Difference between revisions of "Class Journal Week 2"
From LMU BioDB 2013
(Started Class Journal for week 2) |
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:#What is the biggest discovery that I made from these readings? | :#What is the biggest discovery that I made from these readings? | ||
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| + | :The biggest discovery I made from these readings came from the Hayes article. I thought that it would make sense that because DNA has to fit into the nucleus of a cell that it would have to be very information dense, but learning that DNA actually has extra nucleotides to buffer the effect of mutation and mistranslations was a revelation. I knew about introns and exons, but before now I didn't understand why introns existed. | ||
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:#What part of the readings did I understand the least? | :#What part of the readings did I understand the least? | ||
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| + | :I didn't particularly understand the Nirenberg article. He referred to a lot of organic chemicals that I was unfamiliar with, and the pace of the writing left me glassy-eyed. I think that if I was more familiar with the types of tests he was performing that I would have been more engaged. | ||
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:#How was the genetic code solved experimentally? | :#How was the genetic code solved experimentally? | ||
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| + | :Nirenberg sythesized mRNA and observed which amino acids resulted from a given input. | ||
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:#What is the relationship between the genetic code and a computer code? | :#What is the relationship between the genetic code and a computer code? | ||
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| + | :DNA encodes "lines of programming," a message composed of nucleotides that needs to be "run." A section of DNA in transcribed, just as computers transcribe sections of a program on a disk. In both computers and cells, the transcribed pieces are sent to different parts of the system. In cells, mRNA is translated into amino acids which become proteins, while in computers digital data is translated into analog output. | ||
Revision as of 05:55, 4 September 2013
Lena Hunt
-
- What is the biggest discovery that I made from these readings?
- The biggest discovery I made from these readings came from the Hayes article. I thought that it would make sense that because DNA has to fit into the nucleus of a cell that it would have to be very information dense, but learning that DNA actually has extra nucleotides to buffer the effect of mutation and mistranslations was a revelation. I knew about introns and exons, but before now I didn't understand why introns existed.
-
- What part of the readings did I understand the least?
- I didn't particularly understand the Nirenberg article. He referred to a lot of organic chemicals that I was unfamiliar with, and the pace of the writing left me glassy-eyed. I think that if I was more familiar with the types of tests he was performing that I would have been more engaged.
-
- How was the genetic code solved experimentally?
- Nirenberg sythesized mRNA and observed which amino acids resulted from a given input.
-
- What is the relationship between the genetic code and a computer code?
- DNA encodes "lines of programming," a message composed of nucleotides that needs to be "run." A section of DNA in transcribed, just as computers transcribe sections of a program on a disk. In both computers and cells, the transcribed pieces are sent to different parts of the system. In cells, mRNA is translated into amino acids which become proteins, while in computers digital data is translated into analog output.
