16 resultados para CNK
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Connector enhancer of KSR (CNK) is a multidomain protein required for RAS signaling. Its C-terminal portion (CNKC-term) directly binds to RAF. Herein, we show that the N-terminal portion of CNK (CNKN-term) strongly cooperates with RAS, whereas CNKC-term efficiently blocks RAS- and RAF-dependent signaling when overexpressed in the Drosophila eye. Two effector loop mutants of RASV12, S35 and C40, which selectively activate the mitogen-activated protein kinase (MAPK) and phosphatidylinositol-3-kinase pathways, respectively, do not cooperate with CNK. However, a strong cooperation is observed between CNK and RASV12G37, an effector loop mutant known in mammals to activate specifically the RAL pathway. We have identified two domains in CNKN-term that are critical for cooperation with RAS. Our results suggest that CNK functions in more than one pathway downstream of RAS. CNKc-term seems to regulate RAF, a component of the MAPK pathway, whereas CNKN-term seems to be involved in a MAPK-independent pathway.
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Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal.
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Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal.
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Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal.
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Thèse numérisée par la Direction des bibliothèques de l'Université de Montréal.
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The most widespread rock associations in the Western Block of North China Craton are khondalites distributed mainly in Jining, Liangcheng and Datong. A large quantitiy of garnet-bearing granites are contained in the khondalites. A great deal of research has been carried out on them by previous researchers. Studies of these garnet-bearing granites consist essentially of structural characteristics, petrography and geochemistry, and finally geochronological determinations. Summing up these researches, it will not be difficult to see that all of these authors have regarded these large numbers of garnets (up to 20%) contained in granites as crystallized products from magmas, but they have not proved this from petrological perspective. Theoretically, there are possibly three kinds of petrogenesis as to these garnets. The first one is that they have been transferred to the granites from khondalites by melt when anatexis happened to khondalites, and they, in essence, are residual metamorphic garnets; The second one is that when the khondalites were being melted, these garnets were produced from biotite dehydration melting, and the newly formed garnets intruded together with the melt and eventually molded the garnet-bearing granites. Garnets of this possible kind either showed independent crystals, or garnets from khondalites took place secondary growth under favorable temperature and pressure conditions for their crystallization; The last possibility is that these garnets were crystallized from magmas in which suitable pressure, temperature and composition were available. These garnets, generally, should be fine-grained. The aim of this study is, through examining the mineral chemistry of the garnets and the whole rock chemistry, to ascertain under which kind of mechanism, in the world, did these garnets form? Besides, we try to calculate the temperatures under which khondalites began melting and reactions of the garnets and the cooled melts happened by garnet-biotite thermometry. The whole rock chemistry analyses of the garnet-bearing granites tell us that all the samples are strongly peraluminous (A/CNK greater than 1.1) on the A/NK vs. A/CNK plot. On the SiO2-K2O plot, the granites are mainly constrained to be high-K calc-alkaline and calc-alkaline series, consistent with previous researches. On the ACF((Al2O3-Na2O-K2O)-FeO(T)-CaO) discrimination plot, all the six garnet-bearing granite samples drop into the area of S-type granites. The relationship between CaO/Na2O and SiO2 shows that the overwhelming majority of garnet-bearing granites have a CaO/Na2O value over 0.3, revealing that they probably come from metagreywacke precursors or mediate-felsic orthogeneisses compositionally similar to them. Detailed EPMA analyses conducted on the garnets contained in the garnet-bearing granites show that all the garnets are dominated by almandine and pyrope, which occupy 92-96% (Weight Percentage) of each garnet analyzed, typical of granulite facies. Their chemical composition is entirely different from those crystallized in magmas, but extremely similar to those of typical granulite facies metapelites in khondalites and typical granulites, indicating all the garnets to be metamorphogenic. In addition, REEs distribution patterns of the garnets are totally different from typical biotite granites and peraluminous granites. In other words, both LREE and HREE of our garnets are evidently lower than those from these two kinds of rocks. Moreover, compared to the REE pattern of the garnets from typical amphibolites, LREE content of our garnets is obviously higher and HREE content is a little lower. However, REE patterns of our garnets are completely in harmony with those of garnets from typical granulites. So, the REE patterns of garnets, again, prove that all the garnets we studied are metamorphogenic. Biotites appear in two forms, being as inclusions in the garnet and as selvages immediately adjacent to the garnet, respectively. Two reactions and their corresponding temperatures, with the help of petrography and Garnet-Biotite geothermometers, could be obtained, which are Bt+ Pl+ Qtz→Kfs+ Opx+ Grt+ melt as positive reaction and Kfs+ Grt+ melt→Bt+ Pl+ Qtz as reverse reaction, respectively. Summing up the discussion above, we declare that the garnet-bearing granites distributed in the Western Block of North China Craton are the mixture of melts and restites resulted from biotite dehydration melting. The garnets contained in the restites are the products from biotite dehydration melting and restites from the khondalites, respectively.
