The Picower Institute Director

Li-Huei Tsai

Picower Professor of Neuroscience
Director, The Picower Institute for Learning and Memory
Co-Director, Alana Down Syndrome Center
Professor, Department of Brain and Cognitive Sciences
Senior Associate Member, Broad Institute
Massachusetts Institute of Technology

Contact Info

Office: 46-4235
Phone: 617-324-1658

Administrative Assistant

Thomas Garvey
Office: 46-4235
Phone: 617-324-1658

Our laboratory is interested in elucidating the pathogenic mechanisms underlying neurological disorders that impact learning and memory. We are taking a multidisciplinary approach to investigate the molecular, cellular, and circuit basis of neurodegenerative disorders.

The Role of Cdk5 in Neurodegeneration and Normal Brain Function

Alzheimer’s disease (AD) is a devastating and irreversible brain disorder that eventually leads to dementia and death. Cyclin-dependent kinase 5 (Cdk5) is a brain-specific protein serine/threonine kinase essential for brain development, synaptic plasticity, learning, and memory. We have shown that the hyperactivation of Cdk5 occurs when its regulatory protein p35 is cleaved by the Ca2+-activated protease calpain, under neurotoxic conditions, to liberate the carboxyl-terminal fragment p25. We hypothesized that p25 generation and accumulation play important roles in AD-like neurodegeneration. We created an inducible mouse model of p25 accumulation (the CK-p25 mouse) that displays key pathological hallmarks of AD, including profound neuronal loss in the forebrain, increased β-amyloid (Aβ) peptide production, Tau pathology, and severe cognitive impairment. In this model, increased Aβ levels are observed prior to neuronal loss; furthermore, reducing Aβ production ameliorates memory deficits in the CK-p25 mouse model, suggesting that this event operates synergistically with p25 to lead to the manifestation of neurodegeneration and memory impairment.

To further decipher the role of p25 generation in neurodegeneration, we created a mouse “knock-in” model whereby the endogenous p35 gene is replaced by a mutant p35 that is resistant to calpain cleavage (Δp35KI). Δp35KI mice show normal hippocampus-dependent learning and memory and LTP. However, they exhibit impaired hippocampal long-term depression (LTD). Moreover, Δp35KI hippocampal neurons are resistant to Aβ peptide-induced synaptic depression. The 5XFAD model is a well-established AD mouse model exhibiting abundant amyloid plaque pathology, inflammation, and memory deficits by 6 months of age. Interestingly, memory deficits are not observed in Δp35KI/5XFAD compound mice, and the animals also show ameliorated inflammatory response and reduced Aβ levels. These results strongly suggest that p25 mediates Aβ peptide-associated pathology.

Currently, we are evaluating whether p25 generation also plays a role in Tau-mediated pathology. In addition, we are using CRISPR/Cas9-mediated genome editing to create calpain-resistant p35 alleles in human induced pluripotent stem cells (iPSCs) derived from AD patients (see below) to evaluate the role of p25 generation in the degeneration of human neurons and to create human cellular models of AD for therapeutic investigation.

Chromatin Remodeling and Learning and Memory

Among the available AD mouse models, the CK-p25 mouse uniquely recapitulates the profound neuronal loss observed in advanced stages of AD. Thus, we have used this model to explore novel therapeutic approaches that may be beneficial for cognition even after profound synaptic loss and neuronal death have occurred. We showed that promoting chromatin remodeling in CK-p25 mice with chemical histone deacetylase (HDAC) inhibitors induces robust synaptogenesis and dendritic growth, restores learning and recovers long-term memory—even after massive neuronal loss has occurred. Our findings demonstrated that an epigenetic mechanism involving increased histone acetylation and chromatin remodeling can be beneficial for learning and memory, and that these manipulations are effective even in the face of neuronal loss and neurodegeneration. These observations suggest that memory is not completely erased after neurodegeneration, and provide compelling evidence for developing HDAC inhibitors to reverse cognitive impairment in Alzheimer’s disease.

As our lab delved into the question of what leads to neuronal loss, we found that histone deacytylases regulate neuronal DNA damage and that compromised genome integrity, particularly DNA double-strand breaks (DSBs), is a common and early hallmark of neurodegeneration. Intriguingly, we recently discovered that DSBs are induced by neuronal activity and are actually required for normal learning and memory to occur. We also found that DSBs occur non-randomly in the neuronal genome, but are associated with specific genes. Now that we know the location and purpose of activity-induced DSBs in the neuronal genome, we can begin to determine how these physiological breaks are impacted during disease, and identify potential approaches to rectify DSBs production and enhance DNA damage repair in neurons of neurodegenerative diseases.

