Kenji Hashimoto

Bruce Hammock

An enzyme inhibitor developed in the UC Davis laboratory of Bruce Hammock and tested in mice by a team of international researchers shows promise that it could lead to a drug to prevent or reduce the disabilities associated with the neurodevelopmental disorders of autism and schizophrenia.

“We discovered that soluble epoxide hydrolase (sEH) plays a key role in inflammation associated with neurodevelopmental disorders. Inhibiting that enzyme stops the inflammation and the development of autism-like and schizophrenia-like symptoms in animal models,” said collaborator Kenji Hashimoto, a professor with the Chiba University Center for Forensic Mental Health, Japan. The scientists found higher levels of sEH in a key region of the brain—the prefrontal cortex of juvenile offspring-- after maternal immune activation (MIA).

“Mothers who have MIA, which results from severe stress in that region of the brain, have an increased occurrence of neurodevelopment disorders in their offspring,” Hashimoto explained. “In our study, the sEH enzyme increased dramatically in a key brain region of mice pups from mothers with MIA.”

The research, published today (March 18) in the Proceedings of the National Academy of Sciences (PNAS), is the work of 14 researchers from Chiba University Center for Forensic Mental Health; the Laboratory for Molecular Psychiatry, RIKEN Center for Brain Science, in Wako, Saitama, Japan; and the Hammock laboratory.

Research in Mice Pups
By inhibiting sEH, the researchers reversed cognitive and social interaction deficiencies in the mice pups. They hypothesize that this is due to increasing natural chemicals, which prevent brain inflammation. In people, this could reduce the disabilities associated with autism, such as anxiety, gastrointestinal disturbances and epilepsy.

“The same chemical and biochemical markers behaved as predicted in human stem cells,” said Hammock, a distinguished professor who holds a joint appointment with the Department of Entomology and Nematology and the UC Davis Comprehensive Cancer Center.

Earlier studies have indicated a genetic disposition to the disorders. The team also studied postmortem brain samples from autism patients that confirmed the alterations.

“In the case of both autism and schizophrenia, the epidemiology suggests that both genetics and environment are contributing factors,” said neuroscientist and associate professor Amy Ramsey of the Department of Pharmacology and Toxicology, University of Toronto, who was not involved in the study. “In both cases, maternal infection is a risk factor that might tip the scales for a fetus with a genetic vulnerability. This study is important because it shows that their drug can effectively prevent some of the negative outcomes that occur with prenatal infections. While there are many studies that must be done to ensure its safe use in pregnant women, it could mitigate the neurological impacts of infection during pregnancy.”

Neuroscientist Lawrence David, professor and chair of the School of Public Health, University of Albany, N.Y., who was not involved in the research, said that the study might lead to “an important therapeutic intervention for neurodevelopment disorders.”

Might Be Important Therapeutic Invervention
“There is increasing evidence that maternal immune activation activities (MIA) during fetal development can lead to aberrant neurobehaviors, including autistic-like activities,” said Lawrence, who studies neuroimmunology and immunotoxicology. The study “suggests that enzymatic control of fatty acid metabolism is implicated in neuroinflammation associated with schizophrenia and autism spectrum disorders. The expression of Ephx2 giving rise to soluble epoxide hydrolase (sEH) influences production of fatty acid metabolites, which elevate inflammation in the experimental model of mice after MIA; the sEH inhibitor TPPU (N-[1-(1-oxopropyl)-4-piperidinyl]-N'-[4-(trifluoromethoxy)phenyl)-urea) was postnatally used to improved behaviors. Analysis of cadaver brains from individuals with ASD also expressed increased sEH. Fatty acid metabolites have been known to affect fetal development, especially that of the brain; therefore, TPPU might be an important therapeutic intervention for neurodevelopmental disorders.”

Molecular bioscientist Isaac Pessah of the UC Davis School of Veterinary Medicine, distinguished professor and associate dean of research and graduate education in the Department of Molecular Biosciences, described the findings as “significant” and called for more detailed and expanded studies.

“There is mounting evidence that inappropriate maternal immune responses during pregnancy to infection contributes elevated risk to autism spectrum disorder, at least in a fraction of cases,” Pessah said. “The most significant findings reported here is that a commonly used mouse model of immune-triggered behavioral deficits mimicking some of the core symptoms in autistic children can be suppressed by inhibiting a novel biochemical target, soluble epoxide hydrolase; a target not previously explored as a target for therapeutic intervention to treat ASDs. These findings provide a rational basis for more detailed and expanded studies in mice carrying mutations implicated in ASDs to determine whether the therapeutic benefits of soluble epoxide hydrolase inhibitor(s) observed in this study are more generalizable.”

