Molecular genetic analysis of mottled mice

Cunliffe, Pamela

January 1999

No description available.

572.8

Menkes disease; Copper transport

Copper-transporting proteins and their interactions with platinum-based anticancer substances

Espling, Maria

January 2013

Cisplatin (CisPt) is an important drug that is used against various cancers, including testicular, ovarian, lung, head, and neck cancer. However, its effects are limited by cellular resistance. The resistance is believed to be multifactorial, and may be mediated to varying degree by multiple systems in cells, one of the proposed systems being the copper (Cu) transporting system. The Cu-importer Ctr1 has proven importance for cellular sensitivity to CisPt by regulating its influx, while the Golgi-localized Cu-ATP:ases ATP7A/B can putatively mediate CisPt efflux and/or drug sequestration. Atox1 is a small Cu-chaperone that normally transfers Cu between Ctr1 and ATP7A/B, prior to delivery of Cu to the proteins in the secretory pathway. Since Ctr1 and ATP7A/B are reportedly involved in CisPt-resistance, CisPt interaction with Atox1 was the focus of the project this thesis is based upon.   Using a variety of techniques, Atox1 was found to bind CisPt, also simultaneously with Cu. The Atox1-CisPt complexes were further probed using selected mutants in studies demonstrating that only the two cysteines (Cys12 and Cys15) in the Cu-binding site of Atox1 are essential for CisPt interactions. A proposed Atox1 di-metal complex containing both Cu and CisPt was found to be monomeric, and no loss of Cu was observed. In vitro experiments demonstrated that CisPt could also bind to metal-binding domain 4 of ATP7B (WD4), and that the drug could be transferred from Atox1 to the domain. These findings indicated that Atox1 may transfer CisPt to ATP7A/B in vivo, utilizing the same transport pathway as Cu. However, the CisPt-bound Atox1 complexes were not stable over time; upon incubation, protein unfolding and aggregation were observed. Thus, in vivo, Atox1 might alternatively be a dead-end sink for CisPt.   The effects of the ligands around the Pt-center of Pt-based anticancer drugs and drug derivatives on Atox1 binding and unfolding were also investigated. The ligands’ chemistry and geometry were shown to dictate the extent and rate of the Pt-based substances interactions with Atox1. Finally, the occurrence of Atox1-CisPt interactions in a biological environment was demonstrated by developing and applying an antibody-based method allowing analysis of metals associated with Atox1 extracted from CisPt-treated cells.   The findings presented in this thesis show that CisPt binds to Atox1 and WD4, also simultaneously with Cu, in vitro. The results support the hypothesis that Cu-transporting proteins can mediate cellular resistance to CisPt in vivo, and provide a deeper chemical understanding of the interactions between the proteins and the drug.

Cisplatin

Atox1

copper transport

anticancer drug

resistance

platinum

spectroscopy.

Characterization of Metal Binding Peptides Derived from Copper Trafficking Proteins

Rubino, Jeffrey Tyler

January 2010

<p>Copper was first released into the environment as the result of the mass generation of oxygen from photosynthetic bacteria roughly 2.7 billion years ago. While it proved to be poisonous to early life on Earth, those that met the evolutionary challenge utilized the metal as a cofactor in enzymes to perform biochemically significant functions, while controlling intracellular levels of copper with a sophisticated network of trafficking proteins. Proteins and enzymes that utilize copper as a cofactor have evolved significantly different coordination environments than copper trafficking proteins, as a result of the different functions they perform. Of particular interest was characterizing the unique Cu(I) binding events observed in some of these proteins, the extracellular N-terminal regions of eukaryotic high affinity copper transport proteins (Ctr), and the bacterial periplamsic CusF protein of the CusFBCA Cu(I)/Ag(I) efflux pathway. </p><p>Model peptides corresponding to the methionine rich binding motifs (Mets motifs) were characterized in terms of Cu(I) binding affinity, stoichiometry, and metal specificity, via an ascorbic acid oxidation assay and electrospray ionization mass spectrometry. Metal induced structural features and coordination environments were elucidated with NMR, CD and X-ray spectroscopy. A series of peptides was also examined to infer the relative Cu(I) binding affinities, and susceptibility to oxidation, of methionine, histidine, cysteine residues found in copper binding motifs. The resistance of Cu+ specific peptides to metal catalyzed oxidation is also described. Attempts were also made to model the Cu(I)/Ag(I) tryptophan cation-&#960; interaction observed in CusF.</p> / Dissertation

Chemistry, Inorganic

Copper

Copper transport

Ctr

Methionine

Peptides

Silver

Copper at the Interface of Chemistry and Biology: New Insights into hCtr1 Function and the Role of Histidine in Human Cellular Copper Acquisition

