This image is an artistic impression of Lamarck's central thesis. Lamarck used the giraffe in 1809 to illustrate how experience shapes inheritance. The giraffe stretching its neck represents a heritable experience. The red marks are histone modifications. The birds are proteins that place them.
Chromatin in watercolors. DNA is packaged by DNA packaging proteins called histones that can be modified to carry epigenetic information. Courtesy: Venks Pai

Ragunathan Laboratory · Brandeis University

Decoding the molecular logic of epigenetic inheritance

We study how epigenetic information is established, maintained and remodeled on-demand during adaptation. We are interested in a broad spectrum of problems that encompass chromatin biology that includes fission yeast, non-model fungi and mammalian cells.

Research

Questions we are interested in

Our program of research is focused on understanding how dynamic and transient interactions involving chromatin modifying enzymes lead to the establishment of stable and heritable epigenetic states. While we have mostly been interested in epigenetic silencing mechanisms in S. pombe, our research has diversified over the years to also include non-model fungi and mammalian cell culture models.

01

Epigenetic Inheritance

Using inducible systems in fission yeast, we uncouple H3K9 methylation establishment from its subsequent maintenance. We have been using these systems to identify the distinct roles of heterochromatin associated factors in epigenetic inheritance.

S. pombeH3K9meInducible silencing
02

Heterochromatin Dynamics

We track Swi6/HP1, Clr4, and other heterochromatin associated factors with high spatial and temporal resolution in living cells. Our goal is to use single particle tracking measurements to determine how the biochemical properties of chromatin associated factors tune their interactions with histone substrates in a cellular context.

Single-moleculeSwi6 / Clr4Live-cell imaging
03

Epigenetic Adaptation

Cells can acquire heritable phenotypes by redistributing histone modifications without a genetic change. We quantify the slow kinetics of this adaptation process and trace the trajectories by which fission yeast cells discover novel ways to adapt to new environments.

Adaptation kineticsLineage tracing
04

Synthetic Epigenetic Circuits

By reconstituting minimal chromatin circuits, we test the design principles of epigenetic memory by mapping the conditions under which feedback yields bistability, oscillations, or stable inheritance.

Synthetic biologyFeedback & bistability
05

Chromatin in Non-Model Fungi

We move beyond classic models to polyextremotolerant fungi such as Aureobasidium pullulans, asking how chromatin-based memory lets cells adapt to environmental stress and switch heritably between distinct morphological and cellular states.

A. pullulansStress adaptationPhenotypic switching
06

Genome Defense in Mammals

The human genome serves as a historical archive of viral invasions; nearly 60% of our DNA consists of endogenous retroviruses, transposons, and other repetitive elements. We seek to understand how mammalian cells distinguish self from non-self DNA. In contrast, rDNA which is highly repetitive is actively transcribed, producing ~90% of total RNA in the cell. The regulatory mechanisms that control rDNA expression are also of interest to us.

Mammalian cellsrDNA silencingForeign DNA silencing
Methods

What we use, and what for

Techniques we use in our research

Our research leverages a unique permutation of genetic, biochemical, and biophysical approaches that bridges our understanding of epigenetic phenomena across different biological timescales.

Genetics

Forward and reverse genetic screens in fission yeast to identify and order the factors that build heterochromatin.

Single-Molecule Imaging

Tracking individual silencing factors in living cells to measure binding kinetics and transient interactions.

Biochemical Reconstitution

Purification of chromatin-modifying complexes and reconstituting their activities and interactions with nucleosomes in vitro.

ChIP-seq & RNA-seq

Genome-wide maps of histone modifications and transcription, followed over time during inheritance and adaptation.

Synthetic Biology

Minimal chromatin circuits built from defined parts to test the design principles of epigenetic memory.