To better understand the changes in the epigenome during neurodegeneration, we collaborated with computer scientist, Manolis Kellis, in a comprehensive study that identified new master regulatory elements of AD that are conserved between the inducible CK-p25 mouse model and human AD brains. The combined power of the mouse model with advanced bioinformatics enabled us to identify novel enhancers, rather than coding regions, as significant factors with substantial contribution to the genetic risk for AD. In particular, we found a marked upregulation of genes and enhancers associated with innate immune responses in both AD mouse models and human AD patients. These results have dramatically altered our understanding of the genetic elements contributing to AD risk, and highlight important roles for epigenetic regulation and immune responses inAD pathogenesis. Currently, we are performing cell type specific epigenomic analysis, including ATAC-seq and ChIP-seq, and single cell RNA-sequencing in mouse and human brains to further understand the roles of different neural cell types including neurons, astrocytes, and microglia in AD-related neurodegeneration.

Neuronal Networks, Circuits, and Neurodegeneration

Altered cellular processes in neurodegenerative diseases ultimately lead to disruptions in neural circuits and network connectivity to result in cognitive deficits. Thus, to better understand how disease genes and pathology impact cognitive function in disorders such as AD, we have aspired to alter the activity of specific neural circuits and to evaluate the consequences on pathology, network activity, and behavior. We use targeted genetic approaches such as optogenetics and Designer Receptors Exclusively Activated by Designer Drugs (DREADDs) to manipulate the activity of specific populations of neural cells in the brain. In combination with various AD mouse models, we are examining the effect of stimulating or inhibiting specific cells within hippocampal, basal forebrain, and amygdalar circuits to gain insights into circuit dysfunction underlying neurodegeneration and cognitive deficits.

In particular, our work has revealed network-level disruptions in gamma oscillations in multiple mouse models of AD. Conversely, we are also interested in applying circuit manipulations to ameliorate cognitive deficits in AD. We previously showed that we could induce population-wide gamma oscillations in mice using optogenetics to entrain large groups of neurons to synchronize their firing patterns. Most recently, we developed non-invasive methods of inducing gamma oscillations by presenting sensory stimulation at specific frequencies to the mice. In collaboration with Ed Boyden’s lab at MIT, we used optogenetics or non-invasive sensory stimulation to induce gamma oscillations, and surprisingly found a marked reduction in Aß levels in several AD mouse models. The therapeutic effects of gamma oscillations appear to involve the concerted actions of neurons and microglia to reduce the production and enhance clearance of Aβ, respectively. We are currently testing various parameters of inducing gamma oscillations, such as using other sensory modalities, and examining the potential of gamma stimulation to improve cognition in AD model mice. We are also working on developing other non-invasive methods to affect neural oscillations with spatial and temporal specificity.

Through collaboration with MIT’s Clinical Research Center and faculty members across multiple disciplines at MIT, we are gearing up to apply this technology to human subjects. Initial tests will establish the safety and feasibility of gamma entrainment in humans through sensory stimulation. State-of-the-art technology, such as magnetoencephalography (MEG), electroencephalography (EEG), and functional magnetic resonance imaging (fMRI) will be used to investigate and visualize potential brain oscillation changes. Eventually, our goal is to apply our non-invasive technology to subjects with AD, and determine whether gamma stimulation can help rescue cognitive deficits.

In addition to the manipulation of specific circuits, we aim to map out the sequential temporal and spatial disruptions of neural circuits by the deposition of Aß peptides and aggregated Tau protein in AD, and how Aß and Tau pathology propagates throughout the brain. Current work involves mapping various AD-related pathology in a 3-D manner in mouse and human brains. We are collaborating with Kwanghun Chung at the MIT Picower Institute to apply enhanced CLARITY techniques to interrogate the relationship of ß-amyloid plaques, Tau tangles, neural inflammation, and vasculature pathology in different mouse models of AD and in postmortem human brain samples of AD subjects. We will also use this approach to assess how environmental enrichment and epigenetic drugs, previously shown to improve cognitive function of AD mouse models, influence neuronal circuitry necessary for memory formation and retrieval.