Haas, Kathryn Louise

January 2010

<p>Mechanisms of copper homeostasis are of great interest partly due to their connection to debilitating genetic and neurological disorders. The family of high-affinity copper transporters (Ctr) is responsible for extracellular copper acquisition and internalization in yeast, plants, and mammals, including human. The extracellular domain of the human high-affinity copper transporter (hCtr1) contains essential Cu-binding methionine-rich MXXM and MXM (Mets) motifs that are important for copper acquisition and transport. The hCtr1 extracellular domain also contains potential copper binding histidine (His) clusters, including a high-affinity Cu(II) ATCUN site. As of yet, extracellular His clusters have no established significance for hCtr1 function. We have made model peptides based on the extracellular copper acquisition domain of hCtr1 that is rich in His residues and Mets motifs. The peptides' Cu(I) and Cu(II) binding properties have been characterized by UV-Vis and mass spectrometry. Our findings have been extended to a mouse cell model and we show that His residues are important for hCtr1 function likely because of their contribution to strong copper-binding sites in the hCtr1 extracellular domain responsible for copper acquisition. </p> <p>Copper's pro-oxidant property is also medicinally promising if it can be harnessed to induce oxidative stress as a cancer chemotherapy strategy. Our lab has designed a photocleavable caged copper complex that can selectively release redox-active copper in response to light. The thermodynamic copper binding properties of these potential chemotherapeutics have been characterized</p> / Dissertation

Chemistry, Inorganic

Chemistry, Biochemistry

Caged Copper

Copper

Copper Transport

Ctr1

Membrane Protein

Metal Homeostasis

Role of ORF pCT0018 for copper homeostasis in Listeria monocytogenes strain DRDC8.

Hii, Mei Mei

January 2009

Sequence analysis of part of a large plasmid carried by Australian environmental isolate of Listeria monocytogenes strain DRDC8 has lead to identification of an islet of genes that encode proteins similar to copper binding and transport genes found in other Gram positive bacteria. Comparative sequence analysis showed that there are at least four genes (pCT0017, pCT0018, pCT0019 and ctpA) on this islet predicted to be involved in copper homeostasis. One of these, ctpA, is predicted to encode a P-type ATPase with a function analogous to CopA, a copper transporting gene in Enterococcus hirae. ORF pCT0017 is likely to be a CopY-like regulatory protein which could control the expression of ctpA. ORF pCT0019 is predicted to be a Cu²⁺ binding protein. In addition, two genes located downstream of the ctpA are predicted to encode a two component regulatory system region. The predicted function of ORF pCT0018 is not clear. A related chromosomal gene (cutR) is predicted to also encode a copper transporting P-type ATPase. To investigate the role of the protein encoded by pCT0018, the growth behavior of L. monocytogenes strain DRDC8, other strains carrying mutations within pCT0018, pCT0019, cutR and ctpA, as well as strains cured of the large plasmid, were grown under conditions of copper stress and starvation. The growth data showed that with the exception of strain DRDC8 and other strains carrying ctpA, most were unable to grow at higher copper concentration (>15 mM CuSO₄) and suggested that the copper homeostasis genes located on the large plasmid are associated with tolerance to high levels of copper. Strain DSE955PL, which carries a cutR mutation and is cured of the large plasmid, was the most sensitive (<5 mM CuSO₄). This indicated that proteins encoded by plasmid genes work synergistically to confer tolerance to copper. Of most interest was the fact that a pCT0018 mutant was more sensitive (<15 mM CuSO₄) to high levels of copper than the wild type parent DRDC8 (<20 mM CuSO₄). This suggested that ORF pCT0018 was necessary for copper tolerance. To investigate the effects of insertion mutations in pCT0017, pCT0018 and ctpA on copper uptake and export, the levels of copper accumulated by these strains was assessed using atomic absorption spectroscopy. A significant difference in copper accumulation among the bacteria strains was observed when either LEB or BHI media were used to culture the bacteria. This data suggested that the growth medium chemicals influence the levels of copper accumulated by cells. However, the effect of these media on bacteria growth rates during copper stress was not significant. Atomic absorption analysis of intracellular copper accumulation suggested that DSE955PL and DSE955 (a chromosome mutant) were able to accumulate copper (80 - 110 mg.gˉ¹ dry weight of cells), whereas DRDC8 and strains carrying mutations in pCT0018, ctpA, and strains cured of the large plasmid, were less able to accumulate copper (30 - 70 mg.gˉ¹ dry weight of cells). This data suggested that cutR may encode a copper export system and that ctpA is involved in copper uptake. To investigate the gene expression profile for pCT0018 under elevated copper, reverse transcriptase PCR was used to detect transcripts encoding pCT0017, pCT0018, pCT0019 and pCT0020 from RNA extracted from L. monocytogenes strain DRDC8 following culture at elevated levels of copper. Although transcripts for each of the target genes were detected, transcription was not responsive to copper, nor was the pattern of transcription consistent with that expected for a single operon. To directly determine whether the protein encoded by the pCT0018 open reading frame was able to bind copper, this gene was cloned in pET15b in frame with an N-terminal Histag and expressed in E. coli. The expressed protein was purified with a Ni-NTA column and shown to contain copper. Attempts to directly show that protein pCT0018 could bind copper by Cu-IMAC were unable to unequivocally show that the protein was immobilized on the column. Purified protein was used to raise a polyclonal antiserum in rabbit and the antiserum was used for Western analysis to test expression of pCT0018 by wild type L. monocytogenes DRDC8 and specific gene mutants. Although the antiserum bound to purified protein, it was not possible to demonstrate binding to native pCT0018 in cell lysates prepared from L. monocytogenes DRDC8. SDS-PAGE of cytoplasmic and cell envelope proteins isolated from L. monocytogenes strains was used to identify proteins expressed in response to copper stress and starvation. No significant differences in protein profiles for cytoplasmic protein were observed. However, copper-immobilized metal affinity chromatography (Cu-IMAC) showed that expression of a number of copper binding proteins were differentially expressed by DRDC8 following growth in copper stress and starvation conditions. Three of these proteins were selected for amino sequence analysis by MALDI-TOFF MS. Two were confirmed to be L. monocytogenes non-heme iron-binding ferritin and a thiol peroxidase, both of which bind copper. The other protein was similar to an unknown protein from L. monocytogenes. Interestingly, no proteins directly implicated with the copper homeostasis islet were identified. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1374407 / Thesis (M.Sc.) - University of Adelaide, School of Molecular and Biomedical Science, 2009

