{"_buckets": {"deposit": "02e6a028-faee-4dae-a654-80e7797e3a3c"}, "_deposit": {"created_by": 1, "id": "1026", "owners": [1], "pid": {"revision_id": 0, "type": "depid", "value": "1026"}, "status": "published"}, "_oai": {"id": "oai:ir.soken.ac.jp:00001026", "sets": ["20"]}, "author_link": ["0", "0", "0"], "item_1_biblio_info_21": {"attribute_name": "書誌情報（ソート用）", "attribute_value_mlt": [{"bibliographicIssueDates": {"bibliographicIssueDate": "2006-09-29", "bibliographicIssueDateType": "Issued"}, "bibliographic_titles": [{}]}]}, "item_1_creator_2": {"attribute_name": "著者名", "attribute_type": "creator", "attribute_value_mlt": [{"creatorNames": [{"creatorName": "KIM, Hyung-Cheol"}], "nameIdentifiers": [{"nameIdentifier": "0", "nameIdentifierScheme": "WEKO"}]}]}, "item_1_creator_3": {"attribute_name": "フリガナ", "attribute_type": "creator", "attribute_value_mlt": [{"creatorNames": [{"creatorName": "キム, ユンチョル"}], "nameIdentifiers": [{"nameIdentifier": "0", "nameIdentifierScheme": "WEKO"}]}]}, "item_1_date_granted_11": {"attribute_name": "学位授与年月日", "attribute_value_mlt": [{"subitem_dategranted": "2006-09-29"}]}, "item_1_degree_grantor_5": {"attribute_name": "学位授与機関", "attribute_value_mlt": [{"subitem_degreegrantor": [{"subitem_degreegrantor_name": "総合研究大学院大学"}]}]}, "item_1_degree_name_6": {"attribute_name": "学位名", "attribute_value_mlt": [{"subitem_degreename": "博士（理学）"}]}, "item_1_description_1": {"attribute_name": "ID", "attribute_value_mlt": [{"subitem_description": "2006524", "subitem_description_type": "Other"}]}, "item_1_description_12": {"attribute_name": "要旨", "attribute_value_mlt": [{"subitem_description": "　　　Every organism is product of a long evolutionary history, and it is very important to elucidate key genetic changes that caused significant phenotypic transformation. 　　Evolutionary studies at the molecular level have been mainly focused on protein evolution.This is partly because of our lack of knowledge on the evolutionary patterns of non-coding regions, except for promoter regions and some enhancers. Here, \"non-coding\" regions include intergenic  regions, introns, short repeat sequences such as SINE and VNTR, and nontranslated region of exons. 　　This old framework of molecular evolutionary studies gradually shifted to current genome-wide approach from 1980’s, because not only protein coding regions but also non-coding regions were started to be sequenced.　We, at the beginning of the 21st Century, are in the position of utilizing vast amount of genomic sequences.　It is now the age of \"comparative genomics\" or more appropriately, \"evolutionary genomics \".　Some of these nucleotide sequence comparisons were connected with developmental studies, and the role of \"cis-regulatory\" elements on certain morphological features have been elucidated.　We now have possibility of delineating important genomic changes through comparison of the vast amount of genome sequence data. The purpose of this study is thus to gain a better understanding of the evolutionary significance of non-coding regions in mammalian genomes.\u003cbr /\u003e　　　As the model system, I chose the \u003ci\u003eDlx\u003c/i\u003e gene clusters.　\u003ci\u003eDlx\u003c/i\u003e genes are involved in the development of the vertebrate forebrain, branchial arch, sensory organ, and limbs.　The vertebrate \u003ci\u003eDlx\u003c/i\u003e genes are homologous to Drosophila \u003ci\u003eDistal-less(Dll)\u003c/i\u003egene, that is responsible for limbs outgrowth, and probably arisen as a result of a tandem gene duplication followed by a number of large genomic scale duplications, according to phylogenetic analysis including my own.　There are six \u003ci\u003eDlx\u003c/i\u003egenes in mammalian genomes, located in three chromosomes as three pairs of duplicated genes, namely, \u003ci\u003eDlx1-2,\u003c/i\u003e \u003ci\u003eDlx5-6\u003c/i\u003e, \u003ci\u003eDlx3-7.