Autism in the United States
The Center for Disease Control and Prevention (CDC) estimates that 1 in 68 children in the United States have autism, commonly diagnosed around age 3. It is four times more common in boys than girls. CDC defines autism spectrum disorder as a “developmental disability that can cause significant social, communication and behavioral challenges.” The disorder impairs the ability to communicate and interact.

Approximately 3.5 million people or 1.2 percent of the population in the United States are diagnosed with schizophrenia, one of the leading causes of disability, according to the Schizophrenia and Related Disorders Alliance of America (SARDAA). Scores more go unreported. Approximately three-quarters of persons with schizophrenia develop the illness between 16 and 25 years of age. Statistics also show that between one-third and one half of all homeless adults have schizophrenia, and 50 percent of people diagnosed have received no treatment. Among the symptoms: delusions, hallucinations, disorganized speech, disorganized or catatonic behavior, and obsessive-compulsive disorders, such as hoarding, according to SARDAA.

Promising Prophylactic or Theraputic Target
In their research paper, titled “Key Role of Soluble Epoxide Hydrolase in the Neurodevelopmental Disorders of Offspring After Maternal Immune Activation,” the scientists described sEH as “a promising prophylactic or therapeutic target for neurodevelopmental disorders in offspring after MIA.”

First author Min Ma and second Qian Ren of the Hashimoto lab conducted the animal and biochemical work, while chemists Jun Yang and Sung Hee Hwang of the Hammock lab performed the chemistry and analytical chemistry. Takeo Yoshikawa, a team leader with the RIKEN's Molecular Psychiatry Laboratory, performed measurements of gene expression in the neurospheres from iPSC (induced pluripotent stem cells) from schizophrenia patients and postmortem brain samples from autism patients.

Hashimoto described the international collaboration as “exciting and productive.” This is their third PNAS paper in a series leading to endoplasmic reticulum stress. “We report discovery of a biochemical axis that leads to multiple neurological disorders, including depression, Parkinson's disease, schizophrenia, autism spectrum disorders and similar diseases,” he said.

First Human Trials
William Schmidt, vice president of clinical development at EicOsis, a Davis-based company developing inhibitors to sEH to treat unmet medical needs in humans and companion animals, said the company is devel​oping a first-in-class therapy for neuropathic and inflammatory pain. “EicOsis is in the process of finalizing our first human trials on the inhibitors of the soluble epoxide hydrolase, originally reported from UC Davis,” Schmidt said. “We are targeting the compounds as opioid replacements to treat peripheral neuropathic pain. It is exciting that the same compound series may be used to prevent or treat diseases of the central nervous system.”

Several grants from the National Institutes of Health, awarded to Hammock, supported the research. Hammock praised the many collaborators and students he has worked with on the project. “This work illustrates the value of research universities in bringing together the diverse talent needed to address complex problems,” Hammock said. “It also illustrates the value of fundamental science. This autism research can be traced directly to the fundamental question of how caterpillars turn into butterflies.”

Now working solely on research to benefit humankind, Hammock began his career in insect science at UC Berkeley where he investigated how epoxide hydrolase degrades a caterpillar's juvenile hormone. The process leads to metamorphosis from the larval stage to the adult insect. Hammock then wondered "Does the enzyme occur in plants? Does it occur in mammals?"

It does, and particularly as a soluble epoxide hydrolase in mammals.

"Science is full of surprises," said Hammock, who founded EicOsis to help human patients conquer pain without opioids. "We need to remember that the concept, the clinical target, and even the chemical structure, came from asking how caterpillars turn into butterflies." 