Mathematical Modeling

Quantitative models of epigenetic feedback processes

People

The lab

Principal Investigator
Kaushik Ragunathan

Kaushik Ragunathan

Principal Investigator
Associate Professor, Dept. of Biology
kaushikr@brandeis.edu ORCID: 0000-0003-4776-8589
Postdoctoral Researchers
Sumanth Kumar Maheshwaram

Sumanth Kumar Maheshwaram

Postdoctoral Researcher
Single-molecule imaging of silencing complexes
PhD, Raman Research Institute
Amith Zafal Abdulla

Amith Zafal Abdulla

Postdoctoral Researcher
Modeling epigenetic memory in single-cell lineages
PhD, ENS Lyon
Elizabeth Hemenway

Elizabeth Hemenway

Postdoctoral Researcher
Stress-induced adaptation in polyextremotolerant fungi
PhD, MIT
Graduate Students
Neha Arora

Neha Arora

Graduate Student
Genome defense mechanisms in mammalian cells
BS, Cal Poly Humboldt
Emily Metcalf

Emily Metcalf

Graduate Student
Regulation of rRNA expression in mammalian cells
BA, Cambridge
Katelyn Strauss

Katelyn Strauss

Graduate Student
Mechanisms governing epigenetic inheritance
BS, Boston College
SC

Sarah Chiaradonna

Graduate Student
Evolution informed approaches to epigenetic inheritance
JS

Juan Serrano Jiminez

Graduate Student
Allostery in chromatin modifying enzymes
Research Staff
JG

Jason Garcia

Research Staff
Stress-induced adaptation in polyextremotolerant fungi
Dobby

Dobby

Research Assistant
Being a good boy, fetch, attending lab meetings
BS, Stanfurred
Undergraduate Students
GP

Giang Pham

Undergraduate Researcher
TY

Tori Yamada

Undergraduate Researcher
KN

Khue Nguyen

Undergraduate Researcher
KC

Kaitlyn Chen

Undergraduate Researcher
Publications

The Paper Trail

Pre-prints Under review
Nucleosome remodeling by a CHD enzyme promotes H3K9 methylation establishment and spreading via remodeler-writer feedback
Seman M, Latuda A, Mazumder A, Wolfstädter LM, Huang F, Abdulla AZ, Braun S*, Ragunathan K*
bioRxiv2026.05.03.722496 · preprint
Abstract +Abstract −

In Schizosaccharomyces pombe, the conserved CHD remodeler Mit1 function within the SHREC remodeler-deacetylase complex (a homolog of the metazoan Mi-2/NuRD complex), which is essential for H3K9 methylation-dependent heterochromatin establishment. However, the mechanism by which remodeler activity promotes silencing is unknown. Current models posit a hierarchical relationship between histone modifications and remodeler activity, with Mit1 acting exclusively downstream of H3K9 methylation. Here, we challenge this model by showing that tethering Mit1 at an ectopic site within euchromatin is sufficient to initiate heterochromatin assembly and generate extended domains of de novo H3K9 methylation. This process requires the Mit1 catalytic activity but does not involve direct physical interaction with Clr4, suggesting Mit1-mediated nucleosome remodeling creates a chromatin context that enhances Clr4 function. Using a genome-wide deletion screen, we determined that Mit1-initiated silencing requires all core heterochromatin factors and is critically dependent on Clr4 dosage. Furthermore, Mit1 activity facilitates heterochromatin spreading at subtelomeric regions and promotes H3K9 methylation at novel genomic sites implicated in cellular adaptation. Together, our findings support a model in which remodeler-writer pairs, analogous to reader-writer pairs, constitute conserved regulatory modules through which nucleosome organization directs the establishment of heritable epigenetic states.

Published Papers Peer-reviewed
2024
Tracking live-cell single-molecule dynamics enables measurements of heterochromatin-associated protein–protein interactions
Chen Z, Seman M, Fyodorova Y, Farhat A, Ames A, Levashkevich A, Biswas S, Huang F, Freddolino L*, Biteen JS*, Ragunathan K*
Nucleic Acids Research52(18):10731–10746. doi: 10.1093/nar/gkae692. PMID: 39142658
Abstract +Abstract −

