Columbia University
Irving Medical Center
Neurological Institute
710 West 168th Street, 3rd floor
(212) 305-1818


TaubCONNECT Research Perspective:
March 2025
Sleep Genetics and Cognitive Changes over Time: The Moderating Effect of Age and the Role of Brain
Emerging Roles for Tubulin PTMs in Neuronal Function and Neurodegenerative Disease
Inflammatory Biomarkers Profiles and Cognition Among Older Adults
Synaptic and Cognitive Impairment Associated with L444P Heterozygous Glucocerebrosidase Mutation
Regulation of Synapse Density by Pumilio RNA-Binding Proteins
CD33 and SHP-1/PTPN6 Interaction in Alzheimer's Disease
Cellular Communities Reveal Trajectories of Brain Ageing and Alzheimer's Disease
Epigenetic and Genetic Risk of Alzheimer Disease from Autopsied Brains in two Ethnic Groups
Multi-Omic Analysis of Huntington's Disease Reveals a Compensatory Astrocyte State
Design and Methods of the Early Age-Related Hearing Loss Investigation Randomized Controlled Trial
Updated Safety Results From Phase 3 Lecanemab Study in Early Alzheimer's Disease
The Broken Alzheimer's Disease Genome
Rare Genetic Variation in Fibronectin 1 (FN1) Protects Against APOEΔ4 in Alzheimer's Disease
Cell Subtype-Specific Effects of Genetic Variation in the Alzheimer's Disease Brain
Diet, Pace of Biological Aging, and Risk of Dementia in the Framingham Heart Study
A Comparative Study of Structural Variant Calling in WGS from Alzheimer's Disease Families
Glucocorticoid Stress Hormones Stimulate Vesicle-Free Tau Secretion and Spreading in the Braint
The Effects of Insufficient Sleep and Adequate Sleep on Cognitive Function in Healthy Adults
ZCCHC17 Modulates Neuronal RNA Splicing and Supports Cognitive Resilience in Alzheimer's Disease
Effects of Lithium on Serum Brain-Derived Neurotrophic Factor in Alzheimer's Patients with Agitation
2023 Taub Institute Grants for Emerging Research (TIGER) Awardees!
Rie1 and Sgn1 Form an RNA-Binding Complex that Enforces the Meiotic Entry Cell Fate Decision
Memory and Language Cognitive Data Harmonization Across the United States and Mexico
Education as a Moderator of Help Seeking Behavior in Subjective Cognitive Decline
Multicellular Communities are Perturbed in the Aging Human Brain and Alzheimer's Disease
The Neuropathological Landscape of Hispanic and non-Hispanic White Decedents with Alzheimer Disease
The Early-Onset Alzheimer's Disease Whole-Genome Sequencing Project: Study Design and Methodology
Polygenic Risk Score Penetrance & Recurrence Risk in Familial Alzheimer Disease
High School Quality is Associated with Cognition 58 Years Later
Glucocorticoid-Driven Mitochondrial Damage Stimulates Tau Pathology
A Global View of the Genetic Basis of Alzheimer Disease
ARIA in Patients Treated with Lecanemab (BAN2401) in a Phase 2 Study in Early Alzheimer's Disease
Microglia Reactivity Entails Microtubule Remodeling from Acentrosomal to Centrosomal Arrays
Genuine Selective Caspase-2 Inhibition with new Irreversible Small Peptidomimetics
Cell Type-Specific Changes Identified by Single-Cell Transcriptomics in Alzheimer's Disease
Brain Aging Among Racially and Ethnically Diverse Middle-Aged and Older Adults
First Place: Neuroproteasome Localization and Dysfunction Modulate Pathology in Alzheimer's Disease
Clearance of an Amyloid-Like Translational Repressor is Governed by 14-3-3 Proteins
Diet Moderates the Effect of Resting State Functional Connectivity on Cognitive Function
Retromer Deficiency in Tauopathy Models Enhances the Truncation and Toxicity of Tau
Progranulin Mutations in Clinical and Neuropathological Alzheimer's Disease
Wolframin is a Novel Regulator of Tau Pathology and Neurodegeneration
Homotypic Fibrillization of TMEM106B Across Diverse Neurodegenerative Diseases
Correlation of Plasma and Neuroimaging Biomarkers in Alzheimer's Disease
Tubulin Tyrosination Regulates Synaptic Function and is Disrupted in Alzheimer's Disease
The Penalty of Stress - Epichaperomes Negatively Reshaping the Brain in Neurodegenerative Disorders
The Neuronal Retromer can Regulate Both Neuronal and Microglial Phenotypes of Alzheimer's Disease
