Your search keyword '"Cokus, Shawn"' showing total 7 results

1. High-quality genome and methylomes illustrate features underlying evolutionary success of oaks.

Author

Sork, Victoria L., Cokus, Shawn J., Fitz-Gibbon, Sorel T., Zimin, Aleksey V., Puiu, Daniela, Garcia, Jesse A., Gugger, Paul F., Henriquez, Claudia L., Zhen, Ying, Lohmueller, Kirk E., Pellegrini, Matteo, and Salzberg, Steven L.

Subjects

BIOLOGICAL fitness, GENETIC variation, PHENOTYPIC plasticity, DNA methylation, GENE mapping, GENOTYPE-environment interaction

Abstract

The genus Quercus, which emerged ∼55 million years ago during globally warm temperatures, diversified into ∼450 extant species. We present a high-quality de novo genome assembly of a California endemic oak, Quercus lobata, revealing features consistent with oak evolutionary success. Effective population size remained large throughout history despite declining since early Miocene. Analysis of 39,373 mapped protein-coding genes outlined copious duplications consistent with genetic and phenotypic diversity, both by retention of genes created during the ancient γ whole genome hexaploid duplication event and by tandem duplication within families, including numerous resistance genes and a very large block of duplicated DUF247 genes, which have been found to be associated with self-incompatibility in grasses. An additional surprising finding is that subcontext-specific patterns of DNA methylation associated with transposable elements reveal broadly-distributed heterochromatin in intergenic regions, similar to grasses. Collectively, these features promote genetic and phenotypic variation that would facilitate adaptability to changing environments. The genus Quercus (oaks) has diversified into over 450 species which often play dominant roles in the ecosystems in which they occur. Here the authors present a genome and methylome for a California endemic oak, Quercus lobata, and describe features relevant to its evolutionary success. [ABSTRACT FROM AUTHOR]

Published

2022

2. Association of transcriptome-wide sequence variation with climate gradients in valley oak ( Quercus lobata).

Author

Gugger, Paul, Cokus, Shawn, and Sork, Victoria

Subjects

VALLEY oak, NUCLEOTIDE sequence, BIOLOGICAL evolution, NATURAL selection, SINGLE nucleotide polymorphisms, PLANTS

Abstract

A fundamental goal of evolutionary biology is to understand how environment shapes genetic variation through its effect on demographic processes and through natural selection. In non-model species, transcriptome sequencing generates large single nucleotide polymorphism (SNP) panels to disentangle these influences. Quercus lobata (valley oak) offers an excellent system for such analyses because it has stably occupied a climatically heterogeneous landscape throughout California. We used 220,427 diallelic SNPs from 22 individuals identified against a recently assembled reference transcriptome to (1) quantify transcriptome-wide associations of SNPs with climate indicative of demographic responses to climate, (2) identify SNPs especially associated with climate and thus potential targets of natural selection, and (3) test the hypothesis that genetic diversity is high in climate-adaptive candidate genes. Constrained ordinations (redundancy analysis) and variance partitioning showed that genetic structure in Q. lobata was explained by spatial location (49 %) and climate (24 %), especially minimum temperature and summer/spring precipitation balance, suggesting that climate influences neutral demographic processes and gene flow. After accounting for underlying structure, individual-based environmental association analyses identified 79 SNPs from 49 transcripts as candidates under natural selection by climate. These candidate genes had significantly higher SNP rates per base pair per locus ( θ), nucleotide diversity ( π), and gene diversity ( G) than non-candidate genes. These results provide preliminary support for the hypothesis that balancing selection maintains diversity in climate-adaptive genes. Climate has likely shaped both population demography and local adaptation in valley oak. [ABSTRACT FROM AUTHOR]

