子分类:
- C12Y205/01001: ..二甲烯丙基转转移酶(2.5.1.1)
- C12Y205/01002: ..硫胺素吡啶基酶(2.5.1.2)
- C12Y205/01003: ..硫胺素-磷酸二磷酸化酶(2.5.1.3)
- C12Y205/01004: ..腺苷甲硫氨酸环转移酶(2.5.1.4)
- C12Y205/01005: ..半乳糖-6-硫酸化酶(2.5.1.5)
- C12Y205/01006: ..甲硫氨酸腺苷转移酶(2.5.1.6),即腺苷甲硫氨酸合成酶
- C12Y205/01007: ..UDP-N-乙酰葡糖胺-1-羧基乙烯基转移酶(2.5.1.7)
- C12Y205/01009: ..核黄素合酶(2.5.1.9)
- C12Y205/0101: ..(2E,6E)-法呢基焦磷酸合成酶(2.5.1.10),即牻牛儿基转转移酶
- C12Y205/01011: ..反式-八异戊烯转转移酶(2.5.1.11)(C12Y205/01084,C12Y205/01085优先)
- C12Y205/01015: ..二氢蝶酸合成酶(2.5.1.15)
- C12Y205/01016: ..亚精胺合成酶(2.5.1.16)
- C12Y205/01017: ..钴(I)啉酸a,c-二酰胺腺苷转移酶(2.5.1.17)
- C12Y205/01018: ..谷胱甘肽转移酶(2.5.1.18)
- C12Y205/01019: ..3-磷酸莽草酸1-羧基乙烯基转移酶(2.5.1.19),即5-烯醇丙酮莽草酸-3-磷酸合成酶
- C12Y205/0102: ..橡胶顺式-聚异戊烯顺转移酶(2.5.1.20)
- C12Y205/01021: ..角鲨烯合酶(2.5.1.21),即法呢基-二磷酸法呢基转移酶
- C12Y205/01022: ..精胺合成酶(2.5.1.22)
- C12Y205/01023: ..对称-去甲精胺合酶(2.5.1.23)
- C12Y205/01024: ..盘状腺嘌呤合酶(2.5.1.24)
- C12Y205/01025: ..tRNA-尿苷氨基羧丙烯基转移酶(2.5.1.25)
- C12Y205/01026: ..烷基甘油酮-磷酸合成酶(2.5.1.26)
- C12Y205/01027: ..腺苷酸二甲烯丙基转移酶(2.5.1.27)
- C12Y205/01028: ..二甲基烯丙基顺转移酶(2.5.1.28)
- C12Y205/01029: ..牻牛儿基牻牛儿基二磷酸合酶(2.5.1.29)
- C12Y205/0103: ..七异戊烯二磷酸合酶(2.5.1.30)
- C12Y205/01031: ..二反式,多顺-十一异戊烯-二磷酸合成酶[(2E,6E)-法呢基-二磷酸特异性](2.5.1.31)
- C12Y205/01032: ..15-顺式-八氢番茄红素合成酶(2.5.1.32)
- C12Y205/01033: ..反式-八异戊烯转转移酶(2.5.1.33)(C12Y205/01082,C12Y205/01083优先)
- C12Y205/01034: ..4-二甲烯丙基色氨酸合成酶(2.5.1.34)
- C12Y205/01035: ..(E/Z)-5-苯亚甲基-4-羟基-3-苯基呋喃-2(5H)-酮二甲烯丙基转移酶(2.5.1.35)
- C12Y205/01036: ..三羟基紫檀碱二甲烯丙基转移酶(2.5.1.36)
- C12Y205/01038: ..异诺卡菌素合酶(2.5.1.38)
- C12Y205/01039: ..4-羟基苯甲酸聚异戊烯转移酶(2.5.1.39)
- C12Y205/01041: ..磷酸甘油牻牛儿基牻牛儿基转移酶(2.5.1.41)
- C12Y205/01042: ..牻牛儿基牻牛儿基甘油-磷酸牻牛儿基牻牛儿基转移酶(2.5.1.42)
- C12Y205/01043: ..烟酰胺合成酶(2.5.1.43)
- C12Y205/01044: ..高亚精胺合酶(2.5.1.44)
- C12Y205/01045: ..高亚精胺合酶(亚精胺-特异性)(2.5.1.45)
- C12Y205/01046: ..脱氧辅蛋白合酶(2.5.1.46)
- C12Y205/01047: ..半胱氨酸合成酶(2.5.1.47)
- C12Y205/01048: ..胱硫醚γ-合成酶(2.5.1.48)
- C12Y205/01049: ..O-乙酰高丝氨酸氨基羧丙烯基转移酶(2.5.1.49)
- C12Y205/0105: ..玉米素9-氨基羧乙基转移酶(2.5.1.50)
- C12Y205/01051: ..β-吡唑酰丙氨酸合酶(2.5.1.51)
- C12Y205/01052: ..L-含羞草碱合成酶(2.5.1.52)
- C12Y205/01053: ..尿嘧啶酰丙氨酸合酶(2.5.1.53)
- C12Y205/01054: ..3-脱氧-7-磷酸庚糖酸合成酶(2.5.1.54)
- C12Y205/01055: ..3-脱氧-8-磷酸辛酸合成酶(2.5.1.55)
- C12Y205/01056: ..N-乙酰神经氨酸合成酶(2.5.1.56)
- C12Y205/01057: ..N-酰基神经氨酸-9-磷酸合酶(2.5.1.57)
- C12Y205/01058: ..蛋白质法呢基转移酶(2.5.1.58)
- C12Y205/01059: ..蛋白质牻牛儿基牻牛儿基转移酶 I型(2.5.1.59)
- C12Y205/0106: ..蛋白质牻牛儿基牻牛儿基转移酶 II型(2.5.1.60)
- C12Y205/01061: ..羟甲基胆素合酶(2.5.1.61)
- C12Y205/01062: ..叶绿素合酶(2.5.1.62)
- C12Y205/01063: ..腺苷氟化物合成酶(2.5.1.63)
- C12Y205/01064: ..2-琥珀酰-6-羟基-2,4-环己二烯-1-羧酸合成酶(2.5.1.64)(C12Y202/01009,C12Y402/9902优先)
- C12Y205/01065: ..O-磷酸丝氨酸硫化氢解酶(2.5.1.65)
- C12Y205/01066: ..N2-(2-羧乙基)精氨酸合酶(2.5.1.66)
- C12Y205/01067: ..菊酰焦磷酸合成酶(2.5.1.67)
- C12Y205/01068: ..(2Z,6E)-法呢基焦磷酸合成酶(2.5.1.68)
- C12Y205/01069: ..熏衣草基二磷酸合酶(2.5.1.69)
- C12Y205/0107: ..柚皮素8-二甲烯丙基转移酶(2.5.1.70)
- C12Y205/01071: ..勒奇黄烷酮-G 2''-二甲烯丙基转移酶(2.5.1.71)