Deep Learning Improves Utility of Tau PET in the Study of Alzheimer's Disease
Age of Onset of Huntington's Disease in Carriers of Reduced Penetrance Alleles
Caspase-9: A Multimodal Therapeutic Target With Diverse Cellular Expression in Human Disease
Midlife Vascular Factors and Prevalence of Mild Cognitive Impairment in Late-Life in Mexico
The Association Between Sex and Risk of Alzheimer's Disease in Adults with Down Syndrome
Marked Mild Cognitive Deficits in Humanized Mouse Model of Alzheimer's-Type Tau Pathology
Rapid ATF4 Depletion Resets Synaptic Responsiveness after cLTP
Polygenic Risk Score for Alzheimer's Disease in Caribbean Hispanics
Recognition Memory and Divergent Cognitive Profiles in Prodromal Genetic Frontotemporal Dementia
The Microtubule Cytoskeleton at the Synapse & The Synaptic Life of Microtubules
Optimizing Subjective Cognitive Decline to Detect Early Cognitive Dysfunction
The AD Tau Core Spontaneously Self-Assembles and Recruits Full-Length Tau to Filaments
Olfactory Impairment is Related to Tau Pathology and Neuroinflammation in Alzheimer's Disease
Pathogenic Role of Delta 2 Tubulin in Bortezomib-Induced Peripheral Neuropathy
2: Local Genetic Covariance Analysis with Lipid Traits Identifies Novel Loci for Early-Onset Alzheimer's Disease
3: The Association of Multilingualism with Diverse Language Families and Cognition Among Adults with and Without Education in India
4: Axonal Transport of CHMP2b Is Regulated by Kinesin-Binding Protein and Disrupted by CHMP2bintron5
ANXA11 Biomolecular Condensates Facilitate Protein-Lipid Phase Coupling on Lysosomal Membranes

Peter H. St George-Hyslop, OC, MD, FRCPC, FMedSci, FRS
In collaboration with colleagues at the University of Cambridge, our latest study reveals an unexpected way membrane-less biomolecular condensatesâlike ribonucleoprotein (RNP) granulesâcan directly alter the physical properties of classical membrane-bound organelles such as lysosomes. We focused on the tethering protein annexin A11 (ANXA11), showing that it co=phase transitions with RNP granules. The ANXA11-RNP co-phase separation is driven by the disordered N-terminal low complexity domain (LCD) of ANXA11. We show that condensation of the ANXA11-RNP granule biomolecular condensate (BMC) can induce a matching phase shift in lipids in the lysosomal membrane. As the ANXA11-RNP BMC condenses, it transforms the lipids in the lysosomeâs membrane from a more fluid, âoilyâ state to a firmer, âbutteryâ one. This stiffening appears to give the complex the mechanical resilience it needs to move through the densely packed axoplasm.

Figure 7. Protein-lipid phase coupling in the ANXA11-lysosome ensemble. The ARD of ANXA11 mediates binding to lysosomes in a Ca2+-dependent manner and causes a phase transition in lysosomal membrane lipids into a more ordered state. Condensation of the ANXA11 LCD can then act to tune the magnitude of this lipid phase transition in a coupled manner. ANXA11 interacting partners ALG2 and CALC either increase (ALG2) or decrease (CALC) ANXA11 LCD-based condensation to regulate phase coupled effects on lysosomal membrane lipids.
As recently reported in Nature Communications, we found that lipid ordering in lysosomal membranes increases in step with ANXA11 condensation. Remarkably, this effect persisted even when ANXA11âs native membrane-binding region was replaced with a chemical tag, showing that ANXA11 condensation alone can drive concomitant changes in membrane properties. We call this phenomenon âphase couplingââwhere the state of a protein directly influences the physical state of its attached membrane â stiffening its nanomechanical properties. While similar effects have been observed at the plasma membrane in immune cells, we show BMC interaction with membranes has a much wider impact on cell biology, also occuring on intracellular membranes. We believe this stiffening helps the ANXA11-RNP-lysosome complex endure mechanical shear stress during axonal transport, particularly in neurons with long axons.
