Literature DB >> 35351186

Transcriptome resequencing data for rock pigeon (Columba livia).

Hamed Kharrati-Koopaee1,2, Ali Esmailizadeh3,4, Fatemeh Sabahi5.   

Abstract

OBJECTIVE: How do birds navigate their way? It is one of the interesting question about homing pigeons, however the genetic of navigation has reminded as a puzzle. Optic lobe, olfactory bulb, hippocampus and cere were collected for RNA sampling. The generated RNA-seq represent RNA resequencing data for racing homer (homing) pigeon and other rock pigeon breeds. The obtained data set can provide new insight about hippocampus role and GSR contribution to pigeon magnetoreception. DATA DESCRIPTION: To investigate the navigation ability of rock pigeon breeds, 60 whole transcriptome sequence data sets related to homing pigeon, Shiraz tumblers, feral pigeons and Persian high flyers were obtained. RNA extraction was performed from three brain regions (optic lobe, olfactory bulb, hippocampus) and cere. Paired-end 150 bp short reads (Library size 350 bp) were sequenced by Illumina Hiseq 2000. In this way, about 342.1 Gbp and 130.3 Gb data were provided. The whole transcriptome data sets have been deposited at the NCBI SRA database (PRJNA532674). The submitted data set may play critical role to describe the mechanism of navigation ability of rock pigeon breeds.
© 2022. The Author(s).

Entities:  

Keywords:  Navigation; RNA-seq; Rock pigeon

Mesh:

Year:  2022        PMID: 35351186      PMCID: PMC8961952          DOI: 10.1186/s13104-022-06007-1

Source DB:  PubMed          Journal:  BMC Res Notes        ISSN: 1756-0500


Objective

Iran is a large country that contains a special range of altitudes and climates. Therefore, there is a remarkable genetic diversity of animal species [1, 2]. In Iran, due to several reasons such as decoration, food source and dry droppings pigeons have been considered for many years. Ancient pigeon houses (pigeon towers) in Iran plateau are an interesting historical example of pigeon production [3]. Next generation sequencing (NGS) platforms have revolutionized the DNA sequencing. One of the most popular platforms of NGS is whole transcriptome sequencing (RNA-seq). Whole transcriptome analysis plays a critical role in order to describe the genomic features, identifying biological pathways and networks underlying environmental challenges or different biological systems. The outcomes of RNA-seq data analysis provides new insights about biological puzzles [4]. Previously, we carried out a RNA-seq data analysis among different breeds of rock pigeons in order to explain the navigation ability of different breeds of rock pigeon in Iran [5]. Three brain regions (hippocampus, olfactory bulb, optic lobe) and also cere were selected from Persian high flyers, feral, Shiraz tumblers and homing pigeons. It should be noted that, the navigation ability of studied rock pigeon’s breeds can be classified in different groups. Persian high flyer and Shiraz tumblers are similar in navigation ability. Homing pigeon is known as racing pigeon for orientation of long distances. In contrast, feral pigeons have the weakest navigation ability. Hippocampus through complex structure contribute to learning and memory [5]. The neural basis for olfactory navigation in pigeons has been reported and also the olfactory bulb and hippocampus contribute to navigation in pigeons and mammals [6]. It should be noted that, optic lobe as a part of the midbrain, processes visual, auditory and somatosensory information. Therefore, optic lobe may critical role in navigation, however, no accurate evidence is available for this claim [7]. Various hypotheses are available about navigation and migration ability of birds such as processing spatial cues (hippocampus) [8], magnetoreception [9], olfaction (olfactory bulb), audition (auditory cortex) and visual cues (entopallium) [7]. In order to identify the differentially expressed genes in selected brain regions, 60 whole transcriptomes were sequenced from rock pigeon breeds. The provided data sets showed that the most number of differentially expressed genes (DEGs, 234) were in hippocampus. In contrast to hippocampus, few DEGs were detected in the olfactory bulb (15 genes) and the optic lobe (68 genes) between homing pigeons and other breeds [5]. The most DEGs were reported in hippocampus, for instance candidate genes such as MFSD2A, KIRREL3, KCNAB2, and MAPK8IP2 were significantly up-regulated at least 1.3-fold in the homing pigeon. The outcomes of GO enrichment analysis showed that the DEGs in the hippocampus were overrepresented in terms such as cognition, learning or memory and associative learning. In addition, the potential role of GSR in pigeon magnetoreception was reported [5]. The presented data set can provide new perspective about navigation ability of rock pigeon breeds and also explanation of navigation mechanism by RNA-seq analysis.