 

Modeling neurological disorders using induced pluripotent stem cells (iPSCs) and tissue bioengineering

Our lab has collected human skin fibroblast lines from healthy individuals as well as late onset sporadic AD (LOAD), early onset familial AD (fAD), Autism spectrum disorder (ASD), schizophrenia, bipolar disease, and Down syndrome patients and reprogrammed them into induced pluripotent stem cells (iPSCs). We use genome-editing techniques such as CRISPR/Cas9 to create isogenic cell lines to facilitate the assessment of phenotypic consequences of disease associated genetic variants. These iPSCs are then differentiated into major brain cell types including excitatory neurons, astrocytes, and microglia that can be used for a number of basic and applied research purposes. For example, we can use this system to both examine how specific gene perturbations affect AD-like pathology directly in human neurons and glia, while at the same time screening libraries of drug-like chemicals in a high-throughput fashion to determine potential therapeutic candidates. Increasingly sophisticated culture techniques also allow us to evaluate how disease pathology and genetic variants affect each of the different cell types populating the brain. Using techniques of bioengineering combined with multiphoton deep imaging, optogenetics, and electrophysiology, we can recapitulate and study complex human brain tissue. In these “mini-brain” or organoid cultures, we can examine neuronal and glial activity and examine relevant disease phenotypes such as protein aggregation, neuronal connectivity, and synapse loss. Current efforts aim to better recapitulate the in vivo brain environment by adding engineered vasculature to our 3D organoids to mimic the blood brain barrier. Ultimately, we hope that these techniques will facilitate and expedite drug screening and discovery by allowing us to directly screen engineered human brain organoids for compounds and therapies likely to work in the in vivo human brain.

Li-Huei Tsai received her P.h.D degree from the University of Texas Southwestern Medical Center at Dallas. She then took postdoctoral training from Ed Harlow’s laboratory at Cold Spring Harbor laboratory and Massachusetts General Hospital. She joined the faculty in the Department of Pathology at Harvard Medical School in 1994 and was named an investigator of Howard Hughes Medical Institute in 1997. In 2006, she was appointed Professor in the Department of Brain and Cognitive Sciences, and joined the Picower Institute for Learning and Memory at MIT.

 

Photo credit: David Sella

  • Distinguished Academic Achievement Award, Chinese American Academic and Professional Society
  • Elected Member, Institute of Medicine (IOM), Academy of Sciences
  • Fellow, American Association for the Advancement of Science (AAAS)
  • Glenn Award For Research in Biological Mechanisms of Aging
  • NIH Cantoni Lecture Award
  • Simons Foundation Autism Research Initiative Award
  • Academician, Academia Sinica
  • SfN's MIka Salpeter Llifetime Achievement Award
  • Hans Wigzell Research Foundation Science Prize
  • Fellow, National Academy of Inventors
  • Elected Member, American Academy of Arts & Sciences
  • IBiS Distinguished Investigator 2021
Featured publications are below. For a full list visit the lab website linked above.

October 10, 2017
Mathys H, Adaikkan C, Gao F, Young JZ, Manet E, Hemberg M, De Jager PL, Ransohoff RM, Regev A, Tsai LH, Cell Reports, Cell Rep. 2017 Oct 10; 21 (2): 366-380.
December 8, 2016
Iaccarino HF, Singer AC, Martorell AJ, Rudenko A, Gao F, Gillingham TZ, Mathys H, Seo J, Kritskiy O, Abdurrob F, Adaikkan C, Canter RG, Rueda R, Brown EN, Boyden ES, Tsai L-H, Nature. 2016 Dec 7; 540 (7632): 230-235. Doi: 10.1038/nature20587.
November 10, 2016
Canter RG, Penney J, Tsai L-H, Nature. 2016 Nov 9; 539 (7268): 187-196. doi: 10/1038/nature20412
June 18, 2015
Madabhushi R, Gao F, Pfenning A, Pan L, Yamakawa S, Seo S, Rueda R, Phan T, Yamakawa H, Pao PC, Stott RT, Gjoneska E, Nott A, Cho S, Kellis M, and Tsai L-H, Cell. 2015 Jun 18;161(7):1592-605. doi: 10.1016/j.cell.2015.05.032.
June 17, 2015
Sheng Y., Zhang L., Su S.C., Tsai L.H., Julius Zhu J. (2015) Cereb Coretex. pii: bhv032.

