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You can now continuously translate someone speaking a different language in near real-time with the Translate app. For example, translate a classroom lecture or a speech. The Tap-to-Translate. Hampton High School, Hampton. SCIENCE High Schoo. Copyofdnamutationspracticeworksheet (1).docx - DNA Mutations Practice Worksheet DIRECTIONS Transcribe and translate the original DNA sequence Then. For WiMAX OFDM specification, TTG/RTG should be 5 µS and TTG and RTG of value about 80 µS (i.e. This works fine for Bandwidth of 3.5MHz and Fs of 4MHz. The specification of TTG/RTG Gap vary for OFDMA specification. Check respective wimax standard specifications for the same. Sep 18, 2014 TTG Asia has been delivering incisive editorials and intelligence analysis on pertinent travel trade developments in the Asia-Pacific since 1974. Renowned for its award-winning journalism, this leading industry business resource is widely acclaimed by travel trade professionals as their preferred read. The TTG Asia portfolio of integrated print and online products includes: the staple print. Asap indicate the coat color and the proportion of offspring with that color for each of the following crosses of rabbits. Assume all are homozygous. Alleles: a=agouti, c=chinchilla, a=albino, a is dominant over c and a, c is dominant over a agouti x chinchilla a) 1/2 chinchilla, 1/2 agouti b) 3/4 chinchilla, 1/4 agouti c) all agouti.

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The entire process is protein synthesis for gene expression.

The process of transcription begins when the encoded protein information from the DNA is transferred to the mRNA.It begins when enzyme RNA polymerase bind with promoter region ( the point where the process of transcription begins) of a gene and initiates transcription.,the point where the process of transcription begins. The DNA double helix unwinds, the mRNA align and complementary paring of the bases occurs.

This is followed with the removal of noncoding part(introns) of the mRNA transcripts prior to translation where;The spliceosome removes introns. This is essential because only the encoded part which contain the needed protein to be transcribed is selected.

The mRNA is released, and leave the nucleus through the nuclear pore to the cytoplasm.In the cytoplasm the ribosomes with its two sub-units large and small serve as templates for the mRNA with its anti codons and pairing with the tRNA codons in a complementary pairing for translation of amino acids to polypeptide sequence.

In the process of translation polypeptide chains of amino acids are formed as the complimentary bases paired up to synthesize protein. Different levels of proteins are formed as the primary structure of the polypeptide chain undergoes hierarchical foldings to form the tertiary structure.

Explanation:

1.

Original: ATG AAC CAT TCA

Complimentary: TAC TTG GTA AGT

Transcription: AUG AAC CAU UCA

Amino Acid: Met Asn His Ser

(Start)

2.

Original: ATG GGT CTA GCG AAA GAT

Complimentary: TAC CCA GAT CGC TTT CTA

Transcription: AUG GGU CUA GCG AAA GAU

Amino Acid: Met - Gly - Leu - Ala - Lys - Asp

Question 1:

mRNA transcribes the DNA. This means that it carries the information or instructions of DNA that determines what protein needs to be produced. This is why it is called the messenger RNA because it delivers the message to the site of protein production, the ribosomes.

Question 2:

tRNA is also known as transfer RNA. It transfers the amino acids to the mRNA template. It acts as an adaptor to translate the RNA sequence and they carry the amino acid with it.

Question 3:

During transcription, the DNA gives its instructions to the mRNA and it transcribes it in a sort of code that links to a specific amino acid. This occurs in the nucleus. When transcription is done, it then takes it out of the nucleus and into the cytoplasm. This transcribed message is then brought to the ribosome, where it will stay to be translated into amino acids.

Question 4:

During translation, the DNA code that was transcribed into mRNA code will be in the ribosome, where the tRNA will bring the amino acid it carries that is specific to the sequence of the mRNA sequence. The tRNA line up specific to the sequence and the amino acids they carry will bond together in a sort of chain, and create a protein together.

Question 5:

DNA is used to make protein based on the code it carries. Whatever the mRNA transcibes will be from the DNA, so even if the RNA is what produces the proteins, it will be based on the DNA sequence given.

Explanation:

When making a DNA complimentary strand for the original strand, all you need to remember are the base pairs:

Guanine (G) - Cytosine (C)

Adenine (A) - Thymine (T)

This is known as the Chargaff's Rule.

So taking your first strand example:

ORIGINAL: ATG AAC CAT TCA

COMPL: TAC TTG GTA AGT

However, when it comes to RNA, there is no Thymine in RNA. So instead of Thymine, Uracil is used. The base pairs would then be:

Thymine (T) - Adenine (A)

Adenine (A) - Uracil (U)

Guanine (G) - Cytosine (C)

Again, taking your example:

ORIGINAL: ATG AAC CAT TCA

COMPL: TAC TTG GTA AGT

Transcription: AUG AAC CAU UCA

During translation, the amino acids are code for specific codons, or groups of 3 bases. The chart given to you shows what each codon codes for.