\u003c/i\u003e　These paired genes are convergently transcribed, and the intergenic regions of each pair contain enhancer elements.　Expression patterns of these known enhancers are often conserved, even between distantly related organisms such as between mouse and zebrafish.　However, evolution has two faces; conservation among different lineages of organisms and diversification at each lineage of organism.　Therefore, it is possible that an evolutionarily conserved region in the common ancestral genome diversified as speciation created morphologically different lineages.　A certain non-coding sequence changes may be responsible for some morphological diversity of placental mammals. \u003cbr /\u003e　　　I first analyzed \u003ci\u003eDlx\u003c/i\u003e gene cluster sequence data of the following 9 species; human, chimpanzee, baboon(macaque for \u003ci\u003eDlx5-6\u003c/i\u003e), mouse, rat, cow, dog, elephant, and whale.　All sequences except for whale were retrieved from the DDBJ/EMBL/GenBank International Nucleotide Sequence Database. Because I was interested in the variation of this gene cluster within mammals, I newly determined \u003ci\u003eDlx1-2,\u003c/i\u003e \u003ci\u003eDlx5-6,\u003c/i\u003e and \u003ci\u003eDlx3-7\u003c/i\u003e genomic sequences (a total of 63.9 kb) for whale (Antarctic minke whale; \u003ci\u003eBalaenoptera bonaerensis\u003c/i\u003e),whose morphology is quite different from other mammals. Whale sequences always clustered with cow in the phylogenetic trees for three clusters, as expected, and the branch length for the whale lineage was slightly shorter than that for cow, suggesting a lower evolutionary rate in whale than cow.　This difference may be caused by longer generation times in whale than cow.　The evolutionary rate for the \u003ci\u003eDlx3-7\u003c/i\u003ecluster was highest among the three clusters for all the 15 branches of the phylogenetic tree expect for two. SINEs were observed in much higher numbers in the Dlx3-7 cluster than the other two clusters, and its density was much higher than the genomic average for human and mouse genomes.　This is probably partly because of high GC content (50-60%) compared to a typical mammalian genome (ca. 40%).　In contrast, LINEs, that tend to be found in low GC content regions, were rare in neither the \u003ci\u003eDlx3-7\u003c/i\u003e cluster nor the other two cluster.\u003cbr /\u003e　　　I also noticed that  three highly conserved regions in \u003ci\u003eDlx1-2\u003c/i\u003e and \u003ci\u003eDlx5-6\u003c/i\u003e clusters contain \"ultra-conserved elements \"(100% identity for more than 200bp among human, mouse, and rat genomes), and they coincided with functionally important enhancers, I12a, I12b, and I56i.　There is thus a possibility that other ultra-conserved elements are also responsible for some unknown important evolutionary changes of placental mammals.　I thus sequenced 105 whale and elephant sequences that are homologous to ultraconserved elements.　Although many sets of ultraconserved element sequences exhibited extremely high levels of conservation between human and whale and between human and elephant, there were some changes, and the rate of nucleotide substitution for non-exonic elements was slower than that for exonic ones.　Ultraconserved elements are also highly conserved in non-mammalian vertebrates but the substitution rate progressively decreased from the common ancestor of vertebrates to that of mammals; the rate outside amniotes is the order of 10\u003csup\u003e-9\u003c/sup\u003e/site/year, while rates for the bird and the mammalian lineages are in the order of 10\u003csup\u003e-11\u003c/sup\u003e/site/year, with 2-3 times higher rate for the bird lineage than the mammalian one.　