PHENOS: a high-throughput and flexible tool for microorganism growth phenotyping on solid media

Barton, David B. H.; Georghiou, Danae; Dave, Neelam; Alghamdi, Majed; Walsh, Thomas A.; Louis, Edward J.; Foster, Steven S.

doi:10.1101/195784

Cited by 3 publications

(3 citation statements)

References 27 publications

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“…Fitness analysis was done following two different strategies, using either Phenosuite software (Singer Instruments) or the PHENOS platform (94). Details of the phenotypic analysis are given in SI Appendix, Supplementary Methods.…”

Section: Analysis Of Mitochondrial Origin In Hybridsmentioning

confidence: 99%

Restoring fertility in yeast hybrids: Breeding and quantitative genetics of beneficial traits

Naseeb

Visinoni

et al. 2021

Proc. Natl. Acad. Sci. U.S.A.

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Hybrids between species can harbor a combination of beneficial traits from each parent and may exhibit hybrid vigor, more readily adapting to new harsher environments. Interspecies hybrids are also sterile and therefore an evolutionary dead end unless fertility is restored, usually via auto-polyploidisation events. In the Saccharomyces genus, hybrids are readily found in nature and in industrial settings, where they have adapted to severe fermentative conditions. Due to their hybrid sterility, the development of new commercial yeast strains has so far been primarily conducted via selection methods rather than via further breeding. In this study, we overcame infertility by creating tetraploid intermediates of Saccharomyces interspecies hybrids to allow continuous multigenerational breeding. We incorporated nuclear and mitochondrial genetic diversity within each parental species, allowing for quantitative genetic analysis of traits exhibited by the hybrids and for nuclear–mitochondrial interactions to be assessed. Using pooled F12 generation segregants of different hybrids with extreme phenotype distributions, we identified quantitative trait loci (QTLs) for tolerance to high and low temperatures, high sugar concentration, high ethanol concentration, and acetic acid levels. We identified QTLs that are species specific, that are shared between species, as well as hybrid specific, in which the variants do not exhibit phenotypic differences in the original parental species. Moreover, we could distinguish between mitochondria-type–dependent and –independent traits. This study tackles the complexity of the genetic interactions and traits in hybrid species, bringing hybrids into the realm of full genetic analysis of diploid species, and paves the road for the biotechnological exploitation of yeast biodiversity.

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Section: Analysis Of Mitochondrial Origin In Hybridsmentioning

confidence: 99%

Restoring fertility in yeast hybrids: Breeding and quantitative genetics of beneficial traits

Naseeb

Visinoni

et al. 2021

Proc. Natl. Acad. Sci. U.S.A.

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“…A lot of work has been done to characterize the phenotypes of microbes for applications ranging from drug discovery to industrial fermentation (Demain & Sanchez, 2009; Schmidt, 2005). Numerous technologies have been developed to facilitate the generation of these data, including Biolog Phenotype MicroArrays (Bochner, 2009; Hosmer et al, 2022), robotic screening tools (Barton et al, 2018), microfluidics devices (Cario et al, 2022), imaging (Kritikos et al, 2017; Ohya et al, 2005) and multiplexed bioreactors such as the eVolver (Wong et al, 2018). However, compared to the extreme speed in the decrease of sequencing cost, measuring phenotypes is still relatively cost and labor intensive; thus, prioritizing which conditions and organisms to measure is a crucial component of experimental design.…”

Section: Introductionmentioning

confidence: 99%

Prediction of representative phenotypes using Multi-Attribute Subset Selection

Forchielli

Wang

Thommes

et al. 2022

Preprint

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Given an array of phenotypes (e.g., yield across strains and conditions), one can ask how to best choose subsets of conditions that are informative about the whole dataset, enabling efficient system identification and providing a basis vector in phenotype space. Here we introduce a mixed integer linear programming approach to choose explanatory and response variables for a phenotypic matrix. We applied the algorithm to a set of fitness measurements for 462 yeast strains under 38 carbon sources, and to the growth phenotypes of 65 marine bacteria on 11 media. The algorithm identifies environments that can be used as features to predict growth under other conditions, providing biologically interpretable metabolic axes for strain discrimination. Our approach could be used to reduce the number of experiments needed to identify a strain or to map its metabolic capabilities. The generality of the algorithm makes it appropriate for addressing subset selection problems in areas beyond biology.

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“…Although limited in scalability, liquid micro-culture assays, in which the growth curves of mutant strains are analyzed, permit characterization of dynamic growth responses as well as identification of marginal fitness phenotypes (Warringer et al 2003;Toussaint and Conconi 2006). Recent efforts have been made to improve scalability of growth curve analysis by leveraging existing genetic mutant colony array technology (Hartman and Tippery 2004;Shah et al 2007;Banks et al 2012;Zackrisson et al 2016;Barton et al 2018).…”

Section: Introductionmentioning

confidence: 99%

Genome-Wide Dynamic Evaluation of the UV-Induced DNA Damage Response

Silva

Michaca

Munson

et al. 2020

G3 Genes|Genomes|Genetics

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Genetic screens in Saccharomyces cerevisiae have allowed for the identification of many genes as sensors or effectors of DNA damage, typically by comparing the fitness of genetic mutants in the presence or absence of DNA damaging treatments. However, these static screens overlook the dynamic nature of DNA damage response pathways, missing time-dependent or transient effects. Here, we examine gene dependencies in the dynamic response to ultraviolet radiation-induced DNA damage by integrating ultra-high-density arrays of 6144 diploid gene deletion mutants with high-frequency time-lapse imaging. We identify 494 ultraviolet radiation response genes which, in addition to recovering molecular pathways and protein complexes previously annotated to DNA damage repair, include components of the CCR4-NOT complex, tRNA wobble modification, autophagy, and, most unexpectedly, 153 nuclear-encoded mitochondrial genes. Notably, mitochondria-deficient strains present time-dependent insensitivity to ultraviolet radiation, posing impaired mitochondrial function as a protective factor in the ultraviolet radiation response.

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PHENOS: a high-throughput and flexible tool for microorganism growth phenotyping on solid media

Cited by 3 publications

References 27 publications

Restoring fertility in yeast hybrids: Breeding and quantitative genetics of beneficial traits

Restoring fertility in yeast hybrids: Breeding and quantitative genetics of beneficial traits

Prediction of representative phenotypes using Multi-Attribute Subset Selection

Genome-Wide Dynamic Evaluation of the UV-Induced DNA Damage Response

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