@article{18761,
  abstract     = {Termites, together with cockroaches, belong to the Blattodea. They possess an XX/XY sex determination system which has evolved from an XX/X0 system present in other Blattodean species, such as cockroaches and wood roaches. Little is currently known about the sex chromosomes of termites, their gene content, or their evolution. We here investigate the X chromosome of multiple termite species and compare them with the X chromosome of cockroaches using genomic and transcriptomic data. We find that the X chromosome of the termite Macrotermes natalensis is large and differentiated showing hall marks of sex chromosome evolution such as dosage compensation, while this does not seem to be the case in the other two termite species investigated here where sex chromosomes may be evolutionary younger. Furthermore, the X chromosome in M. natalensis is different from the X chromosome found in the cockroach Blattella germanica indicating that sex chromosome turn-over events may have happened during termite evolution.},
  author       = {Fraser, Roxanne and Moraa, Ruth and Djolai, Annika and Meisenheimer, Nils and Laube, Sophie and Vicoso, Beatriz and Huylmans, Ann K},
  issn         = {1759-6653},
  journal      = {Genome Biology and Evolution},
  number       = {12},
  publisher    = {Oxford University Press},
  title        = {{Evidence for a novel X chromosome in termites}},
  doi          = {10.1093/gbe/evae265},
  volume       = {16},
  year         = {2024},
}

@article{17458,
  abstract     = {Changes in gene dosage can have tremendous evolutionary potential (e.g. whole-genome duplications), but without compensatory mechanisms, they can also lead to gene dysregulation and pathologies. Sex chromosomes are a paradigmatic example of naturally occurring gene dosage differences and their compensation. In species with chromosome-based sex determination, individuals within the same population necessarily show ‘natural’ differences in gene dosage for the sex chromosomes. In this Review, we focus on the mammalian X chromosome and discuss recent new insights into the dosage-compensation mechanisms that evolved along with the emergence of sex chromosomes, namely X-inactivation and X-upregulation. We also discuss the evolution of the genetic loci and molecular players involved, as well as the regulatory diversity and potentially different requirements for dosage compensation across mammalian species.},
  author       = {Cecalev, Daniela and Vicoso, Beatriz and Galupa, Rafael},
  issn         = {1477-9129},
  journal      = {Development},
  number       = {15},
  publisher    = {The Company of Biologists},
  title        = {{Compensation of gene dosage on the mammalian X}},
  doi          = {10.1242/dev.202891},
  volume       = {151},
  year         = {2024},
}

@misc{17362,
  abstract     = {This is the supplementary data for the paper titled "Single-nucleus atlas of the Artemia female reproductive system suggests germline repression of the Z chromosome", where we described the generation and analysis of single-nucleus expression and chromatin-accessibility data from the female reproductive system of Artemia franciscana. We compared our dataset to the published Drosophila single-nucleus data (over 400 million years of divergence) and highlighted the extreme conservation of several of the molecular pathways of oogenesis and meiosis. We found evidence of global transcriptional quiescence and chromatin condensation in late germ cells, highlighting the conserved role of this repressive stage in arthropod oogenesis. Additionally, we explored the expression patterns of the ZW sex chromosomes during oogenesis. Our data shows that the Z-chromosome is consistently downregulated in germline cells. While this is partly driven by a lack of dosage compensation in the germline, a subset of cells show stronger repression of the Z chromosome.},
  author       = {Elkrewi, Marwan N and Vicoso, Beatriz},
  publisher    = {Institute of Science and Technology Austria},
  title        = {{Data for: "Single-nucleus atlas of the Artemia female reproductive system suggests germline repression of the Z chromosome"}},
  doi          = {10.15479/AT:ISTA:17362},
  year         = {2024},
}

