BioSec 2012: Elizabeth: Difference between revisions

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==Feb 1==
==Feb 1==


Readings for the class:
===Class readings:===
Chapter 6: Cellular Respiration
Chapter 6: Cellular Respiration
Chapter 7: Photosynthesis
Chapter 7: Photosynthesis


===In-class notes:===
Both chapters address how cells make ATP and other byproducts.  
Both chapters address how cells make ATP and other byproducts.  
* not a lot of discussion about how the two processes fit together (I mean, photosynthesis is the more important because it creates the glucose for cellular respiration to use?)
* not a lot of discussion about how the two processes fit together (I mean, photosynthesis is the more important because it creates the glucose for cellular respiration to use?)

Revision as of 03:51, 5 February 2012

Elizabeth's BioSec Notes

(Organized by class dates) Brain dumps, useful insights, points of confusion, it's all here.

Jan 25

Class readings:

Chapter 2: Origins of Life Chapter 3: Selection, Biodiversity, and Biosphere

In-class notes:

  • Chemistry Review
    • energy difference between reactants and products in a chemical reaction
    • however, you need an input of energy to begin the reaction
  • a catalyst changes (lowers the energy needed to reach the intermediate state, making the reaction more likely to take place
    • the catalyst is unchanged in the process
  • Biological catalysts are enzymes (proteins) that hold the reactants and situate them in such a way that the reaction can happen more easily
    • enzymes move the reactants around
    • enzymes can have crystalline structure
  • cell logic is built on pattern-matching
    • enzyme is looking for the reactants that fit its receptors
  • ATP: Adenosine Triphosphate
    • energy carrier/source for cells
    • universal resource, used by all cells
  • ADP: Adenosine Diphosphate
    • similar to ATP, but has one fewer phosphate group
    • has lower energy than ATP
    • the cell expends energy to turn it into ATP
    • then the cell breaks up the ATP to use the stored energy
  • Eukaryotic cells vs. Prokaryotic cells
    • in eukaryotic cells, the genetic sequence isn't simply copied from DNA to RNA. Instead, parts of different sequences are picked and chosen and edited into proteins.
    • this means that a lot of the information in the DNA is there to control and regulate how parts are edited and assembled.
  • Because of how evolution works (building on what already worked), understanding how a system works is equivalent to understanding its history, and why it is the way it is.
    • however, it can be hard to know where stuff came from, and what came first

Jan 27

Feb 1

Class readings:

Chapter 6: Cellular Respiration Chapter 7: Photosynthesis

In-class notes:

Both chapters address how cells make ATP and other byproducts.

  • not a lot of discussion about how the two processes fit together (I mean, photosynthesis is the more important because it creates the glucose for cellular respiration to use?)
  • much of the in-depth chemistry was confusing
  • In Ch 7, I didn't fully understand the last section about photorespiration and how plants avoid it
    • what is the problem, really?
    • I understand that the C4 cycle resolves it

Possible application-y thoughts

  • both photosynthesis and cellular respiration involve a lot of cyclical processes (like loops, I suppose) that transform one product into another
  • the cellular structure model seems like it could be applied to computers (and is similar to what exists), but maybe the metaphor could be extended to be larger?
  • what would ATP map to in the computer world? Information output?
  • It seems that the processes are finely tuned so that most of the by-products (except energy lost in heat) get used - is there a moral in that story?

Feb 3