Role of ORF pCT0018 for copper homeostasis in Listeria monocytogenes strain DRDC8.

Hii, Mei Mei

January 2009

Sequence analysis of part of a large plasmid carried by Australian environmental isolate of Listeria monocytogenes strain DRDC8 has lead to identification of an islet of genes that encode proteins similar to copper binding and transport genes found in other Gram positive bacteria. Comparative sequence analysis showed that there are at least four genes (pCT0017, pCT0018, pCT0019 and ctpA) on this islet predicted to be involved in copper homeostasis. One of these, ctpA, is predicted to encode a P-type ATPase with a function analogous to CopA, a copper transporting gene in Enterococcus hirae. ORF pCT0017 is likely to be a CopY-like regulatory protein which could control the expression of ctpA. ORF pCT0019 is predicted to be a Cu²⁺ binding protein. In addition, two genes located downstream of the ctpA are predicted to encode a two component regulatory system region. The predicted function of ORF pCT0018 is not clear. A related chromosomal gene (cutR) is predicted to also encode a copper transporting P-type ATPase. To investigate the role of the protein encoded by pCT0018, the growth behavior of L. monocytogenes strain DRDC8, other strains carrying mutations within pCT0018, pCT0019, cutR and ctpA, as well as strains cured of the large plasmid, were grown under conditions of copper stress and starvation. The growth data showed that with the exception of strain DRDC8 and other strains carrying ctpA, most were unable to grow at higher copper concentration (>15 mM CuSO₄) and suggested that the copper homeostasis genes located on the large plasmid are associated with tolerance to high levels of copper. Strain DSE955PL, which carries a cutR mutation and is cured of the large plasmid, was the most sensitive (<5 mM CuSO₄). This indicated that proteins encoded by plasmid genes work synergistically to confer tolerance to copper. Of most interest was the fact that a pCT0018 mutant was more sensitive (<15 mM CuSO₄) to high levels of copper than the wild type parent DRDC8 (<20 mM CuSO₄). This suggested that ORF pCT0018 was necessary for copper tolerance. To investigate the effects of insertion mutations in pCT0017, pCT0018 and ctpA on copper uptake and export, the levels of copper accumulated by these strains was assessed using atomic absorption spectroscopy. A significant difference in copper accumulation among the bacteria strains was observed when either LEB or BHI media were used to culture the bacteria. This data suggested that the growth medium chemicals influence the levels of copper accumulated by cells. However, the effect of these media on bacteria growth rates during copper stress was not significant. Atomic absorption analysis of intracellular copper accumulation suggested that DSE955PL and DSE955 (a chromosome mutant) were able to accumulate copper (80 - 110 mg.gˉ¹ dry weight of cells), whereas DRDC8 and strains carrying mutations in pCT0018, ctpA, and strains cured of the large plasmid, were less able to accumulate copper (30 - 70 mg.gˉ¹ dry weight of cells). This data suggested that cutR may encode a copper export system and that ctpA is involved in copper uptake. To investigate the gene expression profile for pCT0018 under elevated copper, reverse transcriptase PCR was used to detect transcripts encoding pCT0017, pCT0018, pCT0019 and pCT0020 from RNA extracted from L. monocytogenes strain DRDC8 following culture at elevated levels of copper. Although transcripts for each of the target genes were detected, transcription was not responsive to copper, nor was the pattern of transcription consistent with that expected for a single operon. To directly determine whether the protein encoded by the pCT0018 open reading frame was able to bind copper, this gene was cloned in pET15b in frame with an N-terminal Histag and expressed in E. coli. The expressed protein was purified with a Ni-NTA column and shown to contain copper. Attempts to directly show that protein pCT0018 could bind copper by Cu-IMAC were unable to unequivocally show that the protein was immobilized on the column. Purified protein was used to raise a polyclonal antiserum in rabbit and the antiserum was used for Western analysis to test expression of pCT0018 by wild type L. monocytogenes DRDC8 and specific gene mutants. Although the antiserum bound to purified protein, it was not possible to demonstrate binding to native pCT0018 in cell lysates prepared from L. monocytogenes DRDC8. SDS-PAGE of cytoplasmic and cell envelope proteins isolated from L. monocytogenes strains was used to identify proteins expressed in response to copper stress and starvation. No significant differences in protein profiles for cytoplasmic protein were observed. However, copper-immobilized metal affinity chromatography (Cu-IMAC) showed that expression of a number of copper binding proteins were differentially expressed by DRDC8 following growth in copper stress and starvation conditions. Three of these proteins were selected for amino sequence analysis by MALDI-TOFF MS. Two were confirmed to be L. monocytogenes non-heme iron-binding ferritin and a thiol peroxidase, both of which bind copper. The other protein was similar to an unknown protein from L. monocytogenes. Interestingly, no proteins directly implicated with the copper homeostasis islet were identified. / http://proxy.library.adelaide.edu.au/login?url= http://library.adelaide.edu.au/cgi-bin/Pwebrecon.cgi?BBID=1374407 / Thesis (M.Sc.) - University of Adelaide, School of Molecular and Biomedical Science, 2009

