DNA ZOO

Today we share some exciting news: a new paper is out today in the Science journal by DNA Zoo and collaborators!

In the manuscript, titled "3D genomics across the tree of life reveals condensin II as a determinant of architecture type" we use the DNA Zoo data to explore the nuclear architecture for 27 species across the eukaryotic tree of life.

We show that all of the chromosomal architectures observed across the species fall into one of just two types: those chromosome territory-like (with chromosomes occupying distinct nuclear subvolumes) and those Rabl-like (resembling the arrangement observed during cell division, with centromeres and/or telomeres clustered and chromosomes often "folded" along the telomere-to-centromere axis). We show that Rabl-like architecture in species is often associated with disruption of condensin II, a protein known to be responsible for lengthwise compaction of chromosomes.

We perform an experiment (led by our colleagues Claire Hoencamp and Benjamin Rowland at the Netherlands Cancer Institute) to disrupt condensin II in human cells. This transforms a territorial chromosome architecture typical of human cells into Rabl. We follow up with some physical simulations, led by our collaborators Sumitabha Brahmachari and José Onuchic at the Center for Theoretical Biological Physics at Rice University, suggesting that condensin II disruption results in long and floppy chromosomes that cannot generate mechanical tensions enough to disrupt the Rabl arrangement "inherited" from cell division. Read more about this in the manuscript and in the joint Baylor College of Medicine and Rice University press release.

As part of the effort described in the manuscript, we publish 17 new chromosome-length genome assemblies. We include the links to the assembly pages for those previously published and those shared today below.

We also generate chromosome-length haploblocks for 7 non-human species using a new Hi-C-based phaser, now part of 3D-DNA. The phaser uses a list of deduplicated Hi-C contacts, as generated by the Juicer pipeline (Durand, Shamim et al., 2016), to phase variants encoded in a vcf (variant call format) file. It plays well with prephased data, e.g. from linked reads, long reads or population data, and generates phasing contact maps to validate the results that can be further polished in Juicebox Assembly Tools. So, JBAT can now not only help with genome assembly, but also assists with phasing!

We explore the coverage requirements for whole chromosome phasing, and show that Hi-C based phasing works in most species, including human. However, we show that in species where the homologs are not separate during interphase, like Drosophila melanogaster, this method cannot be used. This highlights how the principles of genome assembly can vary across different complex eukaryotes.

We will write about the phasing piece separately, and in the meantime, please stay tuned for a few blog posts highlighting some of the newly shared genome assemblies in the next week or so!

• Tammar wallaby (Macropus eugenii)

• Burmese python (Python bivittatus)

• Red piranha (Pygocentrus nattereri)

• Bamboo shark (Chiloscyllium punctatum)

• Arctic lamprey (Lethenteron camtschaticum)

• Sea squirt (Ciona intestinalis-robusta)

• European lancelet (Branchiostoma lanceolatum)

• Sea urchin (Strongylocentrotus purpuratus)

• Tardigrade (Hypsibius dujardini)

• Oriental liver fluke (Clonorchis sinensis)

• California sea hare (Aplysia californica)

• Moss animal (Cristatella mucedo)

• Stony coral (Acropora millepora)

• Sea gooseberry (Pleurobrachia bachei)

• Common mushroom (Agaricus bisporus)

• Chinese muntjac (Muntiacus reevesi)

• Indian muntjac (Muntiacus muntjak)

With a plush mane of vibrant orange fur, the resemblance of the golden lion tamarin (Leontopithecus rosalia) to an actual lion stops there. While the golden lion tamarin is the largest of the four tamarins species, adult monkeys are only 15-25 centimeters tall and weigh around 400-800 grams [1]. Native to the coastal forests of Eastern Brazil, the wild population of golden lion tamarins has deceased due to drastic habitat loss. A survey in 2018 found the wild population to be around 3,200 individuals [2]. Thanks to breeding and reintroduction programs at zoos around the world, this number has risen from the previous estimate of 1,400 individuals in 2015.

Golden lion tamarins live in troops of 2-8 monkeys, consisting of a breeding pair and their offspring. The commonly give birth to twins, occasionally having triplets and quadruplets [3]. They're very vocal, communicating with each other via chirps, screams, and yelps. In the wild, golden lion tamarins will sleep in new dens in hollow trees every night. This is likely a survival tactic to prevent predators from tracking them [4].

Today, we release the genome assembly of the golden lion tamarin, Leontopithecus rosalia. This is a $1K genome assembly with a scaffold N50 = 121 Mb and a contig N50 = 56 Kb. For assembly procedure details, please see our Methods page. Many thanks Coari from the Houston Zoo for providing the sample for this genome assembly. Read more about Coari and her partner Zuno in this blog post by the Houston Zoo!