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湘中地区的锑(金)成矿多与脉岩相伴生,对其成因及对矿床成矿作用的贡献至今仍不清楚。本文通过对板溪石英斑岩脉的研究表明,全岩K,Ar年龄为200Ma±,至少比板溪锑矿成矿晚200Ma,因此脉岩与成矿不存在成因联系。板溪脉岩显示过铝质特征,其A/CNK为1.08~2.61,A/NK为1.08~2.71,K20为0.9%~3.66%,K20±Na2O为4.28%~7.5%,大多数样品的K2O/Na2O小于1。稀土元素以相对富集LREE,LREE分馏不明显、HREE分馏明显,配分曲线右倾为特点,其(LJYb)n为14.47~28.11,(Gd/Yb)n为9.8~14.3,并且具强负Eu异常,δEu为0.05~0.14,这表明岩石在成岩演化过程中,经历了强的分异结晶作用。在原始地幔标准化蛛网图上,脉体相对富集LILE,并具Ti和P负异常。(^87Sr/^86Sr)i变化范围较大,为0.6653~0.7149,其中B-3样品的(^87Sr/^86Sr)i为0.7149,与来自地壳上部的花岗岩的^87Sr/^86Sr初始比值相当。在构造环境判别图中,样品显示岛弧/同碰撞花岗岩的特点。结合前人的研究成果,笔者推测板溪脉岩为地壳上部岩石部分熔融的产物,并经历了混染和高度的分异演化。其动力来源为200Ma左右,地壳叠置加厚作用后幔源岩浆的底侵作用.
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燕山中晚期,个旧岩浆活动强烈,并形成基性、中性、酸性及碱性杂岩体。对此前人已做过很多工作,但对其成因机制并未做详细探讨。本文以神仙水花岗岩、卡房花岗岩及贾沙辉长-二长岩为研究对象采用XRF、ICP-MS、EMPA-1600等分析测试方法,对个旧岩浆杂岩体的元素地球化学特征做了详细的分析和总结,并初步得出以下结论: 1、贾沙辉长-二长岩富集LILE、LREE,相对亏损HREE,并具有富碱特征和Eu的弱负异常,说明其为富集地幔来源;但与OIB相比,具有Nb、Ta、Ti等元素的亏损,说明其受到地壳混染作用。 2、个旧花岗岩普遍具有高硅、高铝、富碱(尤其富钾)等特征。随着SiO2含量的增加,Al2O3、Fe2O3T、MgO、CaO、TiO2、P2O5的含量呈线性降低;当SiO2含量大于70%时,Na2O和K2O含量变化不大。 3、岩石类型上,个旧各花岗岩体的铝质系数A/CNK值为0.92~1.08,属于I型花岗岩;构造环境上,个旧花岗岩形成于大陆碰撞环境,为碰撞晚期或后碰撞构造环境;其主要成分来源于地壳,并有基性成分和酸性成分的混合特征。 4、初步研究表明,个旧花岗岩形成于与玄武质岩浆底侵有关的下部大陆壳重熔作用。
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矿化剂在热液矿床成矿过程中的重要作用一直为人们所关注,矿化剂地球化学行为直接影响成矿元素的富集成矿,不同的矿化剂元素可能对金属成矿具有一定的专属性。本文以著名的江西德兴铜厂超大型斑岩铜矿床和大吉山钨矿床作为研究对象,研究F、Cl与W、Cu成矿的关系。主要的认识如下:(1)F在花岗质岩浆中,可以降低岩浆的粘度、密度、固液相线温度、改变熔体结构,而Cl对熔体结构没有多大的影响。F在流体一花岗质熔体相间,绝大多数配分系数小于1.0,趋向于熔体相中配分,DF随体系中F浓度的升高而增加。Cl在流体一花岗质熔体相间的配分系数均大于1.0,且Dc1 随体系中Cl浓度的升高而增大·Cl强烈地趋向富集于流体相中。(2)Cu在流体一花岗质熔体作用过程中,铜总趋向于流体相中分布(DCu都大于1)。特别是在富Cl流体中Cu浓度较高,说明在富含Cl的热液流体能够从共存的熔体中活化迁移出大量的 Cu,S的加入DCu有降低的趋势。钨趋向于熔体相中富集,其配分系数大多小于1.0。(3)德兴铜厂花岗闪长斑岩属钙碱性系列岩石属I型花岗岩类,具有埃达克岩的特征。岩浆来源于深部,在结晶演化过程中发生了围岩物质的混染,这种高铜含量围岩的混染使成矿物质在岩浆中得到富集,有利于铜的活化、迁移。在铜厂岩体不同的蚀变带中,SiO2、K2O、Cu、Mo等从新鲜斑岩甚至弱蚀变带中带出,而在强蚀变带强烈富集,Cl同样有在强蚀变岩石中富集的趋势;而Na2O、Fe从斑岩体中带出,进入流体相中,流体中大量Fe的存在,有利于铜的沉淀、富集成矿。(4)德兴铜厂斑岩体微量元素和稀土元素地球化学特征表明,该岩体发生了流体一熔体作用,分异出来的流体是一种相对富氯的流体,同时成矿流体的流向是从岩体中心向接触带方向流动。(5)大吉山花岗岩具有高SiO2、A/CNK值,显示过铝质特点。黑云母花岗岩是壳源花岗岩但又受到慢源岩浆或慢源流体的影响。随着花岗岩的演化(从I→II→III)SiO2、K2O+Na2O逐渐增加,ΣFe、Al2O3、CaO、F含量降低,为成矿提供了大量的矿化剂(F)和沉淀剂(Fe、Ca)。Eu负异常从I至III阶段花岗岩逐渐加强,表明该岩浆经历了高度的分异演化。(6)大吉山花岗岩类稀土元素具有“四重效应”配分的特点以及微量元素对玲Rb、Y/Ho、Zr/Hf以及Nb/Ta发生明显分异,暗示在花岗岩岩浆的演化过程中,经历了充分的流体一熔体作用,同时分异出大量富含F、W等矿化剂元素和成矿元素的热液流体,致使钨矿的形成。大吉山石英脉型钨矿的成矿年龄大约在155 Ma。(7)通过对成矿流体和花岗质岩石黑云母、白云母中卤素相对逸度的研究(log(H2O/fHCl)fluid、log(fHF/fHCl)fluid)发现,铜厂斑岩型铜矿床的成矿体系是相对富氯体系,而大吉山石英脉型钨矿床成矿体系相对富氟,同时氟可能主要迁移W、Sn、Nb、Ta等金属元素。(8)结合斑岩型铜矿床成矿流体特征,铜主要以C1的络合物形式存在和迁移,迁移形式主要是CuCl0、CuCl2等。石英脉型钨矿床中,钨主要以钨酸、钨酸盐及其离解形式存在和迁移,如WO42-、HWO4-、NaHWO4、Naw伍.等;在高度富氟的成矿流体中,钨的氟氧络合物(如WO3F-,WO2F42-等)对钨迁移也具有重要的作用。因此,不同矿化剂类型具有一定的成矿专属性,热液铜矿床主要与Cl、S有 关,而热液钨矿床大多与F有关。
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The Jinshajiang suture zone, located in the eastern part of the Tethyan tectonic domain, is noticeable for a large-scale distribution of Late Jurassic to Triassic granitoids. These granitoids were genetically related to the evolution of the Paleo-Tethys Ocean. The Beiwu, Linong and Lunong granitoids occur in the middle zone of the Jinshajiang Suture Zone, and possess similar geochemical features, indicating they share a common magma source. SIMS zircon U-Pb dating reveals the Beiwu, Linong and Lunong granitic intrusions were emplaced at 233.9±1.4 Ma (2 sigma), 233.1 ±1.4 Ma (2 sigma) and 231.0±1.6 Ma (2 sigma), respectively. All of these granitoids are enriched in abundances of Si (SiO2 =65.2-73.5 wt.