Data_Sheet_2_Gene Expression Modification by an Autosomal Inversion Associated With Three Male Mating Morphs.docx

Chromosomal inversions are structural rearrangements that frequently provide genomic substrate for phenotypic diversity. In the ruff Philomachus pugnax, three distinct male reproductive morphs (Independents, Satellites and Faeders) are genetically determined by a 4.5 Mb autosomal inversion. Here we...

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Bibliographic Details
Main Authors: Jasmine L. Loveland (10921377), David B. Lank (8382138), Clemens Küpper (197130)
Format: Dataset
Language:unknown
Published: 2021
Subjects:
Genetics
Genetic Engineering
Biomarkers
Developmental Genetics (incl. Sex Determination)
Epigenetics (incl. Genome Methylation and Epigenomics)
Gene Expression (incl. Microarray and other genome-wide approaches)
Genome Structure and Regulation
Genomics
Genetically Modified Animals
Livestock Cloning
Gene and Molecular Therapy
chromosomal inversion
alternative reproduction strategies
steroidogenic pathway
Philomachus pugnax
SDR42E1
aromatase
HSD17B2
CENPN
Ruff
Online Access:https://doi.org/10.3389/fgene.2021.641620.s002
id ftsmithonian:oai:figshare.com:article/14729790
record_format openpolar
spelling ftsmithonian:oai:figshare.com:article/14729790 2023-05-15T17:58:41+02:00 Data_Sheet_2_Gene Expression Modification by an Autosomal Inversion Associated With Three Male Mating Morphs.docx Jasmine L. Loveland (10921377) David B. Lank (8382138) Clemens Küpper (197130) 2021-06-04T05:55:43Z https://doi.org/10.3389/fgene.2021.641620.s002 unknown https://figshare.com/articles/dataset/Data_Sheet_2_Gene_Expression_Modification_by_an_Autosomal_Inversion_Associated_With_Three_Male_Mating_Morphs_docx/14729790 doi:10.3389/fgene.2021.641620.s002 CC BY 4.0 CC-BY Genetics Genetic Engineering Biomarkers Developmental Genetics (incl. Sex Determination) Epigenetics (incl. Genome Methylation and Epigenomics) Gene Expression (incl. Microarray and other genome-wide approaches) Genome Structure and Regulation Genomics Genetically Modified Animals Livestock Cloning Gene and Molecular Therapy chromosomal inversion alternative reproduction strategies steroidogenic pathway Philomachus pugnax SDR42E1 aromatase HSD17B2 CENPN Dataset 2021 ftsmithonian https://doi.org/10.3389/fgene.2021.641620.s002 2021-06-13T15:11:52Z Chromosomal inversions are structural rearrangements that frequently provide genomic substrate for phenotypic diversity. In the ruff Philomachus pugnax, three distinct male reproductive morphs (Independents, Satellites and Faeders) are genetically determined by a 4.5 Mb autosomal inversion. Here we test how this stable inversion polymorphism affects gene expression in males during the lekking season. Gene expression may be altered through disruptions at the breakpoints and the accumulation of mutations due to suppressed recombination. We used quantitative PCR to measure expression of 11 candidate inversion genes across three different tissues (liver, adrenal glands and gonads) and tested for allelic imbalance in four inversion genes across 12 males of all three morphs (8 Independents, 2 Satellites, 2 Faeders). We quantified transcripts of CENPN, an essential gene disrupted by the inversion at the proximal breakpoint, at different exons distributed near and across the breakpoint region. Consistent with dosage dependent gene expression for the breakpoint gene CENPN, we found that expression in Independents was broadly similar for transcripts segments from inside and outside the inversion regions, whereas for Satellites and Faeders, transcript segments outside of the inversion showed at least twofold higher expression than those spanning over the breakpoint. Within the inversion, observed expression differences for inversion males across all four genes with allele-specific primers were consistent with allelic imbalance. We further analyzed gonadal expression of two inversion genes, HSD17B2 and SDR42E1, along with 12 non-inversion genes related to steroid metabolism and signaling in 25 males (13 Independents, 7 Satellites, 5 Faeders). Although we did not find clear morph differentiation for many individual genes, all three morphs could be separated based on gene expression differences when using linear discriminant analysis (LDA), regardless of genomic location (i.e., inside or outside of the inversion). This was robust to the removal of genes with the highest loadings. Pairwise correlations in the expression of genes showed significant correlations for 9–18 pairs of genes within morphs. However, between morphs, we only found a single association between genes SDR42E1 and AROM for Independents and Satellites. Our results suggest complex and wide-ranging changes in gene expression caused by structural variants. Dataset Philomachus pugnax Ruff Unknown
institution Open Polar
collection Unknown
op_collection_id ftsmithonian
language unknown
topic Genetics
Genetic Engineering
Biomarkers
Developmental Genetics (incl. Sex Determination)
Epigenetics (incl. Genome Methylation and Epigenomics)
Gene Expression (incl. Microarray and other genome-wide approaches)
Genome Structure and Regulation
Genomics
Genetically Modified Animals
Livestock Cloning