@phdthesis{17206,
  abstract     = {Males and females exhibit numerous differences, from the initial stages of sex determination to the
development of secondary sexual characteristics. In Drosophila, these differences have been
thoroughly studied. Extensive research has been performed to understand the role and molecular
mode of action of central sex in determining switch genes, such as transformer (tra) and Sex-lethal
(Sxl). Furthermore, studies have highlighted differential gene expression as an essential mechanism to
create sexual dimorphism. An alternative path to sexual dimorphism that has been less explored is
alternative splicing, the mechanism through which genes can produce multiple transcripts with
distinct properties and functions. The primary switch sex-determining gene Sxl is a good example of
the role of alternative splicing for sex-specific functions: the inclusion of a specific exon determines
the male or female form of the protein, which in turn switches on either the male or female
developmental pathway. The genes that act upstream of Sxl and determine which form is expressed -
the counter genes - have received less attention. This thesis addresses two critical questions about
the molecular encoding of sexes in the Drosophila melanogaster genome: First, the use of splice forms
in male and female tissues in D. melanogaster is examined, inferring the molecular and evolutionary
parameters shaping the diversity of the splicing landscape. Second, the behaviour of counter genes in
Drosophila-related species is investigated, shedding light on potential changes leading to their
incorporation into the sex-determination pathway.
For the alternative splicing analyses, long-read RNA sequencing of testes, ovaries, female and male
midguts, heads, and whole bodies was performed. A novel pipeline was developed to assign unique
transcript identifiers for each sequence of exons and introns in the read, enabling detailed
comparisons of splicing variants in each tissue/sex. Alternative splicing was found to be more
pervasive in females than males (22,201 exclusive splice forms in females versus 12,631 in males),
especially when comparing ovaries to other tissues. The ovaries alone displayed 15,299 exclusive
splice forms, suggesting most female exclusive splice forms originate there. Genome location and gene
age were also correlated with the number of splice forms per gene. In particular, the X and 4th
chromosomes (Muller elements A and F) showed more splice forms per gene than other
chromosomes. Additionally, genes older than 63 million years exhibited more splice forms per gene
than younger genes. Our results suggest that alternative splicing is more prevalent than previously
believed, with numerous female-exclusive forms, age, and location playing significant roles in shaping
its prevalence.
For the counter genes analyses, we combined published gene expression, genomic, and gene
interaction data from various clades (Bactrocera jarvisi, B. oleae, Ceratitis capitata, Mus musculus,
Caenorhabditis elegans, Homo sapiens, and D. melanogaster). The counter genes scute (sc), extra
macrochaetae (emc), groucho (gro), deadpan (dpn), daughterless (da), runt (run), Sxl, hermaphrodite
(her), and tra maintain conserved Muller element locations between C. capitata and D. melanogaster,
which are most of the counter genes identified in the C. capitata genome. Their expression patterns
during early embryogenesis in B. jarvisi and D. melanogaster are also similar for counter genes dpn,
gro, da, and emc. However, Sxl and sc are also found to have more extreme expression ratios between
the species. Lastly, gene interactions within the counter genes are conserved, with da-sc and gro-dpn
interactions occurring in Drosophila, worms, humans, and mice. Interactions such as dpn-sc, dpn-da,
da-emc, and gro-run are present in Drosophila, mice, and humans, suggesting these genes were
recruited by ancestral characteristics, primarily during embryogenesis. The conserved expression,
location, and interactions of counter genes suggest serendipitous recruitment of such genes instead
of a change in those characteristics as they were recruited for this function. },
  author       = {Raices, Julia},
  issn         = {2663-337X},
  pages        = {82},
  publisher    = {Institute of Science and Technology Austria},
  title        = {{Novel approaches to studying alternative splicing in Drosophila Melanogaster : Insights into sex-specific gene expression and the evolution of sex determination}},
  doi          = {10.15479/at:ista:17206},
  year         = {2024},
}