- C12Y205/01072: ..喹啉酸合成酶(2.5.1.72)
- C12Y205/01073: ..O-磷酸-L-丝氨酰-tRNA:半胱氨酸-tRNA合成酶(2.5.1.73)
- C12Y205/01074: ..1,4-二羟基-2-萘甲酸聚异戊烯转移酶(2.5.1.74)
- C12Y205/01075: ..tRNA二甲烯丙基转移酶(2.5.1.75)
- C12Y205/01076: ..半胱氨酸合酶(2.5.1.76)
- C12Y205/01077: ..7,8-二脱甲基-8-羟基-5-脱氮核黄素合成酶(2.5.1.77)
- C12Y205/01078: ..6,7-二甲基-8-核醇基2,4-二氧四氢蝶啶合成酶(2.5.1.78)
- C12Y205/01079: ..热精胺合酶(2.5.1.79)
- C12Y205/0108: ..7-二甲烯丙基色氨酸合酶(2.5.1.80)
- C12Y205/01081: ..牻牛儿基法呢基二磷酸合酶(2.5.1.81)
- C12Y205/01082: ..己异戊烯二磷酸合酶(牻牛儿基牻牛儿基-二磷酸特异性)(2.5.1.82)
- C12Y205/01083: ..己异戊烯-二磷酸合酶((2E,6E)-法呢基-二磷酸特异性)(2.5.1.83)
- C12Y205/01084: ..全反式-九异戊烯-二磷酸合酶(牻牛儿基-二磷酸特异性)(2.5.1.84)
- C12Y205/01085: ..全反式-九异戊烯-二磷酸合酶(牻牛儿基牻牛儿基-二磷酸特异性)(2.5.1.85)
- C12Y205/01086: ..反式,多顺-十异戊二烯二磷酸合酶(2.5.1.86)
- C12Y205/01087: ..二反式,多顺-聚异戊二烯二磷酸合酶((2E,6E)-法呢基二磷酸特异性)(2.5.1.87)
- C12Y205/01088: ..反式,多顺-聚异戊二烯二磷酸合酶((2Z,6E)-法呢基二磷酸特异性)(2.5.1.88)
- C12Y205/01089: ..三反式,多顺-十一异戊烯二磷酸合酶(牻牛儿基牻牛儿基二磷酸特异性)(2.5.1.89)
- C12Y205/0109: ..全反式-辛异戊烯-二磷酸合酶(2.5.1.90)
- C12Y205/01091: ..全反式-十异戊二烯-二磷酸合酶(2.5.1.91)
- C12Y205/01092: ..(2Z,6Z)-法呢基二磷酸合成酶(2.5.1.92)
- C12Y205/01093: ..4-羟基苯甲酸牻牛儿基转移酶(2.5.1.93)
- C12Y205/01094: ..腺苷-氯化物合酶(2.5.1.94)
- C12Y205/01095: ..黄原胶缩酮丙酮酸转移酶(2.5.1.95)
- C12Y205/01096: ..4,4'-二阿朴八氢番茄红素合成酶(2.5.1.96)
- C12Y205/01097: ..假甲酸合成酶(2.5.1.97)
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 41 | UTILIZATION OF PHOSPHOKETOLASE IN THE PRODUCTION OF MEVALONATE, ISOPRENOID PRECURSORS, AND ISOPRENE | US14625487 | 2015-02-18 | US20150225744A1 | 2015-08-13 | Zachary Q. BECK; Andrew C. Eliot; Caroline M. Peres; Dmitrii V. Vaviline |
| The invention provides for methods for the production of mevalonate, isoprene, isoprenoid precursor molecules, and/or isoprenoids in cells via the heterologous expression of phosphoketolase enzymes. | ||||||
| 42 | Biosynthetic Systems Producing Fungal Indole Alkaloids | US14390360 | 2013-04-03 | US20150044735A1 | 2015-02-12 | Shengying Li; Krithika Anand Srinivasan; Robert M. Williams; David H. Sherman |
| The biosynthesis of fungal bicyclo[2.2.2]diazaoctane indole alkaloids with a wide spectrum of biological activities have attracted increasing interest. Their intriguing mode of assembly has long been proposed to feature a non-ribosomal peptide synthetase, a presumed intramolecular Diels-Alderase, a variant number of prenyltransferases, and a series of oxidases responsible for the diverse tailoring modifications of their cyclodipeptide-based structural core. Until recently, the details of these biosynthetic pathways have remained largely unknown due to lack of information on the fungal derived biosynthetic gene clusters. Herein, we report a comparative analysis of four natural product metabolic systems of a select group of bicyclo[2.2.2]diazaoctane indole alkaloids including (+)/(−)-notoamide, paraherquamide and malbrancheamide, in which we propose an enzyme for each step in the biosynthetic pathway based on deep annotation and on-going biochemical studies. | ||||||
