Eukaryotic cells contain numerous iron-requiring pro- teins such as iron-sulfur (Fe-S) cluster proteins, hemoproteins and ribonucleotide reductases (RNRs). These proteins utilize iron as a cofactor and perform key...Eukaryotic cells contain numerous iron-requiring pro- teins such as iron-sulfur (Fe-S) cluster proteins, hemoproteins and ribonucleotide reductases (RNRs). These proteins utilize iron as a cofactor and perform key roles in DNA replication, DNA repair, metabolic catalysis, iron regulation and cell cycle progression. Disruption of iron homeostasis always impairs the functions of these iron- requiring proteins and is genetically associated with diseases characterized by DNA repair defects in mam- mals. Organisms have evolved multi-layered mecha- nisms to regulate iron balance to ensure genome stability and cell development. This review briefly pro- vides current perspectives on iron homeostasis in yeast and mammals, and mainly summarizes the most recent understandings on iron-requiring protein functions involved in DNA stability maintenance and cell cycle control.展开更多
Excess iron is tightly associated with tumorigenesis in multiple human cancer types through a variety of mechanisms including catalyzing the formation of mutagenic hydroxyl radicals, regulating DNA replica- tion, repa...Excess iron is tightly associated with tumorigenesis in multiple human cancer types through a variety of mechanisms including catalyzing the formation of mutagenic hydroxyl radicals, regulating DNA replica- tion, repair and cell cycle progression, affecting signal transduction in cancer cells, and acting as an essential nutrient for proliferating tumor cells, Thus, multiple therapeutic strategies based on iron deprivation have been developed in cancer therapy, During the past few years, our understanding of genetic association and molecular mechanisms between iron and tumorigenesis has expanded enormously. In this review, we briefly summarize iron homeostasis in mammals, and discuss recent progresses in understanding the aberrant iron metabolism in numerous cancer types, with a focus on studies revealing altered signal transduction in cancer cells.展开更多
Cells contain a large number of metalloproteins that commonly harbor at least one metal ion cofactor. In metalloproteins, metal ions are usually coordinated by oxygen, sulfur, or nitrogen centers belonging to amino ac...Cells contain a large number of metalloproteins that commonly harbor at least one metal ion cofactor. In metalloproteins, metal ions are usually coordinated by oxygen, sulfur, or nitrogen centers belonging to amino acid residues in the protein. The presence of the metal ion in metalloproteins allows them to take part in diverse biological processes, such as genome stability, metabolic catalysis, and cell cycle progression. Clinically, alteration of the function of metalloproteins in mammals is genetically associated with diseases characterized by DNA damage and repair defects. The present review focuses on the current perspectives of metal ion homeostasis in different organisms and summarizes the most recent understanding on magnesium, copper, iron, and manganese-containing proteins and their functional involvement in the maintenance of genome stability.展开更多
Eukaryotic organisms require iron to sustain genome stability, cell proliferation and development. Chromosomes contain telomeres to ensure complete replications and avoid fusions. Numerous evidences reveal that iron c...Eukaryotic organisms require iron to sustain genome stability, cell proliferation and development. Chromosomes contain telomeres to ensure complete replications and avoid fusions. Numerous evidences reveal that iron can act directly or indirectly on telomere maintenance. In human, disruption of systemic or cellular iron homeostasis is reportedly to cause serious health problems such as iron overload (hereditary hemochromatosis), iron deficiency anemia, carcinogenesis and acceleration of aging process. These processes commonly associate with abnormal telomere length. Additionally, cells containing mutations in iron-containing proteins such as DNA polymerases (Pola, g, and ~), regulator of telomere length 1 (RTEL1) and the small subunit of ribonucleotide reductases (RNRs) have abnormal telomere length. This review briefly summarizes current understandings on iron homeostasis and telomere maintenance in cancer and aging process, followed by discussing their direct and indirect correlation, and the possible regulatory mechanisms.展开更多
文摘Eukaryotic cells contain numerous iron-requiring pro- teins such as iron-sulfur (Fe-S) cluster proteins, hemoproteins and ribonucleotide reductases (RNRs). These proteins utilize iron as a cofactor and perform key roles in DNA replication, DNA repair, metabolic catalysis, iron regulation and cell cycle progression. Disruption of iron homeostasis always impairs the functions of these iron- requiring proteins and is genetically associated with diseases characterized by DNA repair defects in mam- mals. Organisms have evolved multi-layered mecha- nisms to regulate iron balance to ensure genome stability and cell development. This review briefly pro- vides current perspectives on iron homeostasis in yeast and mammals, and mainly summarizes the most recent understandings on iron-requiring protein functions involved in DNA stability maintenance and cell cycle control.
文摘Excess iron is tightly associated with tumorigenesis in multiple human cancer types through a variety of mechanisms including catalyzing the formation of mutagenic hydroxyl radicals, regulating DNA replica- tion, repair and cell cycle progression, affecting signal transduction in cancer cells, and acting as an essential nutrient for proliferating tumor cells, Thus, multiple therapeutic strategies based on iron deprivation have been developed in cancer therapy, During the past few years, our understanding of genetic association and molecular mechanisms between iron and tumorigenesis has expanded enormously. In this review, we briefly summarize iron homeostasis in mammals, and discuss recent progresses in understanding the aberrant iron metabolism in numerous cancer types, with a focus on studies revealing altered signal transduction in cancer cells.
文摘Cells contain a large number of metalloproteins that commonly harbor at least one metal ion cofactor. In metalloproteins, metal ions are usually coordinated by oxygen, sulfur, or nitrogen centers belonging to amino acid residues in the protein. The presence of the metal ion in metalloproteins allows them to take part in diverse biological processes, such as genome stability, metabolic catalysis, and cell cycle progression. Clinically, alteration of the function of metalloproteins in mammals is genetically associated with diseases characterized by DNA damage and repair defects. The present review focuses on the current perspectives of metal ion homeostasis in different organisms and summarizes the most recent understanding on magnesium, copper, iron, and manganese-containing proteins and their functional involvement in the maintenance of genome stability.
文摘Eukaryotic organisms require iron to sustain genome stability, cell proliferation and development. Chromosomes contain telomeres to ensure complete replications and avoid fusions. Numerous evidences reveal that iron can act directly or indirectly on telomere maintenance. In human, disruption of systemic or cellular iron homeostasis is reportedly to cause serious health problems such as iron overload (hereditary hemochromatosis), iron deficiency anemia, carcinogenesis and acceleration of aging process. These processes commonly associate with abnormal telomere length. Additionally, cells containing mutations in iron-containing proteins such as DNA polymerases (Pola, g, and ~), regulator of telomere length 1 (RTEL1) and the small subunit of ribonucleotide reductases (RNRs) have abnormal telomere length. This review briefly summarizes current understandings on iron homeostasis and telomere maintenance in cancer and aging process, followed by discussing their direct and indirect correlation, and the possible regulatory mechanisms.