@phdthesis{17119,
  abstract     = {Genomes are shaped by natural selection at the level of the organism, as genomic variants that
have a beneficial effect on the viability or fecundity of their carriers are on average expected
to be passed on to more offspring than less beneficial alleles. However, selection also favors
genomic variants that drive their own transmission to the next generation above the mendelian
expectation of 50 percent in heterozygotes, even if these self-promoting variants are less
beneficial to the organism than other variants at the same locus. Such variants, called meiotic
drivers, are found in diverse taxa, and often impose fitness costs on their host organisms. As
meiotic drivers often require multiple genes and sequences for transmission ratio distortion,
they are often found in regions of low recombination, such as inversions, which prevent their
recombination with the non-driving homologous regions. Reduced recombination rates are
expected to lead to the accumulation of deleterious mutations, which may affect hundreds
of genes trapped in the inversions of meiotic drivers. Although the observed fitness costs of
self-promoting haplotypes are thought to possibly reflect sequence degeneration, no study has
systematically investigated the level of degeneration on a meiotic driver. Further, the low
rates of recombination between driving and non-driving haplotypes have limited the power of
traditional genetic studies in uncovering the gene content of meiotic drivers, and made the
the identification of the genes causing transmission ratio distortion difficult.
After an introduction to meiotic drivers in Chapter 1, this thesis presents three studies that
make use of next generation sequencing data to characterize the sequence and expression
evolution of genes on the t-haplotype, a large and ancient meiotic driver in house mice that is
transmitted to up to 100% of the offspring in males heterozygous for it. Chapter 2 presents
a comprehensive assessment of the t-haplotype’s sequence evolution, which shows signs of
sequence degeneration counteracted by occasional recombination with the non-driving homolog
over large parts of the meiotic driver, proposing an explanation for its long-term survival.
Chapter 3 investigates the sequence and expression evolution of genes on the t-haplotype,
and finds widespread expression and copy number changes and signs of less efficient purifying
selection compared to the genes on the non-driving homolog. Further, this chapter finds
candidates for involvment in drive: two positively selected genes on the t-haplotype, and
the discovery of a t-specific gene duplicate, which was gained from another chromosome,
and which acquired novel sequence and testis-specific expression on the t-haplotype. Finally,
Chapter 4 provides unprecedented insights into the gene expression landscape in testes of
t-carrier mice, using single nucleus sequencing. Cell-resolved RNA-sequencing allows the
comparison of expression in spermatids carrying or not carrying the t-haplotype as well as the
timing of t-haplotype-induced expression changes along spermatogenesis. This study shows
the timing of previously found drive-associated genes, and uncovers novel candidate genes and
biological processes that may underlie the complex biology of transmission ratio distortion of
the t-haplotype. Chapter 5 synthesizes the findings of the three studies, and discusses them in
the context of the current state of meiotic drive research.},
  author       = {Kelemen, Réka K},
  isbn         = {978-3-99078-039-8},
  issn         = {2663-337X},
  keywords     = {meiotic driver, neofunctionalization, single nucleus sequencing},
  pages        = {105},
  publisher    = {Institute of Science and Technology Austria},
  title        = {{Characterizing the sequence and expression evolution of the t-haplotype, a model meiotic driver}},
  doi          = {10.15479/at:ista:17119},
  year         = {2024},
}

@phdthesis{18531,
  abstract     = {Sex chromosomes and autosomes exhibit very different evolutionary dynamics.
The Y chromosome usually degenerates, leaving many X-linked loci hemizygous in
males. Since recessive X-linked mutations are always exposed to selection in males,
selection is more efficient on the X chromosome than on autosomes on recessive
mutations, leading to faster adaptation on the X chromosome than other genomic
regions, if beneficial mutations are on average recessive (known as the Faster-X
effect). In the presence of the functional, but non-recombining gametolog on the Y (as
is often the case in young non-recombining regions), recessive mutations are
sheltered from selection on the X chromosome. We model this scenario and show that
the efficiency of selection is reduced on diploid X loci due to sheltering by the Y
chromosome. Reduced efficiency of selection leads to slower adaptation and
increased accumulation of deleterious mutations (Slower-X effect). We extended this
model to explore the effect of sex-specific selection on degeneration of sex
chromosomes, showing theoretically that male-limited genes degenerate on the X
chromosome and female-biased genes degenerate on the Y chromosome. This
prediction depends on the effective population size and the mutation rate, explaining
the variety of sex chromosome degeneration patterns observed in nature.
To test for direct evidence of a Slower-X (or Slower-Z) effect, we analyzed the
ZW sex chromosomes of the flatworm Schistosoma japonicum, which have a very
young non-recombining region with non-degenerated W. Diploid Z-linked genes have
higher ratios of non-synonymous to synonymous polymorphisms than autosomal
genes, supporting reduced efficiency of selection on the diploid Z region. These results
provide evidence of sheltering by the W chromosome, a mechanism that could
contribute to Z (X) chromosome degeneration, and illustrate contrasting evolutionary
patterns in old and young sex chromosome regions. In addition, genes with sexspecific patterns of expression show opposite patterns of selection in the young
(diploid) and old (hemizygous) Z, showing the complex manner in which sex-specific selection shapes the evolutionary patterns of sex chromosomes. },
  author       = {Mrnjavac, Andrea},
  issn         = {2663-337X},
  keywords     = {Sex chromosomes, evolution, selection, sheltering},
  pages        = {181},
  publisher    = {Institute of Science and Technology Austria},
  title        = {{Early stages of sex chromosome evolution}},
  doi          = {10.15479/at:ista:18531},
  year         = {2024},
}

