How well do you know your mutation? Complex effects of genetic background on expressivity, complementation, and ordering of allelic effects

Chandler, Christopher H.; Chari, Sudarshan; Kowalski, Alycia; Choi, Lin; Tack, David C.; DeNieu, Michael; Pitchers, William; Sonnenschein, Anne; Marvin, Leslie; Hummel, Kristen; Marier, Christian; Victory, Andrew; Porter, Cody K.; Mammel, Anna; Holms, Julie; Sivaratnam, Gayatri; Dworkin, Ian

doi:10.1371/journal.pgen.1007075

Cited by 47 publications

(32 citation statements)

References 66 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…We noted a high degree of variations, however, between independent experiments as well as between lines with formally identical genetic background. Similarly, high variability was observed amongst the three controls N 5419 /+ (derived from N 5419 /FM7c x Oregon R), N 5419 / y 1 w 67c23 , and N 5419 /+; Su(H) gwt /+ ( Fig 3 ) in line with the background sensitivity of N phenotypes [ 6 , 41 – 44 ]. In fact, Su(H) attP did not vary significantly from these controls, and neither did Su(H) LLF .…”

Section: Resultssupporting

confidence: 57%

“…Notch mutants were originally picked up by their characteristic notched wing phenotype observed in heterozygous females [ 6 , 39 ] ( Fig 3 ). This phenotype is exquisitely sensitive to genetic background [ 6 , 39 – 41 ], and can be completely rescued by reducing the gene dose of Delta or Hairless [ 42 – 44 ]. We reasoned that H-binding deficient Su(H) alleles might behave similar to H mutants in this context, as we expected them to gain Notch activity, whereas Su(H) null alleles were expected to enhance loss of Notch activity.…”

Section: Resultsmentioning

confidence: 99%

See 1 more Smart Citation

Complex genetic interactions of novel Suppressor of Hairless alleles deficient in co-repressor binding

Preiss¹,

Nagel²,

Heiko³

et al. 2018

PLoS ONE

View full text Add to dashboard Cite

Throughout the animal kingdom, the Notch signalling pathway allows cells to acquire diversified cell fates. Notch signals are translated into activation of Notch target genes by CSL transcription factors. In the absence of Notch signals, CSL together with co-repressors functions as a transcriptional repressor. In Drosophila, repression of Notch target genes involves the CSL homologue Suppressor of Hairless (Su(H)) and the Notch (N) antagonist Hairless (H) that together form a repressor complex. Guided by crystal structure, three mutations Su(H)LL, Su(H)LLF and Su(H)LLL were generated that specifically affect interactions with the repressor H, and were introduced into the endogenous Su(H) locus by gene engineering. In contrast to the wild type isoform, these Su(H) mutants are incapable of repressor complex formation. Accordingly, Notch signalling activity is dramatically elevated in the homozygotes, resembling complete absence of H activity. It was noted, however, that heterozygotes do not display a dominant H loss of function phenotype. In this work we addressed genetic interactions the three H-binding deficient Su(H) mutants display in combination with H and N null alleles. We included a null mutant of Delta (Dl), encoding the ligand of the Notch receptor, as well as of Su(H) itself in our genetic analyses. H, N or Dl mutations cause dominant wing phenotypes that are sensitive to gene dose of the others. Moreover, H heterozygotes lack bristle organs and develop bristle sockets instead of shafts. The latter phenotype is suppressed by Su(H) null alleles but not by H-binding deficient Su(H) alleles which we attribute to the socket cell specific activity of Su(H). Modification of the dominant wing phenotypes of either H, N or Dl, however, suggested some lack of repressor activity in the Su(H) null allele and likewise in the H-binding deficient Su(H) alleles. Overall, Su(H) mutants are recessive perhaps reflecting self-adjusting availability of Su(H) protein.

show abstract

Section: Resultssupporting

confidence: 57%

Section: Resultsmentioning

confidence: 99%

Complex genetic interactions of novel Suppressor of Hairless alleles deficient in co-repressor binding

