Thayer Lab

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('''Mathew J. Thayer, Ph.D.''')
('''Mathew J. Thayer, Ph.D.''')
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== '''Mathew J. Thayer, Ph.D.''' ==
== '''Mathew J. Thayer, Ph.D.''' ==
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[[Image:thayer.jpg|right|frame|]]
Associate Professor<br>
Associate Professor<br>
Department of Biochemistry and Molecular Biology<br>
Department of Biochemistry and Molecular Biology<br>
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(503)494-2447<br>
(503)494-2447<br>
thayerm@ohsu.edu
thayerm@ohsu.edu
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-
 
== RESEARCH INTERESTS ==
== RESEARCH INTERESTS ==
Cancer cells differ from their normal cellular counterparts in many important characteristics, including loss of differentiation, increased genomic instability, and decreased drug sensitivity.  Not surprisingly, genetic alterations occur in most, if not all cancer cells, and are thought to lie at the heart of these phenotypic alterations.  Furthermore, genetic instability is thought to be required to generate the multiple genetic changes that occur in cancer cells.  My laboratory uses somatic cell and molecular genetics to identify and characterize genetic alterations found in tumor cells that induce abnormal cellular phenotypes.  By utilizing this approach, my lab has identified a previously unknown chromosomal abnormality that is associated with certain chromosomal rearrangements.  This chromosomal phenotype is characterized by a delay in mitotic chromosome condensation, a delay in the chromosome replication timing, and significant chromosomal instability.  Chromosomes with this phenotype are common in tumor derived cell lines and in primary tumors.  Furthermore, we have found that exposing cells to ionizing radiation generates chromosomes with this phenotype.  Our findings support a model in which the chromosomal instability found in tumor cells, and in cells exposed to ionizing radiation, stems from a defect in the replication timing of certain chromosomal rearrangements.  Recently, we developed a chromosome engineering strategy that allows us to generate chromosomes with this delayed replication and condensation phenotype in an efficient and reproducible manner.  Our findings indicate that ~5% of all random chromosome translocations display this abnormal phenotype.  In addition, on certain balanced translocations only one of the derivative chromosomes displays the phenotype, indicating that a cis-acting mechanism is responsible for this abnormal chromosomal phenotype.  The primary goal of this proposal is to characterize this cis-acting mechanism that functions to delay the replication timing of entire chromosomes. This proposal utilizes ‘chromosome engineering’ strategies, combined with somatic cell and molecular genetic approaches, to generate and characterize chromosomes with this delayed replication and condensation phenotype.  The long-term goal of these studies is to define the molecular mechanisms responsible for chromosomal instability, one of the most common types of genetic instabilities found in cancer cells.
Cancer cells differ from their normal cellular counterparts in many important characteristics, including loss of differentiation, increased genomic instability, and decreased drug sensitivity.  Not surprisingly, genetic alterations occur in most, if not all cancer cells, and are thought to lie at the heart of these phenotypic alterations.  Furthermore, genetic instability is thought to be required to generate the multiple genetic changes that occur in cancer cells.  My laboratory uses somatic cell and molecular genetics to identify and characterize genetic alterations found in tumor cells that induce abnormal cellular phenotypes.  By utilizing this approach, my lab has identified a previously unknown chromosomal abnormality that is associated with certain chromosomal rearrangements.  This chromosomal phenotype is characterized by a delay in mitotic chromosome condensation, a delay in the chromosome replication timing, and significant chromosomal instability.  Chromosomes with this phenotype are common in tumor derived cell lines and in primary tumors.  Furthermore, we have found that exposing cells to ionizing radiation generates chromosomes with this phenotype.  Our findings support a model in which the chromosomal instability found in tumor cells, and in cells exposed to ionizing radiation, stems from a defect in the replication timing of certain chromosomal rearrangements.  Recently, we developed a chromosome engineering strategy that allows us to generate chromosomes with this delayed replication and condensation phenotype in an efficient and reproducible manner.  Our findings indicate that ~5% of all random chromosome translocations display this abnormal phenotype.  In addition, on certain balanced translocations only one of the derivative chromosomes displays the phenotype, indicating that a cis-acting mechanism is responsible for this abnormal chromosomal phenotype.  The primary goal of this proposal is to characterize this cis-acting mechanism that functions to delay the replication timing of entire chromosomes. This proposal utilizes ‘chromosome engineering’ strategies, combined with somatic cell and molecular genetic approaches, to generate and characterize chromosomes with this delayed replication and condensation phenotype.  The long-term goal of these studies is to define the molecular mechanisms responsible for chromosomal instability, one of the most common types of genetic instabilities found in cancer cells.

Revision as of 12:03, 16 May 2007

Mathew J. Thayer, Ph.D.

Associate Professor
Department of Biochemistry and Molecular Biology
Oregon Health & Science University
3181 SW Sam Jackson Park Road
Portland OR 97239
(503)494-2447
thayerm@ohsu.edu

RESEARCH INTERESTS

Cancer cells differ from their normal cellular counterparts in many important characteristics, including loss of differentiation, increased genomic instability, and decreased drug sensitivity. Not surprisingly, genetic alterations occur in most, if not all cancer cells, and are thought to lie at the heart of these phenotypic alterations. Furthermore, genetic instability is thought to be required to generate the multiple genetic changes that occur in cancer cells. My laboratory uses somatic cell and molecular genetics to identify and characterize genetic alterations found in tumor cells that induce abnormal cellular phenotypes. By utilizing this approach, my lab has identified a previously unknown chromosomal abnormality that is associated with certain chromosomal rearrangements. This chromosomal phenotype is characterized by a delay in mitotic chromosome condensation, a delay in the chromosome replication timing, and significant chromosomal instability. Chromosomes with this phenotype are common in tumor derived cell lines and in primary tumors. Furthermore, we have found that exposing cells to ionizing radiation generates chromosomes with this phenotype. Our findings support a model in which the chromosomal instability found in tumor cells, and in cells exposed to ionizing radiation, stems from a defect in the replication timing of certain chromosomal rearrangements. Recently, we developed a chromosome engineering strategy that allows us to generate chromosomes with this delayed replication and condensation phenotype in an efficient and reproducible manner. Our findings indicate that ~5% of all random chromosome translocations display this abnormal phenotype. In addition, on certain balanced translocations only one of the derivative chromosomes displays the phenotype, indicating that a cis-acting mechanism is responsible for this abnormal chromosomal phenotype. The primary goal of this proposal is to characterize this cis-acting mechanism that functions to delay the replication timing of entire chromosomes. This proposal utilizes ‘chromosome engineering’ strategies, combined with somatic cell and molecular genetic approaches, to generate and characterize chromosomes with this delayed replication and condensation phenotype. The long-term goal of these studies is to define the molecular mechanisms responsible for chromosomal instability, one of the most common types of genetic instabilities found in cancer cells.

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