Data description

It should be noted that, the outcomes of transcriptome data analysis and additional methods details have previously been published in Molecular Biology and Evolution journal [5]. In order to investigate the navigation ability of rock pigeon breeds, four rock pigeon breeds, including 4 homing pigeons [30-45], 3 Shiraz tumblers [62-73], 4 feral pigeons [14-29], 4 Persian high flyers [46-61] were collected for RNA sampling from hippocampus (HC), olfactory bulb (OB) and optic lobe (OP) and cere (NS) tissues (Table 1). Pigeon samples were collected from different regions (Tehran, Marvdasht, Shiraz and Kerman) in Iran. In current study, 15 samples of rock pigeons were collected, however RNA sampling was carried out for OP, OB, NS and HC tissues (four different tissues) for each breed. In this way, the BioProject contains 60 RNA-seq samples [11]. Table 1 shows the all direct links for each tissue of rock pigeons. RNA was extracted by QIAGEN kit protocol. Agarose gel (1%) electrophoresis and Nanodrop [ratio 260/280 (nm)] were used to evaluation of the extracted RNA. Paired-end 150 bp short reads (Library size 350 bp) were sequenced by Illumina Hiseq 2000 [5]. Around 342.1 Gbp and 130.3 Gb data were provided [5] (Table 1). Btrim (version: 2.0) was applied to adaptors trimming and quality control of RNA-seq samples. Tophat2 (v2.0.13) [10] under default parameters was utilized to map the short reads to the Cliv_1.0 rock pigeon reference genome [12]. Cufflinks (v2.1.1) [13] was used to assemble the transcripts, with the cuffquant and cuffnorm programs in cufflinks used to quantify and normalize the transcript/gene expression abundances, and cuffdiff (located in the cufflinks software) used to detect differentially expressed genes using a Poisson dispersion model with a false discovery rate (FDR < 0.05). The provided data sets provide new insight about importance of the hippocampus for homing ability, and the potential role of GSR in pigeon magnetoreception.
Table 1

The complete RNA-seq data sets of rock pigeons at NCBI SRA database

LabelName of data fileFile type (file extension)Data repository and identifier
Data set 1RNA-seq of optic lobe from feral rock pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102900 [14]

Data set 2RNA-seq of olfactory bulb from feral rock pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102916 [15]

Data set 3RNA-seq of cere from feral rock pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102933 [16]

Data set 4RNA-seq of hippocampus from feral rock pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102949 [17]

Data set 5RNA-seq of optic lobe from feral rock pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102901 [18]

Data set 6RNA-seq of optic lobe from feral rock pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102902 [19]

Data set 7RNA-seq of optic lobe from feral rock pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102903 [20]

Data set 8RNA-seq of olfactory bulb from feral rock pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102917 [21]

Data set 9RNA-seq of olfactory bulb from feral rock pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102918 [22]

Data set 10RNA-seq of olfactory bulb from feral rock pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102919 [23]

Data set 11RNA-seq of cere from feral rock pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102936 [24]

Data set 12RNA-seq of hippocampus from feral rock pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102950 [25]

Data set 13RNA-seq of hippocampus from feral rock pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102951 [26]

Data set 14RNA-seq of hippocampus from feral rock pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102952 [27]

Data set 15RNA-seq of cere from feral rock pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102934 [28]

Data set 16RNA-seq of cere from feral rock pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102935 [29]

Data set 17RNA-seq of optic lobe from homing pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102907 [30]

Data set 18RNA-seq of olfactory bulb from homing pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102924 [31]

Data set 19RNA-seq of cere from homing pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102940 [32]

Data set 20RNA-seq of hippocampus from homing pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102921 [33]

Data set 21RNA-seq of hippocampus from homing pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102898 [34]

Data set 22RNA-seq of hippocampus from homing pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102899 [35]

Data set 23RNA-seq of optic lobe from homing pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102908 [36]

Data set 24RNA-seq of optic lobe from homing pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102909 [37]

Data set 25RNA-seq of hippocampus from homing pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102910 [38]

Data set 26RNA-seq of optic lobe from homing pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102911 [39]