@unpublished{18549,
  abstract     = {Sex-linked and autosomal loci experience different selective pressures and
evolutionary dynamics. X (or Z) chromosomes are often hemizygous, as Y (or W)
chromosomes often degenerate. Such hemizygous regions can be under greater
efficacy of selection, as recessive mutations are immediately exposed to selection in
the heterogametic sex (the so-called Faster-X or Faster-Z effect). However, in young
non-recombining regions, Y/W chromosomes often have many functional genes, and
many X/Z-linked loci are therefore diploid. The sheltering of recessive mutations on
the X/Z by the Y/W homolog is expected to drive a Slower-X (Slower-Z) effect for
diploid X/Z loci, i.e. a reduction in the efficacy of selection. While the Faster-X effect
has been studied extensively, much less is known empirically about the evolutionary
dynamics of diploid X or Z chromosomes. Here, we took advantage of published
population genomic data in the female-heterogametic human parasite Schistosoma
japonicum to characterize the gene content and diversity levels of the diploid and
hemizygous regions of the Z chromosome. We used different metrics of selective
pressures acting on genes to test for differences in the efficacy of selection in
hemizygous and diploid Z regions, relative to autosomes. We found consistent
patterns suggesting reduced Ne, and reduced efficacy of purifying selection, on both
hemizygous and diploid Z regions. Moreover, relaxed selection was particularly
pronounced for female-biased genes on the diploid Z, as predicted by Slower-Z
theory.
},
  author       = {Mrnjavac, Andrea and Vicoso, Beatriz},
  booktitle    = {bioRxiv},
  title        = {{Evidence of a Slower-Z effect in Schistosoma japonicum}},
  doi          = {10.1101/2024.07.02.601697},
  year         = {2024},
}

@article{17890,
  abstract     = {Our understanding of the molecular pathways that regulate oogenesis and define cellular identity in the Arthropod female reproductive system and the extent of their conservation is currently very limited. This is due to the focus on model systems, including Drosophila and Daphnia, which do not reflect the observed diversity of morphologies, reproductive modes, and sex chromosome systems. We use single-nucleus RNA and ATAC sequencing to produce a comprehensive single nucleus atlas of the adult Artemia franciscana female reproductive system. We map our data to the Fly Cell Atlas single-nucleus dataset of the Drosophila melanogaster ovary, shedding light on the conserved regulatory programs between the two distantly related Arthropod species. We identify the major cell types known to be present in the Artemia ovary, including germ cells, follicle cells, and ovarian muscle cells. Additionally, we use the germ cells to explore gene regulation and expression of the Z chromosome during meiosis, highlighting its unique regulatory dynamics and allowing us to explore the presence of meiotic sex chromosome silencing in this group.},
  author       = {Elkrewi, Marwan N and Vicoso, Beatriz},
  issn         = {1553-7404},
  journal      = {PLoS Genetics},
  number       = {8},
  publisher    = {Public Library of Science},
  title        = {{Single-nucleus atlas of the Artemia female reproductive system suggests germline repression of the Z chromosome}},
  doi          = {10.1371/journal.pgen.1011376},
  volume       = {20},
  year         = {2024},
}

@article{15009,
  abstract     = {Since the commercialization of brine shrimp (genus Artemia) in the 1950s, this lineage, and in particular the model species Artemia franciscana, has been the subject of extensive research. However, our understanding of the genetic mechanisms underlying various aspects of their reproductive biology, including sex determination, is still lacking. This is partly due to the scarcity of genomic resources for Artemia species and crustaceans in general. Here, we present a chromosome-level genome assembly of A. franciscana (Kellogg 1906), from the Great Salt Lake, United States. The genome is 1 GB, and the majority of the genome (81%) is scaffolded into 21 linkage groups using a previously published high-density linkage map. We performed coverage and FST analyses using male and female genomic and transcriptomic reads to quantify the extent of differentiation between the Z and W chromosomes. Additionally, we quantified the expression levels in male and female heads and gonads and found further evidence for dosage compensation in this species.},
  author       = {Bett, Vincent K and Macon, Ariana and Vicoso, Beatriz and Elkrewi, Marwan N},
  issn         = {1759-6653},
  journal      = {Genome Biology and Evolution},
  number       = {1},
  publisher    = {Oxford University Press},
  title        = {{Chromosome-level assembly of Artemia franciscana sheds light on sex chromosome differentiation}},
  doi          = {10.1093/gbe/evae006},
  volume       = {16},
  year         = {2024},
}

