Structure-dependent bypass of DNA interstrand crosslinks by translesion synthesis polymerases

DNA interstrand crosslinks (ICLs), inhibit DNA metabolism by covalently linking two strands of DNA and are formed by antitumor agents such as cisplatin and nitrogen mustards. Multiple complex repair pathways of ICLs exist in humans that share translesion synthesis (TLS) past a partially processed ICL as a common step. We have generated site-specific major groove ICLs and studied the ability of Y-family polymerases and Pol ζ to bypass ICLs that induce different degrees of distortion in DNA. Two main factors influenced the efficiency of ICL bypass: the length of the dsDNA flanking the ICL and the length of the crosslink bridging two bases. Our study shows that ICLs can readily be bypassed by TLS polymerases if they are appropriately processed and that the structure of the ICL influences which polymerases are able to read through i

Structure-dependent bypass of DNA interstrand crosslinks by translesion synthesis polymerases

DNA interstrand crosslinks (ICLs), inhibit DNA metabolism by covalently linking two strands of DNA and are formed by antitumor agents such as cisplatin and nitrogen mustards. Multiple complex repair pathways of ICLs exist in humans that share translesion synthesis (TLS) past a partially processed ICL as a common step. We have generated site-specific major groove ICLs and studied the ability of Y-family polymerases and Pol zeta to bypass ICLs that induce different degrees of distortion in DNA. Two main factors influenced the efficiency of ICL bypass: the length of the dsDNA flanking the ICL and the length of the crosslink bridging two bases. Our study shows that ICLs can readily be bypassed by TLS polymerases if they are appropriately processed and that the structure of the ICL influences which polymerases are able to read through itope

CLONING and EXPRESSION of P1B-TYPE ATPase, HMA1

P1B-type ATPases are very important for the transport of heavy metals in many organisms. Heavy metal transport is crucial for biological systems because it enables the function and development of essential processes. AtHMA1 is a P1B-type ATPase in Arabidopsis thaliana which is suspected to play a role in Mn2+ transport. This project focuses on the cloning and expression of HMA1 in order to further characterize this P1B-type ATPase

Turkey-Iran -- a comparative case study in modernization

The path to Modernization Theory in the Middle East can be influenced along two different parameters; states with natural resources (primarily oil) and states without significant natural resources. This theory is examined by contrasting case studies involving Turkey (non-oil producer) and oil rich Iran in an effort to explicate their development. This comparative analysis will attempt to document and contrast the differences between these two nations along the road to modernization. We would like to document baseline data to assist this comparison. This is accomplished by the use of comparative data elements examining social, political, and economic phenomena of these two nations within the context of historical development and modernization. Our goal will be to inform these two modernization tracks in an effort to enhance our knowledge on how these variables changed with the influence of the presence or absence of natural resources, mainly oil. We also will attempt to review the consequences of these variables in elevating the status of these two nations on the world stage of globalization. In addition, our research will seek to explain how these variables are helpful in explaining Modernization Theory particularly as it applies to the Middle East. Finally, we have a major interest in the role of technology and democratic variables as markers for progress in modernization

Mutations in ERCC4, encoding the DNA-repair endonuclease XPF, cause Fanconi anemia

BFanconi anemia (FA) is a rare genomic instability disorder characterized by progressive bone marrow failure and predisposition to cancer. FA-associated gene products are involved in the repair of DNA interstrand crosslinks (ICLs). Fifteen FA-associated genes have been identified, but the genetic basis in some individuals still remains unresolved. Here, we used whole-exome and Sanger sequencing on DNA of unclassified FA individuals and discovered biallelic germline mutations in ERCC4 (XPF), a structure-specific nuclease-encoding gene previously connected to xeroderma pigmentosum and segmental XFE progeroid syndrome. Genetic reversion and wild-type ERCC4 cDNA complemented the phenotype of the FA cell lines, providing genetic evidence that mutations in ERCC4 cause this FA subtype. Further biochemical and functional analysis demonstrated that the identified FA-causing ERCC4 mutations strongly disrupt the function of XPF in DNA ICL repair without severely compromising nucleotide excision repair. Our data show that depending on the type of ERCC4 mutation and the resulting balance between both DNA repair activities, individuals present with one of the three clinically distinct disorders, highlighting the multifunctional nature of the XPF endonuclease in genome stability and human disease

Mutations in ERCC4, Encoding the DNA-Repair Endonuclease XPF, Cause Fanconi Anemia

Fanconi anemia (FA) is a rare genomic instability disorder characterized by progressive bone marrow failure and predisposition to cancer. FA-associated gene products are involved in the repair of DNA interstrand crosslinks (ICLs). Fifteen FA-associated genes have been identified, but the genetic basis in some individuals still remains unresolved. Here, we used whole-exome and Sanger sequencing on DNA of unclassified FA individuals and discovered biallelic germline mutations in ERCC4 (XPF), a structure-specific nuclease-encoding gene previously connected to xeroderma pigmentosum and segmental XFE progeroid syndrome. Genetic reversion and wild-type ERCC4 cDNA complemented the phenotype of the FA cell lines, providing genetic evidence that mutations in ERCC4 cause this FA subtype. Further biochemical and functional analysis demonstrated that the identified FA-causing ERCC4 mutations strongly disrupt the function of XPF in DNA ICL repair without severely compromising nucleotide excision repair. Our data show that depending on the type of ERCC4 mutation and the resulting balance between both DNA repair activities, individuals present with one of the three clinically distinct disorders, highlighting the multifunctional nature of the XPF endonuclease in genome stability and human disease.clos