Menicon Professor in Neuroscience Troy Littleton

Troy Littleton

Menicon Professor in Neuroscience
Investigator in The Picower Institute for Learning and Memory
Professor, Department of Biology
Professor, Department of Brain and Cognitive Sciences
Massachusetts Institute of Technology

Contact Info

Office: 46-3251
Phone: 617-452-2605
Email: troy@mit.edu

Administrative Assistant

Charles Moss
Office: 46-3241
Phone: 617-452-2070
Email: vmoss@mit.edu

The focus of my laboratory’s work is to understand the mechanisms by which neurons form synaptic connections, how synapses transmit information, and how synapses change during learning and memory. We combine molecular biology, protein biochemistry, electrophysiology, and imaging approaches with Drosophila genetics to address these questions. Neurotransmitter release from synaptic vesicle fusion is the fundamental mechanism for neuronal communication at synapses. Since the work of Bernard Katz, it has been known that synaptic vesicle fusion is triggered by Ca2+ influx into the presynaptic terminal. Vesicular trafficking pathways are ubiquitous among eukaryotes, with fusion driven by the SNARE complex. Neurotransmitters can be released during evoked fusion following an action potential, or through spontaneous fusion of vesicles (termed “minis”) in the absence of nerve stimulation. One of the major goals of my research program has been to define how vesicular trafficking mediates synaptic transmission, and how this process can be altered to change neuronal communication. At synapses, SNARE-mediated fusion is uniquely regulated to allow rapid and Ca2+-triggered synaptic vesicle fusion. Several key adaptations to the core fusion machinery require synapse specific SNARE-binding proteins, including Synaptotagmin 1 (Syt 1) and Complexin (Cpx). We have extensively studied how these proteins control synaptic output. Syt 1 is a synaptic vesicle protein that binds to SNARE complexes and membrane phospholipids in a Ca2+-dependent manner. My lab and others have shown that Syt 1 functions as the Ca2+ sensor for fast synchronous neurotransmitter release. Cpx is a small cytosolic α-helical protein that binds assembled SNARE complexes. We have shown that association of Cpx with SNAREs allows it to function as a facilitator for synaptic vesicle fusion and as a fusion clamp to prevent premature exocytosis in the absence of Ca2+. A key avenue of our ongoing research program is to understand how these proteins, together with other key fusion regulators, mediate cycles of SNARE assembly and disassembly in a precisely coordinated fashion to support synaptic transmission. Similarly, we also seek to understand how the core fusion machinery can be rapidly modified, for example through phosphorylation, to alter presynaptic function and synaptic plasticity.

We use the Drosophila NMJ as a model synapse to uncover general principles of synapse biology. Recent work in the lab is also seeking to understand how synaptic vesicle release probability and release mode are determined at individual release sites. Evoked release following an action potential has been well characterized for its function in activating the postsynaptic cell, but the significance of spontaneous release is less clear. Whether receptors on the postsynaptic cell have the ability to distinguish between neurotransmitters released through the two independent fusion pathways is still under debate. If both vesicle release mechanisms activate the same set of receptors, crosstalk would occur between the two modes of fusion. However, if spontaneous release occurs at distinct release sites, the postsynaptic cell may be capable of differentiating between the two modes of release, suggesting spontaneous fusion may represent a separate information channel independent of the traditional Ca2+-activated evoked release pathway. The major confound to this question has been the inability to examine vesicle fusion at individual active zones. Classical electrophysiological studies of synaptic transmission measure the postsynaptic effect of neurotransmitter release over a population of release sites, precluding an analysis of how individual active zones participate in and regulate these two modes of vesicle fusion. We have developed transgenically expressed Ca2+ sensors that allow imaging of postsynaptic glutamate receptor activation following vesicle fusion, providing a mechanism to visualize all exocytotic events occurring through both spontaneous and evoked release pathways at Drosophila glutamatergic neuromuscular junctions. This toolkit allows us to generate release probability maps for both spontaneous and evoked fusion for all active zones at a synapse. By imaging a defined neuromuscular connection with ~ 300 active zones between the synaptic partners, we have begun to analyze the relationship between spontaneous and evoked release and determine how release mode and release probability are regulated at individual active zones at this model glutamatergic synapse. Unexpectedly, we have discovered that a subset of active zones are dedicated to spontaneous release, indicating a population of postsynaptic receptors is uniquely activated by this mode of vesicle fusion. We have also found that release probability can vary more than 100-fold between neighboring active zones. This is an exciting finding and provides us a mechanism to understand how single active zone release probability is regulated. The ability to measure individual active zones for their release probability also allows us to determine how active zone release properties can change during synaptic plasticity. It is likely that evoked and spontaneous active zone release probability is not a static property of synaptic connections, and can be differentially regulated during distinct modes of synaptic plasticity. Synaptic plasticity mechanisms can be manifested through changes in N (the number of release sites), P (probability of release) or Q (quantal size). Many factors have been suggested to regulate these properties. However, the lack of a tool to examine single active zone release probability has made it difficult to dissect how these changes play out over a population of release sites. We are now in a position to examine how plastic changes in release properties at the NMJ map onto alterations in individual active zone release probability. By mapping single active zone release probability during both acute and homeostatic synaptic plasticity and following the properties, we can gain new insights into presynaptic mechanisms underlying synaptic communication and plasticity at a model glutamatergic synapse.