Visualizing and measuring molecular-scale interactions in living cells represents a major challenge, but recent advances in single-molecule super-resolution microscopy are bringing us closer to achieving this goal. Single-molecule super-resolution microscopy enables high-resolution and sensitive imaging of the positions and movement of molecules in living cells. HP1 proteins are important regulators of gene expression because they selectively bind and recognize H3K9 methylated (H3K9me) histones to form heterochromatin-associated protein complexes that silence gene expression, but several important mechanistic details of this process remain unexplored. Here, we extended live-cell single-molecule tracking studies in fission yeast to determine how HP1 proteins interact with their binding partners in the nucleus. We measured how genetic perturbations that affect H3K9me alter the diffusive properties of HP1 proteins and their binding partners, and we inferred their most likely interaction sites. Our results demonstrate that H3K9 methylation spatially restricts HP1 proteins and their interactors, thereby promoting ternary complex formation on chromatin while simultaneously suppressing off-chromatin binding. As opposed to being an inert platform to direct HP1 binding, our studies propose a novel function for H3K9me in promoting ternary complex formation by enhancing the specificity and stimulating the assembly of HP1-protein complexes in living cells.

Mapping the dynamics of epigenetic adaptation in S. pombe during heterochromatin misregulation
Larkin A, Kunze C, Seman M, Levashkevich A, Curran J, Morris-Evans D, Lemieux S, Khalil AS*, Ragunathan K*
Developmental Cell59(16):2222–2238.e4. doi: 10.1016/j.devcel.2024.07.006. PMID: 39094565
Abstract +Abstract −

Epigenetic mechanisms enable cells to develop novel adaptive phenotypes without altering their genetic blueprint. Recent studies show histone modifications, such as heterochromatin-defining H3K9 methylation (H3K9me), can be redistributed to establish adaptive phenotypes. We developed a precision-engineered genetic approach to trigger heterochromatin misregulation on-demand in fission yeast. This enabled us to trace genome-scale RNA and H3K9me changes over time in long-term, continuous cultures. Adaptive H3K9me establishes over remarkably slow timescales relative to the initiating stress. We captured dynamic H3K9me redistribution events which depend on an RNA binding complex MTREC, ultimately leading to cells converging on an optimal adaptive solution. Upon stress removal, cells relax to new transcriptional and chromatin states, establishing memory that is tunable and primed for future adaptive epigenetic responses. Collectively, we identify the slow kinetics of epigenetic adaptation that allow cells to discover and heritably encode novel adaptive solutions, with implications for drug resistance and response to infection.

Epigenetic memory is governed by an effector recruitment specificity toggle in Heterochromatin Protein 1
Ames A, Seman M, Larkin A, Raiymbek G, Chen Z, Levashkevich A, Kim B, Biteen JS, Ragunathan K*
Nature Communications15(1):6276. doi: 10.1038/s41467-024-50538-z. PMID: 39054315
Abstract +Abstract −

HP1 proteins are essential for establishing and maintaining transcriptionally silent heterochromatin. They dimerize, forming a binding interface to recruit diverse chromatin-associated factors. Although HP1 proteins are known to rapidly evolve, the extent of variation required to achieve functional specialization is unknown. To investigate how changes in amino acid sequence impacts heterochromatin formation, we performed a targeted mutagenesis screen of the S. pombe HP1 homolog, Swi6. Substitutions within an auxiliary surface adjacent to the HP1 dimerization interface produce Swi6 variants with divergent maintenance properties. Remarkably, substitutions at a single amino acid position lead to the persistent gain or loss of epigenetic inheritance. These substitutions increase Swi6 chromatin occupancy in vivo and altered Swi6-protein interactions that reprogram H3K9me maintenance. We show how relatively minor changes in Swi6 amino acid composition in an auxiliary surface can lead to profound changes in epigenetic inheritance providing a redundant mechanism to evolve HP1-effector specificity.

