This Week at ICERM
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September 15, 2024
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9:00 - 9:45 am EDTIn Search of Markov Solutions11th Floor Lecture Hall
- Speaker
- Vivek Borkar, IIT Bombay, India
- Session Chair
- Arnab Ganguly, Louisiana State University
Abstract
This talk will summarise recent contributions to two strands of research - mimicking one dimensional marginals of random processes by Markov processes, and selecting a Markov family of solutions for degenerate diffusions with non-unique solutions (also known as Markov selection).
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10:00 - 10:30 am EDTCoffee Break11th Floor Collaborative Space
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10:30 - 11:15 am EDTEstimating Rare Event Probabilities in Reflecting Brownian Motion11th Floor Lecture Hall
- Speaker
- Kevin Leder, University of Minnesota
- Session Chair
- Arnab Ganguly, Louisiana State University
Abstract
Reflecting Brownian motion (RBM) is a stochastic process that behaves like a Brownian motion in the interior of its domain and is pushed into the interior whenever it reaches the boundary of its domain. RBM’s in the positive orthant were first introduced by Harrison and Reiman 1981, and arise naturally in a wide variety of settings, e.g., heavy traffic queueing networks. A difficult question that has received a significant amount of attention is identifying the asymptotics for tail probabilities associated with RBM in the positive orthant. In this work we focus on the specific tail probability that a stable RBM started near the origin exits a large box before returning to the origin. We develop particle based algorithms to estimate this probability. Using results of Dean and Dupuis 2008 we are able to develop algorithms that efficiently estimate this tail probability in two dimensions. In three and higher dimensions, we are not able to construct an efficient estimator, but we do construct estimators that are provably superior (in an asymptotic sense) to standard Monte Carlo. Numerical results show the benefits of our algorithm to standard Monte Carlo. This is based on joint work with Xin Liu and Zicheng Wang.
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11:30 am - 12:15 pm EDTReflecting Diffusions in Curved Nonsmooth Domains11th Floor Lecture Hall
- Speaker
- Cristina Costantini, University of Chieti-Pescara
- Session Chair
- Arnab Ganguly, Louisiana State University
Abstract
Reflecting diffusions arise in many applications: from stochastic networks, to singular stochastic control, to the motion of physical particles, etc.. In many examples the domain in which the reflecting diffusion is to be confined is nonsmooth or the direction of reflection varies nonsmoothly: in these cases it is not obvious that a reflecting diffusion with the prescribed direction of reflection exists and is uniquely characterized. After reviewing the literature, in which the works by Dupuis and Ishii play a central role, I will discuss how a recent ergodic theorem for inhomogeneous killed Markov chains allows to extend the 1993 Dupuis and Ishii results to some new classes of domains and directions of reflection. In particular one can obtain existence and uniqueness of a semimartingale reflecting diffusion in a piecewise smooth domain in dimension 2, possibly with cusps, under optimal conditions on the directions of reflection, and one can uniquely characterize obliquely reflecting Brownian motion in some piecewise smooth cones. The talk is based on joint works with T.G. Kurtz.
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12:30 - 2:00 pm EDTLunch/Free Time
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2:00 - 2:45 pm EDTUsing Weak Convergence Methods to Establish Exit Time Asymptotics for a Small Noise Infinite-dimensional System11th Floor Lecture Hall
- Speaker
- David Lipshutz, Flatiron Institute
- Session Chair
- Tao Pang, North Carolina State University
Abstract
Dynamical systems with small noise arise in a wide variety of applications. In such applications, we'd like to know how long it takes the small noise system to escape stable equilibra of the corresponding deterministic system. For finite-dimensional systems, these "exit times" are typically established by proving large deviation principles that are uniform over compact sets. However, for infinite-dimensional systems, bounded sets are no long compact and this approach does not naturally extend. Here, in the context of a small noise stochastic delay differential equation with strong solutions whose natural state space is infinite-dimensional, we show how the weak convergence method that was pioneered by Paul Dupuis can be used to prove a large deviation principle that is uniform over bounded sets. In turn, this enables us to prove exit time asymptotics for the small noise stochastic delay differential equation.
