Arabidopsis phenotyping through geometric morphometrics

Manacorda, Carlos Augusto; Asurmendi, Sebastián

doi:10.1093/gigascience/giy073

Cited by 26 publications

(26 citation statements)

References 70 publications

(111 reference statements)

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“…The visualization of the body shape differences, associated with other groups of correlated morphological traits, allowed to obtain a clear diagnosis of sh morphology for each population [43,44]. Visualization tools might help in further study of the putative underlying mechanisms involved [45]. The result of the present study is in line with other studies based on truss analysis [4,[46][47][48][49] and geometric morphometrics [50,51] which have shown the sh species to have a distinctive morphology.…”

Section: Discussionsupporting

confidence: 83%

Morphological plasticity in a wild freshwater fish, Systomus sarana (Cyprinidae) from India: a glimpse through advanced morphometric toolkits 

Gupta

Dwivedi

Tripathi

2020

Preprint

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Background: Body morphology supposed to underpin wide differences in animal performance that can be used to understand the diversification of characters. Further, identifying the fish population with unique shape due to variations in their morphometric characters enable better management of these subunits. Advanced statistical toolkits of morphometry called truss network system and geometric morphometrics have been increasingly used for detecting variations in morphological traits between subunits of fish populations. The present study was therefore carried out with the objective of determining phenotypically distinct units of freshwater fish Systomus sarana collected from geographically isolated locations.Methods: In the present study, 154 specimens of olive barb, S. sarana were collected from four distantly located rivers covering the northern (Ganga), southern (Godavari), central (Narmada), and eastern (Mahanadi) regions of India. Truss-network system and geometric morphometrics have been utilized. Fourteen landmarks were digitized uniformly on each specimen. In the present study, the truss network system yielded size-corrected morphometric characters that were subjected to univariate and multivariate statistical assessment. Results: Analysis of variance (ANOVA) presented significant differences among 63 out of 90 variables (p<0.05). Truss approach includes principal component analysis (PCA) and discriminant function analysis (DFA) while the geometric approach includes PCA, DFA, canonical variate analysis (CVA), partial least square (PLS), the relative warp (RW), and wireframes. CVA extracted Mahalanobis and Procrustes distances among groups found to be highly significant (p<0.0001). In linear DFA, the overall assignment of correctly classified individuals into their original groups was 86.2% for Ganga, 86.1% for the Godavari, 93.9% for the Narmada, and 92.9% for the Mahanadi population. Conclusions: The results revealed significant variations in the morphometric characters which were reflected in the shape of different body features of the studied populations. Both methods revealed analogous results and significant differences among groups in examined features. Our results suggest that S. sarana shows morphological plasticity across different rivers in India. This study supports the concept that geographical isolation among fish populations can lead to morphological variations.

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Section: Discussionsupporting

confidence: 83%

Morphological plasticity in a wild freshwater fish, Systomus sarana (Cyprinidae) from India: a glimpse through advanced morphometric toolkits 

Gupta

Dwivedi

Tripathi

2020

Preprint

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“…Nevertheless, the tangent distances of specimens to the most outlying taxon, the common dolphin, were consistently slightly less than the partial Procrustes distances for the same pairwise comparisons, suggesting that there was some subtle effect of the distortion due to tangent projection for the extreme comparisons. In recent years, a number of studies have computed similar correlations between pairwise Procrustes and tangent distances among landmark configurations in diverse organisms and consistently found that these correlations were extremely close to 1.0 (Pretorius and Scholtz 2001;Polly 2002;Frost et al 2003;Fontaneto et al 2004;Lockwood et al 2004;McNulty 2004;Viscosi and Cardini 2011;Bai et al 2012;De Meulemeester et al 2012;Renner 2012;Neustupa 2013;Siver et al 2013;Ullmann et al 2017;Manacorda and Asurmedi 2018). Rohlf (1999) commented that he was not aware of any reports of biological datasets where the tangent projection did not provide a satisfactory approximation (with the exception of inadvertent inclusion of reflected specimens in the data).…”

Section: Tangent Space Approximation To Shape Spacesmentioning

confidence: 99%

Walking on Kendall’s Shape Space: Understanding Shape Spaces and Their Coordinate Systems

Klingenberg

2020

Evol Biol

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More and more analyses of biological shapes are using the techniques of geometric morphometrics based on configurations of landmarks in two or three dimensions. A fundamental concept at the core of these analyses is Kendall's shape space and local approximations to it by shape tangent spaces. Kendall's shape space is complex because it is a curved surface and, for configurations with more than three landmarks, multidimensional. This paper uses the shape space for triangles, which is the surface of a sphere, to explore and visualize some properties of shape spaces and the respective tangent spaces. Considerations about the dimensionality of shape spaces are an important step in understanding them, and can offer a coordinate system that can translate between positions in the shape space and the corresponding landmark configurations and vice versa. By simulation studies "walking" along that are great circles around the shape space, each of them corresponding to the repeated application of a particular shape change, it is possible to grasp intuitively why shape spaces are curved and closed surfaces. From these considerations and the available information on shape spaces for configurations with more than three landmarks, the conclusion emerges that the approach using a tangent space approximation in general is valid for biological datasets. The quality of approximation depends on the scale of variation in the data, but existing analyses suggest this should be satisfactory to excellent in most empirical datasets.

