DNA in the nucleus is transcribed into mRNA which is then translated into proteins. Transcription involves mRNA copying the DNA sequence. Translation occurs in the cytoplasm where mRNA binds to ribosomes and uses tRNA and its anticodons to add amino acids together in the correct sequence specified by mRNA to form a protein chain. Once translation is complete, the mRNA nucleotides are recycled in the cell.
The document describes the process of protein synthesis. mRNA binds to the ribosome and tRNA brings amino acids to the ribosome based on the mRNA codons. The amino acids are linked together based on the mRNA codons until a stop codon is reached, forming a protein chain.
The document describes the process of transcription and translation in cells. It shows how DNA in the nucleus is transcribed into mRNA, which passes through the nucleus pore into the cytoplasm. In the cytoplasm, ribosomes read the mRNA codons and join amino acids specified by tRNA molecules to form a protein chain. The chain continues growing until a stop codon is reached, resulting in a complete protein.
The document describes the process of DNA replication. It explains that the helicase enzyme first unwinds and separates the two strands of DNA. Then, DNA polymerase adds complementary nucleotides to each strand to recreate the original double helix structure. An RNA primer is used to initiate replication of the lagging strand, which is synthesized as Okazaki fragments and later joined by DNA ligase.
Transcription and translation are the two processes by which DNA is converted into functional proteins. During transcription, the DNA code is copied into a messenger RNA (mRNA) molecule. The mRNA then directs protein synthesis during translation, where ribosomes read the mRNA code and link amino acids together to form a protein chain based on the genetic instructions.
The document describes the process of transcription and translation. RNA polymerase in the nucleus reads DNA and produces mRNA, which exits into the cytoplasm. The ribosome then reads the mRNA and uses tRNA to assemble amino acids into a protein according to the mRNA's codon sequence.
RNA polymerase binds to DNA and transcribes it into mRNA. The mRNA exits the nucleus and binds to ribosomes in the cytoplasm during translation. Amino acids are joined via tRNA and peptide bonds to form a protein, which is complete when the ribosome reaches a stop codon.
The document describes the process of DNA replication. It begins with DNA unwinding at the origin of replication site, where helicase enzymes cause the double helix to separate. Free nucleotides then base pair with the exposed, complementary bases on each single strand. DNA polymerase joins the nucleotides to form new polynucleotide chains. Finally, the two new DNA molecules each contain one original and one new strand, and the double helix reforms.
The document summarizes the process of DNA replication. It explains that during replication, the DNA double helix unwinds and splits so that DNA polymerase can copy nucleotides to form new strands on each side. The strands are then rejoined by DNA ligase. It also discusses the importance of telomeres, telomerase, transplanted cells, and Okazaki fragments in replication and cell growth.
The document describes the process of protein synthesis. mRNA binds to the ribosome and tRNA brings amino acids to the ribosome based on the mRNA codons. The amino acids are linked together based on the mRNA codons until a stop codon is reached, forming a protein chain.
The document describes the process of transcription and translation in cells. It shows how DNA in the nucleus is transcribed into mRNA, which passes through the nucleus pore into the cytoplasm. In the cytoplasm, ribosomes read the mRNA codons and join amino acids specified by tRNA molecules to form a protein chain. The chain continues growing until a stop codon is reached, resulting in a complete protein.
The document describes the process of DNA replication. It explains that the helicase enzyme first unwinds and separates the two strands of DNA. Then, DNA polymerase adds complementary nucleotides to each strand to recreate the original double helix structure. An RNA primer is used to initiate replication of the lagging strand, which is synthesized as Okazaki fragments and later joined by DNA ligase.
Transcription and translation are the two processes by which DNA is converted into functional proteins. During transcription, the DNA code is copied into a messenger RNA (mRNA) molecule. The mRNA then directs protein synthesis during translation, where ribosomes read the mRNA code and link amino acids together to form a protein chain based on the genetic instructions.
The document describes the process of transcription and translation. RNA polymerase in the nucleus reads DNA and produces mRNA, which exits into the cytoplasm. The ribosome then reads the mRNA and uses tRNA to assemble amino acids into a protein according to the mRNA's codon sequence.
RNA polymerase binds to DNA and transcribes it into mRNA. The mRNA exits the nucleus and binds to ribosomes in the cytoplasm during translation. Amino acids are joined via tRNA and peptide bonds to form a protein, which is complete when the ribosome reaches a stop codon.