@article{11479,
  abstract     = {Understanding population divergence that eventually leads to speciation is essential for evolutionary biology. High species diversity in the sea was regarded as a paradox when strict allopatry was considered necessary for most speciation events because geographical barriers seemed largely absent in the sea, and many marine species have high dispersal capacities. Combining genome-wide data with demographic modelling to infer the demographic history of divergence has introduced new ways to address this classical issue. These models assume an ancestral population that splits into two subpopulations diverging according to different scenarios that allow tests for periods of gene flow. Models can also test for heterogeneities in population sizes and migration rates along the genome to account, respectively, for background selection and selection against introgressed ancestry. To investigate how barriers to gene flow arise in the sea, we compiled studies modelling the demographic history of divergence in marine organisms and extracted preferred demographic scenarios together with estimates of demographic parameters. These studies show that geographical barriers to gene flow do exist in the sea but that divergence can also occur without strict isolation. Heterogeneity of gene flow was detected in most population pairs suggesting the predominance of semipermeable barriers during divergence. We found a weak positive relationship between the fraction of the genome experiencing reduced gene flow and levels of genome-wide differentiation. Furthermore, we found that the upper bound of the ‘grey zone of speciation’ for our dataset extended beyond that found before, implying that gene flow between diverging taxa is possible at higher levels of divergence than previously thought. Finally, we list recommendations for further strengthening the use of demographic modelling in speciation research. These include a more balanced representation of taxa, more consistent and comprehensive modelling, clear reporting of results and simulation studies to rule out nonbiological explanations for general results.},
  author       = {De Jode, Aurélien and Le Moan, Alan and Johannesson, Kerstin and Faria, Rui and Stankowski, Sean and Westram, Anja M and Butlin, Roger K. and Rafajlović, Marina and Fraisse, Christelle},
  issn         = {1752-4571},
  journal      = {Evolutionary Applications},
  number       = {2},
  pages        = {542--559},
  publisher    = {Wiley},
  title        = {{Ten years of demographic modelling of divergence and speciation in the sea}},
  doi          = {10.1111/eva.13428},
  volume       = {16},
  year         = {2023},
}

@article{14604,
  abstract     = {Sex chromosomes have evolved independently multiple times, but why some are conserved for more than 100 million years whereas others turnover rapidly remains an open question. Here, we examine the homology of sex chromosomes across nine orders of insects, plus the outgroup springtails. We find that the X chromosome is likely homologous across insects and springtails; the only exception is in the Lepidoptera, which has lost the X and now has a ZZ/ZW sex-chromosome system. These results suggest the ancestral insect X chromosome has persisted for more than 450 million years—the oldest known sex chromosome to date. Further, we propose that the shrinking of gene content the dipteran X chromosome has allowed for a burst of sex-chromosome turnover that is absent from other speciose insect orders.},
  author       = {Toups, Melissa A and Vicoso, Beatriz},
  issn         = {1558-5646},
  journal      = {Evolution},
  number       = {11},
  pages        = {2504--2511},
  publisher    = {Oxford University Press},
  title        = {{The X chromosome of insects likely predates the origin of class Insecta}},
  doi          = {10.1093/evolut/qpad169},
  volume       = {77},
  year         = {2023},
}