Preiss¹,

Nagel²,

Heiko³

et al. 2018

PLoS ONE

View full text Add to dashboard Cite

show abstract

“…To confirm the specificity of the UGT72E3 gene mutation effect and evaluate a possible functional redundancy with UGT72E1 and UGT72E2 , lignin was quantified in the double ugt72e1,2 mutant used as a control. Indeed, mutant complementation is often used to gain knowledge on the role of a particular gene, but has many disadvantages such as position effect of the T-DNA [ 32 ] carrying the non-mutated gene along with the variability of transgene expression by RNA sensing mechanisms [ 33 ] but also possible influences of environmental parameters [ 34 ].…”

Section: Resultsmentioning

confidence: 99%

UDP-GLYCOSYLTRANSFERASE 72E3 Plays a Role in Lignification of Secondary Cell Walls in Arabidopsis

Baldacci‐Cresp

Roy

Huss

et al. 2020

IJMS

View full text Add to dashboard Cite

Lignin is present in plant secondary cell walls and is among the most abundant biological polymers on Earth. In this work we investigated the potential role of the UGT72E gene family in regulating lignification in Arabidopsis. Chemical determination of floral stem lignin contents in ugt72e1, ugt72e2, and ugt72e3 mutants revealed no significant differences compared to WT plants. In contrast, the use of a novel safranin O ratiometric imaging technique indicated a significant increase in the cell wall lignin content of both interfascicular fibers and xylem from young regions of ugt72e3 mutant floral stems. These results were globally confirmed in interfascicular fibers by Raman microspectroscopy. Subsequent investigation using a bioorthogonal triple labelling strategy suggested that the augmentation in lignification was associated with an increased capacity of mutant cell walls to incorporate H-, G-, and S-monolignol reporters. Expression analysis showed that this increase was associated with an up-regulation of LAC17 and PRX71, which play a key role in lignin polymerization. Altogether, these results suggest that UGT72E3 can influence the kinetics of lignin deposition by regulating monolignol flow to the cell wall as well as the potential of this compartment to incorporate monomers into the growing lignin polymer.

show abstract

“…Despite these QC advantages, we argue that it is the re-use of lines between studies that will prove key to accounting for variation within these models (Volpato et al, 2018). The genetic background significantly contributes to iPSC cellular heterogeneity (Box 1), including differentiation potency, cellular morphology and gene expression variation (Chandler et al, 2017;Kilpinen et al, 2017). Thus, the effect of a variant of interest must be disentangled from the unique genetic backgrounds of the studied lines.…”

Section: Strategies To Reduce Variationmentioning

confidence: 99%

Addressing variability in iPSC-derived models of human disease: guidelines to promote reproducibility

Volpato

Webber

2020

Disease Models &Amp; Mechanisms

238

169

View full text Add to dashboard Cite

Induced pluripotent stem cell (iPSC) technologies have provided in vitro models of inaccessible human cell types, yielding new insights into disease mechanisms especially for neurological disorders. However, without due consideration, the thousands of new human iPSC lines generated in the past decade will inevitably affect the reproducibility of iPSC-based experiments. Differences between donor individuals, genetic stability and experimental variability contribute to iPSC model variation by impacting differentiation potency, cellular heterogeneity, morphology, and transcript and protein abundance. Such effects will confound reproducible disease modelling in the absence of appropriate strategies. In this Review, we explore the causes and effects of iPSC heterogeneity, and propose approaches to detect and account for experimental variation between studies, or even exploit it for deeper biological insight.

show abstract

How well do you know your mutation? Complex effects of genetic background on expressivity, complementation, and ordering of allelic effects

Cited by 47 publications

References 66 publications

Complex genetic interactions of novel Suppressor of Hairless alleles deficient in co-repressor binding

Complex genetic interactions of novel Suppressor of Hairless alleles deficient in co-repressor binding

UDP-GLYCOSYLTRANSFERASE 72E3 Plays a Role in Lignification of Secondary Cell Walls in Arabidopsis

Addressing variability in iPSC-derived models of human disease: guidelines to promote reproducibility

Contact Info

Product

Resources

About