The condensation of HP1-α/Swi6 imparts nuclear stiffness
Williams JF, Surovtsev IV, Schreiner SM, Chen Z, Raiymbek G, Nguyen H, Hu Y, Biteen JS, Mochrie SGJ, Ragunathan K, King MC*
Cell Reports43(7):114373. doi: 10.1016/j.celrep.2024.114373. PMID: 38900638
Abstract +Abstract −

Biomolecular condensates have emerged as major drivers of cellular organization. It remains largely unexplored, however, whether these condensates can impart mechanical function(s) to the cell. The heterochromatin protein HP1α (Swi6 in Schizosaccharomyces pombe) crosslinks histone H3K9 methylated nucleosomes and has been proposed to undergo condensation to drive the liquid-like clustering of heterochromatin domains. Here, we leverage the genetically tractable S. pombe model and a separation-of-function allele to elucidate a mechanical function imparted by Swi6 condensation. Using single-molecule imaging, force spectroscopy, and high-resolution live-cell imaging, we show that Swi6 is critical for nuclear resistance to external force. Strikingly, it is the condensed yet dynamic pool of Swi6, rather than the chromatin-bound molecules, that is essential to imparting mechanical stiffness. Our findings suggest that Swi6 condensates embedded in the chromatin meshwork establish the emergent mechanical behavior of the nucleus as a whole, revealing that biomolecular condensation can influence organelle and cell mechanics.

Direct observation of autoubiquitination for an integral membrane ubiquitin ligase in ERAD
Assainar BM, Ragunathan K*, Baldridge RD*
Nature Communications15(1):1340. doi: 10.1038/s41467-024-45541-3. PMID: 38351109
Abstract +Abstract −

The endoplasmic reticulum associated degradation (ERAD) pathway regulates protein quality control at the endoplasmic reticulum. ERAD of lumenal and membrane proteins requires a conserved E3 ubiquitin ligase, called Hrd1. We do not understand the molecular configurations of Hrd1 that enable autoubiquitination and the subsequent retrotranslocation of misfolded protein substrates from the ER to the cytosol. Here, we have established a generalizable, single-molecule platform that enables high-efficiency labeling, stoichiometry determination, and functional assays for any integral membrane protein. Using this approach, we directly count Hrd1 proteins reconstituted into individual proteoliposomes. We report that Hrd1 assembles in different oligomeric configurations with mostly monomers and dimers detected at limiting dilution. By correlating oligomeric states with ubiquitination in vitro, we conclude that Hrd1 monomers are inefficient in autoubiquitination while dimers efficiently assemble polyubiquitin chains. Therefore, our results reveal the minimal composition of a Hrd1 oligomer that is capable of autoubiquitination. Our methods are broadly applicable to studying other complex membrane protein functions using reconstituted bilayer systems.

2023
Uncoupling the distinct functions of HP1 proteins during heterochromatin establishment and maintenance
Seman M, Levashkevich A, Larkin A, Huang F, Ragunathan K*
Cell Reports42(11):113428. doi: 10.1016/j.celrep.2023.113428. PMID: 37952152
Abstract +Abstract −

H3K9 methylation (H3K9me) marks transcriptionally silent genomic regions called heterochromatin. HP1 proteins are required to establish and maintain heterochromatin. HP1 proteins bind to H3K9me, recruit factors that promote heterochromatin formation, and oligomerize to form phase-separated condensates. We do not understand how these different HP1 properties are involved in establishing and maintaining transcriptional silencing. Here, we demonstrate that the S. pombe HP1 homolog, Swi6, can be completely bypassed to establish silencing at ectopic and endogenous loci when an H3K4 methyltransferase, Set1, and an H3K14 acetyltransferase, Mst2, are deleted. Deleting Set1 and Mst2 enhances Clr4 enzymatic activity, leading to higher H3K9me levels and spreading. In contrast, Swi6 and its capacity to oligomerize were indispensable during epigenetic maintenance. Our results demonstrate the role of HP1 proteins in regulating histone modification crosstalk during establishment and identify a genetically separable function in maintaining epigenetic memory.

Sperm chromatin structure and reproductive fitness are altered by substitution of a single amino acid in mouse protamine 1
Moritz L, Schon SB, Rabbani M, Sheng Y, Agrawal R, Glass-Klaiber J, Sultan C, Camarillo JM, Clements J, Baldwin MR, Diehl AG, Boyle AP, O'Brien PJ, Ragunathan K, Hu YC, Kelleher NL, Nandakumar J, Li JZ, Orwig KE, Redding S, Hammoud SS
Nature Structural & Molecular Biology30(8):1077–1091. doi: 10.1038/s41594-023-01033-4. PMID: 37460896
Abstract +Abstract −