The document describes the process of DNA replication. It begins with DNA unwinding at the origin of replication site, where helicase enzymes cause the double helix to separate. Free nucleotides then base pair with the exposed, complementary bases on each single strand. DNA polymerase joins the nucleotides to form new polynucleotide chains. Finally, the two new DNA molecules each contain one original and one new strand, and the double helix reforms.
The document summarizes the process of DNA replication. It explains that during replication, the DNA double helix unwinds and splits so that DNA polymerase can copy nucleotides to form new strands on each side. The strands are then rejoined by DNA ligase. It also discusses the importance of telomeres, telomerase, transplanted cells, and Okazaki fragments in replication and cell growth.
Gregor Mendel was an Austrian monk who is considered the father of genetics. He conducted experiments with pea plants in which he studied 7 different traits. Through his experiments, Mendel discovered the principles of heredity, including that traits are passed from parents to offspring through discrete units called genes, and that some genes are dominant while others are recessive. When Mendel crossed plants with different traits, he found that the offspring expressed the traits of only one parent, not a blend, and that recessive traits could reappear in later generations. This led Mendel to propose that genes segregate and assort independently during the formation of gametes.
The document describes the process of protein synthesis. It explains that RNA polymerase first breaks the hydrogen bonds of DNA to copy it and make an mRNA strand. The mRNA strand then leaves the nucleus through the nuclear pore into the cytoplasm. In the cytoplasm, the mRNA binds to a ribosome where tRNA reads its bases and adds complementary amino acids to form a polypeptide chain.
Transcription occurs in the cell nucleus where DNA is unzipped and RNA polymerase adds complementary RNA nucleotides to the DNA template strand, forming mRNA. The mRNA is processed - a cap and tail are added and introns are removed. The completed mRNA contains codons of three nucleotides that code for amino acids. Translation occurs in the cytoplasm where the mRNA binds to ribosomes and tRNA molecules with matching anticodons deliver amino acids specified by mRNA codons, assembling the polypeptide chain specified by the mRNA.
This flip book depicts the process of protein synthesis, showing how DNA is transcribed into mRNA, which is then translated by ribosomes into a polypeptide chain. The flip book steps through transcription, where RNA polymerase copies DNA into mRNA, then translation, where the mRNA passes through the ribosome and interacts with tRNA and rRNA to add amino acids in the correct order specified by codons until a full protein is synthesized.
This document is a flip book that summarizes the process of protein synthesis. It shows how DNA is transcribed into mRNA by RNA polymerase in the nucleus. The mRNA is then transported out of the nucleus through the nuclear pore and binds to the ribosome in the cytoplasm. The ribosome reads the mRNA codons and binds transfer RNA (tRNA) with complementary anticodons. The tRNA brings amino acids to form peptide bonds and a polypeptide chain, which eventually folds into a functional protein.
This flip book depicts the process of protein synthesis, showing how DNA is transcribed into mRNA, which is then translated by ribosomes into a polypeptide chain. The flip book steps through transcription, where RNA polymerase copies DNA into mRNA, then translation, where the mRNA passes through the ribosome and interacts with tRNA and rRNA to add amino acids in the correct order specified by codons until a full protein is synthesized.
The document describes the process of transcription and translation in a cell. RNA polymerase unwinds DNA and creates an mRNA strand in the nucleus. The mRNA strand then moves to the cytoplasm through the nuclear pore. In the cytoplasm, the mRNA strand binds to a ribosome where tRNA brings amino acids to add to a growing polypeptide chain based on the mRNA codons. The polypeptide chain then folds into the final 3D protein structure.
The document describes the process of protein synthesis, which occurs in two steps: transcription and translation. In transcription, DNA is unwound and an mRNA strand is created using nucleotides. In translation, the mRNA strand is sent to the cytoplasm where it binds to a ribosome. tRNA molecules then bind to the ribosome and add amino acids specified by the mRNA code, forming a peptide bond between amino acids and creating a protein chain.
The document describes the process of protein synthesis, which occurs in two steps: transcription and translation. In transcription, DNA is unwound and an mRNA strand is created using nucleotides. The mRNA strand is then released and the DNA strands rebind. In translation, the mRNA moves to the cytoplasm and binds to ribosomes. tRNA molecules bind to the ribosome according to the mRNA code, and each tRNA connects to a specific amino acid. Translation begins as tRNA molecules form base pairs with the mRNA, and peptide bonds form between the amino acids, creating a protein.