____________________________________________________________________________________________

ABSTRACT, PNAS Paper, "Key Role of Soluble Epoxide Hydrolase in the Neurodevelopmental Disorders of Offspring After Maternal Immune Activation"
“Maternal infection during pregnancy increases the risk of neurodevelopmental disorders such as schizophrenia and autism spectrum disorder (ASD) in offspring. In rodents, maternal immune activation (MIA) yields offspring with schizophrenia- and ASD-like behavioral abnormalities. Soluble epoxide hydrolase (sEH) plays a key role in inflammation associated with neurodevelopmental disorders. Here we found higher levels of sEH in the prefrontal cortex (PFC) of juvenile offspring after MIA. Oxylipin analysis showed decreased levels of epoxy-fatty acids in the PFC of juvenile offspring after MIA, supporting increased activity of sEH in the PFC of juvenile offspring. Furthermore, the expression of sEH (or EPHX2) mRNA in iPSC-derived neurospheres from schizophrenia patients with the 22q11.2 deletion was higher than that of healthy controls. Moreover, the expression of EPHX2 mRNA in the postmortem brain samples (Brodmann area 9 and 40) from ASD patients was higher than that of controls. Treatment of TPPU (a potent sEH inhibitor) into juvenile offspring from P28 to P56 could prevent cognitive deficits and loss of parvalbumin (PV)-immunoreactivity in the medial PFC of adult offspring after MIA. In addition, dosing of TPPU to pregnant mothers from E5 to P21 could prevent cognitive deficits, and social interaction deficits and PV-immunoreactivity in the mPFC of juvenile offspring after MIA. These findings suggest that increased activity of sEH in the PFC plays a key role in the etiology of neurodevelopmental disorders in offspring after MIA. Therefore, sEH would represent a promising prophylactic or therapeutic target for neurodevelopmental disorders in offspring after MIA.”

Related Research Published in PNAS

• Soluble Epoxide Hydrolase Plays a Key Role in the Pathogenesis of Parkinson's Disease
  
• Gene Deficiency and Pharmacological Inhibition of Soluble Epoxide Hydrolase Confers Resilience to Repeated Social Defeat Stress

Contacts:
Bruce Hammock, bdhammock@ucdavis.edu
Kenji Hashimoto, hashimoto@faculty.chiba-u.jp 

Grace Jones, earlier in her career at the University of Kentucky

Born Jan. 30, 1951 in Hong Kong and fondly known as “Amazing Grace,” she received her doctorate at UC Davis in 1983 with major professor Hammock, now a UC Davis distinguished professor who holds a joint appointment with the Department of Entomology and Nematology and the UC Davis Comprehensive Cancer Center.

Her husband of 41 years, Davy Jones, a longtime professor in the UK Department of Toxicology and Cancer Biology, received his doctorate from UC Davis, studying with major professor Jeffrey Granett of the then Department of Entomology.

Hammock described Grace Jones as a hard-working scientist with “amazing skill and creative insight.”

“Following her research at Texas A&M University, Grace joined my lab in the 1970s at UC Riverside and then finished her PhD at Davis in 1983,” recalled Hammock, a member of the UC Riverside faculty from 1975 to 1980, when he accepted a joint-faculty appointment in toxicology and entomology at UC Davis.

“She asked how juvenile hormone regulated the development of moth larvae that are serious agricultural pests,” Hammock said. “She also found two parasites, one of which sped up host larval development and the other of which slowed host larval development. She found that both parasitoids were manipulating the host insect endocrine system to their benefit.  Endocrine regulation of insect development was a theme of Grace's whole career which she pursued with amazing skill, hard work and creative insight.”

Longtime friend and colleague Lynn Riddiford, emerita professor of biology at the University of Washington, Seattle, who worked with Grace Jones on a National Science Foundation grant, praised her as “a creative and imaginative scientist.”

“Her research focused on the action of juvenile hormone (JH), a key hormone regulating metamorphosis in insects,” Riddiford said. “Early on Grace studied the molecular mechanisms involved in the regulation by JH of several proteins in the cabbage looper, Trichoplusia ni—the JH-inducible JH esterase that breaks down JH and several JH-suppressible hemolymph storage proteins. Her work was always careful and thorough and contributed significantly to the field.”

Riddiford said that “Grace became intrigued by the idea that Ultraspiracle (USP), the heterodimeric partner of the ecdysone receptor (EcR), might be the long-sought JH receptor. She pursued this line of research with rigor, and later found that USP bound methyl farnesoate, the immediate precursor of JH, with the high affinity typical for hormone receptors. Furthermore, she showed that the methyl farnesoate-USP complex was critical for the larval-pupal transformation in Drosophila. Even though her initial idea that USP was the JH receptor proved wrong, her work stimulated the field and resulted in a deeper understanding of the factors controlling metamorphosis in Drosophila.”

