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Erratum to: The draft genome of a socially polymorphic halictid bee, Lasioglossum albipes
Genome Biology volume 16, Article number: 34 (2015)
Abstract
During the type-setting of the final version of the article [1] some of the additional files were swapped, and several were completely replaced. The correct files are republished in this Erratum.
Erratum
During the type-setting of the final version of the article [1] some of the additional files were swapped, and several were completely replaced. The editors apologize for the clerical mistake that led to the loss of some of the additional files.
In the final version of the article:
Additional File 8 is wrongly denoted as Additional File 22;
Additional File 9 is wrongly denoted as Additional File 23;
Additional File 10 is wrongly denoted as Additional File 24;
Additional File 11 is wrongly denoted as Additional File 25;
Additional File 12 is wrongly denoted as Additional File 1;
Additional File 14 is wrongly denoted as Additional File 3;
Additional File 20 is wrongly denoted as Additional File 9;
Additional File 21 is wrongly denoted as Additional File 10;
Additional File 22 is wrongly denoted as Additional File 11;
Additional File 23 is wrongly denoted as Additional File 12;
Additional File 25 is wrongly denoted as Additional File 14;
Additional Files 1 is wrongly replaced by Additional File 12;
Additional Files 3 is wrongly replaced by Additional File 14;
Additional Files 5 is wrongly replaced by Additional File 16;
Additional Files 24 is wrongly replaced by Additional File 10.
Additional Files 2, 4, 6, 7, 13, 15, 16, 17, 18 and 19 are correct in the final version of the article.
All Additional Files were correct in the provisional version of the article. Below please find the correct full list of Additional Files associated with this article.
References
Kocher SD, Li C, Yang W, Tan H, Yi SV, Yang X, et al. The draft genome of a socially polymorphic halictid bee, Lasioglossum albipes. Genome Biol. 2013;14:R142.
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Additional information
Cai Li contributed equally to this work.
The online version of the original article can be found under doi:10.1186/gb-2013-14-12-r142.
Additional files
Additional file 1:
Sample information. Sample collection data for specimens used in genome and transcriptome sequencing. Sample names, sex, collection dates, region, and GPS coordinates are specified, as well as the libraries each specimen was used to construct.
Additional file 2:
Repeats in the genome. Repeat annotation was conducting using RepeatMasker. The overlaps between repeats have been excluded before the calculation of the total size. The length and percent of the genome comprised by each repeat is included.
Additional file 3:
Genome assembly comparisons. Comparison of genome assemblies for sequenced hymenopteran species. L. albipes is highly comparable to these other sequenced species.
Additional file 4:
Gene prediction statistics. Gene prediction relied on three strategies: de novo prediction, homology-based approaches using four well-annotated genomes, and RNA sequencing (CCG). Statistics indicate the number of genes annotated with each method, the average transcript and coding sequence (CDS) lengths, the average number of exons per gene, and the average exon and intron lengths.
Additional file 5:
Gene predictions in comparison to other sequenced insect genomes. Comparisons of coding sequence (CDS), mRNA, exon, and intron length were conducted across five arthropod genomes. Amel: Apis mellifera, Cele: Caenorhabditis elegans, Dmel: Drosophila melanogaster, Hsal: Harpegnathos saltator, Lalb: Lasioglossum albipes.
Additional file 6:
Orthology between L. albipes and other species. The top row includes the number of genes annotated in the current L. albipes assembly, and subsequent rows represent the number of orthologs in L. albipes in comparison with each named species, all sequenced ants (H. saltator, C. floridanus, A. echinatior, S. invicta, L. humile, P. barbatus, and A. cephalotes), and all sequenced Hymenoptera (all ants plus A. mellifera and N. vitripennis).
Additional file 7:
Non-coding RNA genes in the genome. Annotated ncRNA summary statistics. The average length of miRNA is for the predicted precursor miRNA. The number of copies annotated in the genome, their average length in basepairs, summed total length, and the percentage of the genome comprised by each element are included.
Additional file 8:
GO enrichment in L. albipes specific genes. The P values were adjusted by FDR and the cutoff of adjusted P value is 0.05.
Additional file 9:
IPR enrichment in L. albipes specific genes. The P values were adjusted by FDR and the cutoff of adjusted P value is 0.05.
Additional file 10:
IPR domains over-represented in the L. albipes lineage. The domains that have at least 10 copies are included in this table. Additional columns report the number of domains characterized in each species. Aech: A. echinatior, Amel: A. mellifera, Cflo: C. floridanus, Dmel: D. melanogaster, Hsal: H. saltator, Lalb: L. albipes, Nvit: N. vitripennis, Sinv: S. invicta.