Among mammalian species, dog and whale lineages showed slower rate (2.7 and 3.1x 10\u003csup\u003e-11\u003c/sup\u003e/site/year, respectively)than that(4.7x 10\u003csup\u003e-11\u003c/sup\u003e/site/year) for elephant.　This result suggests that even the ultra-conserved regions experienced lineage specific changes and some of these changes may be responsible for lineage specific phenotypes.\u003cbr /\u003e　　　As the \u003ci\u003eDlx3-7\u003c/i\u003e cluster had more heterogeneity than the other two \u003ci\u003eDlx\u003c/i\u003e clusters, there is a higher chance to find species or lineage changes in this cluster.　I thus determined nucleotide sequences of the \u003ci\u003eDlx3-7\u003c/i\u003e cluster for morphologically quite diverse five mammalian species; dolphin, elephant, aardvark, otter, and sea lion.　Dolphin(Dall’s porpoise; \u003ci\u003ePhocoenoides dalli\u003c/i\u003e) belongs to Order Cetartiodactyla, elephant (Asiatic elephant; \u003ci\u003eElephas maximus\u003c/i\u003e) and aardvark (\u003ci\u003eOrycteropus afer\u003c/i\u003e)belongs to Order Afrotheria, and otter (Eurasian river otter, \u003ci\u003eLutra lutra\u003c/i\u003e), and sea lion (California sea lion; \u003ci\u003eZalophus californianus\u003c/i\u003e) belongs to Order Carnivora.　　I first determined their mitochondrial ribosomal RNA sequences, and confirmed species identity by comparing then with already available sequences deposited in the DDBJ/EMBL/GenBank International Nucleotide Sequence Database.\u003cbr /\u003e　　　Four long PCR amplifications were conducted for each species to cover the entire \u003ci\u003eDlx3-7\u003c/i\u003e cluster region.　I designed PCR primers from highly conserved regions residing within and nearby the cluster.　All long PCR amplifications were successful, and amplicons were subjected to shotgum sequencing.　In total, I determined about 137.2 kb (average = 27.4kb), and 84.5kb(average = 16.9kb) were in the intergenic region.　Although majority of the determined sequences are non-coding, there are many regions with high conservation, and the multiple alignment of the entire region was possible using ClustalW.　The phylogenetic trees constructed for the entire region and the intergenic region were both concordant with the known mammalian phylogeny, indicating orthologous relationship of these newly determined six species including whale and already available 12 species (human, chimpanzee, baboon, lemur, rabbit, mouse, rat, dog, bat cow, pig, and armadillo, retrieved from the DDBJ/EMBL/GenBank International Nucleotide Sequence Database).\u003cbr /\u003e　　　I compared those 18  genomic sequences of the \u003ci\u003eDlx3-7\u003c/i\u003e cluster in order to investigate species specific changes occurred on the evolutionarily conserved regions among the mammalian species using mVISTA and MultiPipMaker.　A total of nine regions of multispecies conserved non-coding sequences were found.　These conserved nine regions were almost identical with those previously found (Sumiyama et al., 2002; Sumiyama, personal communication), indicating their highly conserved nature throughout mammalian evolution.　I then multiply aligned these nine regions, and extracted species or lineage specific changes based on the species phylogeny.　These species-specific changes included both substitutions and insertions/deletions.　There was no clear characteristic in substitutions.　Among three species of Cetartiodactyla, whale and dolphin experienced more deletions than insertions compared to cow.　Deletions were also more frequent in three species(dog, otter, and sea lion) of Carnivora.\u003cbr /\u003e　　　I found many putative transcription factor binding sites from top five conserved regions using TRANSFEC.　A certain numbers of whale and dolphin lineage specific changes were found from these multispecies conserved sequences.　In particular, one conserved region had 9bp (AGTGCCTGG) deletion existing in only whale and dolphin.　