Published

2016

3. Relationship between nucleosome positioning and DNA methylation.

Author

Chodavarapu, Ramakrishna K., Feng, Suhua, Bernatavichute, Yana V., Pao-Yang Chen, Stroud, Hume, Yu, Yanchun, Hetzel, Jonathan A., Kuo, Frank, Kim, Jin, Cokus, Shawn J., Casero, David, Bernal, Maria, Huijser, Peter, Clark, Amander T., Krämer, Ute, Merchant, Sabeeha S., Zhang, Xiaoyu, Jacobsen, Steven E., and Pellegrini, Matteo

Subjects

METHYLATION, ARABIDOPSIS thaliana, DNA, PLANT genetics, RNA polymerases, METHYLTRANSFERASES, CELL nuclei, HISTONES, GENOMES, EXONS (Genetics), INTRONS

Abstract

Nucleosomes compact and regulate access to DNA in the nucleus, and are composed of approximately 147 bases of DNA wrapped around a histone octamer. Here we report a genome-wide nucleosome positioning analysis of Arabidopsis thaliana using massively parallel sequencing of mononucleosomes. By combining this data with profiles of DNA methylation at single base resolution, we identified 10-base periodicities in the DNA methylation status of nucleosome-bound DNA and found that nucleosomal DNA was more highly methylated than flanking DNA. These results indicate that nucleosome positioning influences DNA methylation patterning throughout the genome and that DNA methyltransferases preferentially target nucleosome-bound DNA. We also observed similar trends in human nucleosomal DNA, indicating that the relationships between nucleosomes and DNA methyltransferases are conserved. Finally, as has been observed in animals, nucleosomes were highly enriched on exons, and preferentially positioned at intron–exon and exon–intron boundaries. RNA polymerase II (Pol II) was also enriched on exons relative to introns, consistent with the hypothesis that nucleosome positioning regulates Pol II processivity. DNA methylation is also enriched on exons, consistent with the targeting of DNA methylation to nucleosomes, and suggesting a role for DNA methylation in exon definition. [ABSTRACT FROM AUTHOR]

Published

2010

4. Genome-wide erasure of DNA methylation in mouse primordial germ cells is affected by AID deficiency.

Author

Popp, Christian, Dean, Wendy, Feng, Suhua, Cokus, Shawn J., Andrews, Simon, Pellegrini, Matteo, Jacobsen, Steven E., and Reik, Wolf

Subjects

DNA, METHYLATION, GERM cells, GENETICS, GENOMES, EMBRYOS, GENETIC mutation, ESCHERICHIA coli, TISSUES

Abstract

Epigenetic reprogramming including demethylation of DNA occurs in mammalian primordial germ cells (PGCs) and in early embryos, and is important for the erasure of imprints and epimutations, and the return to pluripotency. The extent of this reprogramming and its molecular mechanisms are poorly understood. We previously showed that the cytidine deaminases AID and APOBEC1 can deaminate 5-methylcytosine in vitro and in Escherichia coli, and in the mouse are expressed in tissues in which demethylation occurs. Here we profiled DNA methylation throughout the genome by unbiased bisulphite next generation sequencing in wild-type and AID-deficient mouse PGCs at embryonic day (E)13.5. Wild-type PGCs revealed marked genome-wide erasure of methylation to a level below that of methylation deficient (Np95-/-, also called Uhrf1-/-) embryonic stem cells, with female PGCs being less methylated than male ones. By contrast, AID-deficient PGCs were up to three times more methylated than wild-type ones; this substantial difference occurred throughout the genome, with introns, intergenic regions and transposons being relatively more methylated than exons. Relative hypermethylation in AID-deficient PGCs was confirmed by analysis of individual loci in the genome. Our results reveal that erasure of DNA methylation in the germ line is a global process, hence limiting the potential for transgenerational epigenetic inheritance. AID deficiency interferes with genome-wide erasure of DNA methylation patterns, indicating that AID has a critical function in epigenetic reprogramming and potentially in restricting the inheritance of epimutations in mammals. [ABSTRACT FROM AUTHOR]

Published

2010

5. ATXR5 and ATXR6 are H3K27 monomethyltransferases required for chromatin structure and gene silencing.

Author

Jacob, Yannick, Suhua Feng, LeBlanc, Chantal A., Bernatavichute, Yana V., Stroud, Hume, Cokus, Shawn, Johnson, Lianna M., Pellegrini, Matteo, Jacobsen, Steven E., and Michaels, Scott D.

