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    Proteomics and Deep Sequencing Comparison of Seasonally Active Venom Glands in the Platypus Reveals Novel Venom Peptides and Distinct Expression Profiles
    Wong, ESW ; Morgenstern, D ; Mofiz, E ; Gombert, S ; Morris, KM ; Temple-Smith, P ; Renfree, MB ; Whittington, CM ; King, GF ; Warren, WC ; Papenfuss, AT ; Belov, K (AMER SOC BIOCHEMISTRY MOLECULAR BIOLOGY INC, 2012-11)
    The platypus is a venomous monotreme. Male platypuses possess a spur on their hind legs that is connected to glands in the pelvic region. They produce venom only during the breeding season, presumably to fight off conspecifics. We have taken advantage of this unique seasonal production of venom to compare the transcriptomes of in- and out-of-season venom glands, in conjunction with proteomic analysis, to identify previously undiscovered venom genes. Comparison of the venom glands revealed distinct gene expression profiles that are consistent with changes in venom gland morphology and venom volumes in and out of the breeding season. Venom proteins were identified through shot-gun sequenced venom proteomes of three animals using RNA-seq-derived transcripts for peptide-spectral matching. 5,157 genes were expressed in the venom glands, 1,821 genes were up-regulated in the in-season gland, and 10 proteins were identified in the venom. New classes of platypus-venom proteins identified included antimicrobials, amide oxidase, serpin protease inhibitor, proteins associated with the mammalian stress response pathway, cytokines, and other immune molecules. Five putative toxins have only been identified in platypus venom: growth differentiation factor 15, nucleobindin-2, CD55, a CXC-chemokine, and corticotropin-releasing factor-binding protein. These novel venom proteins have potential biomedical and therapeutic applications and provide insights into venom evolution.
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    Evolution of coding and non-coding genes in HOX clusters of a marsupial
    Yu, H ; Lindsay, J ; Feng, Z-P ; Frankenberg, S ; Hu, Y ; Carone, D ; Shaw, G ; Pask, AJ ; O'Neill, R ; Papenfuss, AT ; Renfree, MB (BMC, 2012-06-18)
    BACKGROUND: The HOX gene clusters are thought to be highly conserved amongst mammals and other vertebrates, but the long non-coding RNAs have only been studied in detail in human and mouse. The sequencing of the kangaroo genome provides an opportunity to use comparative analyses to compare the HOX clusters of a mammal with a distinct body plan to those of other mammals. RESULTS: Here we report a comparative analysis of HOX gene clusters between an Australian marsupial of the kangaroo family and the eutherians. There was a strikingly high level of conservation of HOX gene sequence and structure and non-protein coding genes including the microRNAs miR-196a, miR-196b, miR-10a and miR-10b and the long non-coding RNAs HOTAIR, HOTAIRM1 and HOXA11AS that play critical roles in regulating gene expression and controlling development. By microRNA deep sequencing and comparative genomic analyses, two conserved microRNAs (miR-10a and miR-10b) were identified and one new candidate microRNA with typical hairpin precursor structure that is expressed in both fibroblasts and testes was found. The prediction of microRNA target analysis showed that several known microRNA targets, such as miR-10, miR-414 and miR-464, were found in the tammar HOX clusters. In addition, several novel and putative miRNAs were identified that originated from elsewhere in the tammar genome and that target the tammar HOXB and HOXD clusters. CONCLUSIONS: This study confirms that the emergence of known long non-coding RNAs in the HOX clusters clearly predate the marsupial-eutherian divergence 160 Ma ago. It also identified a new potentially functional microRNA as well as conserved miRNAs. These non-coding RNAs may participate in the regulation of HOX genes to influence the body plan of this marsupial.
