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187 papers • 13,263 citations • Sorted by year • Download PDF (PDF by citations)
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1GC Content Across Insect Genomes: Phylogenetic Patterns, Causes and Consequences
Journal of Molecular Evolution, 2024, 92, 138-152
1.75Citations (PDF)
2Diversity, duplication, and genomic organization of homeobox genes in Lepidoptera
Genome Research, 2023, 33, 32-44
4.610Citations (PDF)
3Rapid Evolution of the Embryonically Expressed Homeobox Gene<i>LEUTX</i>within Primates
Genome Biology and Evolution, 2023, 15,
2.50Citations (PDF)
4The genome sequence of the buff-tip, Phalera bucephala (Linnaeus, 1758)
Wellcome Open Research, 2022, 7, 28
1.02Citations (PDF)
5The genome sequence of the square-spot rustic, Xestia xanthographa (Schiffermuller, 1775)
Wellcome Open Research, 2022, 7, 37
1.02Citations (PDF)
6The genome sequence of the angle shades moth, Phlogophora meticulosa (Linnaeus, 1758)
Wellcome Open Research, 2022, 7, 89
1.01Citations (PDF)
7The genome sequence of the silver Y moth, Autographa gamma (Linnaeus, 1758)
Wellcome Open Research, 2022, 7, 100
1.01Citations (PDF)
8The genome sequence of the large yellow underwing, Noctua pronuba (Linnaeus, 1758)
Wellcome Open Research, 2022, 7, 119
1.01Citations (PDF)
9The genome sequence of the Clifden nonpareil, Catocala fraxini (Linnaeus, 1758)
Wellcome Open Research, 2022, 7, 129
1.00Citations (PDF)
10PRD-Class Homeobox Genes in Bovine Early Embryos: Function, Evolution, and Overlapping Roles
Molecular Biology and Evolution, 2022, 39,
4.75Citations (PDF)
11The genome sequence of the brimstone moth, Opisthograptis luteolata (Linnaeus, 1758)
Wellcome Open Research, 2022, 7, 227
1.00Citations (PDF)
12Compromised Function of the Pancreatic Transcription Factor PDX1 in a Lineage of Desert Rodents
Journal of Mammalian Evolution, 2021, 28, 965-977
1.70Citations (PDF)
13Evidence from oyster suggests an ancient role for Pdx in regulating insulin gene expression in animals
Nature Communications, 2021, 12,
14.110Citations (PDF)
14Dynamic Molecular Evolution of Mammalian Homeobox Genes: Duplication, Loss, Divergence and Gene Conversion Sculpt PRD Class Repertoires
Journal of Molecular Evolution, 2021, 89, 396-414
1.710Citations (PDF)
15The genome sequence of the poplar hawk-moth, Laothoe populi  (Linnaeus, 1758)
Wellcome Open Research, 2021, 6, 237
1.01Citations (PDF)
16The genome sequence of the snout, Hypena proboscidalis (Linnaeus, 1758)
Wellcome Open Research, 2021, 6, 236
1.00Citations (PDF)
17The genome sequence of the yellow-tail moth, Euproctis similis (Fuessly, 1775)
Wellcome Open Research, 2021, 6, 227
1.00Citations (PDF)
18The genome sequence of the white ermine, Spilosoma lubricipeda Linnaeus 1758
Wellcome Open Research, 2021, 6, 271
1.00Citations (PDF)
19The genome sequence of the peach blossom moth, Thyatira batis (Linnaeus, 1758)
Wellcome Open Research, 2021, 6, 267
1.01Citations (PDF)
20The genome sequence of Svensson’s copper underwing, Amphipyra berbera Rungs, 1949
Wellcome Open Research, 2021, 6, 314
1.00Citations (PDF)
21The genome sequence of the sycamore, Acronicta aceris (Linnaeus, 1758)
Wellcome Open Research, 2021, 6, 326
1.01Citations (PDF)
22The genome sequence of the iron prominent, Notodonta dromedarius (Linnaeus, 1767)
Wellcome Open Research, 2021, 6, 341
