Seba's short-tailed bat (Carollia perspicillata)
Seba's short-tailed bats have a special leaf structure on their nose. This helps to focus and direct sounds when using echolocation: Seba's calls are the most directional sonar beams in any species of echolocating bat! Read more about Seba's short-tailed bats in Wikipedia.
Seba's Short-tailed Bats (Carollia perspicillata) group roosting in old building, photo by Bernard Dupont [CC BY-SA 2.0], via flickr.com
Chromosome-length genome assembly
Download the CarPer_v1_BIUU_HiC.fasta.gz file containing the chromosome-length (2n=20) assembly of the seba's short-tailed bat genome. All modifications with respect to the draft (see below) are annotated in the CarPer_v1_BIUU_HiC.assembly file. Some basic stats associated with the new reference, CarPer_v1_BIUU_HiC, are listed below. The full data release can be explored here.
Contig length (bp) | Number of contigs | Contig N50 (bp) | Longest contig (bp) |
|---|---|---|---|
2,689,025,505 | 1,929,225 | 10,340 | 256,642 |
Scaffold length (bp) | Number of scaffolds | Scaffold N50 (bp) | Longest scaffold (bp) |
|---|---|---|---|
2,732,657,905 | 1,838,869 | 96,450,962 | 480,894,793 |
Draft
The chromosome-length genome assembly is based on the draft assembly CarPer_v1_BIUU (GCA_004027735.1), credited below.
Genereux, D.P., Serres, A., Armstrong, J., Johnson, J., Marinescu, V.D., Murén, E., Juan, D., Bejerano, G., Casewell, N.R., Chemnick, L.G., Damas, J., Di Palma, F., Diekhans, M., Fiddes, I.T., Garber, M., Gladyshev, V.N., Goodman, L., Haerty, W., Houck, M.L., Hubley, R., Kivioja, T., Koepfli, K.-P., Kuderna, L.F.K., Lander, E.S., Meadows, J.R.S., Murphy, W.J., Nash, W., Noh, H.J., Nweeia, M., Pfenning, A.R., Pollard, K.S., Ray, D.A., Shapiro, B., Smit, A.F.A., Springer, M.S., Steiner, C.C., Swofford, R., Taipale, J., Teeling, E.C., Turner-Maier, J., Alfoldi, J., Birren, B., Ryder, O.A., Lewin, H.A., Paten, B., Marques-Bonet, T., Lindblad-Toh, K., Karlsson, E.K., Zoonomia Consortium, 2020. A comparative genomics multitool for scientific discovery and conservation. Nature 587, 240-245. https://doi.org/10.1038/s41586-020-2876-6.
Method
3D Assembly was performed using 3D-DNA pipeline (Dudchenko et al., Science, 2017). The genome was reviewed using Juicebox Assembly Tools (Dudchenko et al., bioRxiv, 2018). See Methods for more information.
Hi-C sample
The blood sample for in situ Hi-C preparation was donated by a female individual, and provided to us by Houston Zoo.
Hi-C Contact maps
Hi-C data was aligned to the draft reference using Juicer (Durand, Shamim et al., Cell Systems, 2016), and contact maps visualizing the alignments with respect to the draft and the new reference were built using 3D-DNA (Dudchenko et al., Science, 2017). The contact maps can be explored below via Juicebox.js interactive tool (Robinson et al., Cell Systems, 2018). (Please note that the interactive figures are scaled 1:2.) To explore the assembly in greater detail, please download the .hic and .assembly files from the data release folder and use Juicebox Assembly Tools (Dudchenko et al., bioRxiv, 2018).
References
If you use this genome assembly in your research, please check that the conditions of use associated with the draft permit it, and acknowledge the following work.
Genereux, D.P., Serres, A., Armstrong, J., Johnson, J., Marinescu, V.D., Murén, E., Juan, D., Bejerano, G., Casewell, N.R., Chemnick, L.G., Damas, J., Di Palma, F., Diekhans, M., Fiddes, I.T., Garber, M., Gladyshev, V.N., Goodman, L., Haerty, W., Houck, M.L., Hubley, R., Kivioja, T., Koepfli, K.-P., Kuderna, L.F.K., Lander, E.S., Meadows, J.R.S., Murphy, W.J., Nash, W., Noh, H.J., Nweeia, M., Pfenning, A.R., Pollard, K.S., Ray, D.A., Shapiro, B., Smit, A.F.A., Springer, M.S., Steiner, C.C., Swofford, R., Taipale, J., Teeling, E.C., Turner-Maier, J., Alfoldi, J., Birren, B., Ryder, O.A., Lewin, H.A., Paten, B., Marques-Bonet, T., Lindblad-Toh, K., Karlsson, E.K., Zoonomia Consortium, 2020. A comparative genomics multitool for scientific discovery and conservation. Nature 587, 240-245. https://doi.org/10.1038/s41586-020-2876-6.
Dudchenko, O., Batra, S.S., Omer, A.D., Nyquist, S.K., Hoeger, M., Durand, N.C., Shamim, M.S., Machol, I., Lander, E.S., Aiden, A.P., Aiden, E.L., 2017. De novo assembly of the Aedes aegypti genome using Hi-C yields chromosome-length scaffolds. Science 356, 92–95. https://doi.org/10.1126/science.aal3327.
Dudchenko, O., Shamim, M.S., Batra, S., Durand, N.C., Musial, N.T., Mostofa, R., Pham, M., Hilaire, B.G.S., Yao, W., Stamenova, E., Hoeger, M., Nyquist, S.K., Korchina, V., Pletch, K., Flanagan, J.P., Tomaszewicz, A., McAloose, D., Estrada, C.P., Novak, B.J., Omer, A.D., Aiden, E.L., 2018. The Juicebox Assembly Tools module facilitates de novo assembly of mammalian genomes with chromosome-length scaffolds for under $1000. bioRxiv 254797. https://doi.org/10.1101/254797.
Disclaimer
This is a work in progress. If you notice any discrepancies in the map or have data that confirms or contradicts the suggested reference, please email us at thednazoo@gmail.com or leave a comment on the Forum.