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    The mammary gland-specific marsupial ELP and eutherian CTI share a common ancestral gene
    Pharo, EA ; De Leo, AA ; Renfree, MB ; Thomson, PC ; Lefevre, CM ; Nicholas, KR (BMC, 2012-06-08)
    BACKGROUND: The marsupial early lactation protein (ELP) gene is expressed in the mammary gland and the protein is secreted into milk during early lactation (Phase 2A). Mature ELP shares approximately 55.4% similarity with the colostrum-specific bovine colostrum trypsin inhibitor (CTI) protein. Although ELP and CTI both have a single bovine pancreatic trypsin inhibitor (BPTI)-Kunitz domain and are secreted only during the early lactation phases, their evolutionary history is yet to be investigated. RESULTS: Tammar ELP was isolated from a genomic library and the fat-tailed dunnart and Southern koala ELP genes cloned from genomic DNA. The tammar ELP gene was expressed only in the mammary gland during late pregnancy (Phase 1) and early lactation (Phase 2A). The opossum and fat-tailed dunnart ELP and cow CTI transcripts were cloned from RNA isolated from the mammary gland and dog CTI from cells in colostrum. The putative mature ELP and CTI peptides shared 44.6%-62.2% similarity. In silico analyses identified the ELP and CTI genes in the other species examined and provided compelling evidence that they evolved from a common ancestral gene. In addition, whilst the eutherian CTI gene was conserved in the Laurasiatherian orders Carnivora and Cetartiodactyla, it had become a pseudogene in others. These data suggest that bovine CTI may be the ancestral gene of the Artiodactyla-specific, rapidly evolving chromosome 13 pancreatic trypsin inhibitor (PTI), spleen trypsin inhibitor (STI) and the five placenta-specific trophoblast Kunitz domain protein (TKDP1-5) genes. CONCLUSIONS: Marsupial ELP and eutherian CTI evolved from an ancestral therian mammal gene before the divergence of marsupials and eutherians between 130 and 160 million years ago. The retention of the ELP gene in marsupials suggests that this early lactation-specific milk protein may have an important role in the immunologically naïve young of these species.
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    Transcriptomic analysis supports similar functional roles for the two thymuses of the tammar wallaby
    Wong, ESW ; Papenfuss, AT ; Heger, A ; Hsu, AL ; Ponting, CP ; Miller, RD ; Fenelon, JC ; Renfree, MB ; Gibbs, RA ; Belov, K (BMC, 2011-08-19)
    BACKGROUND: The thymus plays a critical role in the development and maturation of T-cells. Humans have a single thoracic thymus and presence of a second thymus is considered an anomaly. However, many vertebrates have multiple thymuses. The tammar wallaby has two thymuses: a thoracic thymus (typically found in all mammals) and a dominant cervical thymus. Researchers have known about the presence of the two wallaby thymuses since the 1800s, but no genome-wide research has been carried out into possible functional differences between the two thymic tissues. Here, we used pyrosequencing to compare the transcriptomes of a cervical and thoracic thymus from a single 178 day old tammar wallaby. RESULTS: We show that both the tammar thoracic and the cervical thymuses displayed gene expression profiles consistent with roles in T-cell development. Both thymuses expressed genes that mediate distinct phases of T-cells differentiation, including the initial commitment of blood stem cells to the T-lineage, the generation of T-cell receptor diversity and development of thymic epithelial cells. Crucial immune genes, such as chemokines were also present. Comparable patterns of expression of non-coding RNAs were seen. 67 genes differentially expressed between the two thymuses were detected, and the possible significance of these results are discussed. CONCLUSION: This is the first study comparing the transcriptomes of two thymuses from a single individual. Our finding supports that both thymuses are functionally equivalent and drive T-cell development. These results are an important first step in the understanding of the genetic processes that govern marsupial immunity, and also allow us to begin to trace the evolution of the mammalian immune system.
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    Analysis of the platypus genome suggests a transposon origin for mammalian imprinting
    Pask, AJ ; Papenfuss, AT ; Ager, EI ; Mccoll, KA ; Speed, TP ; Renfree, MB (BIOMED CENTRAL LTD, 2009)
    BACKGROUND: Genomic imprinting is an epigenetic phenomenon that results in monoallelic gene expression. Many hypotheses have been advanced to explain why genomic imprinting evolved in mammals, but few have examined how it arose. The host defence hypothesis suggests that imprinting evolved from existing mechanisms within the cell that act to silence foreign DNA elements that insert into the genome. However, the changes to the mammalian genome that accompanied the evolution of imprinting have been hard to define due to the absence of large scale genomic resources between all extant classes. The recent release of the platypus genome has provided the first opportunity to perform comparisons between prototherian (monotreme; which appear to lack imprinting) and therian (marsupial and eutherian; which have imprinting) mammals. RESULTS: We compared the distribution of repeat elements known to attract epigenetic silencing across the entire genome from monotremes and therian mammals, particularly focusing on the orthologous imprinted regions. There is a significant accumulation of certain repeat elements within imprinted regions of therian mammals compared to the platypus. CONCLUSIONS: Our analyses show that the platypus has significantly fewer repeats of certain classes in the regions of the genome that have become imprinted in therian mammals. The accumulation of repeats, especially long terminal repeats and DNA elements, in therian imprinted genes and gene clusters is coincident with, and may have been a potential driving force in, the development of mammalian genomic imprinting. These data provide strong support for the host defence hypothesis.