@misc{14614,
  abstract     = {Many insects carry an ancient X chromosome—the Drosophila Muller element F—that likely predates their origin. Interestingly, the X has undergone turnover in multiple fly species (Diptera) after being conserved for more than 450 My. The long evolutionary distance between Diptera and other sequenced insect clades makes it difficult to infer what could have contributed to this sudden increase in rate of turnover. Here, we produce the first genome and transcriptome of scorpionflies (genus Panorpa), an insect belonging to a long overlooked sister-order to Diptera: Mecoptera. Combining our genome assembly with genomic short-read data, we obtain genome coverage and identify X-linked super-scaffolds. We further perform a gene homology analysis between the Panorpa X and a closely related Diptera species, and we assess the conservation of the Panorpa X-linked gene content with that of more distantly related insect species. We explored the structure of the Panorpa X by determining its repeat content, GC content, and nucleotide diversity. Finally, we used RNAseq data to detect the presence of dosage compensation in somatic tissues, as well as to explore gene expression tissue-specificity, and sex-bias in gene expression. We find high conservation of gene content between the mecopteran X and the dipteran Muller F element, as well as several shared biological features, such as the presence of dosage compensation and a low amount of genetic diversity, consistent with a low recombination rate. However, the 2 homologous X chromosomes differ strikingly in their size and number of genes they carry. Our results therefore support a common ancestry of the mecopteran and ancestral dipteran X chromosomes, and suggest that Muller element F shrank in size and gene content after the split of Diptera and Mecoptera, which may have contributed to its turnover in dipteran insects.},
  author       = {Lasne, Clementine and Elkrewi, Marwan N},
  keywords     = {Panorpa, scorpionfly, genome, transcriptome},
  publisher    = {Institute of Science and Technology Austria},
  title        = {{The scorpionfly (Panorpa cognata) genome highlights conserved and derived features of the peculiar dipteran X chromosome}},
  doi          = {10.15479/AT:ISTA:14614},
  year         = {2023},
}

@misc{14616,
  abstract     = {Sex chromosomes have evolved independently multiple times, but why some are conserved for more than 100 million years whereas others turnover rapidly remains an open question. Here, we examine the homology of sex chromosomes across nine orders of insects, plus the outgroup springtails. We find that the X chromosome is likely homologous across insects and springtails; the only exception is in the Lepidoptera, which has lost the X and now has a ZZ/ZW sex chromosome system. These results suggest the ancestral insect X chromosome has persisted for more than 450 million years – the oldest known sex chromosome to date. Further, we propose that the shrinking of gene content of the Dipteran X chromosome has allowed for a burst of sex-chromosome turnover that is absent from other speciose insect orders.},
  author       = {Toups, Melissa A and Vicoso, Beatriz},
  publisher    = {Dryad},
  title        = {{The X chromosome of insects likely predates the origin of Class Insecta}},
  doi          = {10.5061/DRYAD.HX3FFBGKT},
  year         = {2023},
}

@misc{14617,
  abstract     = {Sex chromosomes have evolved independently multiple times, but why some are conserved for more than 100 million years whereas others turnover rapidly remains an open question. Here, we examine the homology of sex chromosomes across nine orders of insects, plus the outgroup springtails. We find that the X chromosome is likely homologous across insects and springtails; the only exception is in the Lepidoptera, which has lost the X and now has a ZZ/ZW sex chromosome system. These results suggest the ancestral insect X chromosome has persisted for more than 450 million years – the oldest known sex chromosome to date. Further, we propose that the shrinking of gene content of the Dipteran X chromosome has allowed for a burst of sex-chromosome turnover that is absent from other speciose insect orders.},
  author       = {Toups, Melissa A and Vicoso, Beatriz},
  publisher    = {Zenodo},
  title        = {{The X chromosome of insects likely predates the origin of Class Insecta}},
  doi          = {10.5281/ZENODO.8138705},
  year         = {2023},
}

@article{14742,
  abstract     = {Chromosomal rearrangements (CRs) have been known since almost the beginning of genetics.
While an important role for CRs in speciation has been suggested, evidence primarily stems
from theoretical and empirical studies focusing on the microevolutionary level (i.e., on taxon
pairs where speciation is often incomplete). Although the role of CRs in eukaryotic speciation at
a macroevolutionary level has been supported by associations between species diversity and
rates of evolution of CRs across phylogenies, these findings are limited to a restricted range of
CRs and taxa. Now that more broadly applicable and precise CR detection approaches have
become available, we address the challenges in filling some of the conceptual and empirical
gaps between micro- and macroevolutionary studies on the role of CRs in speciation. We
synthesize what is known about the macroevolutionary impact of CRs and suggest new research avenues to overcome the pitfalls of previous studies to gain a more comprehensive understanding of the evolutionary significance of CRs in speciation across the tree of life.},
  author       = {Lucek, Kay and Giménez, Mabel D. and Joron, Mathieu and Rafajlović, Marina and Searle, Jeremy B. and Walden, Nora and Westram, Anja M and Faria, Rui},
  issn         = {1943-0264},
  journal      = {Cold Spring Harbor Perspectives in Biology},
  keywords     = {General Biochemistry, Genetics and Molecular Biology},
  number       = {11},
  publisher    = {Cold Spring Harbor Laboratory Press},
  title        = {{The impact of chromosomal rearrangements in speciation: From micro- to macroevolution}},
  doi          = {10.1101/cshperspect.a041447},
  volume       = {15},
  year         = {2023},
}