Nanoparticle-delivered RNA reduces neuroinflammation in lab tests

December 11, 2023
Research Findings
In mice and human cell cultures, MIT researchers showed that novel nanoparticles can deliver a potential therapy for inflammation in the brain, a prominent symptom in Alzheimer’s disease

How a mutation in microglia elevates Alzheimer’s risk

November 16, 2023
Research Findings
A new MIT study finds that microglia with mutant TREM2 protein reduce brain circuit connections, promote inflammation and contribute to Alzheimer’s pathology in other ways

Aging Brain Initiative symposium showcases ‘cutting edge’ research across MIT

November 1, 2023
Picower Events
Seed projects, posters represent a wide range of labs working on technologies, therapeutic strategies, and fundamental research to advance understanding of age-related neurodegenerative disease

Decoding the complexity of Alzheimer’s disease

September 28, 2023
Research Findings
By analyzing epigenomic and gene expression changes that occur in Alzheimer’s disease, researchers identify cellular pathways that could become new drug targets

Molecule reduces inflammation in Alzheimer’s models

August 29, 2023
Research Findings
A potential new Alzheimer’s drug represses the harmful inflammatory response of the brain’s immune cells, reducing disease pathology, preserving neurons and improving cognition in preclinical tests

Picower postdoc earns Burroughs Wellcome Fund award

June 13, 2023
Picower People
‘Career Award at the Scientific Interface’ recognizes Rebecca Pinals’ research to create a nanosensor-integrated brain-on-a-chip model of Alzheimer’s disease.

Atlas of human brain blood vessels highlights changes in Alzheimer’s disease

June 1, 2023
Research Findings
MIT researchers characterize gene expression patterns for 22,500 brain vascular cells across 428 donors, revealing insights for Alzheimer’s onset and potential treatments.

40 Hz vibrations reduce Alzheimer’s pathology, symptoms in mouse models

May 18, 2023
Research Findings
Tactile stimulation improved motor performance, reduced phosphorylated tau, preserved neurons and synapses and reduced DNA damage, a new study shows

From labs to the streets, experts work to defuse childhood threats to mental health

May 18, 2023
Picower Events
Symposium speakers describe numerous ways to promote prevention, resilience, healing and wellness after early life stresses

Neuroscientists identify cells especially vulnerable to Alzheimer’s

April 19, 2023
Research Findings
Neurons that form part of a memory circuit are among the first brain cells to show signs of neurodegeneration in Alzheimer’s disease.

Fatema Abdurrod
Technical Associate

Chinnakkaruppan Adaikkan
Postdoctoral Associate

Scarlett Barker
Graduate Student

Joel Blanchard
Postdoctoral Associate

Maeve Bonner
Postdoctoral Fellow

Adele Bubnys
Postdoctoral Associate

Michael Bula
Technical Associate

Hugh Cam
Scientific Manager

Diane Chan
Postdoctoral Fellow

Xiao Chen
Postdoctoral Associate

Sara Elmsaouri
Technical Associate

Elizabeth Gjoneska
Research Scientist

Wen-Chin (Brian) Huang
Postdoctoral Associate

David Kim
Technical Associate

Tak Ko
Research Scientist

Oleg Kritskiy
Technical Associate

Yuan-Ta (Ada) Lin
Postdoctoral Fellow

Asaf Marco
Postdoctoral Associate

Hansruedi Mathys
Postdoctoral Associate

Erica McNamara
Mouse Colony Manager

Hiruy Meharena
Postdoctoral Fellow

Blerta Milo
Technical Associate

Priyanka Narayan
Postdoctoral Fellow

Ping-Chieh (Jenny) Pao
Postdoctoral Associate

Zhuyu (Verna) Peng
Technical Associate

Jay Penney
Postdoctoral Fellow

Ravi Raju
Visiting MD/Fellow

William Ralvenius
Postdoctoral Fellow

Ryan Stott
Graduate Student

Jun Wang
Technical Associate

Ashley Watson
Postdoctoral Fellow

Gwyneth Welch
Graduate Student

Hannah Woolf
Technical Associate

Linda Yang
Technical Associate

Chung Jong Yu
Graduate Student

Ying Zhou
Laboratory Manager