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3:00 - 3:45 pm EDTRenormalized relative entropies and an H-theorem for interacting diffusions on sparse graphs11th Floor Lecture Hall
- Speaker
- Kavita Ramanan, Brown University
- Session Chair
- Tao Pang, North Carolina State University
Abstract
We consider a class of conditional McKean-Vlasov processes that arise in the study of interacting Langevin diffusions on regular trees. We establish an H-theorem that characterizes the long-time behavior of these processes. Specifically, we show that a certain function that arises when taking the limit of certain renormalized relative entropies serves as a global Lyapunov function for the associated measure flow. We also provide counterexamples to highlight some subtleties in the approach, and discuss some open problems. This is joint work with Kevin Hu.
September 16, 2024
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8:30 - 8:50 am EDTCheck In11th Floor Collaborative Space
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8:50 - 9:00 am EDTWelcome11th Floor Lecture Hall
- Session Chair
- Brendan Hassett, ICERM/Brown University
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9:00 - 9:45 am EDTPhylogenetic Semidirected Networks and a Tractable Dissimilarity Measure11th Floor Lecture Hall
- Speaker
- Cécile Ané, University of Wisconsin - Madison
- Session Chair
- Hector Banos, California State University San Bernardino
Abstract
From many data types, we hope identify the phylogenetic semidirected network that generated the data, but not the rooted network. In the semidirected network, some but not all edges are directed. I will define a general class of semidirected phylogenetic networks, with a stable set of leaves, tree nodes and hybrid nodes. This class includes both rooted phylogenetic trees and networks, and unrooted phylogenetic trees. I will show various fundamental properties for these networks, including how to generalize the ""tree-child"" property from rooted to semidirected networks. I then will define an edge-based representation of semidirected phylogenetic networks, which generalizes the node-based μ-representation of a rooted network by Cardona et al. (2009), and the split-based representation of an unrooted tree. It leads to a dissimilarity between semidirected networks, which can be efficiently computed in near-quadratic time, and extends the widely-used Robinson-Foulds distance on both rooted trees and unrooted trees. This dissimilarity is in fact a distance on the space of tree-child semidirected phylogenetic networks.
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10:00 - 10:30 am EDTCoffee Break11th Floor Collaborative Space
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10:30 - 11:15 am EDTGene flow processes in phylogenetic networks and their macroevolutionary implications11th Floor Lecture Hall
- Speaker
- Joshua Justison, Iowa State University
- Session Chair
- Laura Kubatko, The Ohio State University
Abstract
Gene flow is a highly dynamic suite of processes that includes events like lateral gene transfer, hybridization, and introgression. Even between clades across the Tree of Life, these processes can have different controlling factors and mechanisms that ultimately affect the macroevolutionary patterns we observe. In this talk I will discuss some of the ways that various gene flow processes can be modeled on a macroevolutionary scale. I simulated phylogenetic networks from the birth-death-hybridization process to demonstrate that phylogenetic networks can have drastically different diversification dynamics and topological profiles as we change our underlying assumptions around reticulate patterns. This work emphasizes the need to think critically when choosing an appropriate and fitting model for a given empirical system. This marks an exciting opportunity for biologists to use their system-specific knowledge to model gene flow appropriately and test macroevolutionary hypotheses regarding the role of gene flow to affect diversification and adaptation.
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11:30 am - 12:15 pm EDTTrait Evolution on Two or More Trees11th Floor Lecture Hall
- Speaker
- James Degnan, University of New Mexico
- Session Chair
- Laura Kubatko, The Ohio State University
Abstract
Modeling of trait evolution usually assumes a known phylogeny on which traits evolve such as from Brownian Motion or an OU process. It is conceptually not clear if the phylogeny should be a species tree or a gene tree. Here, we develop a model where a trait evolves on two different gene trees. We introduce a parameter p for the contribution of each gene so that a researcher can estimate the proportion of contribution from each. The example is applied to cultivated rice with two genes that strongly influence grain width but have very different topologies.