| 43 | METHODS FOR PRODUCING ISOBUTENE FROM 3-METHYLCROTONIC ACID | EP16809650.1 | 2016-11-17 | EP3377639A2 | 2018-09-26 | ALLARD, Mathieu; ANISSIMOVA, Maria; MARLIERE, Philippe |
| Described are methods for the production of isobutene comprising the enzymatic conversion of 3-methylcrotonic acid into isobutene wherein said 3-methylcrotonic acid is obtained by the enzymatic conversion of 3-methylcrotonyl-CoA into 3- methylcrotonic acid or wherein said 3-methylcrotonic acid is obtained by the enzymatic conversion of 3-hydroxyisovalerate (HIV) into 3-methylcrotonic acid. It is described that the enzymatic conversion of 3-methylcrotonic acid into isobutene can, e.g., be achieved by making use of a 3-methylcrotonic acid decarboxylase, preferably an FMN-dependent decarboxylase associated with an FMN prenyl transferase, an aconitate decarboxylase (EC 4.1.1.6), a methylcrotonyl-CoA carboxylase (EC 6.4.1.4), or a geranoyl-CoA carboxylase (EC 6.4.1.5). | ||||||
| 44 | CYTOKININ SYNTHASE ENZYMES, CONSTRUCTS, AND RELATED METHODS | EP15796311 | 2015-05-21 | EP3146055A4 | 2017-10-25 | BEESON IV WILLIAM T; WESTFALL PATRICK JOHN |
| The present disclosure relates to a new class of cytokinin biosynthetic enzymes, cytokinin synthases, which have two domains: an isopentenyl transfer (IPT)-like domain and a cytokinin nucleotide phosphoribohydrolase (PRH)-like domain. The invention provides compositions and methods for the recombinant production of cytokinin synthase, host cells and transformants that include the cytokinin synthases, as well as compositions and formulations that include the disclosed cytokinin synthase. | ||||||
| 45 | METHODS FOR RECOMBINANT PRODUCTION OF SAFFRON COMPOUNDS | EP15708225.6 | 2015-03-06 | EP3114210A2 | 2017-01-11 | KUMAR, A.S. Sathish |
| Recombinant microorganisms and methods for producing saffron compounds including crocetin, crocetin dialdehyde, crocin or picrocrocin are disclosed herein. | ||||||
| 46 | METHOD FOR PRODUCING TERPENES | EP13788057 | 2013-05-13 | EP2847331A4 | 2015-11-25 | BROMANN KIRSI; TOIVARI MERVI; NAKARI-SETÄLÄ TIINA; RUOHONEN LAURA |
| The present invention concerns a method for producing terpenes in fungi comprising the steps of (a) providing a modified terpene biosynthetic gene cluster inside a host cell, wherein one or more of the naturally occurring genes or promoters of the cluster have been replaced, truncated or removed, (b) providing a transcription factor inside the host cell, the transcription factor activating the terpene biosynthetic gene cluster; (c) cultivating said host in conditions allowing the expression of the transcription factor activating the cluster; and optionally (d) recovering the thus produced terpene product. | ||||||