1.00Citations (PDF)
23The genome sequence of the broad-bordered yellow underwing, Noctua fimbriata (Schreber, 1759)
Wellcome Open Research, 2021, 6, 345
1.02Citations (PDF)
24The genome sequence of the yellow-tail moth, Euproctis similis (Fuessly, 1775)
Wellcome Open Research, 2021, 6, 227
1.01Citations (PDF)
25The genome sequence of the lime hawk-moth, Mimas tiliae (Linnaeus, 1758)
Wellcome Open Research, 2021, 6, 357
1.02Citations (PDF)
26The genome sequence of the swallow prominent, Pheosia tremula (Clerck, 1759)
Wellcome Open Research, 2021, 6, 335
1.01Citations (PDF)
27The genome sequence of the spectacle, Abrostola tripartita Hufnagel, 1766
Wellcome Open Research, 2021, 6, 330
1.01Citations (PDF)
28The genome sequence of the bramble shoot moth, Notocelia uddmanniana (Linnaeus, 1758)
Wellcome Open Research, 2021, 6, 348
1.00Citations (PDF)
29Divergent genes in gerbils: prevalence, relation to GC-biased substitution, and phenotypic relevance
BMC Evolutionary Biology, 2020, 20,
3.43Citations (PDF)
30Mutation of amphioxus Pdx and Cdx demonstrates conserved roles for ParaHox genes in gut, anus and tail patterning
BMC Biology, 2020, 18,
4.016Citations (PDF)
31Jellyfish genomes reveal distinct homeobox gene clusters and conservation of small RNA processing
Nature Communications, 2020, 11,
14.145Citations (PDF)
32Widespread patterns of gene loss in the evolution of the animal kingdom
Nature Ecology and Evolution, 2020, 4, 519-523
7.676Citations (PDF)
33Gene profiling of head mesoderm in early zebrafish development: insights into the evolution of cranial mesoderm
EvoDevo, 2019, 10,
3.318Citations (PDF)
34Of eyes and embryos: subfunctionalization of the<i>CRX</i>homeobox gene in mammalian evolution
Proceedings of the Royal Society B: Biological Sciences, 2019, 286, 20190830
2.65Citations (PDF)
35Reconstruction of the ancestral metazoan genome reveals an increase in genomic novelty
Nature Communications, 2018, 9,
14.188Citations (PDF)
36Amphioxus functional genomics and the origins of vertebrate gene regulation
Nature, 2018, 564, 64-70
40.1181Citations (PDF)
37Historical and current patterns of gene flow in the butterfly <i>Pararge aegeria</i>
Journal of Biogeography, 2018, 45, 1628-1639
3.513Citations (PDF)
38Mouse Obox and Crxos modulate preimplantation transcriptional profiles revealing similarity between paralogous mouse and human homeobox genes
EvoDevo, 2018, 9,
3.313Citations (PDF)
39Lineage-specific rediploidization is a mechanism to explain time-lags between genome duplication and evolutionary diversification
Genome Biology, 2017, 18,
8.4118Citations (PDF)
40New genes from old: asymmetric divergence of gene duplicates and the evolution of development
Philosophical Transactions of the Royal Society B: Biological Sciences, 2017, 372, 20150480
4.187Citations (PDF)
41Novel and divergent genes in the evolution of placental mammals
Proceedings of the Royal Society B: Biological Sciences, 2017, 284, 20171357
2.617Citations (PDF)
42A sister of <i>NANOG</i> regulates genes expressed in pre-implantation human development
Open Biology, 2017, 7, 170027
3.411Citations (PDF)
43Genome sequence of a diabetes-prone rodent reveals a mutation hotspot around the ParaHox gene cluster
Proceedings of the National Academy of Sciences of the United States of America, 2017, 114, 7677-7682
7.724Citations (PDF)