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12:30 - 2:30 pm EDTNetworking LunchWorking Lunch - 11th Floor Collaborative Space
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2:30 - 3:15 pm EDTReconstruction of Ancestral Genomes and Sub-genomes11th Floor Lecture Hall
- Speaker
- Lingling Jin, University of Saskatchewan
- Session Chair
- Sebastien Roch, University of Wisconsin-Madison
Abstract
Evolution is a process that involves an organism’s DNA changing over time. Often, this process is driven by external stressors (such as environmental changes, diseases, pests) and/or selective breeding. Recognizing how genomes evolve is of universal biological interest about species origin, survival and adaptation. The fast-increasing number and diversity of sequenced genomes open the door to analyzing the dynamics of evolution at whole-genome resolution. By using a successive ancestral contig construction technique based on statistically conserved syntenic orders of genes, we developed methods to reconstruct chromosome-level ancestral genomes of extant species or subgenomes within a single genome as a result of whole genome doubling/tripling. These methods were applied and verified in many lineages across different studies that improved the scientific knowledge of genome evolution in various biological systems. In the talk, I will first introduce RACCROCHE and SyntenyLink, pipelines for ancestral genome or sub-genome reconstruction, and our research on genome evolution based on genes, their syntenic orders, chromosomal gene co-occurrences, subgenome dominance in gene expressions, novel genomic variations (structural variants and transposable elements) and their relationship with plant phenomics. A particularly important application of this work is to crop species that exhibit rapid rates of evolution. By understanding genome evolution and its impact on plant phenotypes, breeders will be able to make informed decisions on how to breed crops with desired traits.
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3:30 - 4:00 pm EDTCoffee Break11th Floor Collaborative Space
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4:00 - 4:45 pm EDTIdentifiability and Reconstruction of Phylogenetic Networks11th Floor Lecture Hall
- Speaker
- Leo van Iersel, Delft University of Technology
- Session Chair
- Sebastien Roch, University of Wisconsin-Madison
Abstract
Is it possible to reconstruct the correct phylogenetic network if one is given sufficient data? This question has statistical, algebraic, combinatorial and algorithmic sides and has gained quite some interest recently. In this talk, I will discuss recent progress and major open questions related to the identifiability of semi-directed phylogenetic networks under Markov models, the usefulness of quarnets and quadratic phylogenetic invariants, algorithms for constructing the tree of blobs and for constructing level-1 networks, and the elusiveness of level-2.
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5:00 - 6:30 pm EDTReception11th Floor Collaborative Space
September 17, 2024
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9:00 - 9:45 am EDTInferring Cell Lineage Trees and Differentiation Maps for Organismal Development11th Floor Lecture Hall
- Speaker
- Benjamin Raphael, Princeton University
- Session Chair
- Tandy Warnow, University of Illinois Urbana-Champaign
Abstract
The development of a multicellular organism from a single founder cell is the result of a complex process involving growth, death, and differentiation of cells. Recent advances in genome editing and single cell sequencing technologies allow researchers to induce somatic mutations in the genome during development and to simultaneously measure induced mutations and cell state from thousands of cells. In this talk, I will describe two algorithms to infer the developmental process from such dynamic lineage tracing data. First, I will describe Startle (Star tree lineage exploration), an algorithm that reconstructs cell lineage trees from mutations induced during genome editing. Startle models the unique characteristics of the genome editing process using the star homoplasy model to overcome errors and missing data in the measured mutations. Next, I will describe our algorithm Carta to infer a cell differentiation map – a directed graph describing transitions between cell types – from single cell lineage tracing data. Carta models unmeasured progenitor cell types using the concept of a potency set and infers a cell differentiation map that balances the trade-off between the complexity of the cell differentiation map and the number of unobserved cell type transitions on the lineage tree.