%), and large-ion-lithophile-elements (LILEs), but depleted in high-field-strength-elements contents (HFSEs, e.g., Nb, Ta, Ti). In addition, they have low P2O5 contents (0.06-0.11 wt.%), A/CNK values ([molecular Al2O3/(CaO+Na2O+K2O)], mostly<1.1) and 10000Ga/Al ratios (1.7-2.2), consistent with the characteristics of I-type granites. In terms of isotopic compositions, these granitoids have high initial 87Sr/86Sr ratios (0.7078-0.7148), Pb isotopic compositions [(206Pb/204Pb)t=18.213-18.598, (207Pb/204Pb)t=15.637-15.730 and (208Pb/204Pb)t=38.323-38.791], zircon d18O values (7. per mil-9.3 per mil) and negative eNd(t) values (-5.1 to -6.7), suggesting they were predominantly derived from the continental crust. Their Nb/Ta ratios (average value=8.6) are consistent with those of the lower continental crust (LCC). However, variable ?Hf(t) values (-8.6 to +2.8) and the occurrences of mafic microgranular enclaves (MMEs) suggest that mantle-derived melts and lower crustal magmas were involved in the generation of these granitoids. Moreover, the high Pb isotopic ratios and elevated zircon d18O values of these rocks indicate a significant contribution of the upper crustal composition. We propose a model in which the Beiwu, Linong and Lunong granitoids were generated under a late collisional or post-collisional setting. It is possible that this collision was completed before Late Triassic. Decompression induced mantle-derived magmas underplated and provided the heat for the anatexis of the crust. Hybrid melts including mantle-derived and the lower crustal magmas were then generated. The hybrid melts thereafter ascended to a shallow depth and resulted in some degree of sedimentary rocks assimilation. Such three-component mixing magmas source and subsequent fractional crystallization could be responsible for the formation of the Beiwu, Linong and Lunong granitoids.
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The Yangla copper deposit, situated in the middle section of Jinshajiang tectonic belt between Zhongza-Zhongdian block and Changdu-Simao block, is a representative and giant copper deposit that has been discovered in Jinshajiang-Lancangjiang-Nujiang region in recent years. There are coupled relationship between Yangla granodiorite and copper mineralization in the Yangla copper deposit. Five molybdenite samples yielded a well-constrained 187Re-187Os isochron age of 233.3±3 Ma, the metallogenesis is therefore slightly younger than the crystallization age of the granodiorite. S, Pb isotopic compositions of the Yangla copper deposit indicate that the ore-forming materials were derived from the mixture of upper crust and mantle, also with the magmatic contributions. In the late Early Permian, the Jinshajiang Oceanic plate was subducted to the west, resulting in the formation of a series of gently dipping thrust faults in the Jinshajiang tectonic belt, meanwhile, accompanied magmatic activities. In the early Late Triassic, which was a time of transition from collision-related compression to extension in the Jinshajiang tectonic belt, the thrust faults were tensional; it would have been a favorable environment for forming ore fluids. The ascending magma provided a channel for the ore-forming fluid from the mantle wedge. After the magma arrived at the base of the early-stage Yangla granodiorite, the platy granodiorite at the base of the body would have shielded the late-stage magma from the fluid. The magma would have cooled slowly, and some of the ore-forming fluid in the magma would have entered the gently dipping thrust faults near the Yangla granodiorite, resulting in mineralization.