44The dawn of amphioxus molecular biology - a personal perspective
International Journal of Developmental Biology, 2017, 61, 585-590
1.33Citations (PDF)
45Never Ending Analysis of a Century Old Evolutionary Debate: “Unringing” the Urmetazoon Bell
Frontiers in Ecology and Evolution, 2016, 4,
2.214Citations (PDF)
46Evolutionary origin and functional divergence of totipotent cell homeobox genes in eutherian mammals
BMC Biology, 2016, 14,
4.039Citations (PDF)
47Diversity of human and mouse homeobox gene expression in development and adult tissues
BMC Developmental Biology, 2016, 16,
2.520Citations (PDF)
48Conservation, Duplication, and Divergence of Five Opsin Genes in Insect Evolution
Genome Biology and Evolution, 2016, 8, 579-587
2.565Citations (PDF)
49Reinforcing the Egg-Timer: Recruitment of Novel Lophotrochozoa Homeobox Genes to Early and Late Development in the Pacific Oyster
Genome Biology and Evolution, 2015, 7, 677-688
2.537Citations (PDF)
50The Hox cluster microRNA miR-615: a case study of intronic microRNA evolution
EvoDevo, 2015, 6,
3.317Citations (PDF)
51A Burst of miRNA Innovation in the Early Evolution of Butterflies and Moths
Molecular Biology and Evolution, 2015, 32, 1161-1174
4.732Citations (PDF)
52Scenarios for the making of vertebrates
Nature, 2015, 520, 450-455
40.153Citations (PDF)
53Cdx ParaHox genes acquired distinct developmental roles after gene duplication in vertebrate evolution
BMC Biology, 2015, 13,
4.011Citations (PDF)
54A Diversity of Conserved and Novel Ovarian MicroRNAs in the Speckled Wood (Pararge aegeria)
PLoS ONE, 2015, 10, e0142243
2.512Citations (PDF)
55Strepsiptera, Phylogenomics and the Long Branch Attraction Problem
PLoS ONE, 2014, 9, e107709
2.548Citations (PDF)
56Ancient Expansion of the Hox Cluster in Lepidoptera Generated Four Homeobox Genes Implicated in Extra-Embryonic Tissue Formation
PLoS Genetics, 2014, 10, e1004698
3.345Citations (PDF)
57Genomic organisation of the seven ParaHox genes of coelacanths
Journal of Experimental Zoology Part B: Molecular and Developmental Evolution, 2014, 322, 352-358
2.03Citations (PDF)
58Enigmatic Orthology Relationships between Hox Clusters of the African Butterfly Fish and Other Teleosts Following Ancient Whole-Genome Duplication
Molecular Biology and Evolution, 2014, 31, 2592-2611
4.731Citations (PDF)
59Discovery and Classification of Homeobox Genes in Animal Genomes
Methods in Molecular Biology, 2014, , 3-18
0.04Citations (PDF)
60A family of diatom-like silicon transporters in the siliceous loricate choanoflagellates
Proceedings of the Royal Society B: Biological Sciences, 2013, 280, 20122543
2.638Citations (PDF)
61The genomes of four tapeworm species reveal adaptations to parasitism
Nature, 2013, 496, 57-63
40.1550Citations (PDF)
62How are comparative genomics and the study of microRNAs changing our views on arthropod endocrinology and adaptations to the environment?
General and Comparative Endocrinology, 2013, 188, 16-22
1.617Citations (PDF)
63Evolution of homeobox genes
Wiley Interdisciplinary Reviews: Developmental Biology, 2013, 2, 31-45
3.9228Citations (PDF)
64Extensive Chordate and Annelid Macrosynteny Reveals Ancestral Homeobox Gene Organization
Molecular Biology and Evolution, 2012, 29, 157-165
4.741Citations (PDF)
65A genome-wide view of transcription factor gene diversity in chordate evolution: less gene loss in amphioxus?