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10:00 - 10:30 am EDTCoffee Break11th Floor Collaborative Space
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10:30 - 11:15 am EDTSimultaneous reconstruction of phylogenetic trees and transmission trees11th Floor Lecture Hall
- Speaker
- Caroline Colijn, Simon Fraser University
- Session Chair
- Tandy Warnow, University of Illinois Urbana-Champaign
Abstract
The utility of whole-genome sequencing for pathogens, and how informative sequence data are for outbreaks, remains unknown, and is important as public health systems around the world decide how much sequencing to undertake for infectious disease surveillance. In this talk, I introduce an MCMC method for simultaneous reconstruction of phylogenetic trees and transmission trees using sequence data for a person-to-person outbreak of an infectious disease. The method is called BREATH: Bayesian Reconstruction and Evolutionary Analysis of Transmission Histories. BREATH's transmission process accounts for a flexible natural history of infection (including a latent period if desired) and a separate process for sampling. It allows for unsampled individuals and for individuals to have diverse within-host infections. BREATH also accounts for the fact that an outbreak may still be ongoing at the time of analysis, using a recurrent events approach to account for right truncation. We perform a simulation study to verify our implementation, and apply BREATH to a previously-described 13-year outbreak of tuberculosis. We find that using a transmission process to inform the phylogenetic reconstruction results in better resolution of the phylogeny (in topology, branch length and tree height) and a more precise estimate of the time of origin of the outbreak. But even with whole-genome sequence data, considerable uncertainty remains about transmission events. An open source implementation of BREATH is available from https://github.com/rbouckaert/transmission as the BREATH package to BEAST 2.
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11:30 am - 12:15 pm EDTAnomalous Phylogenetic Networks under the Coalescent model11th Floor Lecture Hall
- Speaker
- Hector Banos, California State University San Bernardino
- Session Chair
- Tandy Warnow, University of Illinois Urbana-Champaign
Abstract
Hybridization plays a crucial role during the evolutionary process of some species. In such cases, phylogenetic trees are insufficient to describe species-level relationships. Phylogenetic networks (also known as admixture graphs in population genetics) are the objects used to represent the evolutionary histories that allow such interactions. The inference of phylogenetic networks from biological data presents many challenges, and methods have been developed under different frameworks and model assumptions to overcome some of these challenges. In this talk, we present a comprehensive overview of existing methods for estimating explicit networks (networks depicting evolutionary history) from biological data. We discuss their distinct model assumptions, framework, hypotheses, and drawbacks.
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12:30 - 2:30 pm EDTLunch/Free Time
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2:30 - 3:30 pm EDTPoster Blitz- 11th Floor Lecture Hall
- Session Chair
- John Rhodes, University of Alaska Fairbanks
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3:30 - 5:00 pm EDTPoster Session/Coffee BreakPoster Session - 11th Floor Collaborative Space
September 18, 2024
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9:00 - 9:45 am EDTSyntenic Reconciliation with Synesth: Achievements and Future Progress11th Floor Lecture Hall
- Speaker
- Nadia El-Mabrouk, Universite de Montreal
- Session Chair
- Laura Kubatko, The Ohio State University
Abstract
Synesth is one of the most comprehensive and flexible tool for tree reconciliation allowing for events on syntenies (i.e. homologous genomic regions containing multiple genes evolving together) including duplications, transfers, fissions, and transient events going through unsampled species. This model allows building histories that explicate the inconsistencies between a synteny tree (i.e. with leaves representing syntenies rather than single genes) and its associated species tree. An inductive characterization of the solution space using different algebras for each granularity (Pareto-optimal histories, Pareto-optimal event count vectors or minimum event cost histories) leads to efficient dynamic programming algorithms. We show how Synesth can be applied to infer evolutionary scenarios for CRISPR-Cas systems. We address the challenge of building a synteny tree and present FullSynesth, a generalization of Synesth rather starting from a set of gene trees. Finally, we show how this field opens the way to many unexplored algorithmic problems.
