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Transcript 
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HOW PROTEINS ARE MADE
Decoding the Information
in DNA
What You’ll Learn
How the structure of DNA
compares to the structure of
RNA
The purpose of transcription
of DNA.
The purpose of translation of
RNA.
You most likely know the
importance of DNA to
living things. You may
recall that DNA contains
all of the genetic
information for an
organism. Most of the
information in DNA is
stored in coding segments
known as genes. A gene is
a specific sequence of
nucleotides in a strand of
DNA that codes for a
specific sequence of
amino acids. The amino
acids form chains that
make a certain protein
depending on the order of
the nitrogenous bases.
Just like 26 letters of the
alphabet make words, 20
amino acids can be joined
The role of codons to the
sequence of amino acids in
the production of a protein.
together in various orders and lengths
to make different proteins. Let us
discuss how that genetic information
gets processed into the molecules
needed to make proteins.
Why are proteins so important?
Proteins are some of the most valuable molecules for life. Proteins are essential to build muscle.
They are found in cell membranes to help with transport. Hormones and enzymes are also proteins.
Without these vital biomolecules, life could not exist!
DNA – the “plan” for making proteins
DNA is basically an informational molecule as it
stores the information needed to produce the
proteins. You may remember that the DNA
molecule is made of repeating nucleotides
composed of pentose sugar called deoxyribose, a
phosphate group, and one of four nitrogenous
bases (adenine, thymine, cytosine or guanine).
DNA has the “plan” to make all of the proteins.
However, DNA is a large molecule and it can’t fit
through the nuclear pores. It has to remain inside
the nucleus. So, how does the information get to
the ribosomes in the cytoplasm for the production
of proteins? That’s where a molecule called RNA
comes in!
RNA is different from DNA
RNA is known as ribonucleic acid. RNA is
different from DNA in a few ways.
1. The sugar in RNA is ribose.
2. RNA is usually single-stranded.
3. RNA is smaller than DNA, but can be
millions of nucleotides long.
4. RNA can leave the nucleus.
5. RNA has the nitrogen base “uracil”
instead of thymine
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Transcription – making the template for a protein
There are three main types of RNA:
mRNA, rRNA, and tRNA. These RNA
molecules have different structures and,
therefore, have different jobs in the
protein-making process, or protein
synthesis. This process of making
proteins consists of two major stages:
transcription and translation.
During transcription, the mRNA strand
provides a way to transport the
information contained in the DNA inside
the nucleus to other parts of the cell. As
DNA codons are transcribed into RNA, it
is a uracil on the RNA that is base paired
with adenine.
An enzyme, RNA polymerase, separates
the DNA strands in a section of DNA that
codes for a particular protein.
A complementary mRNA strand is
formed by base-paring to the original
DNA strand.
Once the sequence of the DNA is copied
into mRNA, the DNA zips back up.
mRNA now contains the DNA
“message” and leaves the nucleus.
Reading mRNA
The mRNA molecule now has the
genetic code to make a protein. The
mRNA strand will be read three letters at
a time. These three letter sections are
called RNA codons. These codons will
specify a single amino acid that will be
added to a string of amino acids, known
as a polypeptide, that will eventually
make a protein.
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Now that the mRNA has left the nucleus, it is on its way to the ribosome. The
ribosome is made of rRNA that will bind to the mRNA to help assemble amino acids
into a protein. Before the protein can be made, the mRNA codons have to be
translated at the ribosome.
Here are the steps of translation:
1. Translation begins with the “Start” codon
AUG. This codon moves into the
ribosome.
2. For every mRNA codon, there is a tRNA
anticodon that base-pairs to the bases of
mRNA. Each tRNA molecule can only
carry one specific amino acid. The tRNA
brings the correct amino acid to the
ribosome.
3. The next codon is read. The
complementary tRNA base-pairs with the
codon bringing the correct amino acid to
the ribosome.
4. The ribosome joins the two amino acids.
Another tRNA molecule comes in and
reads the next codon.
This process repeats and the protein will
continue growing until a Stop codon signals
the end point for making that particular
protein.
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