We also identified two regulatory proteinsâALG2 and CALCâthat modulate this phase coupling. ALG2 enhances ANXA11 condensation and membrane stiffening, potentially priming the complex for movement. CALC does the opposite, reducing condensation and softening the membrane, which may aid in cargo release. These regulators also influence the complexâs ability to bind RNP granules, suggesting a finely tuned system where protein and membrane phase transitions coordinate intracellular transport.
Overall, our findings suggest a highly adaptable system where phase transitions in proteins in BMCs and lipids in cellular membranes work together â in this instance to control cargo movement inside cells. This work connects two major areas of cell biologyâmembrane-less and membrane-bound compartmentsâand could offer new insight into diseases like ALS. Indeed, several proteins in RNP granules (e.g. FUS, TDP43) and ANXA11 are the sites of ALS-causing mutations.
Peter H. St George-Hyslop, OC, MD, FRCPC, FMedSci, FRS
Belle and Murray Nathan Professor of Neurology (in the Taub Institute)
Co-Director,
The Carol and Gene Ludwig Center for Research on Neurodegeneration
ps2764@cumc.columbia.edu

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Nicholas Ray, PhD | Christiane Reitz, MD, PhD |
Early-onset Alzheimerâs disease (EOAD), which begins before age 65, accounts for about 10% of Alzheimerâs cases. While some cases are linked to mutations in APP, PSEN1, and PSEN2, most remain genetically unexplained. Building on previous work, our teamâin collaboration with the laboratories of Drs. Caghan Kizil, Philip L. De Jager, and colleaguesâexplored whether lipid metabolism contributes to EOAD risk. Using genetic covariance analysis across five lipid traitsâtotal cholesterol, HDL-C, LDL-C, non-HDL-C, and triglyceridesâwe identified three genomic regions with shared genetic architecture and five overlapping loci. These included known AD risk genes (APOE, TREM2, MS4A4E) and novel candidates (LILRA5, LRRC25).
To prioritize genes in the three regions identified by the genetic covariance analysis, we created composite scores for each gene. These scores combined data from multiple sources: gene-based analysis, AD risk scores from Agora (calculated using various multi-omic data, including GWAS, eQTL, transcriptomic, and proteomic data), MetaBrain eQTL data from the cortex and hippocampus, eQTL colocalization analyses across 61 GTEx datasets, ROSMAP brain methylation data, and single-cell RNA sequencing data from both humans and zebrafish. This novel prioritization approach identified ANKDD1B, CUZD1, and MS4A6A as key genes of interest.
ANKDD1B encodes the ankyrin repeat and death domain containing 1 B protein and is linked to both dyslipidemia and diabetes. CUZD1 encodes a protein located in secretory granules in the pancreas that plays a role in lipid metabolism. This gene also contributes to the zymogen activation pathway, which is associated with AD. MS4A6 is a well-known AD-risk that encodes a member of the membrane-spanning 4A gene family and may also contribute to atherosclerosis. Published in PLOS Genetics, our findings provide evidence of shared genetic pathways between EOAD and lipid regulation, suggesting new avenues for understanding disease mechanisms and identifying therapeutic targets. Further work is needed to confirm causal variants and improve genetic risk prediction. Ongoing work includes the exploration of these genes using whole-genome-sequencing data from the Alzheimer's Disease Sequencing Project.
Nicholas Ray, PhD
Postdoctoral Research Scientist in the Gertrude H. Sergievsky Center
nrr2132@cumc.columbia.edu
Christiane Reitz, MD, PhD
Professor of Neurology and Epidemiology (in the Taub Institute and the Gertrude H. Sergievsky Center)
cr2101@cumc.columbia.edu


Miguel Arce RenterĂa, PhD
Most studies on multilingualism and cognitive aging treat multilingual adults as a single group when in fact they demonstrate substantial within-group variability. A key factor in which multilinguals differ is on which languages they use. Prior studies combined different language pairs within a multilingual group regardless of the linguistic similarity between the languages. The demands of cross-language interference are a potential mechanism that may strengthen cognitive control among multilinguals, suggesting that more similar languages may be more prone to interference and thus provide more frequent opportunities to strengthen cognitive control. In a new study led by me, with the help of postdoctoral fellow Dr. Iris Strangmann and collaborators from the University of Southern California and University of Michigan, we examined how these linguistic differences relate to cognitive function in older multilingual adults with and without formal education.