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    Genome sequence of an Australian kangaroo, Macropus eugenii, provides insight into the evolution of mammalian reproduction and development
    Renfree, MB ; Papenfuss, AT ; Deakin, JE ; Lindsay, J ; Heider, T ; Belov, K ; Rens, W ; Waters, PD ; Pharo, EA ; Shaw, G ; Swwong, E ; Lefevre, CM ; Nicholas, KR ; Kuroki, Y ; Wakefield, MJ ; Zenger, KR ; Wang, C ; Ferguson-Smith, M ; Nicholas, FW ; Hickford, D ; Yu, H ; Short, KR ; Siddle, HV ; Frankenberg, SR ; Chew, KY ; Menzies, BR ; Stringer, JM ; Suzuki, S ; Hore, TA ; Delbridge, ML ; Mohammadi, A ; Schneider, NY ; Hu, Y ; O'Hara, W ; Al Nadaf, S ; Wu, C ; Feng, Z-P ; Cocks, BG ; Wang, J ; Flicek, P ; Searle, SMJ ; Fairley, S ; Beal, K ; Herrero, J ; Carone, DM ; Suzuki, Y ; Sugano, S ; Toyoda, A ; Sakaki, Y ; Kondo, S ; Nishida, Y ; Tatsumoto, S ; Mandiou, I ; Hsu, A ; McColl, KA ; Lansdell, B ; Weinstock, G ; Kuczek, E ; McGrath, A ; Wilson, P ; Men, A ; Hazar-Rethinam, M ; Hall, A ; Davis, J ; Wood, D ; Williams, S ; Sundaravadanam, Y ; Muzny, DM ; Jhangiani, SN ; Lewis, LR ; Morgan, MB ; Okwuonu, GO ; Ruiz, SJ ; Santibanez, J ; Nazareth, L ; Cree, A ; Fowler, G ; Kovar, CL ; Dinh, HH ; Joshi, V ; Jing, C ; Lara, F ; Thornton, R ; Chen, L ; Deng, J ; Liu, Y ; Shen, JY ; Song, X-Z ; Edson, J ; Troon, C ; Thomas, D ; Stephens, A ; Yapa, L ; Levchenko, T ; Gibbs, RA ; Cooper, DW ; Speed, TP ; Fujiyama, A ; Graves, JAM ; O'Neill, RJ ; Pask, AJ ; Forrest, SM ; Worley, KC (BMC, 2011)
    BACKGROUND: We present the genome sequence of the tammar wallaby, Macropus eugenii, which is a member of the kangaroo family and the first representative of the iconic hopping mammals that symbolize Australia to be sequenced. The tammar has many unusual biological characteristics, including the longest period of embryonic diapause of any mammal, extremely synchronized seasonal breeding and prolonged and sophisticated lactation within a well-defined pouch. Like other marsupials, it gives birth to highly altricial young, and has a small number of very large chromosomes, making it a valuable model for genomics, reproduction and development. RESULTS: The genome has been sequenced to 2 × coverage using Sanger sequencing, enhanced with additional next generation sequencing and the integration of extensive physical and linkage maps to build the genome assembly. We also sequenced the tammar transcriptome across many tissues and developmental time points. Our analyses of these data shed light on mammalian reproduction, development and genome evolution: there is innovation in reproductive and lactational genes, rapid evolution of germ cell genes, and incomplete, locus-specific X inactivation. We also observe novel retrotransposons and a highly rearranged major histocompatibility complex, with many class I genes located outside the complex. Novel microRNAs in the tammar HOX clusters uncover new potential mammalian HOX regulatory elements. CONCLUSIONS: Analyses of these resources enhance our understanding of marsupial gene evolution, identify marsupial-specific conserved non-coding elements and critical genes across a range of biological systems, including reproduction, development and immunity, and provide new insight into marsupial and mammalian biology and genome evolution.