Quantitative Biology Seminar Series

Thursday, December 4, 2025

Covariance Models for Genetic Cohorts with Complex Relatedness Structures

Speaker: Alejandro Ochoa, Assistant Professor of Biostatistics & Bioinformatics, Faculty Network Member of the Duke Institute for Brain Sciences, Duke University School of Medicine

Time: 12:30pm - 2 PM

Location: CDS 1646

Modern population genetic datasets are getting larger and are more likely to include individuals with different ancestries, admixture, and close and distant family relatives. However, many key statistical genetics analyses are not well suited for these data, especially when they assume that samples are drawn from one or a few homogeneous populations. Professor Ochoa's lab is focused on developing models for arbitrary relatedness. The key observation is that, while standard models assume that samples are independent, complex relatedness structures result in strong covariance patterns between genetic variants of individuals, so modeling such covariance is imperative. The main model of genetic covariance is called the kinship model. I will review previous models of relatedness for genetic association studies, particularly principal components regression and linear mixed-effects models (LMMs), and related mathematical tricks for decorrelating data. Ochoa's team has shown that LMMs are critical to model real datasets, which have numerous distant relatives. Ochoa developed an unbiased kinship estimator when there is population structure, which in practice yields more interpretable values, is crucial for accurate estimation of heritability, and permits fast admixture model fitting. Lastly, Ochoa describes their most recent work for modeling linkage disequilibrium under relatedness, extending the kinship model to cross-correlation between different loci and individuals. The teams' generalized model enables modeling of arbitrary relatedness in common polygenic risk score approaches. Overall, the team's work is laying the foundation for expanding the models that can be applied to all individuals in a dataset regardless of their ancestry.

Thursday, October 16, 2025

Studying Single Cells Through Multi-condition and Spatial Context

Speaker: Xiuwei Zhang is an Assistant Professor and J. Z. Liang Early Career Assistant Professor in the School of Computational Science and Engineering at the Georgia Institute of Technology

Time: 12:30-2 PM

Location: CDS 1646

With the advances in single-cell technologies, cells are profiled through multiple modalities, and data on samples from an increasing number of individuals are obtained. Professor Zhang will present our method, scDisInFact, that disentangles variation in multi-batch multi-condition scRNA-seq datasets and predicts data under unseen conditions. I will also present methods developed in our group on spatial transcriptomics (ST) data, including SpaDecoder, which performs cell type deconvolution for spot-based ST data, and TemSOMap, which integrates spatial and scRNA-seq data by considering both spatial and temporal information of cells. Finally, I will present scMultiSim, which can be used to evaluate methods for multi-omics and spatial data.

Thurs., April 17, 2025

Perpetual Evolution and Diversification Driven by Ecological Feedback

Speaker: Daniel S. Fisher, David Starr Jordan Professor of Science, Department of Applied Physics, Stanford University

Time: 12:30 PM - 2 PM

Location: 665 Commonwealth Ave., Room 1646

Genomic data on Prochlorococcus, a cyanobacterium that dominates photosynthesis in tropical oceans, suggest that even in seemingly simple well-mixed environments with little ecological structure, microbial populations diversify extensively and continually evolve. Even in laboratory experimental evolutions designed to avoid ecological effects, populations continue to evolve at a faster rate than would expect in a constant environment.   Together, these raise crucial questions: Do the complexities of even simple cells make evolution in high-dimensional phenotypic spaces very different than low-dimensional caricatures?  With weak ecological feedback can evolution continue forever without slowing down?  And how much ecological complexity is needed to generate and sustain extensive diversity?  Progress on these questions gleaned from simple eco-evo models of resource competition, and of bacteria-phage interactions, will be discussed.  The possibility of a highly diverse spatio-temporally chaotic ecological “phase” will be introduced.

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Thurs., March 20, 2025

Integrative Computational Approaches for Modeling Complex Disease Biology Across Scales and Systems

Speaker: Vicky Yao,Assistant Professor, Department of Computer Science, Rice University

Time: 12:30 PM - 2 PM

Location: 665 Commonwealth Ave., Room 1646

To effectively model the molecular underpinnings of complex traits and diseases, computational methods must integrate diverse data types, handle partial or limited observations, and remain robust to variations in dataset size. In this talk, Professor Yao will present several recent methods we have developed to address these challenges across diverse studies, assay types, and organisms, leveraging novel statistical and machine learning approaches. First, Professor Yao will introduce ALPINE, an NMF-based framework that disentangles the influence of technical and non-relevant phenotypic factors in single-cell transcriptomic data, enabling the integration of multiple studies. Integrating across data types, Professor Yao will discuss our method, seismic, which combines genome-wide association studies with single-cell RNA sequencing to prioritize disease-relevant cell types, linking genetic variation to cellular function. Finally, Professor Yao will discuss ETNA, a language translation-inspired approach that embeds protein-protein interaction networks from different organisms into a shared space, facilitating cross-species functional comparisons. Together, these methods highlight how diverse data sources can be integrated across molecular, cellular, and organism levels to better model complex disease biology.

September 19, 2024

Meet & Greet Reception
12:30 - 2 PM in CDS 1646

About: Join us for a Quantitative Biology Seminar Series Meet & Greet Reception on Thursday, September 19. The networking event is designed for faculty, researchers, professionals, and students in the field of quantitative biology to share ideas, foster collaborations, and connect with others who share a passion for integrating quantitative methods into biological sciences.