Troy Littleton received his MD and Ph.D. from Baylor College of Medicine in Houston, TX. He completed his postdoctoral training at the University of Wisconsin. In 2000, he joined the faculty of the Department of Biology and the Picower Institute for Learning and Memory at MIT.

  • 2020 Award for Excellence in Undergraduate Advising, MIT Brain and Cognitive Sciences
  • Poitras Scholar Award in Neuroscience
  • Alfred P. Sloan Research Fellow
  • Human Frontier Science Program Junior Faculty Fellowship
  • Searle Scholar Award
  • Surdna Research Foundation Award
  • Wade Fund Award
  • David and Lucile Packard Foundation Fellowship for Science and Engineering
  • Fred and Carole Middleton Career Development Professorship
  • Member, Faculty of 1000
  • Distinguished Alumni Award, Baylor College of Medicine
Featured publications are below. For a full list visit the lab website linked above.

September 12, 2017
Guan, Z., Bykhovskaia, M., Jorquera, R.A., Sutton, R.B., Akbergenova, Y. & Littleton, J.T. eLIFE, 6:e28409
May 25, 2016
Harris, K.P., Piccioli, Z.D., Perrimon, N. & Littleton, J.T. eLIFE, e13881
November 18, 2015
Cho, R.W., Buhl L.K., Volfson, D., Tran, A., Feng, L., Akbergenova, Y. & Littleton, J.T. Neuron 88: 749-761
September 4, 2014
Herrmann, D.N.*, Horvath, R.*, Sowden, J.E., Gonzales, M., Sanchez-Mejias, A., Guan, Z., Whittaker, R.G., Almodovar, J.L., Lane, M., Bansagi, B., Pyle, A., Boczonadi, V., Lochmuller, H. Griffen, H., Chinnery, P.F., Lloyd, T.E., Littleton, J.T.* & Zuchner, S.*, Am J Hum Genetics 95: 332-339
October 30, 2013
Melom, J.E., Akbergenova, Y., Gavornik, J.P. & Littleton, J.T., J. Neuroscience 33: 17253-17263

From Molecules to Memory

December 20, 2024
Research Feature
On a biological foundation of ions and proteins, the brain forms, stores, and retrieves memories to inform intelligent behavior

Livestreaming the Brain

March 15, 2024
Research Feature
To learn how the brain works, Picower Institute labs are advancing technologies and methods to watch it live as it happens

'Cellf' Expression

December 20, 2023
Research Feature
Picower Institute scientists are using single cell genomics techniques to measure gene expression and produce unque insights into nervous system biology and disease

Individual neurons mix multiple RNA edits of key synapse protein, fly study finds

September 18, 2023
Research Findings
Neurons stochastically generated up to eight different versions of a protein regulating neurotransmitter release, which could vary how they communicate with other cells

Study connects neural gene expression differences to functional distinctions

August 23, 2023
Research Findings
Researchers compared a pair of superficially similar motor neurons in fruit flies to examine how their differing use of the same genome produced distinctions in form and function

Petite & Profound

June 22, 2023
Research Feature
Why studying simple organisms—none larger than the palm of your hand—is so integral to understanding nervous system health, disease and evolution.

Without key extracellular protein, neuronal axons break and synaptic connections fall apart

June 12, 2023
Research Findings
MIT scientists find evidence that a protein common to flies and people is essential for supporting the structure of axons that neurons project to make circuit connections. When those break down, the connections follow suit.

Spring break tours give high schoolers a chance to see science up close

March 31, 2023
Picower Events
Teens from area high schools got the chance to learn about advanced biology and brain research on field trips to MIT

Providing new pathways for neuroscience research and education

September 29, 2022
Picower People
Payton Dupuis finds new scientific interests and career opportunities through MIT summer research program in biology.

New findings reveal how neurons build and maintain their capacity to communicate

July 20, 2022
Research Findings
Nerve cells regulate and routinely refresh the collection of calcium channels that enable them to send messages across circuit connections

Yulia Akbergenova
Research Scientist

Elizabeth Brija
Graduate Student

Andres Crane
Graduate Student

Zhuo Guan
Research Scientist

Suresh Jetti
Postdoctoral Fellow

Karen Leopold
Graduate Student

Charles Moss
Administrative Assistant

Kiel Ormerod
Postdoctoral Fellow

Monica Quinoies
Graduate Student

Nicole Ann Santiago
Graduate Student

Chad Sauvola
Graduate Student

Dina Volfson
Tech/Lab Manager

Shirley Weiss
Postdoctoral Fellow