The document describes the process of protein synthesis, which occurs in two main steps - transcription and translation. Transcription takes place in the nucleus and involves RNA polymerase copying genetic information from DNA to mRNA. Translation occurs in the cytoplasm at ribosomes, where the mRNA code is used to assemble amino acids in the correct order to produce a protein. The start codon on mRNA pairs with a complementary tRNA to initiate translation.
DNA replication begins at the origin of replication where DNA helicase unwinds and unzips the double helix. DNA polymerase reads the bases on one strand and adds complementary bases to the other strand. The leading strand is replicated continuously while the lagging strand is replicated discontinuously in fragments called Okazaki fragments. DNA primase adds primers to fill in the lagging strand, and DNA ligase seals the fragments together with phosphodiester bonds.
This protein synthesis flip book illustrates the process of transcription and translation. It shows DNA being transcribed into mRNA by RNA polymerase in the nucleus. The mRNA is then transported to the cytoplasm where it passes through ribosomes. During this process, transfer RNA (tRNA) molecules match to the mRNA codons and add amino acids to form a polypeptide chain through peptide bonds. Eventually a full protein is synthesized from the mRNA instructions.
The document outlines the process of protein synthesis which has two main parts - transcription and translation. In transcription, mRNA strands are created in the nucleus from a DNA template with the help of RNA polymerase. The mRNA then exits the nucleus through nuclear pores. In translation, which occurs in the cytoplasm, ribosomes read the mRNA to produce a protein. Transfer RNA molecules match their anticodons to mRNA codons and bring corresponding amino acids. The amino acids are linked together by peptide bonds to form a polypeptide chain, which becomes a protein when translation is complete.
Protein synthesis flipbook @yoloswagginator24punxsyscience
The document summarizes the process of protein synthesis. It describes how RNA polymerase unwinds DNA and copies it to mRNA. The mRNA strand then exits the nucleus through the nuclear pore and moves to ribosomes. At the ribosomes, the mRNA is read and translated to form a polypeptide chain of amino acids.
The document outlines the process of protein synthesis which has two main parts - transcription and translation. In transcription, mRNA strands are created in the nucleus from a DNA template with the help of RNA polymerase. The mRNA then exits the nucleus through nuclear pores. In translation, which occurs in the cytoplasm, ribosomes read the mRNA to produce a protein. Transfer RNA molecules match their anticodons to mRNA codons and bring corresponding amino acids. The amino acids are linked together by peptide bonds to form a polypeptide chain, which becomes a protein when translation is complete.
The document shows the process of protein synthesis:
1) In the nucleus, RNA polymerase unzips DNA and copies its sequence into a messenger RNA (mRNA) strand.
2) The mRNA exits the nucleus through the nuclear pore and enters the cytoplasm.
3) In the cytoplasm, the mRNA binds to a ribosome which reads its sequence in groups of three bases (codons).
4) Transfer RNA (tRNA) molecules matching these codons bring specific amino acids to the ribosome.
5) The amino acids are linked together to form a polypeptide chain, which later folds into a functional protein.
The document is a flip book that summarizes the key steps of protein synthesis: 1) DNA is unwound in the cell nucleus and an mRNA strand is produced, 2) the mRNA strand moves from the nucleus to the cytoplasm where ribosomes are located, 3) ribosomes read the mRNA strand and amino acids are attached through peptide bonds to form a protein, which then folds into its tertiary structure.
The document summarizes the process of protein synthesis. DNA in the nucleus is transcribed into mRNA by RNA polymerase. The mRNA then exits the nucleus and binds to a ribosome in the cytoplasm. The ribosome reads the mRNA and uses transfer RNA molecules to add amino acids to form a protein chain. The protein folds into its final shape.
The document discusses protein synthesis in cells. It explains that RNA polymerase in the cell nucleus reads DNA and synthesizes mRNA. The mRNA then exits the nucleus through nuclear pores and binds to ribosomes. At the ribosomes, tRNA matches codons on the mRNA and releases amino acids, forming peptide bonds between amino acids to create a polypeptide chain. When the ribosome reaches a stop codon, the polypeptide releases and folds into its tertiary structure to become a functional protein.
