Our laboratory investigates the biology of axons, including the reciprocal interactions with myelinating glia that drive assembly of myelinated fibers. Disruption of axon-glial interactions are candidates to contribute to various neurological disorders including multiple sclerosis. Our goal is to elucidate these interactions in order to ameliorate demyelination and promote repair in myelin disorders. Current studies are focused on several broadly related questions.

Salzer Lab

NYU Langone Health Neuroscience Institute

Our Questions

1. How do reciprocal interactions between axons and glia drive assembly of myelinated axons?

We are characterizing both juxtacrine and paracrine signals between axons and glial that regulate myelination; these signals are candidates to drive demyelination under pathological conditions.

Axons can either be ensheathed in separate pockets of Remak Schwann cells or myelinated by individual Schwann cells depending on instructive axonal cues. Diagrams illustrate these two distinctive axon-Schwann cell relationships; bottom images are ac…

Axons can either be ensheathed in separate pockets of Remak Schwann cells or myelinated by individual Schwann cells depending on instructive axonal cues. Diagrams illustrate these two distinctive axon-Schwann cell relationships; bottom images are actual electron micrographs from peripheral nerves.

Electrogenic domains of neurons are illustrated. Left: the axon initial segment (AIS) of a cultured hippocampal neuron stained for Ankyrin G. Right: nodes of Ranvier along the myelinated axons of the sciatic nerve stained for NaV (green), a paranoda…

Electrogenic domains of neurons are illustrated. Left: the axon initial segment (AIS) of a cultured hippocampal neuron stained for Ankyrin G. Right: nodes of Ranvier along the myelinated axons of the sciatic nerve stained for NaV (green), a paranodal marker (blue) and a juxtaparanodal marker (red, Kv1.1)

2. How do myelinating glial cells drive the reorganization of axons into electrogenic domains that are essential for proper conduction of action potentials?

We are examining the assembly of the axon initial segment (AIS) and nodes of Ranvier, sites of action potential initiation and regeneration, respectively. We are characterizing the cell biology of how these domains form, how their assembly is coordinated with myelination, and are investigating activity-dependent plasticity of the AIS, which mediates homeostatic plasticity.

3. Elucidating the pathology of demyelination and the contributions of adult neural stem cells (NSCs) to remyelination in the adult CNS.

We are particularly interested in the role of the Sonic hedgehog pathway in regulating stem cell repair in the CNS and PNS and the interactions of NSCs with microglia during demyelination and remyelination.

Pharmacological inhibition of Gli1 improves stem cell repair of demyelinated lesions and - as shown here - functional recovery from a relapsing/remitting form of EAE (experimental autoimmune encephalomyelitis) in mice; from Samanta et al, 2015.

Pharmacological inhibition of Gli1 improves stem cell repair of demyelinated lesions and - as shown here - functional recovery from a relapsing/remitting form of EAE (experimental autoimmune encephalomyelitis) in mice; from Samanta et al, 2015.

Serial block face EM reconstruction of myelinated axons in the CNS (corpus callosum)

Serial block face EM reconstruction of myelinated axons in the CNS (corpus callosum)

Methods

For these various studies, we use primary neuron and myelinating cocultures, novel transgenic/knockout mice including those undergoing toxin or autoimmune-medated demyelination, and employ various imaging modalities (EM/immuno-EM, live imaging, STORM, serial block face reconstructions, etc.) to further parse mechanisms that mediate these events.

Our Recent Publications

Schwann Cell Development and Myelination

Salzer, James L; Feltri, M Laura; Jacob, Claire.

Cold Spring Harb Perspect Biol. 2024 Sep 3;16(9):a041360

Glia trigger endocytic clearance of axonal proteins to promote rodent myelination

Bekku, Yoko et al.

Dev Cell. 2024 Mar 11;59(5):627-644.e10.

Neural stem cells and oligodendrocyte progenitor cells compete for remyelination in the corpus callosum

Moyon, Sarah; Holloman, Mara; Salzer, James L.

Front Cell Neurosci. 2023 Jan 26:17:1114781.

Gli1 Regulates the Postnatal Acquisition of Peripheral Nerve Architecture

Zotter, Brendan et al.

J Neurosci. 2022 Jan 12;42(2):183-201.

Activated microglia drive demyelination via CSF1R signaling

Marzan, Dave E et al.

Glia. 2021 Jun;69(6):1583-1604.

Accumulation of Neurofascin at nodes of Ranvier is regulated by a Paranodal Switch

Zhang, Yanqing et al.

Journal of Neuroscience. 2020 40:5709–5723.

Control of Channel Clustering by Cleavage

Salzer, James L.

Neuron. 2020 Jun 3;106(5):707-709.

Independent anterograde transport and retrograde cotransport of domain components of myelinated axons

Bekku, Yoko; Salzer, James L.

J. Cell Biol. 2020 Jun 1;219(6):e201906071.

Localized Myosin II Activity Regulates Assembly And Plasticity Of The Axon Initial Segment

Berger, Stephen L et al.

Neuron. 2018 Feb 07; 97(3):555-570.e6

 
 

Our Members

James Salzer Principle Investigator

Faculty Page

Neuroscience Institute

Professor, Department of Neuroscience and Physiology

Professor, Department of Neurology

Yanqing Zhang

Research Assistant Professor

Yoko Bekku

Research Assistant Professor

Angelina Evangelou

Post-Doctoral Research Scientist

Ashley Sartoris

MD/PhD Student

Haroon Arain

Research Associate

Christy Munson

PhD Student

Frances Kestel

Undergraduate Student

Margaret Mushi

Research Associate

Find more information on our recent alumni here

Join Us

POST-DOCTORAL RESEARCHERS

Candidates with a PhD in neuroscience, immunology, and/or cell biology with a strong publication record and a passion for tackling challenging questions should email Dr. Salzer with an introduction, CV and the contact information for three references.