Additional file 11:
Putatively lost genes in L. albipes lineage. Genes that appear to be lost in the L. albipes lineage are included in this table. The functions are derived from Swiss-Prot annotation database. Amel gene IDs represent the gene annotation symbol in the Apis mellifera genome assembly.
Additional file 12:
IPR domains under-represented in L. albipes lineage. IPR domains under-represented in the L. albipes lineage are included in this table. Additional columns report the number of domains characterized in each species. Aech: A. echinatior, Amel: A. mellifera, Cflo: C. floridanus, Dmel: D. melanogaster, Hsal: H. saltator, Lalb: L. albipes, Nvit: N. vitripennis, Sinv: S. invicta.
Additional file 13:
Phylogenetic tree of yellow and MRJP genes. The MRJP genes are highlighted in light green (top), yellow genes highlighted in light blue (bottom). Red branches are A. mellifera orthologs, and dark blue branches are L. albipes.
Additional file 14:
Putative DNMT homologs in L. albipes. Putative DNMT homologs in L. albipes were identified using a BLASTP search against human, chicken, Nasonia, and honey bee (A. mellifera). L. albipes gene IDs, the target ID, and the E-values are included in this table.
Additional file 15:
Maximum likelihood tree of DNMT orthologs. A BLASTP query of the putative dnmt homologs of L. albipes (Lalb) to human (Hsap), honey bee (Amel), chicken (Ggal), Nasonia (Nvit), and Drosophila (Dmel) revealed four L. albipes genes that are putative DNA methyltransferases. A maximum-likelihood tree depicts the relationships among the three DNMTs and their respective orthologs in each species. Bootstrap values indicate level of support at each node.
Additional file 16:
Distribution of GC content in L. albipes. L. albipes exons are G+C enriched compared to the genomic background, while introns have lower G+C contents compared to the genome.
Additional file 17:
CpG and GpC O/E ratios are negatively correlated. (A) CpG O/E and (B) GpC O/E are strongly negatively correlated with G+C contents. Consequently, CDs exhibit lower GpC O/E compared to the genomic background.
Additional file 18:
CpG and GpC O/E ratios by GC content. Genes and genomic fragments were divided into five groups according to their G+C content. Our results show that across all the groups, CpG O/E values of CDS are still significantly lower than that of the genome background when GC content is minimized, while GpC O/E values of CDS are highly similar to those of genome background.
Additional file 19:
Candidate genes for methylation. A total of 1,801 genes have significantly lower CpG O/E ratios than the genomic background but not significantly different GpC O/E (FDR <0.2). These represent strong candidates for DNA methylation. GeneID names, CpG O/E, GpC O/E, and FDR-corrected P values are included in this table.
Additional file 20:
Genes showing signatures of accelerated evolution in L. albipes. Genes showing signatures of accelerated evolution in L. albipes relative to other tested lineages. Null omega is the expected omega value; L. albipes alternative omega is the estimated omega value for the L. albipes lineage as compared to the other tested lineages.
Additional file 21:
Genes showing signatures of accelerated evolution in Apoidea. Genes showing signatures of accelerated evolution in Apoidea (bees) relative to other tested lineages. Null omega is the expected omega value; Apoidea alternative omega is the estimated omega value for the Apoidea branches as compared to the other tested lineages.
Additional file 22:
GO enrichment of genes undergoing accelerated evolution in L. albipes. Results of Gene Ontology analyses for genes experiencing accelerated evolution in L. albipes. BP: biological process, CC: cellular component, MF: molecular function.
Additional file 23:
IPR enrichment of genes experiencing accelerated evolution in L. albipes. IPR enrichment analysis results with IPR IDs and titles for genes experiences accelerated evolution in L. albipes relative to other tested lineages.
Additional file 24:
KEGG pathway enrichment genes undergoing accelerated evolution in L. albipes. KEGG analysis revealed several pathways associated with genes experiencing accelerated evolution in the L. albipes lineage. MapID and Map Title are specified according to the KEGG database.
Additional file 25:
Individual resequencing. Ka/Ks calculations using genome sequences for a solitary and social female identified six genes that appear to be experiencing positive selection between social forms (FDR <0.1). These genes, the length of the coding sequence, synonymous (Ks) and non-synonymous (Ka) substitutions, and their ratio (Ka/Ks) are summarized in this table.
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Kocher, S.D., Li, C., Yang, W. et al. Erratum to: The draft genome of a socially polymorphic halictid bee, Lasioglossum albipes . Genome Biol 16, 34 (2015). https://doi.org/10.1186/s13059-014-0574-0
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DOI: https://doi.org/10.1186/s13059-014-0574-0