00:03
In order to answer this question, let's talk about dna, okay, in the central dogma.
00:07
So it says complete.
00:09
Remember, base pairing rules where adenine pairs with, timing, and cytosine with, one.
00:16
This is in dna because in rna, these changes just by replacing the uracil by t.
00:23
In this case, you have atg, so you have here for the dna template, t, c, here you have c, t t t t t t t t t t g a t g t g t g t g t g t g okay so this is your temporary stand now the messenger rna remember that in the messenger rna is going to have the same sequence as the coding strength of dna so you'll have to copy this strand here, here, but replacing the thymines by uracin.
01:06
So you're going to have here, a u -g, g -a -g, a -a -a -u, g -a -a -a -c -g, okay, c -u -u -a -u, g -c -u -n -a -a -c.
01:30
Now also as well as this happens, the dna template also has the same, sequence as a transfer rna codon, okay? or columns.
01:40
Just replacing again that thymines by uraxin because this is rna.
01:44
And in rna you have uracin instead of time.
01:46
So you have here, m -u -a -c -c -u -c -u -u -a -c -u -a -c -u -a -c -u -a -c -u -g -g -a -u -g.
02:09
Okay? so this is your sequence of transfer -a -n -a -c -o -g.
02:14
And now they are telling you to translate this sequence here.
02:19
This i you have to use the messenger rna here so okay so a ug according to the to the genetic code codes for methionine so you have here methionine then you have g a g and gag codes for glutamate then you have a a asparaging then you have g a g a u and ga u cause for aspartate then you have gaa that calls for glutamate.
03:00
Then you have cuu that calls for leucing.
03:08
Then you have auu that calls for isolucing.
03:17
Then you have gggu, gcu that calls for alanine.
03:24
Then you have aac that calls for asparaging.
03:31
Okay, asparaging.
03:31
Now the one letter code here, they are also providing this here...