Methodology for predicting microelectronic substrate warpage incorporating copper trace pattern characteristics

McCaslin, Luke

January 2008

Thesis (M. S.)--Mechanical Engineering, Georgia Institute of Technology, 2009. / Committee Chair: Sitaraman, Suresh; Committee Member: Peak, Russell; Committee Member: Ume, Charles

Phosphorylation of STAT1 Serine 727 Enhances Platinum Resistance in Uterine Serous Carcinoma / 子宮体部漿液性癌において、STAT1のセリン727リン酸化はプラチナ抵抗性に関わる

Zeng, Xiang

25 November 2019

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第22117号 / 医博第4530号 / 新制||医||1039(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 武藤 学, 教授 松原 和夫, 教授 滝田 順子 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

STAT1

pSTAT1-serine

casein kinase2

copper transport protein

uterine serous carcinoma

490

Methodology for predicting microelectronic substrate warpage incorporating copper trace pattern characteristics

McCaslin, Luke

09 July 2008

The current trend in electronics manufacturing is to decrease the size of electronic components while attempting to increase processing power and performance. This is leading to increased interest in thinner printed wiring boards and finer line widths and wire pitches. However, mismatches in the thermomechanical properties of materials used can lead to warpage, hindering these goals. Warpage can be problematic as it leads to misalignments during package assembly, reduced tolerances, and a variety of operational failures. Current warpage prediction techniques utilize isotropic volume averaging to estimate effective material properties in layers of copper mixed with interlayer dielectric material. However, these estimates do not provide material properties with sufficient accuracy to predict warpage, as they contain no information about the orientation of the copper traces. This thesis describes the development of a new technique to predict the warpage of a particular substrate. The technique accounts for both the trace pattern planar density and planar orientation in determining effective orthotropic material properties for each layer of a multi-layer substrate. Starting with the trace pattern image, this technique first divides the trace pattern into several smaller areas for a given layer of the substrate and then uses image processing techniques to determine the copper percentage and average trace orientation in each small area. The copper percentage and average trace direction orientation are used in conjunction with the material properties of copper and the dielectric material to calculate the effective orthotropic material properties of each smaller area of the substrate. A finite-element model is then created where each layer is represented as a concatenation of several small areas with independent directional properties, and such a model is then subjected to sequential thermal excursion as seen in the actual fabrication process. The results from the models have been compared against experimental data with a great degree of accuracy. The modeling technique and the results obtained clearly demonstrate the need for the proposed subdivisional orthotropic material property calculations, as opposed to homogeneous isotropic properties typically used for each layer in computational simulations, as these more accurate directional properties are capable of predicting warpage with higher accuracy.

Finite element modeling

Microelectronics packaging

Metals Thermomechanical properties

Copper Transport properties

Copper Thermal conductivity

Microelectronic packaging

Electronic packaging

Surface mount technology