| 47 | METHOD FOR PRODUCING TERPENES | EP13788057.1 | 2013-05-13 | EP2847331A1 | 2015-03-18 | BROMANN, Kirsi; TOIVARI, Mervi; NAKARI-SETÄLÄ, Tiina; RUOHONEN, Laura |
| The present invention concerns a method for producing terpenes in fungi comprising the steps of (a) providing a modified terpene biosynthetic gene cluster inside a host cell, wherein one or more of the naturally occurring genes or promoters of the cluster have been replaced, truncated or removed, (b) providing a transcription factor inside the host cell, the transcription factor activating the terpene biosynthetic gene cluster; (c) cultivating said host in conditions allowing the expression of the transcription factor activating the cluster; and optionally (d) recovering the thus produced terpene product. | ||||||
| 48 | NUCLEIC ACID STRUCTURE CONTAINING A PYRIPYROPENE BIOSYNTHESIS GENE CLUSTER AND A MARKER GENE | EP11736900 | 2011-01-19 | EP2530149A4 | 2014-01-15 | AIHARA SATO; SUMIDA NAOMI; MURASHIMA KOICHIRO; YANAI KOUJI; ANZAI HIROYUKI; YAMAMOTO KENTARO |
| 49 | METHOD FOR MANUFACTURING A PYRIPYROPENE | EP11736899 | 2011-01-19 | EP2530164A4 | 2013-12-25 | ANZAI HIROYUKI; YAMAMOTO KENTARO; OYAMA KAZUHIKO; TSUCHIDA MARIKO; GOTO KIMIHIKO; MITOMI MASAAKI |
| There is provided a method for culturing a microorganism in which a particular polynucleotide or a recombinant vector comprising it/them is introduced with an intermediate compound necessary for biosynthesis of pyripyropene A. The method of the present invention allows for the production of pyripyropene. | ||||||
| 50 | CYTOKININ SYNTHASE ENZYMES, CONSTRUCTS, AND RELATED METHODS | EP15796311.7 | 2015-05-21 | EP3146055A2 | 2017-03-29 | BEESON, IV, William T.; WESTFALL, Patrick John |
| The present disclosure relates to a new class of cytokinin biosynthetic enzymes, cytokinin synthases, which have two domains: an isopentenyl transfer (IPT)-like domain and a cytokinin nucleotide phosphoribohydrolase (PRH)-like domain. The invention provides compositions and methods for the recombinant production of cytokinin synthase, host cells and transformants that include the cytokinin synthases, as well as compositions and formulations that include the disclosed cytokinin synthase. | ||||||
| 51 | PLANTS HAVING INCREASED TOLERANCE TO HERBICIDES | EP14791106 | 2014-04-28 | EP2992090A4 | 2017-01-11 | PASTERNAK MACIEJ; TRESCH STEFAN; KRAUS HELMUT; HUTZLER JOHANNES; LERCHL JENS; MIETZNER THOMAS; PAULIK JILL MARIE |
| The present invention refers to a method for controlling undesired vegetation at a plant cultivation site, the method comprising the steps of providing, at said site, a plant that comprises at least one nucleic acid comprising a nucleotide sequence encoding a wild-type hydroxyphenyl pyruvate dioxygenase or a mutated hydroxyphenyl pyruvate dioxygenase (mut-HPPD) which is resistant or tolerant to a HPPD-inhibiting herbicide and/or a nucleotide sequence encoding a wild-type homogentisate solanesyl transferase or a mutated homogentisate solanesyl transferase (mut-HST) which is resistant or tolerant to a HPPD-inhibiting herbicide, applying to said site an effective amount of said herbicide. The invention further refers to plants comprising mut-HPPD, and methods of obtaining such plants. | ||||||
