Widespread Impact of Chromosomal Inversions on Gene Expression Uncovers Robustness via Phenotypic Buffering

Naseeb, Samina; Carter, Zorana; Minnis, David; Donaldson, Ian J.; Zeef, Leo; Delneri, Daniela

doi:10.1093/molbev/msw045

Cited by 36 publications

(43 citation statements)

References 126 publications

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“…Although inversions can be engineered for proof of function in some organisms 30 , this is infeasible in Boechera . However, the KB model predicts that relatives of the ancestral haplotype that gave rise to the inversion might still exist as non-inverted genotypes nearby.…”

Section: Qtls Within the Inversionmentioning

confidence: 99%

Young inversion with multiple linked QTLs under selection in a hybrid zone

et al. 2017

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Fixed chromosomal inversions can reduce gene flow and promote speciation in two ways: by suppressing recombination and by carrying locally favored alleles at multiple loci. However, it is unknown whether favored mutations slowly accumulate on older inversions or if young inversions spread because they capture preexisting adaptive Quantitative Trait Loci (QTLs). By genetic mapping, chromosome painting and genome sequencing we have identified a major inversion controlling ecologically important traits in Boechera stricta. The inversion arose since the last glaciation and subsequently reached local high frequency in a hybrid speciation zone. Furthermore, the inversion shows signs of positive directional selection. To test whether the inversion could have captured existing, linked QTLs, we crossed standard, collinear haplotypes from the hybrid zone and found multiple linked phenology QTLs within the inversion region. These findings provide the first direct evidence that linked, locally adapted QTLs may be captured by young inversions during incipient speciation.

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Section: Qtls Within the Inversionmentioning

confidence: 99%

Young inversion with multiple linked QTLs under selection in a hybrid zone

et al. 2017

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“…Identification of this translocation required reads to span at least 12 Kbp due to the large repetitive elements surrounding the translocation breakpoints, explaining why it was previously undetected. While the translocation did not disrupt any coding sequence and is unlikely to cause phenotypical changes (Naseeb et al 2016), there may be decreased spore viability upon mating with other CEN.PK strains. Our ability to detect structural heterogeneity within a culture shows that nanopore sequencing could also be valuable in detecting structural variation within a genome between different chromosome copies, which occurs frequently in aneuploid yeast genomes (Gorter de Vries, Pronk and Daran 2017).…”

Section: Discussionmentioning

confidence: 89%

Nanopore sequencing enables near-completede novoassembly ofSaccharomyces cerevisiaereference strain CEN.PK113-7D

Salazar

Vries

Broek

et al. 2017

Preprint

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The haploid Saccharomyces cerevisiae strain CEN.PK113-7D is a popular model system for metabolic engineering and systems biology research. Current genome assemblies are based on short-read sequencing data scaffolded based on homology to strain S288C. However, these assemblies contain large sequence gaps, particularly in subtelomeric regions, and the assumption of perfect homology to S288C for scaffolding introduces bias. In this study, we obtained a near-complete genome assembly of CEN.PK113-7D using only Oxford Nanopore Technology's MinION sequencing platform. Fifteen of the 16 chromosomes, the mitochondrial genome and the 2-μm plasmid are assembled in single contigs and all but one chromosome starts or ends in a telomere repeat. This improved genome assembly contains 770 Kbp of added sequence containing 248 gene annotations in comparison to the previous assembly of CEN.PK113-7D. Many of these genes encode functions determining fitness in specific growth conditions and are therefore highly relevant for various industrial applications. Furthermore, we discovered a translocation between chromosomes III and VIII that caused misidentification of a MAL locus in the previous CEN.PK113-7D assembly. This study demonstrates the power of long-read sequencing by providing a high-quality reference assembly and annotation of CEN.PK113-7D and places a caveat on assumed genome stability of microorganisms.

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“…It has been shown that S. cerevisiae strains carrying single gene inversions can cause fitness defects in nutrient‐limited media (Naseeb & Delneri, ). However, large chromosomal inversions in S. cerevisiae can be either lethal or neutral depending upon the environmental conditions (Naseeb et al, ). Similar findings were observed by Avelar et al () in S. pombe , showing that inversions and translocations can have beneficial or deleterious growth affects for both meiotic and mitotic fitness.…”

Section: Cre‐loxp Mediated Recombinationmentioning

confidence: 99%

“…Therefore, by the action of the Cre recombinase, the selectable marker can be rescued, leaving only one loxP 'scar' in the genome. The key benefit of this system is that the Cre recombinase can catalyse either multiple gene deletions (Akada et al, 2006), inversions (Naseeb et al, 2016;Naseeb & Delneri, 2012) or translocations of a chromosomal fragment (Delneri et al, 2003) depending on the orientation and location of loxP sequences flanking that fragment. When multiple deletions is the objective of the study, the availability of multiple different loxP sequences (Carter & Delneri, 2010) Overview of the yeast genome editing methods described here.…”

Section: Cre-loxp Mediated Recombinationmentioning

confidence: 99%

“…Alternatively, the Cas9 gene is integrated into the yeast genome and the gRNA is delivered on a plasmid. After expression, the gRNA locates the target sequence and the endonuclease cleaves the foreign DNA that subsequently leads to either NHEJ or HR events [Colour figure can be viewed at wileyonlinelibrary.com] large chromosomal inversions in S. cerevisiae can be either lethal or neutral depending upon the environmental conditions (Naseeb et al, 2016). Similar findings were observed by Avelar et al (2013) in S. pombe, showing that inversions and translocations can have beneficial or deleterious growth affects for both meiotic and mitotic fitness.…”

Section: Cre-loxp Mediated Recombinationmentioning

confidence: 99%

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History of genome editing in yeast

Fraczek

Naseeb

Delneri

2018

Yeast

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For thousands of years humans have used the budding yeast Saccharomyces cerevisiae for the production of bread and alcohol; however, in the last 30–40 years our understanding of the yeast biology has dramatically increased, enabling us to modify its genome. Although S. cerevisiae has been the main focus of many research groups, other non‐conventional yeasts have also been studied and exploited for biotechnological purposes. Our experiments and knowledge have evolved from recombination to high‐throughput PCR‐based transformations to highly accurate CRISPR methods in order to alter yeast traits for either research or industrial purposes. Since the release of the genome sequence of S. cerevisiae in 1996, the precise and targeted genome editing has increased significantly. In this ‘Budding topic’ we discuss the significant developments of genome editing in yeast, mainly focusing on Cre‐loxP mediated recombination, delitto perfetto and CRISPR/Cas.

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Widespread Impact of Chromosomal Inversions on Gene Expression Uncovers Robustness via Phenotypic Buffering

Cited by 36 publications

References 126 publications

Young inversion with multiple linked QTLs under selection in a hybrid zone

Young inversion with multiple linked QTLs under selection in a hybrid zone

Nanopore sequencing enables near-completede novoassembly ofSaccharomyces cerevisiaereference strain CEN.PK113-7D

History of genome editing in yeast

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