Briefings in Functional Genomics, 2012, 11, 177-186
2.834Citations (PDF)
66The oyster genome reveals stress adaptation and complexity of shell formation
Nature, 2012, 490, 49-54
40.11,787Citations (PDF)
67Evolution of the Alx homeobox gene family: parallel retention and independent loss of the vertebrate Alx3 gene
Evolution & Development, 2011, 13, 343-351
2.033Citations (PDF)
68<scp>HomeoDB2</scp>: functional expansion of a comparative homeobox gene database for evolutionary developmental biology
Evolution & Development, 2011, 13, 567-568
2.094Citations (PDF)
69The Animal Kingdom
2011, ,
19Citations (PDF)
70From genomes to morphology: a view from amphioxus
Acta Zoologica, 2010, 91, 81-86
1.18Citations (PDF)
71Ancient homeobox gene loss and the evolution of chordate brain and pharynx development: deductions from amphioxus gene expression
Proceedings of the Royal Society B: Biological Sciences, 2010, 277, 3381-3389
2.612Citations (PDF)
72Degenerate evolution of the hedgehog gene in a hemichordate lineage
Proceedings of the National Academy of Sciences of the United States of America, 2009, 106, 7491-7494
7.79Citations (PDF)
73Comprehensive survey and classification of homeobox genes in the genome of amphioxus, Branchiostoma floridae
Development Genes and Evolution, 2008, 218, 579-590
0.864Citations (PDF)
74Asymmetry in a pterobranch hemichordate and the evolution of left–right patterning
Developmental Dynamics, 2008, 237, 3634-3639
1.732Citations (PDF)
75Developmental biology of pterobranch hemichordates: History and perspectives
Genesis, 2008, 46, 587-591
1.230Citations (PDF)
76The origins of graptolites and other pterobranchs: a journey from ‘Polyzoa’
Lethaia, 2008, 41, 303-316
1.314Citations (PDF)
77The amphioxus genome and the evolution of the chordate karyotype
Nature, 2008, 453, 1064-1071
40.11,320Citations (PDF)
78HomeoDB: a database of homeobox gene diversity
Evolution & Development, 2008, 10, 516-518
2.060Citations (PDF)
79Do cnidarians have a ParaHox cluster? Analysis of synteny around a <i>Nematostella</i> homeobox gene cluster
Evolution & Development, 2008, 10, 725-730
2.030Citations (PDF)
80The Urbilaterian Super-Hox cluster
Trends in Genetics, 2008, 24, 259-262
13.035Citations (PDF)
81Correlating Bayesian date estimates with climatic events and domestication using a bovine case study
Biology Letters, 2008, 4, 370-374
2.767Citations (PDF)
82The amphioxus genome illuminates vertebrate origins and cephalochordate biology
Genome Research, 2008, 18, 1100-1111
4.6413Citations (PDF)
83Protochordates
Methods in Molecular Biology, 2008, , 563-566
0.01Citations (PDF)
84Wholemount In Situ Hybridization to Amphioxus Embryos
Methods in Molecular Biology, 2008, , 703-706
0.02Citations (PDF)
85The butterfly Danaus chrysippus (Lepidoptera: Nymphalidae) in Kenya is variably infected with respect to genotype and body size by a maternally transmitted male-killing endosymbiont (Spiroplasma)
International Journal of Tropical Insect Science, 2007, 27, 62
1.118Citations (PDF)
86A Degenerate ParaHox Gene Cluster in a Degenerate Vertebrate
Molecular Biology and Evolution, 2007, 24, 2681-2686
4.730Citations (PDF)
87Annotation, nomenclature and evolution of four novel homeobox genes expressed in the human germ line
Gene, 2007, 387, 7-14
2.439Citations (PDF)
88The origins of multicellularity: a multi-taxon genome initiative
Trends in Genetics, 2007, 23, 113-118
13.0176Citations (PDF)
89Origin and evolution of a myxozoan worm