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10:00 - 10:30 am EDTCoffee Break11th Floor Collaborative Space
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10:30 - 11:15 am EDTThe Implications of Empirical Sequence Capture Studies in Birds for Large-scale Phylogenetics11th Floor Lecture Hall
- Speaker
- Edward Braun, University of Florida
- Session Chair
- Hector Banos, California State University San Bernardino
Abstract
Birds are an extensively studied clade with more than 10,000 named species. Many relationships within birds have proven to be difficult to recover in phylogenetic analyses. This difficulty reflects several factors, including discordance among gene trees, shifts in evolutionary rates, changes in the model of sequence evolution across the avian tree, and the complexity of the recombination landscape for bird genomes. There are multiple efforts to generate sequence data for all bird taxa; this talk will focus on an effort to use ultraconserved element (UCE) sequence capture to generate data for all currently recognized bird species. Analyses of UCE data for large numbers of taxa presents several challenges. More specifically, I will describe the performance of phylogenomic methods with a UCE dataset with hundreds and thousands of taxa. The methods used in these comparisons include the commonly used methods (maximum likelihood analysis of concatenated data, gene tree summary methods, and SVDquartets) as well as a “new” method called METAL (Metric algorithm for Estimation of Trees based on Aggregation of Loci). Empirical studies have obvious limitations since they represent a single realization of an evolutionary history, but they also provide information that is difficult to obtain in more controlled situations like simulations.
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11:30 am - 12:15 pm EDTA Divide-and-conquer Approach to Phylogenetic Network Inference11th Floor Lecture Hall
- Speaker
- Kristina Wicke, New Jersey Institute of Technology
- Session Chair
- Hector Banos, California State University San Bernardino
Abstract
Inference of phylogenetic networks from biological sequence data is a challenging problem, with many theoretical and practical questions still unresolved. In this talk, we introduce a novel divide-and-conquer approach for inferring level-1 networks under the network multispecies coalescent model. We first infer the “tree of blobs” of the network, in which all reticulations are collapsed into nodes. We then focus on resolving the multifurcations within this tree, which correspond to the network’s cycles, by determining an optimal cycle structure for each. Once the multifurcations are individually resolved, we combine them to obtain the full network, provided the cycles collectively allow for a rooting to exist. This method will be implemented in the R package MSCquartets, and we demonstrate its effectiveness through both simulated and empirical datasets. Additionally, we discuss some open problems and avenues for future research. This talk is based on joint work with Elizabeth Allman, Hector Baños, and John Rhodes.
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12:25 - 12:30 pm EDTGroup Photo (Immediately After Talk)11th Floor Lecture Hall
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12:30 - 2:30 pm EDTLunch/Free Time
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2:30 - 3:15 pm EDTSimplifying Two Gene-order Inference Problems11th Floor Lecture Hall
- Speaker
- Krister Swenson, National Center for Scientific Research (CNRS)
- Session Chair
- Caroline Colijn, Simon Fraser University
Abstract
Inference problems on gene-orders have suffered limited applicability due to complex models, and complications related to preprocessing the data. For instance, we lack practical ways to sample rearrangement scenarios, and traditional estimates of breakpoint re-use are highly dependent on the resolution of the syntenic blocks. We first simplify the task of counting scenarios by relating genome rearrangement scenarios to quadragulations and planar trees of a convex polygon. Next, we present an optimization problem for computing breakpoint re-use on a phylogeny, rather than between a single pair of genomes.
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3:30 - 4:00 pm EDTCoffee Break11th Floor Collaborative Space
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4:00 - 4:45 pm EDTPhylogenetic Networks with Multiple Roots11th Floor Lecture Hall
- Speaker
- Katharina Huber, University of East Anglia
- Session Chair
- Caroline Colijn, Simon Fraser University
Abstract
One of the defining properties of a (rooted) phylogenetic network is that it has a unique root. For some biological processes such as introgression between lineages where it is important to preserve lineage information, this uniqueness of the root can make a phylogenetic network too restrictive a model to appropriately account for such processes. In the form of a forest-based network and an aboreal network, this has recently led to the introduction of a multiple rooted network to represent molecular evolution. In this talk, we will first introduce these types of networks and then present some novel results for them.
