The shape of things to come: Topological data analysis and biology, from molecules to organisms

Amézquita, Erik J.; Quigley, Michelle; Ophelders, Tim; Munch, Elizabeth; Chitwood, Daniel H.

doi:10.1002/dvdy.175

“…Leaf shape—a feature that is complex, conspicuous, and easily observable—is readily used to classify closely related botanical specimens, as well as to assess the developmentally or environmentally driven alterations within single plants. While the diversity of leaf shape can be recognized by specialists and communicated to others through writing, the geometric properties of leaf shape allow for the quantification of differences that we perceive visually (Amézquita et al, 2020). Furthermore, our assessment of leaf morphology is limited with individual leaves, which only allow us to observe facets of the comprehensive phenotype.…”

Section: Discussionmentioning

confidence: 99%

Composite modeling of leaf shape along shoots discriminates Vitis species better than individual leaves

Bryson

¹

,

Brown

²

,

Mullins

³

et al. 2020

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PremiseLeaf morphology is dynamic, continuously deforming during leaf expansion and among leaves within a shoot. Here, we measured the leaf morphology of more than 200 grapevines (Vitis spp.) over four years and modeled changes in leaf shape along the shoot to determine whether a composite leaf shape comprising all the leaves from a single shoot can better capture the variation and predict species identity compared with individual leaves.MethodsUsing homologous universal landmarks found in grapevine leaves, we modeled various morphological features as polynomial functions of leaf nodes. The resulting functions were used to reconstruct modeled leaf shapes across the shoots, generating composite leaves that comprehensively capture the spectrum of leaf morphologies present.ResultsWe found that composite leaves are better predictors of species identity than individual leaves from the same plant. We were able to use composite leaves to predict the species identity of previously unassigned grapevines, which were verified with genotyping.DiscussionObservations of individual leaf shape fail to capture the true diversity between species. Composite leaf shape—an assemblage of modeled leaf snapshots across the shoot—is a better representation of the dynamic and essential shapes of leaves, in addition to serving as a better predictor of species identity than individual leaves.

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“…Big data problems are often addressed using methods such as dimension reduction (e.g., clustering of expression data), latent feature extraction, or machine learning (e.g., neural networks) (Hériché et al, 2019 ). Spatially-derived patterns, such as plant anatomical structures, are typically addressed using topology and geometry (Amézquita et al, 2020 ). The identified patterns (e.g., correlation between x and y in Figure 1 ) constrain the set of possible hypotheses about mechanistic relationships that can explain these observed patterns.…”

Section: Review Of Modeling In Plant Biologymentioning

confidence: 99%

Overcoming the Challenges to Enhancing Experimental Plant Biology With Computational Modeling

Dale

¹

,

Oswald

²

,

Jalihal

³

et al. 2021

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The study of complex biological systems necessitates computational modeling approaches that are currently underutilized in plant biology. Many plant biologists have trouble identifying or adopting modeling methods to their research, particularly mechanistic mathematical modeling. Here we address challenges that limit the use of computational modeling methods, particularly mechanistic mathematical modeling. We divide computational modeling techniques into either pattern models (e.g., bioinformatics, machine learning, or morphology) or mechanistic mathematical models (e.g., biochemical reactions, biophysics, or population models), which both contribute to plant biology research at different scales to answer different research questions. We present arguments and recommendations for the increased adoption of modeling by plant biologists interested in incorporating more modeling into their research programs. As some researchers find math and quantitative methods to be an obstacle to modeling, we provide suggestions for easy-to-use tools for non-specialists and for collaboration with specialists. This may especially be the case for mechanistic mathematical modeling, and we spend some extra time discussing this. Through a more thorough appreciation and awareness of the power of different kinds of modeling in plant biology, we hope to facilitate interdisciplinary, transformative research.

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“…Big data problems are often addressed using methods such as dimension reduction (e.g., clustering of expression data), latent feature extraction, or machine learning (e.g., neural networks) [107]. Spatially-derived patterns, such as plant anatomical structures, are typically addressed using topology and geometry [60]. The identified patterns (e.g.…”

Section: Question 1: What Kinds Of Models Are There?mentioning

confidence: 99%

Overcoming the challenges to enhancing experimental plant biology with computational modeling

Dale¹,

Oswald²,

Jalihal³

et al. 2021

Preprint

0

View full text Add to dashboard Cite

The study of complex biological systems necessitates computational modeling approaches that are currently underutilized in plant biology. Many plant biologists have trouble identifying or adopting modeling methods to their research, particularly mechanistic mathematical modeling. Here we address challenges that limit the use of computational modeling methods, particularly mechanistic mathematical modeling. We divide computational modeling techniques into either pattern models (e.g., bioinformatics, machine learning, or morphology) or mechanistic mathematical models (e.g., biochemical reactions, biophysics, or population models), which both contribute to plant biology research at different scales to answer different research questions. We present arguments and recommendations for the increased adoption of modeling by plant biologists interested in incorporating more modeling into their research programs. As some researchers find math and quantitative methods to be an obstacle to modeling, we provide suggestions for easy-to-use tools for non-specialists and for collaboration with specialists. This may especially be the case for mechanistic mathematical modeling, and we spend some extra time discussing this. Through a more thorough appreciation and awareness of the power of different kinds of modeling in plant biology, we hope to facilitate interdisciplinary, transformative research.

show abstract

The shape of things to come: Topological data analysis and biology, from molecules to organisms

Cited by 49 publications

References 55 publications

Composite modeling of leaf shape along shoots discriminates Vitis species better than individual leaves

Composite modeling of leaf shape along shoots discriminates Vitis species better than individual leaves

Overcoming the Challenges to Enhancing Experimental Plant Biology With Computational Modeling

Overcoming the challenges to enhancing experimental plant biology with computational modeling

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