@article{13260,
  abstract     = {Experimental evolution studies are powerful approaches to examine the evolutionary history of lab populations. Such studies have shed light on how selection changes phenotypes and genotypes. Most of these studies have not examined the time course of adaptation under sexual selection manipulation, by resequencing the populations’ genomes at multiple time points. Here, we analyze allele frequency trajectories in Drosophila pseudoobscura where we altered their sexual selection regime for 200 generations and sequenced pooled populations at 5 time points. The intensity of sexual selection was either relaxed in monogamous populations (M) or elevated in polyandrous lines (E). We present a comprehensive study of how selection alters population genetics parameters at the chromosome and gene level. We investigate differences in the effective population size—Ne—between the treatments, and perform a genome-wide scan to identify signatures of selection from the time-series data. We found genomic signatures of adaptation to both regimes in D. pseudoobscura. There are more significant variants in E lines as expected from stronger sexual selection. However, we found that the response on the X chromosome was substantial in both treatments, more pronounced in E and restricted to the more recently sex-linked chromosome arm XR in M. In the first generations of experimental evolution, we estimate Ne to be lower on the X in E lines, which might indicate a swift adaptive response at the onset of selection. Additionally, the third chromosome was affected by elevated polyandry whereby its distal end harbors a region showing a strong signal of adaptive evolution especially in E lines.},
  author       = {De Castro Barbosa Rodrigues Barata, Carolina and Snook, Rhonda R. and Ritchie, Michael G. and Kosiol, Carolin},
  issn         = {1759-6653},
  journal      = {Genome biology and evolution},
  number       = {7},
  publisher    = {Oxford University Press},
  title        = {{Selection on the fly: Short-term adaptation to an altered sexual selection regime in Drosophila pseudoobscura}},
  doi          = {10.1093/gbe/evad113},
  volume       = {15},
  year         = {2023},
}

@phdthesis{14058,
  abstract     = {Females and males across species are subject to divergent selective pressures arising
from di↵erent reproductive interests and ecological niches. This often translates into a
intricate array of sex-specific natural and sexual selection on traits that have a shared
genetic basis between both sexes, causing a genetic sexual conflict. The resolution of
this conflict mostly relies on the evolution of sex-specific expression of the shared genes,
leading to phenotypic sexual dimorphism. Such sex-specific gene expression is thought
to evolve via modifications of the genetic networks ultimately linked to sex-determining
transcription factors. Although much empirical and theoretical evidence supports this
standard picture of the molecular basis of sexual conflict resolution, there still are a
few open questions regarding the complex array of selective forces driving phenotypic
di↵erentiation between the sexes, as well as the molecular mechanisms underlying sexspecific adaptation. I address some of these open questions in my PhD thesis.
First, how do patterns of phenotypic sexual dimorphism vary within populations,
as a response to the temporal and spatial changes in sex-specific selective forces? To
tackle this question, I analyze the patterns of sex-specific phenotypic variation along
three life stages and across populations spanning the whole geographical range of Rumex
hastatulus, a wind-pollinated angiosperm, in the first Chapter of the thesis.
Second, how do gene expression patterns lead to phenotypic dimorphism, and what
are the molecular mechanisms underlying the observed transcriptomic variation? I
address this question by examining the sex- and tissue-specific expression variation in
newly-generated datasets of sex-specific expression in heads and gonads of Drosophila
melanogaster. I additionally used two complementary approaches for the study of the
genetic basis of sex di↵erences in gene expression in the second and third Chapters of
the thesis.
Third, how does intersex correlation, thought to be one of the main aspects constraining the ability for the two sexes to decouple, interact with the evolution of sexual
dimorphism? I develop models of sex-specific stabilizing selection, mutation and drift
to formalize common intuition regarding the patterns of covariation between intersex
correlation and sexual dimorphism in the fourth Chapter of the thesis.
Alltogether, the work described in this PhD thesis provides useful insights into the
links between genetic, transcriptomic and phenotypic layers of sex-specific variation,
and contributes to our general understanding of the dynamics of sexual dimorphism
evolution.},
  author       = {Puixeu Sala, Gemma},
  isbn         = {978-3-99078-035-0},
  issn         = {2663-337X},
  pages        = {230},
  publisher    = {Institute of Science and Technology Austria},
  title        = {{The molecular basis of sexual dimorphism: Experimental and theoretical characterization of phenotypic, transcriptomic and genetic patterns of sex-specific adaptation}},
  doi          = {10.15479/at:ista:14058},
  year         = {2023},
}

