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- Challenges and Chances: A Review of the 1st Stem Cell Community Day
- Summertime, and the Livin’ Is Easy…
- Follow-on-Biologics – More than Simple Generics
- Bacteria Versus Body Cells: A 1:1 Tie
- Behind the Crime Scene: How Biological Traces Can Help to Convict Offenders
- Every 3 Seconds Someone in the World Is Affected by Alzheimer's
- HIV – It’s Still Not Under Control…
- How Many Will Be Convicted This Time?
- Malaria – the Battle is Not Lost
- Physicians on Standby: The Annual Flu Season Can Be Serious
- At the Forefront in Fighting Cancer
- Molecular Motors: Think Small and yet Smaller Again…
- Liquid Biopsy: Novel Methods May Ease Cancer Detection and Therapy
- They Are Invisible, Sneaky and Disgusting – But Today It’s Their Special Day!
- How Many Cells Are in Your Body? Probably More Than You Think!
- What You Need to Know about Antibiotic Resistance – Findings, Facts and Good Intentions
- Why Do Old Men Have Big Ears?
- The Condemned Live Longer: A Potential Paradigm Shift in Genetics
- From Research to Commerce
- Chronobiology – How the Cold Seasons Influence Our Biorhythms
- Taskforce Microbots: Targeted Treatment from Inside the Body
- Eyes on Cancer Therapy
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- 1995年の受賞者
1995 Award Winner Professor Dr. Stephen P. Jackson Wellcome/CRC Institute, University of Cambridge, England
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The work of Professor Jackson
Much of Professor Jackson's research has focused on how proteins of the transcription machinery work at the molecular level and how gene transcription is regulated. For example, he has made the surprising discovery that many transcription factors are glycosylated. Furthermore, his laboratory has shown that an important mechanism for controlling transcrip-tion during the cell cycle is the regulation of transcription factor TFIIIB, which consists of the TATA-binding protein and several proteins called TAFs. Other major achievements in this area include work revealing fundamental similarities between the three transcription systems of eukaryotes, and the discovery that transcription in a group of organisms called archaebacteria is very similar to that in human cells.Recently, Professor Jackson has directed most of his efforts on studies of the enzyme called DNA-dependent protein kinase(DNA-PK). For example, he has utilized the combination of biochemistry and molecular biology to show that DNA-PK is able to phosphorylate many proteins that bind DNA, including transcription factors Sp1, c-Jun, and p53. Furthermore, he has demonstrated that DNA-PK is essential for the development of the immune system - being required for the process of V(D)J recombination that generates the genes for T-cell receptor proteins and antibodies.Moreover, he has discovered that DNA-PK recognizes DNA damage that is caused by agents such as ionizing radiation. Thus, cells or animals defective in DNA-PK are hypersensitive to the killing effects of DNA damaging agents. Unrepaired DNA damage can kill cells, or can lead to diseases such as cancer through the generation of mutations or through causing the loss important genetic material. Since ionizing radiation is involved in both the generation and treatment of cancers, Professor Jackson's future work on DNA-PK may have considerable medical importance. Consistent with this prediction, Professor Jackson's laboratory has recently cloned the gene for the catalytic subunit of DNA-PK and has shown that it is related to a protein called ATM,which, when mutated,predisposes humans to cancer. Much of Professor Jackson's future work will be directed towards trying to understand how DNA-PK, ATM and other related proteins function.
Much of Professor Jackson's research has focused on how proteins of the transcription machinery work at the molecular level and how gene transcription is regulated. For example, he has made the surprising discovery that many transcription factors are glycosylated. Furthermore, his laboratory has shown that an important mechanism for controlling transcrip-tion during the cell cycle is the regulation of transcription factor TFIIIB, which consists of the TATA-binding protein and several proteins called TAFs. Other major achievements in this area include work revealing fundamental similarities between the three transcription systems of eukaryotes, and the discovery that transcription in a group of organisms called archaebacteria is very similar to that in human cells.Recently, Professor Jackson has directed most of his efforts on studies of the enzyme called DNA-dependent protein kinase(DNA-PK). For example, he has utilized the combination of biochemistry and molecular biology to show that DNA-PK is able to phosphorylate many proteins that bind DNA, including transcription factors Sp1, c-Jun, and p53. Furthermore, he has demonstrated that DNA-PK is essential for the development of the immune system - being required for the process of V(D)J recombination that generates the genes for T-cell receptor proteins and antibodies.Moreover, he has discovered that DNA-PK recognizes DNA damage that is caused by agents such as ionizing radiation. Thus, cells or animals defective in DNA-PK are hypersensitive to the killing effects of DNA damaging agents. Unrepaired DNA damage can kill cells, or can lead to diseases such as cancer through the generation of mutations or through causing the loss important genetic material. Since ionizing radiation is involved in both the generation and treatment of cancers, Professor Jackson's future work on DNA-PK may have considerable medical importance. Consistent with this prediction, Professor Jackson's laboratory has recently cloned the gene for the catalytic subunit of DNA-PK and has shown that it is related to a protein called ATM,which, when mutated,predisposes humans to cancer. Much of Professor Jackson's future work will be directed towards trying to understand how DNA-PK, ATM and other related proteins function.
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