The process of transcription begins in the cell nucleus, where RNA polymerase breaks apart DNA and uses it as a template to create mRNA strands. During this process, thymine is replaced with uracil to form RNA. The mRNA strand then exits the nucleus through a nuclear pore. Translation occurs in the cytoplasm, where the mRNA is read by ribosomes in groups of three codons. Transfer RNA molecules bring amino acids to the ribosome based on codon-anticodon base pairing. As the ribosome moves along the mRNA, the growing polypeptide chain is released once a stop codon is reached.
Gregor Mendel was an Austrian monk who is considered the father of genetics. He conducted experiments with pea plants in which he studied 7 different traits. Through his experiments, Mendel discovered the principles of heredity, including that traits are passed from parents to offspring through discrete units called genes, and that some genes are dominant while others are recessive. When Mendel crossed plants with different traits, he found that the offspring expressed the traits of only one parent, not a blend, and that recessive traits could reappear in later generations. This led Mendel to propose that genes segregate and assort independently during the formation of gametes.
The document describes the process of protein synthesis. It explains that RNA polymerase first breaks the hydrogen bonds of DNA to copy it and make an mRNA strand. The mRNA strand then leaves the nucleus through the nuclear pore into the cytoplasm. In the cytoplasm, the mRNA binds to a ribosome where tRNA reads its bases and adds complementary amino acids to form a polypeptide chain.
Transcription occurs in the cell nucleus where DNA is unzipped and RNA polymerase adds complementary RNA nucleotides to the DNA template strand, forming mRNA. The mRNA is processed - a cap and tail are added and introns are removed. The completed mRNA contains codons of three nucleotides that code for amino acids. Translation occurs in the cytoplasm where the mRNA binds to ribosomes and tRNA molecules with matching anticodons deliver amino acids specified by mRNA codons, assembling the polypeptide chain specified by the mRNA.
This flip book depicts the process of protein synthesis, showing how DNA is transcribed into mRNA, which is then translated by ribosomes into a polypeptide chain. The flip book steps through transcription, where RNA polymerase copies DNA into mRNA, then translation, where the mRNA passes through the ribosome and interacts with tRNA and rRNA to add amino acids in the correct order specified by codons until a full protein is synthesized.
This document is a flip book that summarizes the process of protein synthesis. It shows how DNA is transcribed into mRNA by RNA polymerase in the nucleus. The mRNA is then transported out of the nucleus through the nuclear pore and binds to the ribosome in the cytoplasm. The ribosome reads the mRNA codons and binds transfer RNA (tRNA) with complementary anticodons. The tRNA brings amino acids to form peptide bonds and a polypeptide chain, which eventually folds into a functional protein.
This flip book depicts the process of protein synthesis, showing how DNA is transcribed into mRNA, which is then translated by ribosomes into a polypeptide chain. The flip book steps through transcription, where RNA polymerase copies DNA into mRNA, then translation, where the mRNA passes through the ribosome and interacts with tRNA and rRNA to add amino acids in the correct order specified by codons until a full protein is synthesized.
The document describes the process of transcription and translation in a cell. RNA polymerase unwinds DNA and creates an mRNA strand in the nucleus. The mRNA strand then moves to the cytoplasm through the nuclear pore. In the cytoplasm, the mRNA strand binds to a ribosome where tRNA brings amino acids to add to a growing polypeptide chain based on the mRNA codons. The polypeptide chain then folds into the final 3D protein structure.
The document describes the process of protein synthesis, which occurs in two steps: transcription and translation. In transcription, DNA is unwound and an mRNA strand is created using nucleotides. In translation, the mRNA strand is sent to the cytoplasm where it binds to a ribosome. tRNA molecules then bind to the ribosome and add amino acids specified by the mRNA code, forming a peptide bond between amino acids and creating a protein chain.
The document describes the process of protein synthesis, which occurs in two steps: transcription and translation. In transcription, DNA is unwound and an mRNA strand is created using nucleotides. The mRNA strand is then released and the DNA strands rebind. In translation, the mRNA moves to the cytoplasm and binds to ribosomes. tRNA molecules bind to the ribosome according to the mRNA code, and each tRNA connects to a specific amino acid. Translation begins as tRNA molecules form base pairs with the mRNA, and peptide bonds form between the amino acids, creating a protein.