Data set 27RNA-seq of olfactory bulb from homing pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102925 [40]

Data set 28RNA-seq of olfactory bulb from homing pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102926 [41]

Data set 29RNA-seq of olfactory bulb from homing pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102927 [42]

Data set 30RNA-seq of cere from homing pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102941 [43]

Data set 31RNA-seq of cere from homing pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102942 [44]

Data set 32RNA-seq of cere from homing pigeonFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102944 [45]

Data set 33RNA-seq of optic lobe from Persian high flyerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102912 [46]

Data set 34RNA-seq of olfactory bulb from Persian high flyerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102928 [47]

Data set 35RNA-seq of cere from Persian high flyerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102945 [48]

Data set 36RNA-seq of hippocampus from Persian high flyerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102932 [49]

Data set 37RNA-seq of hippocampus from Persian high flyerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102943 [50]

Data set 38RNA-seq of cere from Persian high flyerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102946 [51]

Data set 39RNA-seq of cere from Persian high flyerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102947 [52]

Data set 40RNA-seq of cere from Persian high flyerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102948 [53]

Data set 41RNA-seq of hippocampus from Persian high flyerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102954 [54]

Data set 42RNA-seq of hippocampus from Persian high flyerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102955 [55]

Data set 43RNA-seq of olfactory bulb from Persian high flyerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102929 [56]

Data set 44RNA-seq of olfactory bulb from Persian high flyerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102930 [57]

Data set 45RNA-seq of olfactory bulb from Persian high flyerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102931 [58]

Data set 46RNA-seq of optic lobe from Persian high flyerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102913 [59]

Data set 47RNA-seq of optic lobe from Persian high flyerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102914 [60]

Data set 48RNA-seq of optic lobe from Persian high flyerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102915 [61]

Data set 49RNA-seq of optic lobe from Shiraz tumblerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102904 [62]

Data set 50RNA-seq of olfactory bulb from Shiraz tumblerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102920 [63]

Data set 51RNA-seq of cere from Shiraz tumblerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102937 [64]

Data set 52RNA-seq of hippocampus from Shiraz tumblerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102953 [65]

Data set 53RNA-seq of hippocampus from Shiraz tumblerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102896 [66]

Data set 54RNA-seq of hippocampus from Shiraz tumblerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102897 [67]

Data set 55RNA-seq of optic lobe from Shiraz tumblerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102905 [68]

Data set 56RNA-seq of optic lobe from Shiraz tumblerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102906 [69]

Data set 57RNA-seq of olfactory bulb from Shiraz tumblerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102922 [70]

Data set 58RNA-seq of olfactory bulb from Shiraz tumblerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102923 [71]

Data set 59RNA-seq of cere from Shiraz tumblerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102938 [72]

Data set 60RNA-seq of cere from Shiraz tumblerFastq (fq.gz)

NCBI SRA database

https://identifiers.org/ncbi/insdc.sra:SRR10102939 [73]

The complete RNA-seq data sets of rock pigeons at NCBI SRA database NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102900 [14] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102916 [15] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102933 [16] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102949 [17] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102901 [18] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102902 [19] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102903 [20] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102917 [21] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102918 [22] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102919 [23] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102936 [24] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102950 [25] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102951 [26] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102952 [27] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102934 [28] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102935 [29] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102907 [30] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102924 [31] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102940 [32] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102921 [33] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102898 [34] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102899 [35] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102908 [36] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102909 [37] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102910 [38] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102911 [39] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102925 [40] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102926 [41] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102927 [42] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102941 [43] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102942 [44] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102944 [45] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102912 [46] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102928 [47] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102945 [48] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102932 [49] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102943 [50] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102946 [51] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102947 [52] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102948 [53] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102954 [54] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102955 [55] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102929 [56] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102930 [57] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102931 [58] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102913 [59] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102914 [60] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102915 [61] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102904 [62] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102920 [63] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102937 [64] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102953 [65] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102896 [66] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102897 [67] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102905 [68] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102906 [69] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102922 [70] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102923 [71] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102938 [72] NCBI SRA database https://identifiers.org/ncbi/insdc.sra:SRR10102939 [73]

Limitations

In the current study, only four breeds of rock pigeon were investigated and also four tissues were sampled for RNA-seq analysis. In this way, the data set could not present a comprehensive information of brain regions for navigation ability in rock pigeons.
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