Your search keyword '"Lawrence-Dill, Carolyn J."' showing total 5 results

1. Gene Ontology Meta Annotator for Plants (GOMAP)

Author

Wimalanathan, Kokulapalan and Lawrence-Dill, Carolyn J.

Published

2021

2. Gene function annotations for the maize NAM founder lines.

Author

Fattel, Leila, Yanarella, Colleen F., Ngara, Blessing, Johnson, Olivia T., Campbell, Darwin A., Wimalanathan, Kokulapalan, and Lawrence-Dill, Carolyn J.

Subjects

TEXT files, ANNOTATIONS, AMINO acid sequence, PLANT genomes, GENES, GENE ontology, CORN, COMPUTATIONAL neuroscience

Abstract

Objectives: We annotated the latest published sequences of the 26 Zea mays Nested Association Mapping (NAM) founder lines using GOMAP, the Gene Ontology Meta Annotator for Plants. The maize NAM panel enables researchers to understand and identify the genetic basis of complex traits. Annotations of predicted functions for genes can help researchers investigate gene-phenotype associations, prioritize candidate genes for phenotypes of interest, and formulate testable hypotheses about gene function/phenotype associations. The creation and release of high-confidence, high-coverage gene function annotation sets for the NAM founder lines is critical to accelerate the generation of knowledge in maize genetics research. GOMAP is a high-throughput computational pipeline that annotates gene functions genome-wide in plant genomes using Gene Ontology functional class terms. Here we report and share GOMAP-generated functional annotations for the NAM founder lines. Data description: Datasets include the protein sequences used as input, GOMAP-generated annotation files, scripts used to update obsolete terms, and GAF-formatted tab-delimited text files of gene function annotations along with README files that describe formatting, content, and how files relate to each other. [ABSTRACT FROM AUTHOR]

Published

2024

3. Standardized genome-wide function prediction enables comparative functional genomics: a new application area for Gene Ontologies in plants.

Author

Fattel, Leila, Psaroudakis, Dennis, Yanarella, Colleen F, Chiteri, Kevin O, Dostalik, Haley A, Joshi, Parnal, Starr, Dollye C, Vu, Ha, Wimalanathan, Kokulapalan, and Lawrence-Dill, Carolyn J

Subjects

FUNCTIONAL genomics, COMPARATIVE genomics, PLANT genes, PLANT genomes, GENE ontology, GENOMES

Abstract

Background Genome-wide gene function annotations are useful for hypothesis generation and for prioritizing candidate genes potentially responsible for phenotypes of interest. We functionally annotated the genes of 18 crop plant genomes across 14 species using the GOMAP pipeline. Results By comparison to existing GO annotation datasets, GOMAP-generated datasets cover more genes, contain more GO terms, and are similar in quality (based on precision and recall metrics using existing gold standards as the basis for comparison). From there, we sought to determine whether the datasets across multiple species could be used together to carry out comparative functional genomics analyses in plants. To test the idea and as a proof of concept, we created dendrograms of functional relatedness based on terms assigned for all 18 genomes. These dendrograms were compared to well-established species-level evolutionary phylogenies to determine whether trees derived were in agreement with known evolutionary relationships, which they largely are. Where discrepancies were observed, we determined branch support based on jackknifing then removed individual annotation sets by genome to identify the annotation sets causing unexpected relationships. Conclusions GOMAP-derived functional annotations used together across multiple species generally retain sufficient biological signal to recover known phylogenetic relationships based on genome-wide functional similarities, indicating that comparative functional genomics across species based on GO data holds promise for generating novel hypotheses about comparative gene function and traits. [ABSTRACT FROM AUTHOR]

Published

2022

4. Genome-wide association studies from spoken phenotypic descriptions: a proof of concept from maize field studies.

Author

Yanarella, Colleen F, Fattel, Leila, and Lawrence-Dill, Carolyn J

Subjects

*GENOME-wide association studies, *FIELD research, *GENE ontology, *PHENOTYPES, *PLANTING, *CORN

Abstract

We present a novel approach to genome-wide association studies (GWAS) by leveraging unstructured, spoken phenotypic descriptions to identify genomic regions associated with maize traits. Utilizing the Wisconsin Diversity panel, we collected spoken descriptions of Zea mays ssp. mays traits, converting these qualitative observations into quantitative data amenable to GWAS analysis. First, we determined that visually striking phenotypes could be detected from unstructured spoken phenotypic descriptions. Next, we developed two methods to process the same descriptions to derive the trait plant height, a well-characterized phenotypic feature in maize: (1) a semantic similarity metric that assigns a score based on the resemblance of each observation to the concept of 'tallness' and (2) a manual scoring system that categorizes and assigns values to phrases related to plant height. Our analysis successfully corroborated known genomic associations and uncovered novel candidate genes potentially linked to plant height. Some of these genes are associated with gene ontology terms that suggest a plausible involvement in determining plant stature. This proof-of-concept demonstrates the viability of spoken phenotypic descriptions in GWAS and introduces a scalable framework for incorporating unstructured language data into genetic association studies. This methodology has the potential not only to enrich the phenotypic data used in GWAS and to enhance the discovery of genetic elements linked to complex traits but also to expand the repertoire of phenotype data collection methods available for use in the field environment. [ABSTRACT FROM AUTHOR]

Published

2024

5. Maize GO Annotation—Methods, Evaluation, and Review (maize‐GAMER).

Author

Wimalanathan, Kokulapalan, Friedberg, Iddo, Andorf, Carson M., and Lawrence‐Dill, Carolyn J.

Abstract

We created a new high‐coverage, robust, and reproducible functional annotation of maize protein‐coding genes based on Gene Ontology (GO) term assignments. Whereas the existing Phytozome and Gramene maize GO annotation sets only cover 41% and 56% of maize protein‐coding genes, respectively, this study provides annotations for 100% of the genes. We also compared the quality of our newly derived annotations with the existing Gramene and Phytozome functional annotation sets by comparing all three to a manually annotated gold standard set of 1,619 genes where annotations were primarily inferred from direct assay or mutant phenotype. Evaluations based on the gold standard indicate that our new annotation set is measurably more accurate than those from Phytozome and Gramene. To derive this new high‐coverage, high‐confidence annotation set, we used sequence similarity and protein domain presence methods as well as mixed‐method pipelines that were developed for the Critical Assessment of Function Annotation (CAFA) challenge. Our project to improve maize annotations is called maize‐GAMER (GO Annotation Method, Evaluation, and Review), and the newly derived annotations are accessible via MaizeGDB (http://download.maizegdb.org/maize-GAMER) and CyVerse (B73 RefGen_v3 5b+ at doi.org/10.7946/P2S62P and B73 RefGen_v4 Zm00001d.2 at doi.org/10.7946/P2M925). [ABSTRACT FROM AUTHOR]

Published

2018