DNA ZOO

The koala is recognized worldwide as a symbol of Australia, who got their name from the word Dharug gula, meaning no water. It was at one time thought, since the animals were not observed to come down from trees often, that they were able to survive without drinking. The secret lay in their diet: the eucalyptus leaves. The leaves have a high-water content, so the koala does not need to drink often. But the notion that they do not need to drink water at all is a myth [1].

Koalas typically inhabit open eucalyptus woodlands. They are super cute, cuddly and fluffy, yet very territorial wild species. Koalas are evolutionarily and biologically distinct from other marsupials. The modern koala is the only living representative of the marsupial family Phascolarctidae, a family that once included several genera and species. During the Oligocene and Miocene, koalas lived in rainforests and had less specialised diets [2]. During the Miocene, the Australian continent began drying out, leading to the decline of rainforests and the spread of open Eucalyptus woodlands. The genus Phascolarctos split from Litokoala in the late Miocene [2][3] and had several adaptations that allowed it to live on a specialised eucalyptus diet [4].

Unlike kangaroos and eucalyptus-eating possums, koalas are hindgut fermenters, and their digestive retention can last for up to 100 hours in the wild, or up to 200 hours in captivity. They can eat highly toxic eucalyptus leaves that would kill most other mammals, but they are picky eaters, so very prone to habitat loss. They are able to digest the toxins present in eucalyptus leaves due to their expansion of cytochrome P450 gene family of metabolic enzymes, which breaks down these poisons in the liver [5].

Koalas are listed as a vulnerable species by the International Union for Conservation of Nature [6]. The animal was hunted heavily in the early 20th century for its fur, and large-scale cullings in Queensland resulted in a public outcry that initiated a movement to protect the species. Sanctuaries were established, and translocation efforts moved to new regions koalas whose habitat had become fragmented or reduced. Among the many threats to their existence are habitat destruction caused by agriculture, urbanization, droughts and associated bushfires, some related to climate change.

The animals are particularly vulnerable to bushfires due to their slow movements and the flammability of eucalyptus trees. The koala instinctively seeks refuge in the higher branches, where it is vulnerable to intense heat and flames. Bushfires also fragment the animal's habitat, which restricts their movement and leads to population decline and loss of genetic diversity [7].

The chromosome-length assembly we share today is based on a draft assembly phaCin_unsw_v4.1 submitted to NCBI by The Earlham Institute, UK with full refseq representative genome data (Johnson et al., Nat. Genet. 2018). Please visit The Koala Genome Consortium website and learn about the efforts by the Koala Genome Project, a pioneering collaborative research led by Australian geneticist Rebecca Nicole Johnson AM, with far-reaching and significant implications for the conservation of Australian koalas!

The above draft was scaffolded with in situ 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.

We gratefully acknowledge the collaboration with Natasha Tay, Harry Butler Institute, Murdoch University, and samples provided by the Ranger Red's Zoo & Conservation park. The Hi-C work was enabled by resources provided by DNA Zoo Australia, the University of Western Australia (UWA) and by DNA Zoo, Aiden Lab at the Baylor College of Medicine (BCM) with additional computational resources and support from the Pawsey Supercomputing Centre with funding from the Australian Government and the Government of Western Australia.

A high-quality genome sequence is an essential resource required to implement genomics data into conservation management initiatives. More than 80% of the current 200 Australian national vertebrate recovery plans have genetic action listed in the species recovery plan with only less than 15% with any genomic data available. The genomic resources for understanding genetic diversity is of utmost importance in species conservation.

This chromosome-length genome assembly enables a highly detailed 3D view of the genome architecture for koala, karyotype evolution studies, identification of new genome linked markers and learning how the overall structure of genes evolve from a zoonotic point of view. Having koala DNA organized into 8 chromosomes (see map below) in the present release provides a cost-effective method for fast and reliable analyses options for conservation management initiatives. We hope the improved assembly will also offer further insights into the species’ genetic susceptibility to diseases like koala retrovirus (KoRV) and Chlamydia, serve as a basis for innovative vaccines, and facilitate new conservation management solutions that incorporate the species’ population and genetic structure, such as facilitating gene flow via habitat connectivity or translocations.

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

Blog by: Parwinder Kaur

Citations

1. "Bigger and better 'Blinky Drinkers' to quench koalas' thirst this summer". NSW Environment & Heritage. Archived from the original on 22 July 2019.

2. Louys, J.; Aplin, K.; Beck, R. M. D.; Archer, M. (2009). "Cranial anatomy of Oligo-Miocene koalas (Diprotodontia: Phascolarctidae): Stages in the evolution of an extreme leaf-eating specialization". Journal of Vertebrate Paleontology. 29 (4): 981–92. doi:10.1671/039.029.0412. S2CID 86356713.

3. Black, K.; Archer, M.; Hand, S. J. (2012). "New Tertiary koala (Marsupialia, Phascolarctidae) from Riversleigh, Australia, with a revision of phascolarctid phylogenetics, paleoecology, and paleobiodiversity". Journal of Vertebrate Paleontology. 32 (1): 125–38. doi:10.1080/02724634.2012.626825. S2CID 86152273.

4. Tyndale-Biscoe, p. 226 Archived 3 June 2016 at the Wayback Machine.

5. Koalas are eating their forests into extinction — even feasting on poisonous eucalyptus plants National Post, 4 July 2018.

6. Woinarski, J. & Burbidge, A.A. 2020. Phascolarctos cinereus (amended version of 2016 assessment). The IUCN Red List of Threatened Species 2020.

7. Moyal, pp. 209–11 Archived 11 June 2016 at the Wayback Machine.

Naked mole-rats Heterocephalus glaber are born wrinkled and pink, with few whisker-like hairs to help them navigate their surroundings. They are quite comfortable in their own skin, and keep their birthday suits and style throughout their life span!