Check out below how the chromosomes in the new assembly relate to those of the white-tufted-ear marmoset Callithrix jacchus and human. For comparison with the marmoset we used the recent genome assembly from McDonnell Genome Institute at Washington University, here, and the human genome assembly used is hg38 (GRCh38.p13), by the Genome Reference Consortium.

This is the 11th primate genome the DNA Zoo has released! Interested in more New World primates? Check out, e.g., the assembly pages for the pygmy marmoset and the Bolivian squirrel monkey.

The golden perch (Macquaria ambigua) is one of the most widespread and abundant large native fishes in the lowlands of the Murray-Darling Basin of Eastern Australia and represents an important recreational and commercial fisheries species (1).

This native fish covers approximately 2,250,000 km2 and its distribution exposes the species to a wide variety of climatic and habitat conditions, ranging from isolated groundwater-fed waterholes to broad lowland river channels and streams (2). Distribution and abundance have been affected by environmental changes such as those caused by dams and weirs which have affected stream flows and water temperature regimes and acted as barriers to extensive migrations of adult fish.

Golden perch are medium-bodied and long-lived fish, reaching around 550mm total length and 27 years of age in river habitats. The golden perch is also considered a periodic species. Although they may be strongly site attached for long periods, the golden perch can undertake migrations of tens to thousands of kilometres across a range of river conditions at certain times. They are also highly fecund, with females producing more than half a million eggs (3). The golden perch is reported to spawn between October and April when water temperatures are above 23 degrees Celsius or when warm temperatures coincide with a rise in water level (1).

It is a species member of the threatened "Lowland Riverine Fish Community of the Southern Murray Darling Basin" which is listed under the Flora and Fauna Guarantee Act (1988) as its natural range and abundance has declined since European settlement. It is also listed as part of the endangered Lower Murray River ecological community (NSW Fisheries Management Act, 1994) (4).

To support ongoing management and conservation efforts, DNA Zoo has been working with James O’Dwyer, Dr Nick Murphy and Dr Katherine Harrisson at La Trobe University, Melbourne, to obtain a chromosome-length assembly genome of the golden perch. In 2020 we also produced a chromosome-length assembly of the golden perch’s sister species the Macquarie perch.

The chromosome-length assembly we share today is based on the draft assembly available on NCBI generated by Han Ming Gan, Deakin Genomics Centre. The draft genome assembly of the Murray Darling Basin golden perch lineage was created using MaSuRCA v. 3.2.6 (Zimin et al. 2013), using Oxford Nanopore MinION reads polished with short-insert size Illumina NovaSeq reads.

The above draft was scaffolded to 24 chromosomes with 100,680,198M Hi-C reads generated by DNA Zoo labs using 3D-DNA (Dudchenko et al., 2017) and Juicebox Assembly Tools (Dudchenko et al., 2018). See our Methods page for more details.

The sample for Hi-C was kindly provided by Matthew McLellan and Dr Meaghan Duncan from the Narrandera Fisheries Centre (NSW Department of Primary Industries). The Hi-C work was supported by resources provided by DNA Zoo Australia, The University of Western Australia (UWA), La Trobe University team with funding from Australian Research Council-funded project DE190100636. We gratefully acknowledge the computational support from the Pawsey Supercomputing Centre with funding from the Australian Government and the Government of Western Australia.

The following people contributed to the Hi-C chromosome-length upgrade of the project: Erez Aiden, Olga Dudchenko, Ashling Charles & Parwinder Kaur.

Blog by: Ashling Charles, Katherine Harrisson, James O’Dawyer and Parwinder Kaur.

Citations

1. Ebner, B. C., O. Scholz, and B. Gawne. "Golden perch Macquaria ambigua are flexible spawners in the Darling River, Australia." (2009): 571-578.

2. Faulks, Leanne K., Dean M. Gilligan, and Luciano B. Beheregaray. "Clarifying an ambiguous evolutionary history: range‐wide phylogeography of an Australian freshwater fish, the golden perch (Macquaria ambigua)." Journal of Biogeography 37.7 (2010): 1329-1340.

3. Wright, Daniel W., et al. "Size, growth and mortality of riverine golden perch (Macquaria ambigua) across a latitudinal gradient." Marine and Freshwater Research 71.12 (2020): 1651-1661.

4. O'connor, J. P., D. J. O'mahony, and J. M. O'mahony. "Movements of Macquaria ambigua, in the Murray River, south‐eastern Australia." Journal of Fish Biology 66.2 (2005): 392-403.