Integrative and Comparative Biology, 2007, 47, 752-758
2.018Citations (PDF)
90<i>Buddenbrockia</i> Is a Cnidarian Worm
Science, 2007, 317, 116-118
38.2145Citations (PDF)
91A Gbx homeobox gene in amphioxus: Insights into ancestry of the ANTP class and evolution of the midbrain/hindbrain boundary
Developmental Biology, 2006, 295, 40-51
1.986Citations (PDF)
92Patterns of conservation and change in honey bee developmental genes
Genome Research, 2006, 16, 1376-1384
4.6127Citations (PDF)
93An unusual choanoflagellate protein released by Hedgehog autocatalytic processing
Proceedings of the Royal Society B: Biological Sciences, 2006, 273, 401-407
2.652Citations (PDF)
94Breakup of a homeobox cluster after genome duplication in teleosts
Proceedings of the National Academy of Sciences of the United States of America, 2006, 103, 10369-10372
7.762Citations (PDF)
95The evolution of homeobox genes: Implications for the study of brain development
Brain Research Bulletin, 2005, 66, 484-490
3.466Citations (PDF)
96No more than 14: the end of the amphioxus Hox cluster
International Journal of Biological Sciences, 2005, , 19-23
8.658Citations (PDF)
97Amphioxus and ascidian Dmbx homeobox genes give clues to the vertebrate origins of midbrain development
Development (Cambridge), 2004, 131, 3285-3294
3.067Citations (PDF)
98Polyploidy in vertebrate ancestry: Ohno and beyond
Biological Journal of the Linnean Society, 2004, 82, 425-430
1.559Citations (PDF)
99The Trox-2 Hox/ParaHox gene of Trichoplax (Placozoa) marks an epithelial boundary
Development Genes and Evolution, 2004, 214, 170-175
0.894Citations (PDF)
100An antecedent of the MHC-linked genomic region in amphioxus
Immunogenetics, 2004, 55, 782-784
2.835Citations (PDF)
101Eleven daughters of NANOG☆
Genomics, 2004, 84, 229-238
2.7117Citations (PDF)
102Phylogenomics of Eukaryotes: Impact of Missing Data on Large Alignments
Molecular Biology and Evolution, 2004, 21, 1740-1752
4.7342Citations (PDF)
103Title is missing!
Journal of Structural and Functional Genomics, 2003, 3, 75-84
0.055Citations (PDF)
104Dispersal of NK homeobox gene clusters in amphioxus and humans
Proceedings of the National Academy of Sciences of the United States of America, 2003, 100, 5292-5295
7.778Citations (PDF)
105More genes in vertebrates?
2003, , 75-84
2Citations (PDF)
106Were vertebrates octoploid?
Philosophical Transactions of the Royal Society B: Biological Sciences, 2002, 357, 531-544
4.1176Citations (PDF)
107Orphan Worm Finds a Home: Buddenbrockia is a Myxozoan
Molecular Biology and Evolution, 2002, 19, 968-971
4.755Citations (PDF)
108Bayesian Phylogenetic Analysis Supports Monophyly of Ambulacraria and of Cyclostomes
Zoological Science, 2002, 19, 593-599
0.8125Citations (PDF)
109Exploiting genomics in evolutionary developmental biology
International Congress Series, 2002, 1246, 217-229
0.20Citations (PDF)
110Ciona
Current Biology, 2002, 12, R609
3.91Citations (PDF)
111An orphan PRD class homeobox gene expressed in mouse brain and limb development
Development Genes and Evolution, 2002, 212, 293-297
0.811Citations (PDF)
112Ciona intestinalis ParaHox genes: evolution of Hox/ParaHox cluster integrity, developmental mode, and temporal colinearity
Molecular Phylogenetics and Evolution, 2002, 24, 412-417
2.990Citations (PDF)
113The Mnx homeobox gene class defined by HB9 , MNR2 and amphioxus AmphiMnx
Development Genes and Evolution, 2001, 211, 103-107
0.848Citations (PDF)
114Beyond the Hox: how widespread is homeobox gene clustering?