And that life span (>30 years) is quite considerable: naked mole-rats are extremely long-lived compared to other rodents. That's not their only superpower. They famously have an incredibly decreased risk of cancer [1]. They have reduced pain sensitivity.

They are also exceptionally built for a life underground [2]. Their lips are stationed behind their front teeth, allowing them to dig with their shovel-like teeth without filling their mouths with dirt. Interestingly, their teeth can operate similar to chopsticks, separating and moving together to aid their digging [3]. They're able to survive without or in very low oxygen concentrations for long periods of time; 18 minutes at 0% oxygen and around 5 hours at 5% oxygen! Their small eyes and poor vision aren't a hindrance, as they rarely leave the dark tunnels they dig.

They are also social! Specifically, the naked mole-rat social structure is eusocial, operating more similar to a bee-hive than other rodent colonies. One queen mole-rat rules the colony while producing offspring. Like a well-oiled machine, each mole-rat has a purpose in the colony. "Workers" spend their lives digging tunnels, gathering food, and raising the pups while "soldiers" protect the colony from predators. As colonies tend to be highly inbred, "dispersers" seek to leave their native colonies in search of others to live and mate with. These dispersers are behaviorally and morphologically distinct from their peers, generally having a higher body fat content [4].

Today, we share the chromosome-length assembly for the naked mole-rat, Heterocephalus glaber. This genome assembly is a Hi-C upgrade for the draft genome assembly generated by Keane M. et al., Bioinformatics (2014). Please visit the Naked Mole-Rat Genome Resource at http://www.naked-mole-rat.org for the draft genome assembly and more existing genomic resources for this fascinating rodent! Many thanks to Kong from the Houston Zoo for providing the sample used for this chromosome-length Hi-C upgrade (check out the interactive map below).

We're no strangers to rodents here at the DNA Zoo as this is our 18th chromosome-length genome from the rodentia order! Check out the assembly page for the only other known eusocial mammal, the Damaraland mole-rat! Read also this paper by Zhou et al., 2020 with an independent assembly of a Canadian beaver (also assembled independently in our collection, here) and the naked mole-rat.

Citations:

Keane, M., Craig, T., Alföldi, J., Berlin, A. M., Johnson, J., Seluanov, A., Gorbunova, V., Di Palma, F., Lindblad-Toh, K., Church, G. M., & de Magalhães, J. P. (2014). The Naked Mole Rat Genome Resource: facilitating analyses of cancer and longevity-related adaptations. Bioinformatics (Oxford, England), 30(24), 3558–3560. https://doi.org/10.1093/bioinformatics/btu579

Blog post by Karen Holm, DVM, Klaus-Peter Koepfli, PhD, and H.C. Lim, PhD

The Eastern mountain bongo (Tragelaphus eurycerus isaaci) is the largest montane forest dwelling antelope species native to Kenya. The bongo is a member of the Bovidae family and the tribe Tragelaphini or spiral horned antelope, including eland, nyala and sitatunga (Bibi, 2013; Chen et al. 2019). They weigh-in around 200-280kg of body weight and females carry horns as well as the males. They are a rare and elusive species with fewer than 100 surviving in 5 isolated populations in Kenya. Therefore, the IUCN Red List of Threatened Species considers the Eastern mountain bongo Critically Endangered. Another subspecies, the Western bongo, differentiated by morphological and phenotypic evidence, extends across the Dahomey Gap from the Democratic Republic of the Congo to Sierra Leone and is disjunct from the Eastern subspecies.

Conservation efforts of the Eastern subspecies have included a repatriation in 2004 of 18 animals to a semi-captive population at the Mount Kenya Conservancy. There have been many successful births and the herd is growing. In 2019, the Kenya Wildlife Service put together a national recovery and action plan for the Eastern mountain bongo for 2019-2023.

Bongos are unique in that females have 34 chromosomes and males have 33, with an acrocentric Y chromosome that is fused with one of the smaller chromosomeS. In addition, two types of X chromosomes exist, one being acrocentric and the other submetacentric, with the acrocentric X being similar to other tragelaphine antelopes (Benirschke et al., 1982).

Today we share the chromosome-length assembly for the Eastern Mountain Bongo. We thank The Wildlife Conservation Center in Virginia for providing the sample for the initial 10x Genomics Chromium linked-read and Supernova 2.0 de novo assembly, which was funded and assembled by H.C. Lim in the George Mason University Evolutionary Genomics Lab. The genome was then analyzed and annotated by Karen Holm, DVM. This draft assembly is in the process of being written up and published.

We also thank Bernadette and Howard, the two eastern bongos at the Houston Zoo who have provided samples for the chromosome-length Hi-C upgrade. (Read more exciting news from the eastern bongo family at the Houston Zoo here!)

See below how the chromosomes of the eastern bongo (2n=33/34) relate to those of cattle (2n=60).

Citations:

Benirschke, K., Kumamoto, A., Esra, G., & Crocker, K. (1982). The chromosomes of the bongo, Taurotragus (Boocerus) eurycerus. Cytogenetic and Genome Research, 34(1-2), 10-18. doi:10.1159/000131788

Bibi, F. (2013). A multi-calibrated mitochondrial phylogeny of extant Bovidae (Artiodactyla, Ruminantia) and the importance of the fossil record to systematics. BMC Evolutionary Biology, 13(1), 166. doi:10.1186/1471-2148-13-166

Chen, L., Qiu, Q., Jiang, Y., Wang, K., Lin, Z., Li, Z., . . . Wang, W. (2019). Large-scale ruminant genome sequencing provides insights into their evolution and distinct traits. Science, 364(6446). doi:10.1126/science.aav6202