Subjects

METHYLTRANSFERASES, ARABIDOPSIS thaliana, DNA, METHYLATION, CHROMATIN, NUCLEOPROTEINS, GENETIC mutation

Abstract

Constitutive heterochromatin in Arabidopsis thaliana is marked by repressive chromatin modifications, including DNA methylation, histone H3 dimethylation at Lys9 (H3K9me2) and monomethylation at Lys27 (H3K27me1). The enzymes catalyzing DNA methylation and H3K9me2 have been identified; alterations in these proteins lead to reactivation of silenced heterochromatic elements. The enzymes responsible for heterochromatic H3K27me1, in contrast, remain unknown. Here we show that the divergent SET-domain proteins ARABIDOPSIS TRITHORAX-RELATED PROTEIN 5 (ATXR5) and ATXR6 have H3K27 monomethyltransferase activity, and atxr5 atxr6 double mutants have reduced H3K27me1 in vivo and show partial heterochromatin decondensation. Mutations in atxr5 and atxr6 also lead to transcriptional activation of repressed heterochromatic elements. Notably, H3K9me2 and DNA methylation are unaffected in double mutants. These results indicate that ATXR5 and ATXR6 form a new class of H3K27 methyltransferases and that H3K27me1 represents a previously uncharacterized pathway required for transcriptional repression in Arabidopsis. [ABSTRACT FROM AUTHOR]

Published

2009

6. Shotgun bisulphite sequencing of the Arabidopsis genome reveals DNA methylation patterning.

Author

Cokus, Shawn J., Feng, Suhua, Zhang, Xiaoyu, Chen, Zugen, Merriman, Barry, Haudenschild, Christian D., Pradhan, Sriharsa, Nelson, Stanley F., Pellegrini, Matteo, and Jacobsen, Steven E.

Subjects

*ARABIDOPSIS thaliana, *NUCLEIC acids, *GENE expression, *GENETIC regulation, *MOBILE genetic elements, *GENE silencing, *DNA microarrays, *BIOSYNTHESIS, *MOLECULAR genetics

Abstract

Cytosine DNA methylation is important in regulating gene expression and in silencing transposons and other repetitive sequences. Recent genomic studies in Arabidopsis thaliana have revealed that many endogenous genes are methylated either within their promoters or within their transcribed regions, and that gene methylation is highly correlated with transcription levels. However, plants have different types of methylation controlled by different genetic pathways, and detailed information on the methylation status of each cytosine in any given genome is lacking. To this end, we generated a map at single-base-pair resolution of methylated cytosines for Arabidopsis, by combining bisulphite treatment of genomic DNA with ultra-high-throughput sequencing using the Illumina 1G Genome Analyser and Solexa sequencing technology. This approach, termed BS-Seq, unlike previous microarray-based methods, allows one to sensitively measure cytosine methylation on a genome-wide scale within specific sequence contexts. Here we describe methylation on previously inaccessible components of the genome and analyse the DNA methylation sequence composition and distribution. We also describe the effect of various DNA methylation mutants on genome-wide methylation patterns, and demonstrate that our newly developed library construction and computational methods can be applied to large genomes such as that of mouse. [ABSTRACT FROM AUTHOR]

Published

2008

7. MTHFD1 controls DNA methylation in Arabidopsis.

Author

Groth, Martin, Moissiard, Guillaume, Wirtz, Markus, Wang, Haifeng, Garcia-Salinas, Carolina, Ramos-Parra, Perla A., Bischof, Sylvain, Feng, Suhua, Cokus, Shawn J., John, Amala, Smith, Danielle C., Zhai, Jixian, Hale, Christopher J., Long, Jeff A., Hell, Ruediger, Díaz de la Garza, Rocío I., and Jacobsen, Steven E.

Published

2016