The document describes the process of protein synthesis, which occurs in two main steps - transcription and translation. Transcription takes place in the nucleus and involves RNA polymerase copying genetic information from DNA to mRNA. Translation occurs in the cytoplasm at ribosomes, where the mRNA code is used to assemble amino acids in the correct order to produce a protein. The start codon on mRNA pairs with a complementary tRNA to initiate translation.
DNA replication begins at the origin of replication where DNA helicase unwinds and unzips the double helix. DNA polymerase reads the bases on one strand and adds complementary bases to the other strand. The leading strand is replicated continuously while the lagging strand is replicated discontinuously in fragments called Okazaki fragments. DNA primase adds primers to fill in the lagging strand, and DNA ligase seals the fragments together with phosphodiester bonds.
This protein synthesis flip book illustrates the process of transcription and translation. It shows DNA being transcribed into mRNA by RNA polymerase in the nucleus. The mRNA is then transported to the cytoplasm where it passes through ribosomes. During this process, transfer RNA (tRNA) molecules match to the mRNA codons and add amino acids to form a polypeptide chain through peptide bonds. Eventually a full protein is synthesized from the mRNA instructions.
The document outlines the process of protein synthesis which has two main parts - transcription and translation. In transcription, mRNA strands are created in the nucleus from a DNA template with the help of RNA polymerase. The mRNA then exits the nucleus through nuclear pores. In translation, which occurs in the cytoplasm, ribosomes read the mRNA to produce a protein. Transfer RNA molecules match their anticodons to mRNA codons and bring corresponding amino acids. The amino acids are linked together by peptide bonds to form a polypeptide chain, which becomes a protein when translation is complete.
Protein synthesis flipbook @yoloswagginator24punxsyscience
The document summarizes the process of protein synthesis. It describes how RNA polymerase unwinds DNA and copies it to mRNA. The mRNA strand then exits the nucleus through the nuclear pore and moves to ribosomes. At the ribosomes, the mRNA is read and translated to form a polypeptide chain of amino acids.
The document outlines the process of protein synthesis which has two main parts - transcription and translation. In transcription, mRNA strands are created in the nucleus from a DNA template with the help of RNA polymerase. The mRNA then exits the nucleus through nuclear pores. In translation, which occurs in the cytoplasm, ribosomes read the mRNA to produce a protein. Transfer RNA molecules match their anticodons to mRNA codons and bring corresponding amino acids. The amino acids are linked together by peptide bonds to form a polypeptide chain, which becomes a protein when translation is complete.
The document shows the process of protein synthesis:
1) In the nucleus, RNA polymerase unzips DNA and copies its sequence into a messenger RNA (mRNA) strand.
2) The mRNA exits the nucleus through the nuclear pore and enters the cytoplasm.
3) In the cytoplasm, the mRNA binds to a ribosome which reads its sequence in groups of three bases (codons).
4) Transfer RNA (tRNA) molecules matching these codons bring specific amino acids to the ribosome.
5) The amino acids are linked together to form a polypeptide chain, which later folds into a functional protein.
The document is a flip book that summarizes the key steps of protein synthesis: 1) DNA is unwound in the cell nucleus and an mRNA strand is produced, 2) the mRNA strand moves from the nucleus to the cytoplasm where ribosomes are located, 3) ribosomes read the mRNA strand and amino acids are attached through peptide bonds to form a protein, which then folds into its tertiary structure.
The document summarizes the process of protein synthesis. DNA in the nucleus is transcribed into mRNA by RNA polymerase. The mRNA then exits the nucleus and binds to a ribosome in the cytoplasm. The ribosome reads the mRNA and uses transfer RNA molecules to add amino acids to form a protein chain. The protein folds into its final shape.
The document discusses protein synthesis in cells. It explains that RNA polymerase in the cell nucleus reads DNA and synthesizes mRNA. The mRNA then exits the nucleus through nuclear pores and binds to ribosomes. At the ribosomes, tRNA matches codons on the mRNA and releases amino acids, forming peptide bonds between amino acids to create a polypeptide chain. When the ribosome reaches a stop codon, the polypeptide releases and folds into its tertiary structure to become a functional protein.
The process of transcription begins in the cell nucleus, where RNA polymerase breaks apart DNA and uses it as a template to create mRNA strands. During this process, thymine is replaced with uracil to form RNA. The mRNA strand then exits the nucleus through a nuclear pore. Translation occurs in the cytoplasm, where the mRNA is read by ribosomes in groups of three codons. Transfer RNA molecules bring amino acids to the ribosome based on codon-anticodon base pairing. As the ribosome moves along the mRNA, the growing polypeptide chain is released once a stop codon is reached.