Gene and Molecular Therapy
chromosomal inversion
alternative reproduction strategies
steroidogenic pathway
Philomachus pugnax
SDR42E1
aromatase
HSD17B2
CENPN
spellingShingle Genetics
Genetic Engineering
Biomarkers
Developmental Genetics (incl. Sex Determination)
Epigenetics (incl. Genome Methylation and Epigenomics)
Gene Expression (incl. Microarray and other genome-wide approaches)
Genome Structure and Regulation
Genomics
Genetically Modified Animals
Livestock Cloning
Gene and Molecular Therapy
chromosomal inversion
alternative reproduction strategies
steroidogenic pathway
Philomachus pugnax
SDR42E1
aromatase
HSD17B2
CENPN
Jasmine L. Loveland (10921377)
David B. Lank (8382138)
Clemens Küpper (197130)
Data_Sheet_2_Gene Expression Modification by an Autosomal Inversion Associated With Three Male Mating Morphs.docx
topic_facet Genetics
Genetic Engineering
Biomarkers
Developmental Genetics (incl. Sex Determination)
Epigenetics (incl. Genome Methylation and Epigenomics)
Gene Expression (incl. Microarray and other genome-wide approaches)
Genome Structure and Regulation
Genomics
Genetically Modified Animals
Livestock Cloning
Gene and Molecular Therapy
chromosomal inversion
alternative reproduction strategies
steroidogenic pathway
Philomachus pugnax
SDR42E1
aromatase
HSD17B2
CENPN
description Chromosomal inversions are structural rearrangements that frequently provide genomic substrate for phenotypic diversity. In the ruff Philomachus pugnax, three distinct male reproductive morphs (Independents, Satellites and Faeders) are genetically determined by a 4.5 Mb autosomal inversion. Here we test how this stable inversion polymorphism affects gene expression in males during the lekking season. Gene expression may be altered through disruptions at the breakpoints and the accumulation of mutations due to suppressed recombination. We used quantitative PCR to measure expression of 11 candidate inversion genes across three different tissues (liver, adrenal glands and gonads) and tested for allelic imbalance in four inversion genes across 12 males of all three morphs (8 Independents, 2 Satellites, 2 Faeders). We quantified transcripts of CENPN, an essential gene disrupted by the inversion at the proximal breakpoint, at different exons distributed near and across the breakpoint region. Consistent with dosage dependent gene expression for the breakpoint gene CENPN, we found that expression in Independents was broadly similar for transcripts segments from inside and outside the inversion regions, whereas for Satellites and Faeders, transcript segments outside of the inversion showed at least twofold higher expression than those spanning over the breakpoint. Within the inversion, observed expression differences for inversion males across all four genes with allele-specific primers were consistent with allelic imbalance. We further analyzed gonadal expression of two inversion genes, HSD17B2 and SDR42E1, along with 12 non-inversion genes related to steroid metabolism and signaling in 25 males (13 Independents, 7 Satellites, 5 Faeders). Although we did not find clear morph differentiation for many individual genes, all three morphs could be separated based on gene expression differences when using linear discriminant analysis (LDA), regardless of genomic location (i.e., inside or outside of the inversion). This was robust to the removal of genes with the highest loadings. Pairwise correlations in the expression of genes showed significant correlations for 9–18 pairs of genes within morphs. However, between morphs, we only found a single association between genes SDR42E1 and AROM for Independents and Satellites. Our results suggest complex and wide-ranging changes in gene expression caused by structural variants.
format Dataset
author Jasmine L. Loveland (10921377)
David B. Lank (8382138)
Clemens Küpper (197130)
author_facet Jasmine L. Loveland (10921377)
David B. Lank (8382138)
Clemens Küpper (197130)
author_sort Jasmine L. Loveland (10921377)
title Data_Sheet_2_Gene Expression Modification by an Autosomal Inversion Associated With Three Male Mating Morphs.docx
title_short Data_Sheet_2_Gene Expression Modification by an Autosomal Inversion Associated With Three Male Mating Morphs.docx
title_full Data_Sheet_2_Gene Expression Modification by an Autosomal Inversion Associated With Three Male Mating Morphs.docx
title_fullStr Data_Sheet_2_Gene Expression Modification by an Autosomal Inversion Associated With Three Male Mating Morphs.docx
title_full_unstemmed Data_Sheet_2_Gene Expression Modification by an Autosomal Inversion Associated With Three Male Mating Morphs.docx
title_sort data_sheet_2_gene expression modification by an autosomal inversion associated with three male mating morphs.docx
publishDate 2021
url https://doi.org/10.3389/fgene.2021.641620.s002
genre Philomachus pugnax
Ruff
genre_facet Philomachus pugnax
Ruff
op_relation https://figshare.com/articles/dataset/Data_Sheet_2_Gene_Expression_Modification_by_an_Autosomal_Inversion_Associated_With_Three_Male_Mating_Morphs_docx/14729790
doi:10.3389/fgene.2021.641620.s002
op_rights CC BY 4.0
op_rightsnorm CC-BY
op_doi https://doi.org/10.3389/fgene.2021.641620.s002
_version_ 1766167372241043456

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