A Drosophila screen identifies NKCC1 as a modifier of NGLY1 deficiency

Talsness, Dana M; Owings, Katie G; Coelho, Emily; Mercenne, Gaëlle; Pleinis, John M.; Partha, Raghavendran; Hope, Kevin A.; Zuberi, Aamir; Clark, Nathan L.; Lutz, Cathleen; Rodan, Aylin R.; Chow, Clement Y.

doi:10.7554/elife.57831

Cited by 35 publications

(45 citation statements)

References 70 publications

(113 reference statements)

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“…In the course of the present studies, we used ERC, a bioinformatics assay, to predict the localization of a poorly understood ion transporter. While ERC has been described and tested before (Brunette et al, 2019; Clark et al, 2012; Findlay et al, 2014; Raza et al, 2019; Talsness et al, 2020; Ziegler et al, 2016), our approach utilized a novel idea that tracking evolutionary histories of functionally linked proteins may inform their functional context, such as localization. Therefore, using this approach we were able to predict protein localization in the absence of obvious clearly defined functional domains.…”

Section: Discussionmentioning

confidence: 99%

“…This evolutionary rate covariation occurs in physically interacting proteins that coevolve as well as functionally related proteins such as gene regulatory elements, membrane traffic adaptors, and transporters. As a result, ERC has been used to identify the functions of uncharacterized genes, including novel DNA damage-induced apoptosis suppressor, sex peptide network components, regulators of cell adhesion, and ion and aminoacid transporters (Brunette et al, 2019; Clark et al, 2012; Findlay et al, 2014; Raza et al, 2019; Talsness et al, 2020; Ziegler et al, 2016). ERC is calculated as correlation between evolutionary rates throughout a phylogeny.…”

Section: Introductionmentioning

confidence: 99%

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Evolutionary rate covariation identifies SLC30A9 (ZnT9) as a mitochondrial zinc transporter

Kowalczyk

Gbadamosi

Kolor

et al. 2021

Preprint

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Recent advances in genome sequencing have led to the identification of new ion and metabolite transporters, many of which have not been characterized. Due to the variety of subcellular localizations, cargo and transport mechanisms, such characterization is a daunting task, and predictive approaches focused on the functional context of transporters are very much needed. Here we present a case for identifying a transporter localization using evolutionary rate covariation (ERC), a computational approach based on pairwise correlations of amino acid sequence evolutionary rates across the mammalian phylogeny. As a case study, we find that poorly characterized transporter SLC30A9 (ZnT9) uniquely and prominently coevolves with several components of the mitochondrial oxidative phosphorylation chain, suggesting mitochondrial localization. We confirmed this computational finding experimentally using recombinant human SLC30A9. SLC30A9 loss caused zinc mishandling in the mitochondria, suggesting that under normal conditions it acts as a zinc exporter. We therefore propose that ERC can be used to predict the functional context of novel transporters and other poorly characterized proteins.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Evolutionary rate covariation identifies SLC30A9 (ZnT9) as a mitochondrial zinc transporter

Kowalczyk

Gbadamosi

Kolor

et al. 2021

Preprint

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“…In D. melanogaster , a powerful strategy to convert a two-dimensional epistasis mapping screen to a one-dimensional screen, thus increasing the power to detect epistatic interactions, is to introgress or cross a candidate focal allele into the DGRP ( Mackay et al 2012 ; Huang et al 2014 ) or another mapping population. However, most of these studies ( Polaczyk et al 1998 ; Dworkin et al 2009 ; Chow et al 2016 ; Lavoy et al 2018 ; Palu et al 2019 ; Talsness et al 2020 ) utilized dominant-negative mutations with large effects or the GAL4 - UAS system to over-express, mis-express or knockdown expression of the focal gene. Only a few studies utilized mutations with subtle, quantitative effects as focal genes ( Yamamoto et al 2009 ; Swarup et al 2012 ; He et al 2016 ).…”