Organizers: Brian Cleary and Pawel Przytycki, CDS assistant professors and a core faculty members in the Bioinformatics Program, and Pankaj Mehta, professor of Physics and Computing & Data Sciences

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Thurs., December 5, 2024

How do cells message each other and how to check their history of received messages?

Pulin Li, Eugene Bell Career Development Professor of Tissue Engineering; Core Member, Whitehead Institute, MIT

Cells within a tissue frequently exchange information with one another through secreted signaling molecules that travel over tens to hundreds mm. Being able to decipher the communicative relationship amongst cells is crucial for understanding how tissues are formed in embryos, how they perform physiological functions in adults and how communication relationship breaks down in diseases. However, which cell can communicate with which other cell within a tissue is an actively regulated process.

Professor Li's lab combines synthetic biology, mathematical modeling and computational inference to decipher the rules of cell-cell communication in the context of embryo development. In this talk, she will discuss the team's insights in how the distance by which cell communication occurs can be regulated across tissues and evolution. She will also discuss our recent effort in computationally inferring what signals a cell has received using single-cell perturbation and transcriptomics.

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Thurs., October 3, 2024

T Cell Recognition: From Theory to CAR-T Immunotherapy

Paul Francois, Professor, Bioinformatics, Biophysics, Université de Montréal

The immune system performs a fundamental task: distinguishing between self and non-self. In an ideal scenario, formalizing this process would enable us to derive 'design principles', make accurate predictions, and create experimental interventions. In this talk, Professor Francois will illustrate how starting from basic theoretical concepts, we can develop a series of models known as 'adaptive kinetic proofreading' (AKPR). These models capture key aspects of T cell recognition and shed light on immune system blindspots caused by active antagonism.

He then discuss how we employed a specially designed robotic platform to test the core principles of adaptive kinetic proofreading in the context of collective immune responses. In a clinical context, this approach is leading us to innovative applications, such as designing a novel type of CAR-T immunotherapy by transferring specificity from a T cell receptor to a Chimeric one. The team's research demonstrates how integrating theoretical models with robotic quantitative biology can significantly enhance our understanding of cell dynamics and directly impact therapeutic development.

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Thurs., October 17, 2024

Defense Against the Dark Arts: How Cells Collaborate to Resist Viral Infection

Alon Oyler-Yaniv, Principal Investigator, Oyler-Yaniv Lab, Harvard Medical School

The first line of defense against viral infection is the production of type-I interferon, which activates interferon response genes to initiate antiviral defense. However, two key challenges complicate this picture. First, viral replication occurs rapidly, leaving little time for the host to complete two rounds of de novo gene expression before the virus completes its life cycle and spreads to neighboring cells. Second, viruses are notorious for hijacking the host’s translational machinery, preventing infected cells from effectively producing the necessary antiviral proteins. This raises a critical question: how can host cells defend themselves quickly, without relying on infected cells to make new proteins? In this talk, I will present two mechanisms that host tissues use to address this paradox. First, in the presence of TNF, a cytokine produced by macrophages, virus-infected cells activate “guard immunity”. Rather than directly detecting the virus, guard immunity detects viral-induced disruptions in normal cell physiology, triggering rapid programmed cell death that slows down viral spread. Second, infected cells can transfer cGAMP, made from preexisting nucleotides, to neighboring cells, triggering IFN production in uninfected neighbors and inducing antiviral defense in distal cells. This spatial division of labor creates a localized viral microenvironment that cooperatively blocks viral spread. These two mechanisms demonstrate how through contextual cues and collaboration, a population can resist challenges that are otherwise detrimental to an individual cell.

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Thurs., October 24, 2024

Generative AI to Accelerate Protein Design for Health and Sustainability Goals

Debora Marks, Professor of Systems Biology, Harvard Medical School, Broad Institute of Harvard University and MIT 

There’s now an amazing opportunity to develop machine learning methods that can exploit enormous natural sequence and 3D structure diversity to design biological sequences for biotherapeutics and climate change goals. This includes predicting the effects of human genetic variation on disease and drug response, viral evolution, antibody design and optimization of proteins for sustainability. In this talk, Professor Marks will describe new methods in probabilistic deep learning that are enabling huge acceleration in discovery in these fields. She will focus here on the challenges for designing specific protein functions, probabilistic models to generate novel functional biotherapeutics and  viral forecasting, and will also present new results and tools for vaccine design, enzyme optimization and upcycling.

https://marks.hms.harvard.edu/
https://github.com/debbiemarkslab

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POSTPONED UNTIL SPRING 2025

Michael Desai, Professor of Organismic and Evolutionary Biology and Physics, Harvard University

 

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Thurs., November 21, 2024

Statistical Methods for Single-Cell RNA-Seq Analysis and Spatial Transcriptomics

Rafael Irizarry, Professor and Chair of the Department of Data Science at the Dana-Farber Cancer Institute and Professor of Biostatistics at Harvard School of Public Health

Professor Irizarry will share findings demonstrating limitations of current workflows that are popular in single cell RNA-Seq data analysis. Specifically, he will describe challenges and solutions to dimension reduction, cell-type classification, and statistical significance analysis of clustering. He will end the talk describing some of our work related to spatial transcriptomics. Specifically, Irizarry will describe approaches to cell type annotation that account for presence of multiple cell-types represented in the measurements, a common occurrence with technologies such as Visium and SlideSeq, and demonstrate how this approach facilitates the discovery of spatially varying genes.