@article{14077,
  abstract     = {The regulatory architecture of gene expression is known to differ substantially between sexes in Drosophila, but most studies performed
so far used whole-body data and only single crosses, which may have limited their scope to detect patterns that are robust across tissues
and biological replicates. Here, we use allele-specific gene expression of parental and reciprocal hybrid crosses between 6 Drosophila
melanogaster inbred lines to quantify cis- and trans-regulatory variation in heads and gonads of both sexes separately across 3 replicate
crosses. Our results suggest that female and male heads, as well as ovaries, have a similar regulatory architecture. On the other hand,
testes display more and substantially different cis-regulatory effects, suggesting that sex differences in the regulatory architecture that
have been previously observed may largely derive from testis-specific effects. We also examine the difference in cis-regulatory variation
of genes across different levels of sex bias in gonads and heads. Consistent with the idea that intersex correlations constrain expression
and can lead to sexual antagonism, we find more cis variation in unbiased and moderately biased genes in heads. In ovaries, reduced cis
variation is observed for male-biased genes, suggesting that cis variants acting on these genes in males do not lead to changes in ovary
expression. Finally, we examine the dominance patterns of gene expression and find that sex- and tissue-specific patterns of inheritance
as well as trans-regulatory variation are highly variable across biological crosses, although these were performed in highly controlled
experimental conditions. This highlights the importance of using various genetic backgrounds to infer generalizable patterns.},
  author       = {Puixeu Sala, Gemma and Macon, Ariana and Vicoso, Beatriz},
  issn         = {2160-1836},
  journal      = {G3: Genes, Genomes, Genetics},
  keywords     = {Genetics (clinical), Genetics, Molecular Biology},
  number       = {8},
  publisher    = {Oxford University Press},
  title        = {{Sex-specific estimation of cis and trans regulation of gene expression in heads and gonads of Drosophila melanogaster}},
  doi          = {10.1093/g3journal/jkad121},
  volume       = {13},
  year         = {2023},
}

@misc{12933,
  abstract     = {Datasets of the publication "Sex-specific estimation of cis and trans regulation of gene expression in heads and gonads of Drosophila melanogaster".},
  author       = {Puixeu Sala, Gemma},
  publisher    = {Institute of Science and Technology Austria},
  title        = {{Data from: Sex-specific estimation of cis and trans regulation of gene expression in heads and gonads of Drosophila melanogaster}},
  doi          = {10.15479/AT:ISTA:12933},
  year         = {2023},
}

@article{12521,
  abstract     = {Differentiated X chromosomes are expected to have higher rates of adaptive divergence than autosomes, if new beneficial mutations are recessive (the “faster-X effect”), largely because these mutations are immediately exposed to selection in males. The evolution of X chromosomes after they stop recombining in males, but before they become hemizygous, has not been well explored theoretically. We use the diffusion approximation to infer substitution rates of beneficial and deleterious mutations under such a scenario. Our results show that selection is less efficient on diploid X loci than on autosomal and hemizygous X loci under a wide range of parameters. This “slower-X” effect is stronger for genes affecting primarily (or only) male fitness, and for sexually antagonistic genes. These unusual dynamics suggest that some of the peculiar features of X chromosomes, such as the differential accumulation of genes with sex-specific functions, may start arising earlier than previously appreciated.},
  author       = {Mrnjavac, Andrea and Khudiakova, Kseniia and Barton, Nicholas H and Vicoso, Beatriz},
  issn         = {2056-3744},
  journal      = {Evolution Letters},
  keywords     = {Genetics, Ecology, Evolution, Behavior and Systematics},
  number       = {1},
  publisher    = {Oxford University Press},
  title        = {{Slower-X: Reduced efficiency of selection in the early stages of X chromosome evolution}},
  doi          = {10.1093/evlett/qrac004},
  volume       = {7},
  year         = {2023},
}