September 19, 2024
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9:00 - 9:45 am EDTAlgorithms for Exploring Reticulate Evolution using Rooted Phylogenetic Networks11th Floor Lecture Hall
- Speaker
- Daniel Huson, University of Tübingen
- Session Chair
- Leo van Iersel, Delft University of Technology
Abstract
Unrooted phylogenetic networks are often used to represent evolutionary data when incompatibilities are present. Although rooted phylogenetic networks are better suited for explicitly depicting evolutionary histories that involve reticulate events, they have been rarely used in practice, due to a lack of appropriate methods for their calculation. Here we introduce PhyloFusion, a new fast and easily-applicable method for calculating rooted phylogenetic networks on sets of rooted phylogenetic trees. The algorithm can handle tens of trees on hundreds of taxa, allowing unresolved nodes (which arise when edges with low support are contracted) and missing taxa. We demonstrate how the method can be used to explore the phylogenetic relationships between different Influenza A isolates, based on gene trees built on different genome segments.
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10:00 - 10:30 am EDTCoffee Break11th Floor Collaborative Space
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10:30 - 11:15 am EDTPairwise alignment at arbitrary evolutionary distance11th Floor Lecture Hall
- Speaker
- Brandon Legried, Georgia Institute of Technology
- Session Chair
- Leo van Iersel, Delft University of Technology
Abstract
Ancestral sequence reconstruction and phylogenetic reconstruction from present-day states are two important and related problems in computational biology. Multiple sequence alignment is a tertiary task that makes important connections between these two problems. Here, we show that perfect sequence alignment with high probability is possible with a dense enough underlying phylogeny influencing the evolution of genetic sequences. New probabilistic techniques in the evolution of sequences with insertions and deletions are developed, with a view toward more general state spaces. Based on work with Louis Fan, Christine Heitsch, and Sebastien Roch.
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11:30 am - 12:15 pm EDTGeneralized Maternal/Paternal Genotype Markov Model for Single-Cell Lineages11th Floor Lecture Hall
- Speaker
- Julia Chifman, American University
- Session Chair
- Leo van Iersel, Delft University of Technology
Abstract
The advent of single-cell sequencing provides the ability to model the evolution of somatic cells within individuals. For example, inference of cell phylogenies has the potential to advance our understanding of the variation in the process of tumor progression. Phylogenetic methods have been applied in numerous ways to model the evolution of somatic cells from single-cell DNA data using single-nucleotide variants. Some methods implement a finite-sites Markov model by grouping genotypes in various ways, and such models are the focus of this presentation. Since both the maternal and paternal genomes are passed on to daughter cells during mitosis, it is appropriate to start with a phased model of maternal and paternal sequence evolution using a continuous-time Markov process. However, phased genotypes are not always observed, and only unphased genotypes are available. As a result, it is common to group pairs of heterozygous genotypes into single states, leading to an unphased model. Some methods further lump unphased genotypes, resulting in coarser processes. The process with a smaller state space corresponds to a lumped process of the original phased Markov chain and may or may not be Markovian, depending on restrictions imposed on the generator matrix. The purpose of this presentation is to explore the mathematical formulations of phased and unphased Markov processes. We hope to initiate a discussion about whether restrictions should be placed on the generator matrix when inferring tumor phylogenies in practice.