Riddiford added: “Grace will be especially remembered for her amazing drive and determination to forge ahead with her science and to continue to make significant contributions despite the disabilities engendered by her stroke.” (See research publications)

Keith Wing, Hammock's second doctoral student who went on to become a senior research associate at Rohm and Haas and DuPont, and is now a consultant, remembered her as  “a cheerful, hard-working colleague and friend, and wife of Dr. Davy Jones, University of Kentucky. A few of us spent many a late night studying juvenile hormone esterase and binding proteins at UC Riverside and Davis in lepidopteran larvae, trying to help the lab piece together the story of how JH metabolism and transport helped to regulate  insect metamorphosis.”

“We shared everything and always helped each other out,” Wing said. “Grace went on to focus on this in much greater detail, including exploration into insect hormone receptors and regulation.  She was an incredibly dedicated researcher who contributed a lot to the field."

Grace Jones received her bachelor's degree in biology in 1973 from Belmont (N.C.) Abbey College, and her master's degree in biology in 1974 from Jacksonville (Ala.) State University. She did post graduate research at Texas A&M in insect physiology and endocrinology before joining the Hammock lab in UC Riverside (1979-80). After receiving her doctorate in 1983 from UC Davis, she headed to Harvard University's Medical School as a visiting scholar in the Department of Cell Biology and Department of Pathology, working there from 1989 to 2000. Her career then included visiting scientist at Massachusetts Institute of Technology's Department of Biology and a visiting professor at Baylor College of Medicine, where she specialized in stem cell research.

The UC Davis alumnus joined the UK Department of Entomology in 1984 as an assistant research professor, studying insect biochemistry and molecular biology. She was promoted to associate research professor in 1990, and then switched to UK's School of Biological Sciences, becoming an assistant professor of molecular and cellular biology in 1991; an associate professor in 1993; and a full professor in 1999.

"Dr. Jones was a superb, internationally recognized scientist, even as her health declined over the past 18 years, but she continued to work on teaching and research throughout," wrote UK Department of Biology chair Vincent Cassone on a web page memoralizing her. "Over the course of her research career, Dr. Jones had received millions of grant dollars for her important studies from the National Institutes of Health and National Science Foundation, and published more than 100 research articles in prestigious journals such as the Proceedings of the National Academy of Sciences, USA, Journal of Biological Chemistry, and Molecular and Cellular Endocrinology. She and Davy also received a patent in 2007 for a method to identify drugs that interact with insect nuclear receptors, which could be used for biological control of pest species."

"Over the years, students have expressed great admiration and love for Professor Jones in letters and emails, and eminent scientists have expressed their high regard for her work," Cassone wrote. "A Grace Jones Memorial Fund for Family Support has been set up. Donations can be sent to the UK College of Health Science c/o Loralyn Cecil, 900 South Limestone 124E, Lexington, KY 40508 or online at https://karrn.org/. Her infectious smile will be missed in the halls of Biology, as she had her daily walks, arm in arm, color-coordinated with her husband, Davy, a testament to devotion and love."

Davy Jones notified his wife's friends and colleagues, including Hammock, of her death with an email, “Butterfly has flown on.” He attached a photo of Grace and a blue morpho butterfly.

She died in his arms, as this song, “Amazing Grace,” played softly in the room, he wrote.

“UC Riverside, UC Davis and the field lost a wonderful colleague and we have all lost a dear friend,” Hammock told him.  

Allison Gartung, lead author

Dipak Panigrahy, lead researcher

Bruce Hammock, senior author

Now, newly published research on ovarian cancer, involving an anti-inflammatory compound discovered and developed in the Bruce Hammock lab at the University of California, Davis, and tested at Harvard Medical School on mice models, indicates that the compound not only suppresses inflammation but reduces cancer growth, acting as a “surge protector.”

“We are excited about this research and its potential,” said Hammock, a UC Davis distinguished professor who holds a joint appointment with the Department of Entomology and Nematology and the UC Davis Comprehensive Cancer Center. “Chemotherapy and surgery, the mainstays of conventional cancer treatment, can act as double-edged swords. It is tragic that the very treatments used to cure cancer are helping it to survive and grow.”

The research is a “novel approach to suppressing therapy-induced tumor growth and recurrence,” said the 13-member team from Harvard Medical School/Beth Israel Deaconess Medical Center (BIDMC), UC Davis, Institute of Systems Biology of Seattle, and Emory University School of Medicine of Atlanta.