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Title supplied by cataloger.
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The Serra do Caramuru and Tapuio stocks, located in the extreme NE of Rio Piranhas-Seridó Domain (RN), are representative of the Ediacaran-Cambrian magmatism, an important magmatic feature of the Brasilian / Panafrican orogeny of the Borborema Province. These bodies are lithologically similar, intrusive in paleoproterozoic gneiss embasement, being separated by a thin belt of mylonitic orthogneiss. The field relations show a magmatic stratigraphy initiated by dioritic facies that coexists with the porphyritic granitic and equigranular granitic I facies, and less frequently with equigranular granitic II facies. These rocks are crosscut by late granitic dykes and sheets with NE-SW / NNE-SSW orientation. The dioritic facies (diorite, quartz diorite, quartz monzodiorites, tonalite and granodiorite) is leucocratic to melanocratic, rich in biotite and hornblende. The granitic facies are hololeucocratic to leucocratic, and have biotite ± hornblende. Petrographic and geochemical (whole rock) data, especially from Serra do Caramuru pluton, suggest fractionation of zircon, apatite, clinopyroxene (in diorites), opaque minerals, titanite, biotite, hornblende, allanite, plagioclase, microcline and garnet (in dykes). The behavior of trace elements such as Zr, La and Yb indicates that the dioritic magma does not constitute the parental magma for the granitic facies. On the other hand, the granitic facies seems to be cogenetic to each other, displaying differentiation trends and very similar rare earth elements (REE) spectra [12.3≤(La/Yb)N≤190.8; Eu/Eu*=0.30-0.68]. Field relationships and REE patterns [6.96≤(La/Yb)N≤277.8; Eu/Eu*=0.18-0.58] demonstrate that the granitic dykes and sheets are not cogenetically related to the Serra do Caramuru magmatism. The dioritic facies is metaluminous (A/CNK = 0.88-0.74) and shoshonitic, whereas the granitic ones are metaluminous to peraluminous (A/CNK = 1.08-0.93) and high potassium calc-alkaline. Dykes and sheets are strictly peraluminous (A/CNK = 1.01-1.04). Binary diagrams relating compatible and incompatible trace elements and microtextures indicate the fractional crystallization as the dominant mechanism of magmatic evolution of the various facies. The Serra do Caramuru and Tapuio stocks have well preserved magmatic fabric, do not show metamorphic minerals and are structurally isotropic, showing crosscutting contact with the ductile fabric of the basement. These observations lead to interpretate a stage of relative tectonic stability, consistent with the orogenic relaxation period of the Brasiliano / Pan-African orogeny. Chemical plots involving oxides and trace elements indicate late to post-collisional emplacement. In this context, the assumed better mechanism to describe the stocks emplacement within an extensional T Riedel joint, with ENE-WSW extensional vector. The U-Pb zircon age of 553 ± 10 Ma allows correlating the Serra do Caramuru magmatism to the group of post-collisional bodies, equigranular high potassium calc-alkaline granites of the NE of Rio Piranhas-Seridó Domain.