I therefore examined enhancer activity of this whale sequence using transgenic mice.　Although this region contained several substitutions and a 9bp deletion, mice embryos with whale transgenes showed interdigit and AER expression in limb, more or less similar expression pattern to that of mouse lines. This result suggests that this region of the whale and mouse genomes share essential \u003ci\u003ecis-\u003c/i\u003eelements for limb expression.\u003cbr /\u003e　　　　In this study, I analyzed non- cording regions of the three \u003ci\u003eDlx\u003c/i\u003e clusters, including newly determining the three \u003ci\u003eDlx\u003c/i\u003ecluster sequences for whale and the \u003ci\u003eDlx3-7\u003c/i\u003e cluster region for five mammalian species, as well as analysis of ultraconserved non-coding regions for various mammalian species. Some of these non-coding regions have been highly conserved during mammalian radiation, yet I discovered many species and lineage specific changes.　These changes may be connected to species-specific phenotypic features and await experimental verifications in the near future.", "subitem_description_type": "Other"}]}, "item_1_description_7": {"attribute_name": "学位記番号", "attribute_value_mlt": [{"subitem_description": "総研大甲第1004号", "subitem_description_type": "Other"}]}, "item_1_select_14": {"attribute_name": "所蔵", "attribute_value_mlt": [{"subitem_select_item": "有"}]}, "item_1_select_16": {"attribute_name": "複写", "attribute_value_mlt": [{"subitem_select_item": "印刷物から複写可"}]}, "item_1_select_17": {"attribute_name": "公開状況", "attribute_value_mlt": [{"subitem_select_item": "要旨のみ公開"}]}, "item_1_select_8": {"attribute_name": "研究科", "attribute_value_mlt": [{"subitem_select_item": "生命科学研究科"}]}, "item_1_select_9": {"attribute_name": "専攻", "attribute_value_mlt": [{"subitem_select_item": "18 遺伝学専攻"}]}, "item_1_text_10": {"attribute_name": "学位授与年度", "attribute_value_mlt": [{"subitem_text_value": "2006"}]}, "item_creator": {"attribute_name": "著者", "attribute_type": "creator", "attribute_value_mlt": [{"creatorNames": [{"creatorName": "KIM, Hyung-Cheol", "creatorNameLang": "en"}], "nameIdentifiers": [{"nameIdentifier": "0", "nameIdentifierScheme": "WEKO"}]}]}, "item_files": {"attribute_name": "ファイル情報", "attribute_type": "file", "attribute_value_mlt": [{"accessrole": "open_date", "date": [{"dateType": "Available", "dateValue": "2016-02-17"}], "displaytype": "simple", "download_preview_message": "", "file_order": 0, "filename": "甲1004_要旨.pdf", "filesize": [{"value": "439.6 kB"}], "format": "application/pdf", "future_date_message": "", "is_thumbnail": false, "licensetype": "license_11", "mimetype": "application/pdf", "size": 439600.0, "url": {"label": "要旨・審査要旨", "url": "https://ir.soken.ac.jp/record/1026/files/甲1004_要旨.pdf"}, "version_id": "163af24c-8297-4616-a476-4a99eed94370"}]}, "item_language": {"attribute_name": "言語", "attribute_value_mlt": [{"subitem_language": "eng"}]}, "item_resource_type": {"attribute_name": "資源タイプ", "attribute_value_mlt": [{"resourcetype": "thesis", "resourceuri": "http://purl.org/coar/resource_type/c_46ec"}]}, "item_title": "EVOLUTIONARY ANALYSIS OF THE MAMMALIAN DLX GENE CLUSTERS", "item_titles": {"attribute_name": "タイトル", "attribute_value_mlt": [{"subitem_title": "EVOLUTIONARY ANALYSIS OF THE MAMMALIAN DLX GENE CLUSTERS"}, {"subitem_title": "EVOLUTIONARY ANALYSIS OF THE MAMMALIAN DLX GENE CLUSTERS", "subitem_title_language": "en"}]}, "item_type_id": "1", "owner": "1", "path": ["20"], "permalink_uri": "https://ir.soken.ac.jp/records/1026", "pubdate": {"attribute_name": "公開日", "attribute_value": "2010-02-22"}, "publish_date": "2010-02-22", "publish_status": "0", "recid": "1026", "relation": {}, "relation_version_is_last": true, "title": ["EVOLUTIONARY ANALYSIS OF THE MAMMALIAN DLX GENE CLUSTERS"], "weko_shared_id": 1}