Their paper, “Suppression of Chemotherapy-induced Cytokine/Lipid Mediator Surge and Ovarian Cancer by a Dual Cox-2, sEH Inhibitor,” appears today in the Proceedings of the National Academy of Sciences (PNAS).

“To prevent tumor-recurrence after therapy, it will be critical to neutralize the inherent tumor-promoting activity of therapy-generated debris,” said lead author Allison Gartung of Harvard Medical School/BIDMC. “Our results indicate that a dual COX-2/sEH inhibitor may offer a novel alternative to protect the body from a debris-mediated inflammatory response.”

Gartung said that the study confirmed that chemotherapy-killed ovarian cancer cells “induce surrounding immune cells called macrophages to release a surge of cytokines and lipid mediators that create an optimal environment for tumors to survive and grow.”

The team treated the mice models with a dual lipid pathway inhibitor discovered several years ago in the Hammock lab. It integrates two anti-inflammatory drugs (COX-2 inhibitor and soluble expoxide hydrolase (sEH) inhibitor) into a single molecule with the aim of reducing tumor angiogenesis and metastasis.

 Chemist Sung Hee Hwang of the Hammock lab developed the compound, known as PTUPB, for the study.  “The dual inhibitor here follows earlier work we did with it, blocking breast and lung tumors in mice,” Hammock said. “PTUPB is already being clinically evaluated for its therapeutic properties in other diseases.” Chemist Jun Yang of the Hammock lab did the mass spectrometry, showing how stabilization of lipid mediators reduces cancer growth and metastasis. 

Lead researcher Dipak Panigrahy, a former Harvard physician turned full-time researcher, described chemotherapy and surgery “as our best tools for front-line cancer therapy, but chemotherapy and surgery create cell debris that can stimulate inflammation, angiogenesis, and metastasis. Thus, the very treatment used by oncologists to try to cure cancer is also helping it survive and grow. Overcoming the dilemma of debris-induced tumor progression is critical if we are to prevent tumor recurrence of treatment-resistance tumors which lead to cancer therapy failure.”

The tumor cell debris generates a “cytokine surge” that can result in a perfect storm for cancer progression. “The dual inhibitor acts as a surge protector,” Panigrahy said.

Panigrahy, who led angiogenesis and cancer animal modeling in the laboratory of Judah Folkman, a leading cancer research laboratory, based the debris model on his mother's chemotherapy treatments, and dedicated the research to his mother and “all other women who lost their lives to ovarian cancer.” American Cancer Society statistics show that among women, ovarian cancer ranks fifth in cancer deaths. A woman's risk of ovarian cancer is about 1 in 78; every year more than 14,000 die from the disease.

“Traditional cancer therapy sets up a dilemma,” Panigrahy commented. “Yes, we need to kill cancer cells but the inevitable byproduct of successfully doing so also stimulates tumor regrowth and progression. The more tumor cells you kill, the more inflammation you create, which can inadvertently stimulate the growth of surviving tumor cells. Overcoming the dilemma of debris-induced tumor progression is paramount if we are to prevent tumor recurrence of treatment-resistant tumors – the major reason for failure of cancer therapy. Our studies potentially pave the path for a new strategy for the prevention and treatment of chemotherapy-induced resistance with potential to translate to the clinic. If successful, this approach may also allow us to reduce the toxic activity of current treatment regimens.”

“The collaborative work in this paper not only defines a common problem with current cancer therapy, but it actually offers a potential solution to reduce metastasis and tumor growth following therapy,” said Primo Lara Jr., director of the UC Davis Comprehensive Cancer Center and associate director of Translational Research. “I am pleased that our Center was involved in this exciting project and we hope we can be involved in translating this basic research to the clinic.”

Panigrahy said that non-steroidal anti-inflammatory drugs (NSAIDs), which include aspirin and ibuprofen, reduce pain, fever and inflammation “bit may have severe side effects including stomach and brain bleeding as well as severe cardiovascular and kidney toxicity. They also do not specifically enhance clearing of debris.”

“We are exploring all options to translate PTUPB to cancer patients especially in combination with current cancer therapies such as chemotherapy, radiation, immunotherapy, or surgery which either directly or indirectly may generate tumor cell debris,” Panigrahy said. “Our next step is to investigate whether our findings are consistent with clinical studies involving human cancer.”

The Hammock lab has been researching the sEH inhibitor for 50 years. As a graduate student at UC Berkeley, Hammock co-discovered the sEH inhibitor with fellow graduate student Sarjeet Gill, now a distinguished professor at UC Riverside.