Conventional dogma presumes that protamine-mediated DNA compaction in sperm is achieved by electrostatic interactions between DNA and the arginine-rich core of protamines. Phylogenetic analysis reveals several non-arginine residues conserved within, but not across species. The significance of these residues and their post-translational modifications are poorly understood. Here, we investigated the role of K49, a rodent-specific lysine residue in protamine 1 (P1) that is acetylated early in spermiogenesis and retained in sperm. In sperm, alanine substitution (P1(K49A)) decreases sperm motility and male fertility-defects that are not rescued by arginine substitution (P1(K49R)). In zygotes, P1(K49A) leads to premature male pronuclear decompaction, altered DNA replication, and embryonic arrest. In vitro, P1(K49A) decreases protamine-DNA binding and alters DNA compaction and decompaction kinetics. Hence, a single amino acid substitution outside the P1 arginine core is sufficient to profoundly alter protein function and developmental outcomes, suggesting that protamine non-arginine residues are essential for reproductive fitness.

2022
HP1 oligomerization compensates for low-affinity H3K9me recognition and provides a tunable mechanism for heterochromatin-specific localization
Biswas S, Chen Z, Karslake JD, Farhat A, Ames A, Raiymbek G, Freddolino PL*, Biteen JS*, Ragunathan K*
Science Advances8(27):eabk0793. doi: 10.1126/sciadv.abk0793. PMID: 35857444
Abstract +Abstract −

HP1 proteins traverse a complex and crowded chromatin landscape to bind with low affinity but high specificity to histone H3K9 methylation (H3K9me) and form transcriptionally inactive genomic compartments called heterochromatin. Here, we visualize single-molecule dynamics of an HP1 homolog, the fission yeast Swi6, in its native chromatin environment. By tracking single Swi6 molecules, we identify mobility states that map to discrete biochemical intermediates. Using Swi6 mutants that perturb H3K9me recognition, oligomerization, or nucleic acid binding, we determine how each biochemical property affects protein dynamics. We estimate that Swi6 recognizes H3K9me3 with ~94-fold specificity relative to unmodified nucleosomes in living cells. While nucleic acid binding competes with Swi6 oligomerization, as few as four tandem chromodomains can overcome these inhibitory effects to facilitate Swi6 localization at heterochromatin formation sites. Our studies indicate that HP1 oligomerization is essential to form dynamic, higher-order complexes that outcompete nucleic acid binding to enable specific H3K9me recognition.

The cAMP signaling pathway regulates Epe1 protein levels and heterochromatin assembly
Bao K, Shan CM, Chen X, Raiymbek G, Monroe JG, Fang Y, Toda T, Koutmou KS, Ragunathan K, Lu C, Berchowitz LE, Jia S
PLOS Genetics18(2):e1010049. doi: 10.1371/journal.pgen.1010049. PMID: 35171902
Abstract +Abstract −

The epigenetic landscape of a cell frequently changes in response to fluctuations in nutrient levels, but the mechanistic link is not well understood. In fission yeast, the JmjC domain protein Epe1 is critical for maintaining the heterochromatin landscape. While loss of Epe1 results in heterochromatin expansion, overexpression of Epe1 leads to defective heterochromatin. Through a genetic screen, we found that mutations in genes of the cAMP signaling pathway suppress the heterochromatin defects associated with Epe1 overexpression. We further demonstrated that the activation of Pka1, the downstream effector of cAMP signaling, is required for the efficient translation of epe1+ mRNA to maintain Epe1 overexpression. Moreover, inactivation of the cAMP-signaling pathway, either through genetic mutations or glucose deprivation, leads to the reduction of endogenous Epe1 and corresponding heterochromatin changes. These results reveal the mechanism by which the cAMP signaling pathway regulates heterochromatin landscape in fission yeast.