| 52 | GENES AND PROCESSES FOR THE PRODUCTION OF CLAVINE-TYPE ALKALOIDS | EP13831449 | 2013-08-13 | EP2888351A4 | 2016-04-27 | NAESBY MICHAEL; FOLLY CHRISTOPHE; NIELSEN CURT AIMÉ FRIIS; HATSCH ANAELLE; SCHWAB MARKUS; ZELDER OSKAR; HAEFNER STEFAN; SCHRÖDER HARTWIG; HOFF BIRGIT; MOLT ANDREA; DITRICH KLAUS; BREUER MICHAEL; HARTMANN HOLGER; KÖRBER KARSTEN |
| Microorganisms and processes for the recombinant manufacture of clavine-type alkaloids such as cycloclavine, festuclavine, agroclavine, chanoclavine and chanoclavine aldehyde, as well as polypeptides, polynucleotides and vectors comprising such polynucleotides which can be applied in a method for the manufacture of clavine-type alkaloids are provided. | ||||||
| 53 | GENES AND PROCESSES FOR THE PRODUCTION OF CLAVINE-TYPE ALKALOIDS | EP13831449.7 | 2013-08-13 | EP2888351A2 | 2015-07-01 | NAESBY, Michael; FOLLY, Christophe; NIELSEN, Curt Aimé Friis; HATSCH, Anaelle; SCHWAB, Markus; ZELDER, Oskar; HAEFNER, Stefan; SCHRÖDER, Hartwig; HOFF, Birgit; MOLT, Andrea; DITRICH, Klaus; BREUER, Michael; HARTMANN, Holger; KÖRBER, Karsten |
| Microorganisms and processes for the recombinant manufacture of clavine-type alkaloids such as cycloclavine, festuclavine, agroclavine, chanoclavine and chanoclavine aldehyde, as well as polypeptides, polynucleotides and vectors comprising such polynucleotides which can be applied in a method for the manufacture of clavine-type alkaloids are provided. | ||||||
| 54 | METHODS FOR STABILIZING PRODUCTION OF ACETYL-COENZYME A DERIVED COMPOUNDS | EP13750244.9 | 2013-08-07 | EP2882856A1 | 2015-06-17 | JIANG, Hanxiao; MEADOWS, Adam |
| The present disclosure relates to the use of a switch for the production of heterologous non-catabolic compounds in microbial host cells. In one aspect, provided herein are genetically modified microorganisms that produce non-catabolic compounds more stably when serially cultured under aerobic conditions followed by microaerobic conditions, and methods of producing non-catabolic compounds by culturing the genetically modified microbes under such culture conditions. In another aspect, provided herein are genetically modified microorganisms that produce non-catabolic compounds more stably when serially cultured in the presence of maltose followed by the reduction or absence of maltose, and methods of producing non-catabolic compounds by culturing the genetically modified microbes under such culture conditions. | ||||||
| 55 | METHOD FOR MANUFACTURING A PYRIPYROPENE | EP11736899.3 | 2011-01-19 | EP2530164A1 | 2012-12-05 | ANZAI Hiroyuki; YAMAMOTO Kentaro; OYAMA Kazuhiko; TSUCHIDA Mariko; GOTO Kimihiko; MITOMI Masaaki |