Journal of Anatomy, 2001, 199, 13-23
1.871Citations (PDF)
115Ancient origin of the Hox gene cluster
Nature Reviews Genetics, 2001, 2, 33-38
19.1203Citations (PDF)
116Hsp70 sequences indicate that choanoflagellates are closely related to animals
Current Biology, 2001, 11, 967-970
3.966Citations (PDF)
117An Amphioxus Emx Homeobox Gene Reveals Duplication During Vertebrate Evolution
Molecular Biology and Evolution, 2000, 17, 1520-1528
4.727Citations (PDF)
118The amphioxus Hox cluster: deuterostome posterior flexibility andHox14
Evolution & Development, 2000, 2, 284-293
2.0144Citations (PDF)
119Conservation and elaboration of Hox gene regulation during evolution of the vertebrate head
Nature, 2000, 408, 854-857
40.1148Citations (PDF)
120Evidence for 14 homeobox gene clusters in human genome ancestry
Current Biology, 2000, 10, 1059-1062
3.9163Citations (PDF)
121Rare genomic changes as a tool for phylogenetics
Trends in Ecology and Evolution, 2000, 15, 454-459
9.1552Citations (PDF)
122The future of evolutionary developmental biology
Nature, 1999, 402, C41-C44
40.172Citations (PDF)
123Dicyemids are higher animals
Nature, 1999, 401, 762-762
40.153Citations (PDF)
124Amphioxus type I keratin cDNA and the evolution of intermediate filament genes
1999, 285, 50-56
21Citations (PDF)
125Colinear and Segmental Expression of Amphioxus Hox Genes
Developmental Biology, 1999, 213, 131-141
1.9138Citations (PDF)
126Introduction: Gene duplication in development and evolution
Seminars in Cell and Developmental Biology, 1999, 10, 515-516
5.45Citations (PDF)
127Gene duplication: Past, present and future
Seminars in Cell and Developmental Biology, 1999, 10, 541-547
5.4157Citations (PDF)
128The ParaHox gene cluster is an evolutionary sister of the Hox gene cluster
Nature, 1998, 392, 920-922
40.1406Citations (PDF)
129Major Transitions in Animal Evolution: A Developmental Genetic Perspective
American Zoologist, 1998, 38, 829-842
0.763Citations (PDF)
130Neural Tube Is Partially Dorsalized by Overexpression ofHrPax-37:The Ascidian Homologue ofPax-3andPax-7
Developmental Biology, 1997, 187, 240-252
1.9104Citations (PDF)
131Cloning and analysis of an HMG gene from the lamprey Lampetra fluviatilis: gene duplication in vertebrate evolution
Gene, 1997, 184, 99-105
2.433Citations (PDF)
132Vertebrate evolution: Something fishy about Hox genes
Current Biology, 1997, 7, R570-R572
3.941Citations (PDF)
133Evolution of 28S Ribosomal DNA in Chaetognaths: Duplicate Genes and Molecular Phylogeny
Journal of Molecular Evolution, 1997, 44, 135-144
1.772Citations (PDF)
134HoxGenes and Chordate Evolution
Developmental Biology, 1996, 173, 382-395
1.9390Citations (PDF)
135Old head on young shoulders
Nature, 1996, 383, 490-490
40.1107Citations (PDF)
136Origin of patterning in neural tubes
Nature, 1996, 384, 123-123
40.174Citations (PDF)
137Archetypal organization of the amphioxus Hox gene cluster
Nature, 1994, 370, 563-566
40.1502Citations (PDF)
138Gene duplications and the origins of vertebrate development
Development (Cambridge), 1994, 1994, 125-133
3.0592Citations (PDF)
139Development of the zootype
Nature, 1993, 363, 307-308
40.14Citations (PDF)
140Molecular evolution and diversification of the vestimentiferan tube worms