Published recently in Neuropsychology, our study used data from the Longitudinal Aging Study in IndiaâDiagnostic Assessment of Dementia (LASI-DAD), a nationally representative sample of 4,088 Indian adults aged 60 and older, speaking 40 languages and dialects (54% without formal schooling). Participants were categorized based on whether their languages belonged to the same or different language families. This variety of languages was represented across five Indian language families: Indo-Aryan, Dravidian, Austro-Asiatic, Tibeto-Burmese, and Andamanese. In addition to these Indian languages, non-Indian language families which have been increasing in prevalence in India such as Indo-European (i.e., English) and Japonic (i.e., Japanese), among others, were also included.
Figure 1. Association of multilingual status and cognitive functioning among participants with education and without education. Note: All models control for: Age, sex, years of education, education, urbanicity, BMI, hypertension, diabetes, heart disease, smoking status, hearing loss, consumption quartile, and childhood SES (parental education).
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After adjusting for covariates in the full and propensity-score matched samples, multilingual participants with formal education outperformed monolinguals across cognitive domains, regardless of language similarity. However, among those without formal schooling, only multilinguals speaking related languages showed a cognitive advantage. Our findings demonstrate potential for examining the relationship between multilingualism and cognition in large population-based cohort studies. Future measurement of the various attributes of multilingualism, such as language proficiency and frequency of use, will help us further explore how managing linguistic interference and exposure to similar languages enhances late-life cognition. For more information, listen to my interview on the Neuropsychology Meet the Authors podcast on Spotify or wherever you get your podcasts.
Miguel Arce RenterĂa, PhD
Assistant Professor of Neuropsychology (in Neurology)
ma3347@cumc.columbia.edu

Axonal Transport of CHMP2b Is Regulated by Kinesin-Binding Protein and Disrupted by CHMP2bintron5
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Konner Kirwan, PhD | Clarissa Waites, PhD |
Maintaining the neuronal proteome is essential for nervous system health. Indeed, many studies show that disruption of cellular pathways for protein synthesis, trafficking, and degradation lead to synaptic dysfunction and ultimately neurodegeneration. One such pathway is the ESCRT (endosomal sorting complex required for transport), a series of molecular complexes that sort proteins destined for degradation into multivesicular bodies (MVBs) for delivery to lysosomes. Mutations in the ESCRT protein CHMP2b, responsible for the final step of MVB formation, impair neuronal protein degradation and cause frontotemporal dementia (FTD) and amyotrophic lateral sclerosis (ALS).
Previous studies in mouse models expressing the most common of these mutations, CHMP2bintron5, show that this mutant also promotes early deficits in synaptic function that precede neurodegeneration. To understand how these synaptic defects arise, we performed live imaging experiments to a) characterize the axonal transport and synaptic localization of CHMP2b, and b) determine how these features are disrupted by the CHMP2bintron5 mutation. As recently reported in Life Science Alliance, we found that CHMP2b undergoes vesicular transport in axons, and that both its trafficking and recruitment to synapses are positively regulated by neuronal activity, consistent with the need for ESCRT protein delivery to synapses to catalyze MVB formation facilitating the use-dependent turnover of synaptic proteins. In contrast, our imaging studies of CHMP2bintron5 revealed that this mutant exhibits very little directional transport or synaptic localization under basal conditions, and that these features are not regulated by neuronal activity. Instead, CHMP2bintron5 transport vesicles exhibit oscillatory behavior reminiscent of a âtug-of-warâ between kinesin and dynein motor proteins.
In the second part of the study, we investigated why this phenotype occurs. We demonstrated that it is due to the reduced binding of CHMP2bintron5 to an inhibitor of kinesin-mediated axonal transport, kinesin family binding protein (KBP), leading to dysregulation of the mutantâs trafficking and recruitment to synapses. Additionally, we found that CHMP2bintron5 acts as a dominant-negative to prevent wild-type CHMP2b from properly localizing to synapses. The cumulative result of this mutation is thus a lack of CHMP2b delivery to synapses to facilitate the formation of MVBs for degradation of synaptic proteins, leading to their accumulation, altered synaptic vesicle cycling, and deficient neurotransmitter release.
These findings represent the first characterization of CHMP2b axonal transport dynamics, and implicate KBP as a key regulator of CHMP2b activity-dependent transport and synaptic localization. Moreover, our work provides novel mechanistic insight into how CHMP2bintron5 impairs the axonal transport and synaptic recruitment of CHMP2b, contributing to our understanding of how this ALS/FTD-causative mutant induces synaptic dysfunction.
Clarissa Waites, PhD
Associate Professor of Pathology and Cell Biology and Neuroscience
cw2622@cumc.columbia.edu
