So this chapter is all about nucleic acid structure, DNA replication and chromosome structure. I was delighted when I found out we were moving on to a new unit of the book, genetics! Prior to this year I hadn't really been exposed to genetics too much in depth, so I was excited to explore this topic.
My first useful material is this game from the official site of the Nobel Prize, Nobelprize.org. And did I mention it’s a game?! Oh wait- I did. If you like animations and visual learning, I would suggest trying out the game. It lets you first make copies of a double-stranded DNA molecule by matching base pairs to each strand. When you’re done, you have to read about different organisms and determine which organism the DNA belongs to. But be careful! If you match incorrectly or determine the wrong organism, you’ll lose a ton of points.
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| A screenshot from the game. |
This game was a great break from usual learning out of a text book. Interactivity is my most successful way of learning, so I actually did learn a lot from this game. It was also fun too, so that was an added bonus. If you have some free time I’d recommend playing this game.
Next I found this video that explains telomere replication. When reading the book I understood the structure and function of telomeres, but I didn’t exactly get the replication process. This video does a good job explaining the entire process and integrating exactly what telomerase does. The book had very nicely drawn visuals, which I’ll credit it for, but seeing this as an animation made this seem much simpler and easier. I liked how the nucleotides were all colored to show which regions were the genes and which regions were the telomeres. In addition, this video is from a biology textbook, it’s not just some random video. It’s only two minutes long, and it pretty much summarizes what the book says in 6 long paragraphs.
Being on the topic of telomeres, I decided to read more about it online and stumbled across this PubMed article. The article talks about telomere length in cardiovascular disease and how telomeres play a role in aging. Atherosclerosis is an age-related disease that involves different types of leukocytes. Telomere dysfunction has been connected in aging and senescence. Shorter leukocyte telomere length (LTL) has been verified to predict cardiovascular disease and mortality. The article overviews telomere biology and telomere dynamics of different leukocyte populations. In addition, the article talks about pitfalls in the methodology of LTL quantification and how telomere length can be implemented as an individual biomarker for cardiovascular aging. It’s actually really interesting how big of a role telomeres play in our lives.
Being on the topic of telomeres, I decided to read more about it online and stumbled across this PubMed article. The article talks about telomere length in cardiovascular disease and how telomeres play a role in aging. Atherosclerosis is an age-related disease that involves different types of leukocytes. Telomere dysfunction has been connected in aging and senescence. Shorter leukocyte telomere length (LTL) has been verified to predict cardiovascular disease and mortality. The article overviews telomere biology and telomere dynamics of different leukocyte populations. In addition, the article talks about pitfalls in the methodology of LTL quantification and how telomere length can be implemented as an individual biomarker for cardiovascular aging. It’s actually really interesting how big of a role telomeres play in our lives.
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