Investigating mitotic inheritance of histone modifications using tethering strategies
Larkin A, Ames A, Seman M, Ragunathan K*
Methods in Molecular Biology2529:419–440 · book chapter. doi: 10.1007/978-1-0716-2481-4_18. PMID: 35733025
Abstract +Abstract −

The covalent and reversible modification of histones enables cells to establish heritable gene expression patterns without altering their genetic blueprint. Epigenetic mechanisms regulate gene expression in two separate ways: (1) establishment, which depends on sequence-specific DNA- or RNA-binding proteins that recruit histone-modifying enzymes to unique genomic loci, and (2) maintenance, which is sequence-independent and depends on the autonomous propagation of preexisting chromatin states during DNA replication. Only a subset of the vast repertoire of histone modifications in the genome is heritable. Here, we describe a synthetic biology approach to tether histone-modifying enzymes to engineer chromatin states in living cells and evaluate their potential for mitotic inheritance. In S. pombe, fusing the H3K9 methyltransferase, Clr4, to the tetracycline-inducible TetR DNA-binding domain facilitates rapid and reversible control of heterochromatin assembly. We describe a framework to successfully implement an inducible heterochromatin establishment system and evaluate its molecular properties. We anticipate that our innovative genetic strategy will be broadly applicable to the discovery of protein complexes and separation-of-function alleles of heterochromatin-associated factors with unique roles in epigenetic inheritance.

2020
An H3K9 methylation-dependent protein interaction regulates the non-enzymatic functions of a putative histone demethylase
Raiymbek G, An S, Khurana N, Gopinath S, Larkin A, Biswas S, Trievel RC, Cho US, Ragunathan K*
eLife9:e53155. doi: 10.7554/eLife.53155. PMID: 32195666
Abstract +Abstract −

H3K9 methylation (H3K9me) specifies the establishment and maintenance of transcriptionally silent epigenetic states or heterochromatin. The enzymatic erasure of histone modifications is widely assumed to be the primary mechanism that reverses epigenetic silencing. Here, we reveal an inversion of this paradigm where a putative histone demethylase Epe1 in fission yeast, has a non-enzymatic function that opposes heterochromatin assembly. Mutations within the putative catalytic JmjC domain of Epe1 disrupt its interaction with Swi6HP1 suggesting that this domain might have other functions besides enzymatic activity. The C-terminus of Epe1 directly interacts with Swi6HP1, and H3K9 methylation stimulates this protein-protein interaction in vitro and in vivo. Expressing the Epe1 C-terminus is sufficient to disrupt heterochromatin by outcompeting the histone deacetylase, Clr3 from sites of heterochromatin formation. Our results underscore how histone modifying proteins that resemble enzymes have non-catalytic functions that regulate the assembly of epigenetic complexes in cells.

A complete, up-to-date publication list is available via ORCID.

News

What's happening in the lab

2026
March

Sarah and Juan both became PhD students in the lab.

Newbie
Opportunities

Join us

We look for curious scientists drawn towards hard mechanistic questions. Our lab is highly interdisciplinary, and we typically have candidates who bring different perspectives. Experience in yeast is not required or mandatory — what we most value is an openness to be informed by exciting scientific questions

We are actively recruiting. When you write, please put [Ragunathan Lab — Position] in your email subject line so your message reaches us.

Postdoctoral Scholars

For candidates with interests in genetics, biochemistry, biophysics, or quantitative biology in any model system.

Include in your email
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Graduate Students

Students join our lab through the Molecular & Cell Biology (MCB) or Biochemistry & Biophysics (BCBP) graduate programs at Brandeis. We welcome rotation students from all Brandeis-associated graduate programs.

Before you rotate
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  • Tell us which research areas interest you
  • Mention any prior research experience

Undergraduates

We host undergraduates for research in a range of capacities throughout the year.

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  • A short statement of interest and career goals
  • Your area of interest
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Contact & Location

Find us

Lab Address

Ragunathan Lab
Department of Biology, Brandeis University
Rosenstiel Center, 4th Floor
415 South Street, Waltham, MA 02453

Shipping Address

Lab Supplies ATTN: Ragunathan Lab, Department of Biology
Brandeis University, Rosenstiel Center
415 South Street, MS-008
Waltham, MA 02453

Office & Email

Office: Rosenstiel 4th Floor · Phone: (781) 736-2407
kaushikr@brandeis.edu

15 miles west of Boston · Near I-95 (Exit 27A) and I-90 · Waltham, MA