19. mRNA Strand comes in and copies the DNA
Key
Thymine:
Cytosine:
Adenine:
Guanine: ** Uracil:
20. Termination Sequence:
The last three bases of
all strands.
mRNA Strand comes in and copies the DNA
Key
Thymine:
Cytosine:
Adenine:
Guanine: ** Uracil:
21. Key
Thymine:
After the mRNA copies the DNA
Cytosine:
goes out into the cytoplasm
Adenine: through nuclear pores.
Guanine: ** Uracil:
24. The mRNA then binds with a ribosome.
Nucleus
Nuclear Pore
mRNA Strand
Ribosome
25. Ribosome
The mRNA soon binds
Key
Cytosine: to a ribosome and can
then begin to turn into
Adenine:
amino acids.
Guanine: ** Uracil:
26. Methionine
tRNA
Ribosome
Anticodons are then
Key brought in by the tRNA
Cytosine: (anti-codon)
Adenine:
Guanine: ** Uracil:
27. Aspartic Acid
tRNA
Ribosome
Anticodons are then
Key brought in by the tRNA
Cytosine: (anti-codon)
Adenine:
Guanine: ** Uracil:
28. tRNA
Ribosome
Amino acids are
released so one
Key
Cytosine: anticodon can connect
with another and
Adenine:
create a peptide bond.
Guanine: ** Uracil:
29. Serine
tRNA
Ribosome
Anticodons are then
Key brought in by the tRNA
Cytosine: (anti-codon)
Adenine:
Guanine: ** Uracil:
30. tRNA
Ribosome
Amino acids are
released so one
Key
Cytosine: anticodon can connect
with another and
Adenine:
create a peptide bond.
Guanine: ** Uracil:
31. Arginine
tRNA
Ribosome
Anticodons are then
Key brought in by the tRNA
Cytosine: (anti-codon)
Adenine:
Guanine: ** Uracil:
32. tRNA
Ribosome
Amino acids are
released so one
Key
Cytosine: anticodon can connect
with another and
Adenine:
create a peptide bond.
Guanine: ** Uracil:
33. Glutamine
tRNA
Ribosome
Anticodons are then
Key brought in by the tRNA
Cytosine: (anti-codon)
Adenine:
Guanine: ** Uracil:
34. tRNA
Ribosome
Amino acids are
released so one
Key
Cytosine: anticodon can connect
with another and
Adenine:
create a peptide bond.
Guanine: ** Uracil:
35. Valine
tRNA
Ribosome
Anticodons are then
Key brought in by the tRNA
Cytosine: (anti-codon)
Adenine:
Guanine: ** Uracil:
36. tRNA
Ribosome
Amino acids are
released so one
Key
Cytosine: anticodon can connect
with another and
Adenine:
create a peptide bond.
Guanine: ** Uracil:
37. Valine
tRNA
Ribosome
Anticodons are then
Key brought in by the tRNA
Cytosine: (anti-codon)
Adenine:
Guanine: ** Uracil:
38. tRNA
Ribosome
Amino acids are
released so one
Key
Cytosine: anticodon can connect
with another and
Adenine:
create a peptide bond.
Guanine: ** Uracil:
39. Leucine
tRNA
Ribosome
Anticodons are then
Key brought in by the tRNA
Cytosine: (anti-codon)
Adenine:
Guanine: ** Uracil:
40. tRNA
Ribosome
Amino acids are
released so one
Key
Cytosine: anticodon can connect
with another and
Adenine:
create a peptide bond.
Guanine: ** Uracil:
41. Aspartic Acid
tRNA
Ribosome
Anticodons are then
Key brought in by the tRNA
Cytosine: (anti-codon)
Adenine:
Guanine: ** Uracil:
42. tRNA
Riboso
Amino acids are
released so one
Key
Cytosine: anticodon can connect
with another and
Adenine:
create a peptide bond.
Guanine: ** Uracil:
43. STOP
R
Anticodons are then
Key brought in by the tRNA
Cytosine: (anti-codon)
Adenine:
Guanine: ** Uracil:
44. Amino acids are
released so one
Key
Cytosine: anticodon can connect
with another and
Adenine:
create a peptide bond.
Guanine: ** Uracil: