Transcriptome analysis of the response of Burmese python to digestion

Duan, Jinjie; Sanggaard, Kristian W.; Schauser, Leif; Lauridsen, Sanne Enok; Enghild, Jan J.; Schierup, Mikkel H.; Wang, Tobias

doi:10.1093/gigascience/gix057

Cited by 20 publications

(14 citation statements)

References 71 publications

(101 reference statements)

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“…Future work on additional varanid species, and other squamate outgroups, will test these hypotheses. Selective pressures acting on these mitochondrial genes in Komodo dragons is consistent with the increased expression of genes associated with oxidative capacity found in pythons after feeding 97 , 98 .…”

Section: Discussionsupporting

confidence: 73%

Genome of the Komodo dragon reveals adaptations in the cardiovascular and chemosensory systems of monitor lizards

et al. 2019

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Monitor lizards are unique among ectothermic reptiles in that they have high aerobic capacity and distinctive cardiovascular physiology resembling that of endothermic mammals. Here, we sequence the genome of the Komodo dragon Varanus komodoensis, the largest extant monitor lizard, and generate a high-resolution de novo chromosome-assigned genome assembly for V. komodoensis using a hybrid approach of long-range sequencing and single-molecule optical mapping. Comparing the genome of V. komodoensis with those of related species, we find evidence of positive selection in pathways related to energy metabolism, cardiovascular homoeostasis, and haemostasis. We also show species-specific expansions of a chemoreceptor gene family related to pheromone and kairomone sensing in V. komodoensis and other lizard lineages. Together, these evolutionary signatures of adaptation reveal the genetic underpinnings of the unique Komodo dragon sensory and cardiovascular systems, and suggest that selective pressure altered haemostasis genes to help Komodo dragons evade the anticoagulant effects of their own saliva. The Komodo dragon genome is an important resource for understanding the biology of monitor lizards and reptiles worldwide.

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Section: Discussionsupporting

confidence: 73%

Genome of the Komodo dragon reveals adaptations in the cardiovascular and chemosensory systems of monitor lizards

et al. 2019

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“…It is possible that brain cell proliferation may not increase at this point because most of the python's energy is focused toward the immediate need: the energetically expensive process of digesting and absorbing a large meal, in which both body reserves and nutrients from the ingested meal are used to 'pay' for the metabolic costs of feeding (Secor and Diamond, 1995;Starck et al, 2004). Visceral organs of pythons respond to feeding by upregulating many genes related to metabolic processes, cell growth and proliferation, and protective responses to oxidative stress (Andrew et al, 2015(Andrew et al, , 2017Duan et al, 2017), in keeping with the fact that proliferation of cells in these organs occurs during the SDA window. Proliferative activity in the brain does occur during this time period, but it is not extensive until 6 days after feeding.…”

Section: Results and Discussion Treatment Effects On New Cell Densitymentioning

confidence: 99%

Food consumption increases cell proliferation in the python brain

Habroun

Schaffner

Taylor

et al. 2018

Journal of Experimental Biology

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Pythons are model organisms for investigating physiological responses to food intake. While systemic growth in response to food consumption is well documented, what occurs in the brain is currently unexplored. In this study, male ball pythons () were used to test the hypothesis that food consumption stimulates cell proliferation in the brain. We used 5-bromo-12'-deoxyuridine (BrdU) as a cell-birth marker to quantify and compare cell proliferation in the brain of fasted snakes and those at 2 and 6 days after a meal. Throughout the telencephalon, cell proliferation was significantly increased in the 6 day group, with no difference between the 2 day group and controls. Systemic postprandial plasticity occurs quickly after a meal is ingested, during the period of active digestion; however, the brain displays a surge of cell proliferation after most digestion and absorption is complete.

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“…Our transcriptome of the vertebrata core genes was more complete than any previously sequenced transcriptome of other snakes [ 54 ]. However, it is expected that not all genes are expressed in the venom gland.…”

Section: Discussionmentioning

confidence: 99%

“…The purified stonefish toxins commonly present potent hemolytic activities due to its ability to form pores in the cell membrane. Also, these toxins elicit potent hypotension, inhibit neuromuscular function, and induce cardiovascular collapse in humans and native predators [ 54 , 68 ]. The stonustoxin-like were also found in the transcriptome of the venom gland of annelids [ 69 ] and are found in a variety of vertebrates, including the common ostrich, platypus, tasmanian devil, and coelacanth [ 70 ].…”

Section: Discussionmentioning

confidence: 99%

In-depth transcriptome reveals the potential biotechnological application of Bothrops jararaca venom gland

Pereira

Messias

Sorroche

et al. 2020

J. Venom. Anim. Toxins incl. Trop. Dis

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Background: Lack of complete genomic data of Bothrops jararaca impedes molecular biology research focusing on biotechnological applications of venom gland components. Identification of full-length coding regions of genes is crucial for the correct molecular cloning design. Methods: RNA was extracted from the venom gland of one adult female specimen of Bothrops jararaca . Deep sequencing of the mRNA library was performed using Illumina NextSeq 500 platform. De novo assembly of B. jararaca transcriptome was done using Trinity. Annotation was performed using Blast2GO. All predicted proteins after clustering step were blasted against non-redundant protein database of NCBI using BLASTP. Metabolic pathways present in the transcriptome were annotated using the KAAS-KEGG Automatic Annotation Server. Toxins were identified in the B. jararaca predicted proteome using BLASTP against all protein sequences obtained from Animal Toxin Annotation Project from Uniprot KB/Swiss-Pro database. Figures and data visualization were performed using ggplot2 package in R language environment. Results: We described the in-depth transcriptome analysis of B. jararaca venom gland, in which 76,765 de novo assembled isoforms, 96,044 transcribed genes and 41,196 unique proteins were identified. The most abundant transcript was the zinc metalloproteinase-disintegrin-like jararhagin. Moreover, we identified 78 distinct functional classes of proteins, including toxins, inhibitors and tumor suppressors. Other venom proteins identified were the hemolytic lethal factors stonustoxin and verrucotoxin. Conclusion: It is believed that the application of deep sequencing to the analysis of snake venom transcriptomes may represent invaluable insight on their biotechnological potential focusing on candidate molecules.

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Transcriptome analysis of the response of Burmese python to digestion

Cited by 20 publications

References 71 publications

Genome of the Komodo dragon reveals adaptations in the cardiovascular and chemosensory systems of monitor lizards

Genome of the Komodo dragon reveals adaptations in the cardiovascular and chemosensory systems of monitor lizards

Food consumption increases cell proliferation in the python brain

In-depth transcriptome reveals the potential biotechnological application of Bothrops jararaca venom gland

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