Journal of the Marine Biological Association of the United Kingdom, 1993, 73, 437-452
0.852Citations (PDF)
141Mice and flies head to head
Nature, 1992, 358, 627-628
40.140Citations (PDF)
142Problems and paradigms: Hoemeobox genes in vertebrate evolution
BioEssays, 1992, 14, 267-273
2.3117Citations (PDF)
143Cloning and evolutionary analysis of msh-like homeobox genes from mouse, zebrafish and ascidian
Gene, 1991, 98, 253-257
2.4114Citations (PDF)
144Cloning of fish zinc-finger genes related to Krox-20 and Krox-24
Biochemical and Biophysical Research Communications, 1991, 179, 1220-1224
2.110Citations (PDF)
145Cloning of segment polarity gene homologues from the unsegmented brachiopod <i>Terebratulina retusa</i> (Linnaeus)
FEBS Letters, 1991, 291, 211-213
2.814Citations (PDF)
146A novel avian W chromosome DNA repeat sequence in the lesser black-backed gull (Larus fuscus)
Chromosoma, 1990, 99, 243-250
2.231Citations (PDF)
147Conservation ofengrailed-like homeobox sequences during vertebrate evolution
FEBS Letters, 1990, 277, 250-252
2.847Citations (PDF)
148Pursuing the functions of vertebrate homeobox genes: Progress and prospects
Trends in Neurosciences, 1989, 12, 206-209
13.47Citations (PDF)
149Homeobox genes and the vertebrate head
Development (Cambridge), 1988, 103, 17-24
3.023Citations (PDF)
150Phylogenetic distribution of Antennapedia-like homoeo boxes
Nature, 1986, 321, 251-253
40.183Citations (PDF)
151The Effect of Gene Duplication on Homology
Novartis Foundation Symposium, 0, , 226-242
1.07Citations (PDF)
152Functional genomics of supergene-controlled behavior in the white-throated sparrow
Faculty Reviews, 0, 10,
4.50Citations (PDF)
153The genome sequence of the dun-bar pinion, Cosmia trapezina (Linnaeus, 1758)
Wellcome Open Research, 0, 7, 189
1.02Citations (PDF)
154The genome sequence of the clay, Mythimna ferrago (Fabricius, 1787)
Wellcome Open Research, 0, 7, 177
1.02Citations (PDF)
155The genome sequence of the 6-spot burnet, Zygaena filipendulae (Linnaeus, 1758)
Wellcome Open Research, 0, 7, 197
1.00Citations (PDF)
156The genome sequence of the peacock moth, Macaria notata (Linnaeus, 1758)
Wellcome Open Research, 0, 7, 228
1.00Citations (PDF)
157The genome sequence of the European badger, Meles meles (Linnaeus, 1758)
Wellcome Open Research, 0, 7, 239
1.03Citations (PDF)
158The genome sequence of the pale mottled willow, Caradrina clavipalpis (Scopoli, 1763)
Wellcome Open Research, 0, 7, 225
1.01Citations (PDF)
159The genome sequence of the sallow kitten, Furcula furcula (Clerck, 1759)
Wellcome Open Research, 0, 7, 229
1.00Citations (PDF)
160The genome sequence of the smoky wainscot, Mythimna impura (Hubner, 1808)
Wellcome Open Research, 0, 7, 226
1.02Citations (PDF)
161The genome sequence of the yellow-legged clearwing, Synanthedon vespiformis (Linnaeus, 1761)
Wellcome Open Research, 0, 7, 233
1.00Citations (PDF)
162The genome sequence of the merveille du jour, Griposia aprilina (Linnaeus, 1758)
Wellcome Open Research, 0, 7, 247
1.00Citations (PDF)
163The genome sequence of the garden grass-veneer, Chrysoteuchia culmella (Linnaeus, 1758)
Wellcome Open Research, 0, 7, 248
1.00Citations (PDF)
164The genome sequence of the acorn piercer, Pammene fasciana (Linnaeus, 1761)