"We have a series of papers largely in PNAS, with the Panigrahy group showing first our soluble epoxide hydrolase inhibitors block tumor growth and metastasis when used with omega3 fish oils or with COX inhibitors and the role for these compounds in regulating a number of mediators of cancer growth," Hammock said.

Multiple grants funded the research. Hammock, the 31-year director of the UC Davis Superfund Program, received funds the National Cancer Institute and the National Institute on Environmental Health Sciences. The Panigrahy laboratory is funded by the Credit Union Kids at Heart Team. Other grants came from the C. J. Buckley Pediatric Brain Tumor Fund, Molly's Magic Wand for Pediatric Brain Tumors, the Markoff Foundation Art-in-Giving Foundation, the Kamen Foundation, Jared Branfman Sunflowers for Life, and the Joe Andruzzi Foundation. An NIH T32-training grant funded Gartung's work.

The Team

Allison Gartung completed her doctorate at Wayne State University in 2016 and has since served as a postdoctoral research fellow at Harvard Medical School/BIDMC. Highly honored for her work, she won the highest award for a post-doctoral fellow (Santosh Nigam Award) at the 15th International Conference on Bioactive Lipids in Cancer, Inflammation and Related Diseases, held in 2017 in Puerta Vallarta, Mexico. She served as a guest editor of a special double-issue of 24 invited world-experts in Cancer and Metastasis Reviews on Bioactive Lipids.

Dipak Panigrahy was accepted into medical school at Boston University at age 17. He trained in surgery with Dr. Roger Jenkins, who performed the first liver transplant in New England. Over the past decade, Panigrahy led angiogenesis and cancer animal modeling in the Judah Folkman laboratory. He joined the Beth Israel Deaconess Medical Center in 2013, and in 2014 was appointed assistant professor of pathology, and currently has a laboratory in the Center for Vascular Biology Research. Panigrahy is the expert on the team for preclinical tumor models and examining novel concepts for cancer therapy at the preclinical stage –the diversity of models he has created and worked with is unmatched.

Bruce Hammock, UC Davis distinguished professor, is the world expert and discoverer of the dual COX2-sEH inhibitor. He received his doctorate in entomology/toxicology from UC Berkeley and joined the UC Davis faculty in 1980. Highly honored by his peers, Hammock is a fellow of the National Academy of Inventors, which honors academic invention and encourages translations of inventions to benefit society. He is a member of the U.S. National Academy of Sciences, and the recipient of scores of awards, including the Bernard B. Brodie Award in Drug Metabolism, sponsored by the America Society for Pharmacology and Experimental Therapeutics; and the first McGiff Memorial Awardee in Lipid Biochemistry,

Mark Kieran of Bristol-Myers Squibb and Professor Vikas Sukhatme (Dean of Emory School of Medicine), both senior co-authors, are leading world-experts on personalized medicine approaches to support the treatment of cancer patients. Kieran is a leading oncologist with expertise in translating novel therapeutic modalities (beyond chemotherapy/irradiation) into the clinic. Plans for clinical trials involving PTUPB are underway.

Professor Sui Huang, with the Institute for Systems Biology (ISB), is known as the world's leading expert on systems biology and debris-induced tumor growth.

(Link to PNAS paper)

Should auld acquaintance be forgot, 
and never brought to mind?

No, they won't—at least not for Bruce Hammock, a distinguished professor at the University of California, Davis, and the hundreds of scientists he's trained over an academic career spanning more than four decades at UC Davis and UC Riverside.

Looking back over 2018, Hammock remembers fondly the weekend that 100 of his former laboratory alumni from 10 countries traveled to Davis to honor his work, reunite, collaborate, and reminiscence.

Billed as “Biochemistry and Society: Celebrating the Career of Professor Bruce Hammock,” the three-day event drew Hammock lab alumni from throughout the United States, as well as Egypt, Spain, China, Australia, New Zealand, Germany, Sweden, Canada and the Czech Republic.

“It was really special and I will treasure that weekend always,” said Hammock, who trained scientists at UC Riverside for five years before joining the UC Davis faculty in 1980. He currently holds a joint appointment with the UC Davis Department of Entomology and Nematology and the UC Davis Comprehensive Cancer Center. He has directed the UC Davis Superfund Program, funded by the National Institutes of Health's National Institute of Environmental Health (NIH/NIEHS), for 31 years.