Section: Discussionmentioning

confidence: 99%

“…If the difference between the quantitative effects of the mutant and wild type varies significantly, there is epistasis, and the modifying loci can be mapped with the same power as for a single marker analysis of the same population. Many such studies in D. melanogaster have revealed extensive cryptic natural variation that modifies effects of mutations with large effects ( Rendel 1959 ; Gibson and van Helden 1997 ; Polaczyk et al 1998 ; Rutherford and Lindquist 1998 ; Gibson et al 1999 ; Dworkin et al 2009 ; Chow et al 2016 ; Lavoy et al 2018 ; Palu et al 2019 ; Talsness et al 2020 ). However, there are relatively few studies that have quantified the extent to which naturally occurring variation epistatically modifies the effects of mutations with subtle quantitative effects ( Yamamoto et al 2009 ; Swarup et al 2012 ; He et al 2016 ).…”

Section: Introductionmentioning

confidence: 99%

Epistasis for head morphology in Drosophila melanogaster

Özsoy

Yılmaz

Patlar

et al. 2021

G3 Genes|Genomes|Genetics

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Epistasis – gene-gene interaction – is common for mutations with large phenotypic effects in humans and model organisms. Epistasis impacts quantitative genetic models of speciation, response to natural and artificial selection, genetic mapping and personalized medicine. However, the existence and magnitude of epistasis between alleles with small quantitative phenotypic effects is controversial and difficult to assess. Here, we use the Drosophila melanogaster Genetic Reference Panel of sequenced inbred lines to evaluate the magnitude of naturally occurring epistasis modifying the effects of mutations in jing and inv, two transcription factors that have subtle quantitative effects on head morphology as homozygotes. We find significant epistasis for both mutations and performed single marker genome wide association analyses to map candidate modifier variants and loci affecting head morphology. A subset of these loci was significantly enriched for a known genetic interaction network, and mutations of the candidate epistatic modifier loci also affect head morphology.

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“…Another example of this type of study is provided by the use of genetically diverse Drosophila strains, known as the Drosophila Genetic Reference Panel (DGRP), to identify components of the genetic background that affect symptoms and severity of the rare NGLY1 deficiency [ 47 ]. As already mentioned, a Drosophila FOP model has been reported [ 4 ]; thus, in principle it would be possible to apply a similar approach to search for genetic modifiers also for the FOP phenotype.…”

Section: A General Approach To Investigate Genetic Modifiers Of Fomentioning

confidence: 99%

Genomic Context and Mechanisms of the ACVR1 Mutation in Fibrodysplasia Ossificans Progressiva

Ravazzolo

Bocciardi

2021

Biomedicines

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Basic research in Fibrodysplasia Ossificans Progressiva (FOP) was carried out in the various fields involved in the disease pathophysiology and was important for designing therapeutic approaches, some of which were already developed as ongoing or planned clinical trials. Genetic research was fundamental in identifying the FOP causative mutation, and the astonishing progress in technologies for genomic analysis, coupled to related computational methods, now make possible further research in this field. We present here a review of molecular and cellular factors which could explain why a single mutation, the R206H in the ACVR1 gene, is absolutely prevalent in FOP patients. We also address the mechanisms by which FOP expressivity could be modulated by cis-acting variants in the ACVR1 genomic region in human chromosome 2q. Finally, we also discuss the general issue of genetic modifiers in FOP.

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A Drosophila screen identifies NKCC1 as a modifier of NGLY1 deficiency

Cited by 35 publications

References 70 publications

Evolutionary rate covariation identifies SLC30A9 (ZnT9) as a mitochondrial zinc transporter

Evolutionary rate covariation identifies SLC30A9 (ZnT9) as a mitochondrial zinc transporter

Epistasis for head morphology in Drosophila melanogaster

Genomic Context and Mechanisms of the ACVR1 Mutation in Fibrodysplasia Ossificans Progressiva

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