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The Serra do Caramuru and Tapuio stocks, located in the extreme NE of Rio Piranhas-Seridó Domain (RN), are representative of the Ediacaran-Cambrian magmatism, an important magmatic feature of the Brasilian / Panafrican orogeny of the Borborema Province. These bodies are lithologically similar, intrusive in paleoproterozoic gneiss embasement, being separated by a thin belt of mylonitic orthogneiss. The field relations show a magmatic stratigraphy initiated by dioritic facies that coexists with the porphyritic granitic and equigranular granitic I facies, and less frequently with equigranular granitic II facies. These rocks are crosscut by late granitic dykes and sheets with NE-SW / NNE-SSW orientation. The dioritic facies (diorite, quartz diorite, quartz monzodiorites, tonalite and granodiorite) is leucocratic to melanocratic, rich in biotite and hornblende. The granitic facies are hololeucocratic to leucocratic, and have biotite ± hornblende. Petrographic and geochemical (whole rock) data, especially from Serra do Caramuru pluton, suggest fractionation of zircon, apatite, clinopyroxene (in diorites), opaque minerals, titanite, biotite, hornblende, allanite, plagioclase, microcline and garnet (in dykes). The behavior of trace elements such as Zr, La and Yb indicates that the dioritic magma does not constitute the parental magma for the granitic facies. On the other hand, the granitic facies seems to be cogenetic to each other, displaying differentiation trends and very similar rare earth elements (REE) spectra [12.3≤(La/Yb)N≤190.8; Eu/Eu*=0.30-0.68]. Field relationships and REE patterns [6.96≤(La/Yb)N≤277.8; Eu/Eu*=0.18-0.58] demonstrate that the granitic dykes and sheets are not cogenetically related to the Serra do Caramuru magmatism. The dioritic facies is metaluminous (A/CNK = 0.88-0.74) and shoshonitic, whereas the granitic ones are metaluminous to peraluminous (A/CNK = 1.08-0.93) and high potassium calc-alkaline. Dykes and sheets are strictly peraluminous (A/CNK = 1.01-1.04). Binary diagrams relating compatible and incompatible trace elements and microtextures indicate the fractional crystallization as the dominant mechanism of magmatic evolution of the various facies. The Serra do Caramuru and Tapuio stocks have well preserved magmatic fabric, do not show metamorphic minerals and are structurally isotropic, showing crosscutting contact with the ductile fabric of the basement. These observations lead to interpretate a stage of relative tectonic stability, consistent with the orogenic relaxation period of the Brasiliano / Pan-African orogeny. Chemical plots involving oxides and trace elements indicate late to post-collisional emplacement. In this context, the assumed better mechanism to describe the stocks emplacement within an extensional T Riedel joint, with ENE-WSW extensional vector. The U-Pb zircon age of 553 ± 10 Ma allows correlating the Serra do Caramuru magmatism to the group of post-collisional bodies, equigranular high potassium calc-alkaline granites of the NE of Rio Piranhas-Seridó Domain.
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Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal.