Attendees took photos and signed the Bruce Hammock illustration, the work of Dennis Preston of East Lansing, Mich. (Photo by Kathy Keatley Garvey)

The distinguished professor, known for his expertise in chemistry, toxicology, biochemistry and entomology, meshes all four sciences in his 50-year research on acute and neuropathic pain in humans and companion animals. It all began with his basic research on how caterpillars become butterflies, research that led to key discoveries about chronic pain.

Since then, his lab has generated more than 80 patents, 300 postdoctoral fellows, and more than 65 graduates, who now hold positions of distinction in academia, industry and government.

Hammock's colleagues, and former postdoctoral fellows, graduate and undergraduate students and visiting scholars arrived at the lab reunion with their spouses--as well as their scientific posters for display and discussion. The posters covered everything from ground-breaking research in prestigious journals to a humorous look at his annual water balloon battles in front of Briggs Hall.

The scientists dined at the UC Davis Conference Center, the Buehler Alumni Center and the Stonegate Country Club; shared months, years and decades of memories; and toasted, roasted and gifted their mentor. Hammock, in turn, toasted, roasted and gifted them.

“We had a blast,” recalled organizer Shirley Gee, a former research toxicologist and manager of the Hammock lab for 31 years. She retired in June 2016 after 40 years of service with the university.

“I have had a vision of this event to honor Bruce for many years now, and it was such a thrill to see it come together,” she said. “Reconnecting in person with all the alumni and their families was more rewarding than I could have imagined, but even more importantly was the thrill of watching alumni reconnect with each other!  There were a lot of tears in the house.  Many people I think were surprised by how the years melted away when they began reacquainting.  I think that speaks to the environment that Bruce created that led to many strong personal and professional bonds.” 

Scientific posters, plus humorous posters, added to the Hammock lab reunion. Here Hammock answers questions from a gathering. (Photo by Kathy Keatley Garvey)

Gee credited her seven-member committee—former Hammock students Keith Wing, Jim Ottea, Tom Sparks, Babak Borhan, Qing Li; postdoctoral fellow and “academic grandson” Kin Sing Stephen Lee, a former student of Babak Borhan; and colleague Sarjeet Gill, now a distinguished professor at UC Riverside, with greatly contributing to the success of the one-of-a-kind celebration.

As graduate students, and  Hammock and Gill worked together in the John Casida lab at UC Berkeley and later in Larry Gilbert's lab where they co-discovered the enzyme, soluble epoxide hydrolase.   Hammock remembers researching juvenile hormones and what's involved in "how caterpillars became butterflies."

Hammock has studied the enzyme system and its inhibitors ever since. He recently formed a Davis-based company, EicOsis, to develop an orally active non-addictive drug for inflammatory and neuropathic pain for human beings and companion animals. Human clinical trials are scheduled to begin in 2019. Several seed-fund grants and a NIH/NINDS (National Institute of Neurological Disorders and Stroke) Blueprint Development Grant support EicOsis.

Hammock, described at the lab reunion as a “genius,” collaborates with scientists worldwide in what's been described as “unprecedented research with a multidisciplinary, integrated approach to research focused on insect biology, mammalian enzymology, and analytical chemistry.” He has authored more than 1000 publications on a wide range of topics in entomology, biochemistry, analytical and environmental chemistry in high quality journals, and has been cited more than 54,000 times. In the epoxide hydrolase field, the Hammock laboratory has published almost 900 peer-reviewed papers. 

Tom Sparks, who was Hammock's first graduate student at UC Riverside, chronicled Hammock's career and recalled humorous anecdotes from his early professorship at UC Riverside. A former professor at Louisiana State University, and now a research fellow in Discovery Research at Dow AgroSciences (now Corteva Agriscience, Indianapolis, Sparks praised Hammock's intellect and curiosity. “For Bruce, it was all about the journey, looking around and operative at the interface between entomology, biochemistry and chemistry.”

Bruce Hammock (left) discusses a poster at the poster session. (Photo by KathyKeatley Garvey)

Gill,  along with University of Utah emeritus professor Glenn Prestwich and UC Davis research scientist Karen Wagner also delivered presentations, fondly recalling their shared time and science with Hammock.

Keith Wing, who was Hammock's second graduate student at UC Riverside/Davis, served as emcee at the lab reunion. A former senior research associate at DuPont and Rohm and Haas and current consultant, Wing said “Bruce has inspired many hundreds of developing scientists. For myself and many others, he was able to see what we could become as scientists and social contributors before we could see it ourselves."