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12:30 - 2:30 pm EDTOpen Problems LunchWorking Lunch - 11th Floor Collaborative Space
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2:30 - 3:15 pm EDTTBA11th Floor Lecture Hall
- Speaker
- Siyu Chen, Princeton University
- Session Chair
- Kristina Wicke, New Jersey Institute of Technology
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3:30 - 4:00 pm EDTCoffee Break11th Floor Collaborative Space
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4:00 - 4:45 pm EDTA Sequential Monte Carlo approach to the Multispecies Coalescent11th Floor Lecture Hall
- Speaker
- Paul Lewis, University of Connecticut
- Session Chair
- Kristina Wicke, New Jersey Institute of Technology
Abstract
Sequential Monte Carlo (SMC, particle filtering) has been used successfully to sample from Bayesian posterior distributions of phylogenetic trees. Our work seeks to apply SMC to the hierarchical Bayesian Multispecies Coalescent (MSC) model. In MSC, the primary distribution of interest is the marginal species tree posterior, which is challenging because the species tree is a hyperparameter that constrains the topology and node heights of the gene trees nested within and is thus only indirectly influenced by the observed sequence data. I will discuss our approach to applying SMC to the MSC model and illustrate with results from simulated as well as empirical datasets.
September 20, 2024
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9:00 - 9:45 am EDTTree Reconstruction from Multi-state Characters11th Floor Lecture Hall
- Speaker
- Charles Semple, University of Canterbury
- Session Chair
- Julia Chifman, American University
Abstract
A central task in evolutionary biology is the construction of phylogenetic trees to represent the ancestral history of a collection of present-day taxa. The data typically used for this task are characters, which describe the attributes of the taxa under consideration. To illustrate, a particular position of aligned DNA sequences is an example of a character. The attributes (states) of this character are the subsets of taxa taking a certain nucleotide at this position. In the context of this task, many questions naturally arise. How do we decide if a collection of characters is compatible (realisable by a single tree)? Does compatibility depend on considering all of the characters in the collection simultaneously or can we do better than that? How many characters does it take to uniquely determine a phylogenetic tree? Does the answer depend on the topology of the tree? If so, how? If the characters have a bounded number of states, how does the number of characters it takes grow with respect to this bound and the number of taxa? In this talk, we investigate these questions, and discuss some old and not so old results.
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10:00 - 10:45 am EDTPhylogenomic Models from Tree Symmetries11th Floor Lecture Hall
- Speaker
- Colby Long, The College of Wooster
- Session Chair
- Julia Chifman, American University
Abstract
A model of genomic sequence evolution on a species tree should include not only a sequence substitution process, but also a coalescent process, since different sites may evolve on different gene trees due to incomplete lineage sorting. Chifman and Kubatko initiated the study of such models, leading to the development of the SVDquartets methods of species tree inference. A key observation was that symmetries in an ultrametric species tree led to symmetries in the joint distribution of bases at the taxa. In this talk, we explore the implications of such symmetry more fully, defining new models incorporating only the symmetries of this distribution, regardless of the mechanism that might have produced them. The models are thus supermodels of many standard ones with mechanistic parameterizations. We present phylogenetic invariants for the models, and discuss identifiability of species tree topologies using them.
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11:00 - 11:30 am EDTCoffee Break11th Floor Collaborative Space
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11:30 am - 12:15 pm EDTTBA11th Floor Lecture Hall
- Speaker
- Arash Jamshidpey, Columbia University
- Session Chair
- Julia Chifman, American University
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12:30 - 1:15 pm EDTAlgebra and Geometry of Phylogenetic Networks11th Floor Lecture Hall
- Speaker
- Elizabeth Gross, University of Hawai'i at Mānoa
- Session Chair
- Julia Chifman, American University
Abstract
Placing a Markov model of evolution on a phylogenetic network gives rise to a statistical model that is particularly amenable to algebraic study by representing it as an algebraic variety. For group-based Markov models, these algebraic varieties are t-varieties with rich combinatorial structure. In this talk, we will present recent results regarding the dimension and defining polynomials of these algebraic varieties. We will then discuss how these properties can be used for establishing identifiability and network inference.
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1:30 - 3:30 pm EDTLunch/Free Time
September 21, 2024
There are no events currently scheduled for September 21st.
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