell news release. In an attempt to understand the complexity of communitywide interactions, questions include: What ecological factors allow the coexistence of similar species? And what evolutionary factors led to the diversification of species? Agrawal's group is currently focused on three major projects: the community and evolutionary ecology of plant-herbivore relationships; factors that make non-native plants successful invaders; and novel opportunities for pest management of potatoes. Recent work on toxin sequestration in monarch butterflies was featured on the cover of the April 20 issue of Proceedings of the National Academy of Sciences."
Agrawal holds two degrees from the University of Pennsylvania, a bachelor's degree in biology and a master's degree in conservation biology. He joined the Cornell faculty in 2004 as an assistant professor of ecology and evolutionary biology, with a joint appointment in the Department of Entomology. He advanced to associate professor in 2005, and to full professor in 2010. He was named the James A. Perkins Professor of Environmental Studies in 2017.
A fellow of the American Association for the Advancement of Science (2012), and recipient of the American Society of Naturalist's E.O. Wilson Award in 2019, Agrawal won the Entomological Society of America's 2013 Founders' Memorial Award and delivered the lecture on Dame Miriam Rothschild (1908-2005) at ESA's 61st annual meeting, held in Austin, Texas.
Agrawal was at UC Davis in January of 2012 to present a seminar on "Evolutionary Ecology of Plant Defenses." His abstract: "In order to address coevolutionary interactions between milkweeds and their root feeding four-eyed beetles, I will present data on reciprocity, fitness tradeoffs, specialization and the genetics of adaptation. In addition to wonderful natural history, this work sheds light on long-standing theory about how antagonistic interactions proceed in ecological and evolutionary time."
Members are elected to NAS in recognition of their distinguished and continuing achievements in original research. Among those previously elected to NAS: Bruce Hammock, UC Davis distinguished professor of entomology who holds a joint appointment with the UC Davis Comprehensive Cancer Center. He was elected to NAS in 1999.