Qing Li, a professor in the University of Hawaii's Department of Molecular Biosciences and Bioengineering College of Tropical Agriculture and Human Resources who received his doctorate from UC Davis, studying with major professors Bruce Hammock and James Seiber, said  that "Bruce is an eminent scientist and a great mentor.  Many of us have benefited from his effective mentorship.  Back in 1990, after he signed my dissertation, he shook my hand, and then he asked me to tape-record it and give him the recordings -- a great 'homework' assignment and good practices for me."

Others commented that they learned this from Hammock: “We explore the unexpected and get to do things that don't work” and “Design things to fail; when they don't fail follow along.”

Hammock, the crowd agreed, seems to follow baseball legend Yogi Berra's sage advice: “If you come to a fork in the road, take it.”

Gill praised Hammock's “impact on human health, environmental health” as well as his love of the outdoors—from kayaking to mountain climbing.

Numerous alumni lauded Hammock's sense of humor. One scientist quoted Albert Einstein as saying “Creativity is intelligence having fun” and added “Bruce is always having fun.”

Among the other comments:

• “I never heard him speak a cross word.”
• "He treats everyone with respect.”
• "Bruce loves science and he loves people.”
• "He never heard a crazy idea.”
• "What Bruce does—he delivers the future.”
• "Bruce has a lot of determination and can approach difficult problems from multiple angles.”
• "Bruce values strong relationships with friends he has made over the years”

Tom Sparks, who was Hammock's first graduate student at UC Riverside, with a gag gift at the lab reunion. (Photo by Kathy Keatley Garvey)

A native of Little Rock, Ark., Hammock received his bachelor of science degree, magna cum laude, in 1969 from Louisiana State University, Baton Rouge, where he majored in entomology and minored in zoology and chemistry. Then it was off to UC Berkeley, for his doctorate in entomology/toxicology in 1973, and postdoctoral fellowship.

It was at UC Berkeley where he met and married his wife, Lassie, who had just entered the doctoral program in plant physiology. They married in 1972 and then “the Army called me up,” Hammock remembers.

Hammock served as a public health medical officer/first lieutenant with the U.S. Army Academy of Health Science in San Antonio, Texas; and then did more postdoctoral research at the Rockefeller Foundation, Department of Biology, Northwestern University, Evanston. Ill.

Hammock then joined the faculty of the Division of Toxicology and Physiology, UC Riverside Department of Entomology in 1975 before heading for UC Davis in 1980 to accept a joint-faculty appointment in toxicology and entomology.

Bruce and Lassie reared three children: Tom, Bruce and Frances. “Frances and her husband, Adrian, teach math at UC San Diego; Bruce is on the UC Davis School of Veterinary Medicine faculty; and Tom, a graduate of the American Film Institute Conservatory, makes movies,” Hammock said, adding that he and Lassie appeared in one of the movies  that Tom directed: "The Last Survivors."

Highly honored by his peers, Hammock is a fellow of the National Academy of Inventors, which honors academic invention and encourages translations of inventions to benefit society. He is a member of the U.S. National Academy of Sciences, a fellow of the Entomological Society of America, and the recipient of scores of awards, including the Bernard B. Brodie Award in Drug Metabolism, sponsored by the America Society for Pharmacology and Experimental Therapeutics; and the first McGiff Memorial Awardee in Lipid Biochemistry.

Hammock told the crowd at the reunion that he began his career studying insect science but switched to human research after encountering “all the suffering involved in acute and neuropathic pain.”

His insect science research centered around how a key enzyme, epoxide hydrolase, degrades a caterpillar's juvenile hormone, leading to metamorphosis from the larval stage to the adult insect. He then wondered "Does the enzyme occur in plants? Does it occur in mammals?" It does, and particularly as a soluble epoxide hydrolase in mammals.

“It is always important to realize that the most significant translational science we do in the university is fundamental science,” said Hammock. “The extreme and poorly treated pain that I observed as a medical officer in a burn clinic in the Army, is a major driver for me to translate this knowledge to help patients with severe pain.”

And it all began with him asking how caterpillars turn into butterflies.

"Science is full of surprises," the distinguished UC Davis professor said. "We need to remember that the concept, the clinical target, and even the chemical structure came from asking how caterpillars turn into butterflies."