Jonathan S. Renk scite author profile

Jonathan S. Renk

5Publications

65Citation Statements Received

490Citation Statements Given

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University of Minnesota

Publications

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Whole-genome variation of transposable element insertions in a maize diversity panel

Qiu

O’Connor

Coletta

et al. 2021

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Intact transposable elements (TEs) account for 65% of the maize genome and can impact gene function and regulation. Although TEs comprise the majority of the maize genome and affect important phenotypes, genome wide patterns of TE polymorphisms in maize have only been studied in a handful of maize genotypes, due to the challenging nature of assessing highly repetitive sequences. We implemented a method to use short read sequencing data from 509 diverse inbred lines to classify the presence/absence of 445,418 non-redundant TEs that were previously annotated in four genome assemblies including B73, Mo17, PH207, and W22. Different orders of TEs (i.e. LTRs, Helitrons, TIRs) had different frequency distributions within the population. LTRs with lower LTR similarity were generally more frequent in the population than LTRs with higher LTR similarity, though high frequency insertions with very high LTR similarity were observed. LTR similarity and frequency estimates of nested elements and the outer elements in which they insert revealed that most nesting events occurred very near the timing of the outer element insertion. TEs within genes were at higher frequency than those that were outside of genes and this is particularly true for those not inserted into introns. Many TE insertional polymorphisms observed in this population were tagged by SNP markers. However, there were also 19.9% of the TE polymorphisms that were not well tagged by SNPs (R2 < 0.5) that potentially represent information that has not been well captured in previous SNP based marker-trait association studies. This study provides a population scale genome-wide assessment of TE variation in maize, and provides valuable insight on variation in TEs in maize and factors that contribute to this variation.

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Whole Genome Variation of Transposable Element Insertions in a Maize Diversity Panel

Qiu

O’Connor

Coletta

et al. 2020

Preprint

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Intact transposable elements (TEs) account for 65% of the maize genome and can impact gene function and regulation. Although TEs comprise the majority of the maize genome and affect important phenotypes, genome wide patterns of TE polymorphisms in maize have only been studied in a handful of maize genotypes, due in part to the challenging nature of assessing highly repetitive sequences. We implemented a method to use short read sequencing data from 509 diverse inbred lines to classify the presence/absence of 494,564 non-redundant TEs that were previously annotated in four genome assemblies including B73, Mo17, PH207, and W22. Different orders of TEs (i.e. LTRs, Helitrons, TIRs) had different frequency distributions within the population. Across the different orders, TE family size was negatively correlated with average population frequency of TEs in the family and nested TEs are at lower frequency than non-nested TEs. Age of LTR elements was positively correlated with population frequency. Comparison with SNP data revealed that while a majority of TEs are tagged by nearby SNPs (r2 > 0.9) there are also many TEs in low to moderate linkage disequilibrium with nearby SNPs. This study provides a population scale genome-wide assessment of TE variation in maize, and provides valuable insight on variation in TEs in maize and factors that contribute to this variation.

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Genetic control of kernel compositional variation in a maize diversity panel

et al. 2021

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Maize (Zea mays L.) is a multi-purpose row crop grown worldwide, which, over time, has often been bred for increased yield at the detriment of lower composition grain quality. Some knowledge of the genetic factors that affect quality traits has been discovered through the study of classical maize mutants; however, much of the underlying genetic control of these traits and the interaction between these traits remains unknown. To better understand variation that exists for grain compositional traits in maize, we evaluated 501 diverse temperate maize inbred lines in five unique environments and predicted 16 compositional traits (e.g., carbohydrates, protein, and starch) based on the output of near-infrared (NIR) spectroscopy. Phenotypic analysis found substantial variation for compositional traits and the majority of variation was explained by genetic and environmental factors. Correlations and trade-offs among traits in different maize types (e.g., dent, sweetcorn, and popcorn) were explored, and significant differences and meaningful correlations were detected. In total, 22.9-71.0% of the phenotypic variation across these traits could be explained using 2,386,666 single nucleotide polymorphism (SNP) markers generated from whole-genome resequencing data. A genome-wide association study (GWAS) was conducted using these same markers and found 72 statistically significant SNPs for 11 compositional traits. This study provides valuable insights in the phenotypic variation and genetic control underlying compositional traits that can be used in breeding programs for improving maize grain quality.

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Food‐Grade Maize Composition, Evaluation, and Genetics for Masa‐Based Products

Holmes¹,

Renk²,

Coaldrake

et al. 2019

Crop Science

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Maize (Zea mays L.) masa (dough or flour that is soaked and cooked in an alkaline solution in the nixtamlization process) based products have been consumed by humans worldwide for thousands of years. Still, there is not a comprehensive understanding of the chemical and physical properties of maize that contribute to masa quality. Starches and proteins affect the alkaline processing of maize but are seldom discussed in a holistic way to understand their individual and combined effects on masa production, particularly in the context of the entire food system from breeding to evaluation to product development and production. In this review, the food‐grade maize production chain is described including current breeding efforts and grain evaluation methods. The compositions of starches and prolamin proteins are also discussed relative to their effect on masa properties. Understanding the interactions of grain endosperm components and final product quality of maize masa‐based products will allow for more efficient breeding and food processing operations in the future.

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Predicting moisture content during maize nixtamalization using machine learning with NIR spectroscopy

et al. 2021

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Jonathan S. Renk

Whole-genome variation of transposable element insertions in a maize diversity panel

Whole Genome Variation of Transposable Element Insertions in a Maize Diversity Panel

Genetic control of kernel compositional variation in a maize diversity panel

Food‐Grade Maize Composition, Evaluation, and Genetics for Masa‐Based Products

Predicting moisture content during maize nixtamalization using machine learning with NIR spectroscopy

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