There is provided a method for culturing a microorganism in which a particular polynucleotide or a recombinant vector comprising it/them is introduced with an intermediate compound necessary for biosynthesis of pyripyropene A. The method of the present invention allows for the production of pyripyropene. |
||||||
| 56 | 미어신 생산용 벡터 및 균주, 및 이를 이용한 미어신의 생산방법 | KR1020150097250 | 2015-07-08 | KR101782891B1 | 2017-09-29 | 우한민; 김은미; 엄영순; 공경택; 이선미; 김연제 |
| 본명세서에는미어신을발현시킬수 있는발현벡터, 상기벡터로형질전환되어향상된미어신생산능을갖는대장균균주, 이를이용한미어신의생산방법및 글리세롤의재활용방법이개시된다. 일측면에있어서, 본발명의형질전환된대장균() 균주는, 글리세롤또는포도당을탄소원으로사용하여, 대량의미어신을고순도로생산할수 있다. 또한, 본발명의대장균균주는폐글리세롤을탄소원으로사용하여, 고부가가치의미어신을생산할수 있으므로, 경제적이고, 친환경적이다. 또한, 휘발성이강한미어신을생산과동시에분리할수 있는장점이있다. | ||||||
| 57 | 시토키닌 신타제 효소, 구축물, 및 관련 방법 | KR1020167031965 | 2015-05-21 | KR1020170007299A | 2017-01-18 | 비슨윌리엄티4세; 웨스트폴패트릭존 |
| 본개시내용은하기 2개의도메인: 이소펜테닐트랜스퍼라제 (IPT)-유사도메인및 시토키닌뉴클레오티드포스포리보히드롤라제 (PRH)-유사도메인을갖는새로운부류의시토키닌생합성효소인시토키닌신타제에관한것이다. 본발명은시토키닌신타제의재조합생산을위한조성물및 방법, 상기시토키닌신타제를포함하는숙주세포및 형질전환체, 뿐만아니라개시된시토키닌신타제를포함하는조성물및 제제를제공한다. | ||||||
| 58 | Method for producing terpenes | US14400346 | 2013-05-13 | US10072279B2 | 2018-09-11 | Kirsi Bromann; Mervi Toivari; Tiina Nakari-Setälä; Laura Ruohonen |
| The present invention concerns a method for producing terpenes in fungi comprising the steps of (a) providing a modified terpene biosynthetic gene cluster inside a host cell, wherein one or more of the naturally occurring genes or promoters of the cluster have been replaced, truncated or removed, (b) providing a transcription factor inside the host cell, the transcription factor activating the terpene biosynthetic gene cluster; (c) cultivating said host in conditions allowing the expression of the transcription factor activating the cluster; and optionally (d) recovering the thus produced terpene product. | ||||||
| 59 | GERANYLGERANYL PYROPHOSPHATE SYNTHASE | US15567620 | 2016-04-21 | US20180132515A1 | 2018-05-17 | ADAM G. LAWRENCE; JOHN ROYER |
| The present invention relates to a recombinant host capable of producing a steviol glycoside comprising a recombinant nucleic acid sequence encoding a polypeptide having geranylgeranyl pyrophosphate (GGPP) synthase activity which comprises the amino acid sequence set forth in SEQ ID NO: 1 or an amino acid sequence having at least about 45% sequence identity thereto. | ||||||
| 60 | Production of cannabinoids in yeast | US14795816 | 2015-07-09 | US09822384B2 | 2017-11-21 | Jason L. Poulos; Anthony N. Farnia |
| Exemplary embodiments provided herein include genetically engineering microorganisms, such as yeast or bacteria, to produce cannabinoids by inserting genes that produce the appropriate enzymes for the metabolic production of a desired compound. | ||||||
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