Wellcome Open Research, 0, 7, 258
1.01Citations (PDF)
165The genome sequence of the Seraphim, Lobophora halterata (Hufnagel, 1767)
Wellcome Open Research, 0, 7, 313
1.00Citations (PDF)
166The genome sequence of the Rustic Shoulder-knot, Apamea sordens (Hufnagel, 1766)
Wellcome Open Research, 0, 8, 51
1.01Citations (PDF)
167The genome sequence of the Miller, Acronicta leporina (Linnaeus, 1758)
Wellcome Open Research, 0, 8, 49
1.00Citations (PDF)
168The genome sequence of the Mouse Moth, Amphipyra tragopoginis (Clerck 1759)
Wellcome Open Research, 0, 8, 54
1.00Citations (PDF)
169The genome sequence of the Green-brindled Crescent, Allophyes oxyacanthae (Linnaeus, 1758)
Wellcome Open Research, 0, 8, 53
1.00Citations (PDF)
170The genome sequence of the Brown Scallop, Philereme vetulata (Denis and Schiffermüller, 1775)
Wellcome Open Research, 0, 8, 58
1.00Citations (PDF)
171The genome sequence of the Dark Arches Apamea monoglypha (Hufnagel, 1766)
Wellcome Open Research, 0, 8, 63
1.00Citations (PDF)
172The genome sequence of the Shuttle-shaped Dart, Agrotis puta (Hübner, 1803)
Wellcome Open Research, 0, 8, 84
1.02Citations (PDF)
173The genome sequence of the Burnished Brass, Diachrysia chrysitis (Linnaeus, 1758)
Wellcome Open Research, 0, 8, 82
1.00Citations (PDF)
174The genome sequence of the Small Square-spot, Diarsia rubi (Vieweg, 1790)
Wellcome Open Research, 0, 8, 210
1.02Citations (PDF)
175The genome sequence of the Brindled Green, Dryobotodes eremita (Fabricius, 1775)
Wellcome Open Research, 0, 8, 208
1.00Citations (PDF)
176The genome sequence of the Brindled Flat-body, Agonopterix arenella (Denis &amp; Schiffermüller, 1775)
Wellcome Open Research, 0, 8, 214
1.00Citations (PDF)
177The genome sequence of the Olive Pearl, Udea olivalis (Denis &amp; Schiffermüller, 1775)
Wellcome Open Research, 0, 8, 238
1.01Citations (PDF)
178The genome sequence of the Streamer, Anticlea derivata (Denis &amp; Schiffermüller, 1775)
Wellcome Open Research, 0, 8, 254
1.01Citations (PDF)
179The genome sequence of the Cinnabar Moth, Tyria jacobaeae (Linnaeus, 1758)
Wellcome Open Research, 0, 8, 255
1.02Citations (PDF)
180The genome sequence of the Ash-bark Knot-horn, Euzophera pinguis (Haworth, 1811)
Wellcome Open Research, 0, 8, 228
1.00Citations (PDF)
181The genome sequence of the Currant Clearwing, Synanthedon tipuliformis (Clerck, 1759)
Wellcome Open Research, 0, 8, 300
1.00Citations (PDF)
182The genome sequence of the Pinion-spotted Pug, Eupithecia insigniata (Hübner, 1790)
Wellcome Open Research, 0, 8, 305
1.01Citations (PDF)
183The genome sequence of the Water Carpet, Lampropteryx suffumata (Denis &amp; Schiffermiiller, 1775)
Wellcome Open Research, 0, 8, 304
1.00Citations (PDF)
184The genome sequence of the Brindled Beauty, Lycia hirtaria (Clerck, 1759)
Wellcome Open Research, 0, 8, 303
1.01Citations (PDF)
185The genome sequence of the Oak Rustic, Dryobota labecula (Esper, 1788)
Wellcome Open Research, 0, 8, 317
1.01Citations (PDF)
186The genome sequence of the White Satin, Leucoma salicis (Linnaeus, 1758)
Wellcome Open Research, 0, 8, 323
1.00Citations (PDF)
187The genome sequence of the Mullein moth, Shargacucullia verbasci (Linnaeus, 1758)
Wellcome Open Research, 0, 8, 346
1.00Citations (PDF)