John G. Hildebrand, Ph.D.

John G. Hildebrand, Ph.D.'s picture
Regents Professor

Telephone: 

(520) 621-6626

Fax: 

(520) 621-8282

Office: 

Gould-Simpson Rm 603

Functional organization and physiology of the insect olfactory system.

Behavior and chemical ecology.

Postembryonic, metamorphic development of the olfactory system.

Degree(s): 

Ph.D. 1969, Rockefeller University

 

Lab Group Curriculum vitae  

 

Research Interests: 

My group conducts research that combines anatomical, behavioral, chemical, and neurophysiological methods in a multidisciplinary approach to problems of the organization, physiology, functions, and postembryonic development of the insect nervous system. The main goal of this work is to discover fundamental principles and mechanisms common to many or all nervous systems through studies of the experimentally favorable nervous systems of insects. In view of the importance of insects in their own right, we also aim to contribute to knowledge that will help to alleviate the harm done by insects that are predators of plants cultivated for food, fuel or fiber or are vectors of microbial or parasitic pathogens. Areas of our principal interest currently include: the physiology, functional organization, and postembryonic development of the olfactory system; sensory control of mating behavior and insect-host interactions, including feeding and oviposition behaviors; chemical ecology and behavioral aspects of interactions with host plants; olfactory learning; and the behavior and sensory neurobiology of local species of Triatomine insects (“kissing bugs”) as potential vectors of Chagas Disease.

Functional organization and physiology of the insect olfactory system. We study the olfactory system of the giant sphinx moth Manduca sexta. Using intracellular recording and staining methods, extracellular and multi-unit recording techniques, and pharmacological manipulations, we explore the neuronal circuitry and synaptic interactions in the antennal lobe (AL), the primary olfactory center in the moth's brain. We also use histological and neuronal tracing methods to learn about the anatomical organization of the AL and its sensory inputs.  Our goal is to understand mechanisms of information processing in the olfactory pathways in the CNS. Much of our work has focused on the sexually dimorphic olfactory subsystem in the male moth that is specialized to detect and process information about the female's sex pheromone. We also conduct multi-level studies of the detection and central processing of information about volatile organic compounds (VOCs) emitted by living plants. We are especially interested in central neural mechanisms encoding olfactory information about behaviorally significant mixtures of VOCs. In addition to our primary focus on the AL, we also are very interested in the higher-order olfactory pathways in the protocerebrum that are involved in processing of the outputs of the ALs and their integration with information of other modalities.

Behavior and chemical ecology. In parallel with our studies of the olfactory system of Manduca, we are investigating the identities of the VOCs emitted by living host- and non-host plants and using a variety of chemical, physiological and behavioral methods to identify behaviorally significant compounds in those complex mixtures. We also study the effects of volatiles on the behavior of flying Manduca in the field and in a laboratory wind tunnel.

Postembryonic, metamorphic development of the olfactory system. For many years we have been interested in neural development and plasticity in the ALs during the postembryonic development of Manduca. We have shown that certain, sexually dimorphic glomeruli characteristic of male and female ALs develop only if the AL is innervated, respectively, by axons of genetically male or female olfactory receptor cells. In a continuing collaboration among members of my group and faculty colleagues Leslie Tolbert, Lynne Oland, Alan Nighorn and their coworkers, a multidisciplinary quest for the cellular and molecular mechanisms underlying these and other aspects of AL development are on-going.
 

Selected Publications: 

Lei H, Chiu H-Y, Hildebrand JG (2013) Responses of protocerebral neurons in male Manduca sexta to sex-pheromone mixtures. J Comp Physiol A 199:997-1014

Martin JP, Lei H, Riffell JA, Hildebrand JG (2013) Synchronous firing of antennal-lobe projection neurons encodes the behaviorally effective ratio of sex-pheromone components in male Manduca sexta. J Comp Physiol A 199:963-979

Riffell JA, Lei H, Abrell L, Hildebrand JG (2013) Neural basis of a pollinator’s buffet: olfactory specialization and learning in the Manduca sexta moth. Science 339:200-204 Published online 6 December 2012 [DOI:10.1126/science.1225483]

Hinterwirth AJ, Medina B, Lockey J, Otten D, Voldman J, Lang JH, Hildebrand JG, Daniel TL (2012) Wireless stimulation of antennal muscles in freely flying hawkmoths leads to flight path changes.  PLoS One 7(12): e52725. doi:10.1371/journal.pone.0052725

Reisenman CE, Savary W, Cowles J, Gregory TL, Hildebrand JG (2012) The distribution and abundance of triatomine insects, potential vectors of Chagas Disease, in a metropolitan area in Southern Arizona, United States. J Med Entomol 49:1254-1261

Reisenman CE, Dacks AM, Hildebrand JG (2011) Local interneuron diversity in the primary olfactory center of the moth Manduca sexta. J Comp Physiol A 197:653-665

Reisenman CE. Gregory T, Guerenstein PG, Hildebrand JG (2011) Feeding and defecation behavior of Triatoma rubida and its potential role as a vector of Chagas Disease in Arizona, USA. Am J Trop Med Hygiene 85:648-656

Lei H, Reisenman CE, Wilson C, Gabbur P, Hildebrand JG (2011) Spiking patterns and their functional implications in the antennal lobe of the Tobacco Hornworm Manduca sexta. PloS One 6(8): e23382

Martin JP, Beyerlein A, Dacks AM, Reisenman CE, Riffell JA, Lei H, Hildebrand JG (2011)  The neurobiology of insect olfaction: sensory processing in a comparative context. Prog Neurobiol 95:427-447

Tsang WM, Stone AL, Otten D, Aldworth ZN, Daniel TL, Hildebrand JG, Levine RB, Voldman J (2011) Insect-machine interface: a carbon nanotube-enhanced flexible neural probe. J Neurosci Meth 204:355-365

Martin JP, Hildebrand JG (2010) Innate recognition of pheromone and food odors in moths: a common mechanism in the antennal lobe? Front Behav Neurosci 4:159. doi:10.3389/fnbeh.2010.00159

Alarcón R, Riffell JA, Davidowitz G, Hildebrand JG, Bronstein JL (2010) Sex-dependent variation in the floral preferences of the hawkmoth Manduca sexta. Anim Behav 80:289-296

Kalberer NM, Reisenman CE, Hildebrand JG (2010) Male moths bearing transplanted female antennae express characteristically female behaviour and central neural activity. J Exp Biol. 213:1272-1280

Reisenman CE, Riffell JA, Bernays EA, Hildebrand JG (2010) Antagonistic effects of floral scent in an insect-plant interaction. Proc Roy Soc B 277:2371-2379

Reisenman CE, Lawrence G, Guerenstein PG, Gregory T, Dotson E, Hildebrand JG (2010) Infection of kissing bugs with Trypanosoma cruzi, Tucson, Arizona, USA. Emerg Infect Diseases 16:400-405

Riffell JA. Lei H, Hildebrand JG (2009) Neural correlates of behavior in the moth Manduca sexta in response to complex odors. Proc Natl Acad Sci USA 106:19219-19226