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“…These discoveries were only possible through the development of a technological infrastructure that allowed us to acquire genomic information at a large scale (Schuster, 2007). While many researchers have argued that phenomics -large scale phenotyping -will bring about a similar revolution in biology, most approaches for collecting high-throughput phenotypic data developed so far are system-specific and difficult to generalize (see Kristensen et al, 2008;Falkingham, 2012;Boyer et al, 2011;Hsiang et al, 2018;Manacorda and Asurmendi, 2018), with the notable exception of sub-cellular phenotypes (e.g., Clish, 2015). As a consequence, for most study systems, phenotyping methods remain low-throughput and can only be applied on a small scale (Houle, Govindaraju, and Omholt, 2010).…”

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

“…A promising way to collect high-throughput phenotypic data is to automate landmark data collection using computer vision techniques (e.g., Manacorda and Asurmendi, 2018). Automated landmarking has become the gold standard in human facial landmarking for both biomedicine (Porto et al, 2019) and, more notoriously, social networking websites and software developed for mobile phones (Kazemi and Sullivan, 2014), but its application in geometric morphometrics has remained restricted (Manacorda and Asurmendi, 2018;Vandaele et al, 2018). However, the explosion in machine learning algorithms for computer vision represents an important technological leap, which lays the foundation for the development of general methods of high-throughput high-dimensional morphometrics (Kazemi and Sullivan, 2014;He et al, 2017;Voulodimos et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

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ML-morph: A Fast, Accurate and General Approach for Automated Detection and Landmarking of Biological Structures in Images

Porto

Voje

2019

Preprint

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1. Morphometrics has become an indispensable component of the statistical analysis of size and shape variation in biological structures. Morphometric data has traditionally been gathered through lowthroughput manual landmark annotation, which represents a significant bottleneck for morphometricbased phenomics. Here we propose a machine-learning-based high-throughput pipeline to collect high-dimensional morphometric data in images of semi rigid biological structures. 2. The proposed framework has four main strengths. First, it allows for dense phenotyping with minimal impact on specimens. Second, it presents landmarking accuracy comparable to manual annotators, when applied to standardized datasets. Third, it performs data collection at speeds several orders of magnitude higher than manual annotators. And finally, it is of general applicability (i.e., not tied to a specific study system). 3. State-of-the-art validation procedures show that the method achieves low error levels when applied to three morphometric datasets of increasing complexity, with error varying from 0.5% to 2% of the structure's length in the automated placement of landmarks. As a benchmark for the speed of the entire automated landmarking pipeline, our framework places 23 landmarks on 13,686 objects (zooids) detected in 1684 pictures of fossil bryozoans in 3.12 minutes using a personal computer. 4. The proposed machine-learning-based phenotyping pipeline can greatly increase the scale, reproducibility and speed of data collection within biological research. To aid the use of the framework, we have developed a file conversion algorithm that can be used to leverage current morphometric datasets for automation, allowing the entire procedure, from model training all the way to prediction, to be performed in a matter of hours.

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Arabidopsis phenotyping through geometric morphometrics

Cited by 26 publications

References 70 publications

Morphological plasticity in a wild freshwater fish, Systomus sarana (Cyprinidae) from India: a glimpse through advanced morphometric toolkits

Morphological plasticity in a wild freshwater fish, Systomus sarana (Cyprinidae) from India: a glimpse through advanced morphometric toolkits

Walking on Kendall’s Shape Space: Understanding Shape Spaces and Their Coordinate Systems

ML-morph: A Fast, Accurate and General Approach for Automated Detection and Landmarking of Biological Structures in Images

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Arabidopsis phenotyping through geometric morphometrics

Cited by 26 publications

References 70 publications

Morphological plasticity in a wild freshwater fish,&nbsp;Systomus&nbsp;sarana&nbsp;(Cyprinidae) from India: a glimpse through advanced morphometric toolkits&nbsp;

Morphological plasticity in a wild freshwater fish,&nbsp;Systomus&nbsp;sarana&nbsp;(Cyprinidae) from India: a glimpse through advanced morphometric toolkits&nbsp;

Walking on Kendall’s Shape Space: Understanding Shape Spaces and Their Coordinate Systems

ML-morph: A Fast, Accurate and General Approach for Automated Detection and Landmarking of Biological Structures in Images

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Product

Resources

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Morphological plasticity in a wild freshwater fish, Systomus sarana (Cyprinidae) from India: a glimpse through advanced morphometric toolkits

Morphological plasticity in a wild freshwater fish, Systomus sarana (Cyprinidae) from India: a glimpse through advanced morphometric toolkits