Original: ATG AAC CAT TCA

Complimentary: TAC TTG GTA AGT

Transcription: AUG AAC CAU UCA

Amino Acid: Met Asn Hist Ser

(Start)

Met - Methionine (Start codon)

Asn - Asparagine

His - Histidine

Ser - Serine

1st template:

Original DNA: ATG AAC CAT TCA GTA TGG

Complimentary DNA: TAC TTG GCA AGT CAT ACC

mRNA molecule: AUG AAC CGU UCA GUA UGG

AMINO ACID: Methionine (Start) - Aspargine (Asn) - Arginine (Arg) - Serine (Ser)- Valine (Val) - Tryprophan (STOP)

2nd template:

Original DNA: ATG GGT CTA GCG AAA GAT

Complimentary DNA: TAC CCA GAT CGC TTT CTA

mRNA molecule: AUG GGU CUA GCG AAA GAU

AMINO ACID: Methionine (Start) - Glycine (Gly) - Leucine (Leu) - Alanine (Ala) - Lysine (Lys) - Apspartic Acid (Asp)

Explanation:

When you are forming the DNA complimentary strand you need to remember that they come in base pairs, and each base pairs up with a specific base. In the case of DNA the base pairs are the following:

A - T ; T - A

C - G; G - C

So:

For every A, its complimentary is T. For every T, it's complimentary is A.

For every C, it's complimentary is G. For every G, it's complimentary is C.

Air notes app. So in the case of your 1st DNA template:

Original DNA: ATG AAC CAT TCA GTA TGG

Complimentary DNA: TAC TTG GCA AGT CAT ACC

During transcription however, mRNA is formed. RNA does not have thymine (T), but Uracil (U) instead. So the base pairs would be different in the case of Adenine(A), thymine and Uracil.

A - U; T - A

C - G; G -C

So:

For every A, it's complimentary is U. For every T, it's complimentary is A.

For every C, it's complimentary is G. For every G, it's complimentary is C.

Going back to your 1st DNA template:

Original DNA: ATG AAC CAT TCA GTA TGG

Complimentary DNA: TAC TTG GCA AGT CAT ACC

mRNA molecule: AUG AAC CGU UCA GUA UGG

Duing translation, tRNA brings the amino acids to the mRNA strand. There is a specific RNA codon sequence that codes for a specific AMINO ACID. These codons are 3 bases grouped together. You can use the table attached to see the amino acid each combination.

Amino acids are the building blocks of protein. The DNA templates determines the type of protein that will be made. The tRNA brings the amino acid to the mRNA template. Then it drops the amino acid off, which will bond with the next amino acid coded to attach to it.

So if you take the first mRNA codon AUG, you can see in the table that it codes for Methionine, which is a start codon, meaning this is the start of a new protein. It will then attach to the next amino acid that codes for the next codon which is AAC that codes for Aspargin. They will continue until it reaches a STOP codon, which means it would be the end of that protein.

Again going back to the template:

mRNA AUG AAC CGU UCA GUA UGG

AMINOACID: Methionine (Start) - Aspargine (Asn) - Arginine (Arg) - Serine (Ser)- Valine (Val) - Tryprophan (STOP)

I hope this will help you to some degree.

DNA Replication:

Duplication of DNA molecule.

Replicate the following strand of DNA:

Original DNA A T G A A C C A T T C A G T A T G G

Complimentary DNA : T A C T T G G T A A G T C A T A C C

Transcription:

Conversion of DNA into mRNA

Transcribe the DNA to make an mRNA molecule

Complimentary DNA: T A C T T G G T A A G T C A T A C C

mRNA Molecule: A U G A A C C A U U C A G U A U G G

Translation:

Conversion of mRNA into proteins

Translate the mRNA into the corresponding amino acids.

mRNA Molecule: A U G A A C C A U U C A G U A U G G

Amino Acid: Methionine, Asparginine, Iso-leucine, Serine, Valine, Trptophan

Using the DNA sequence provided, determine the amino acids.

Original DNA A T G G G T C T A G C G A A A G A T

Complimentary DNA : T A C C C A G A T C G C T T T C T A

mRNA Molecule: A U G G G U C U A G C G A A A G A U

Amino Acid: Methionine, Glycine, Leucine, alanine, Lysine, aspartic acid

Questions:

Using what you have learned in the lesson and the experiment, answer the following questions in complete sentences.

What is the function of mRNA?

To being transcribed into protein

What is the function on tRNA?

To take the amino acids to mRNA

Describe what happens during transcription.

DNA is converted into mRNA

Describe what happens during translation.

mRNA is converted into proteins

Explain how DNA is used to make a protein.

DNA is transcribed into mRNA THAT IS CONVERTED INTO protein

DNA Replication:

Replicate the following strand of DNA:

Original DNA: A T G A A C CA T T C A G T A T G G

Complementary DNA:

Remember that the complimentary base pairs in DNA are Adenine-Thymine and Guanine-Cytosine, or A-T and G-C. This means that if the original sequence is:

A T G A A C C A T T C A G T A T G G

Then the compliment is (replace with the opposite base pairs):

T A C T T G G T A A G T C A T A C C

Transcription:

Transcribe the DNA to make an mRNA molecule

COMPLIMENTARY DNA:

mRNA Molecule:

So if our complimentary DNA (antisense stand) is T A C T T G G T A A G T C A T A C C then to transcribe, we basically create another complimentary strand, but for mRNA, we use Uracil instead of Thymine:

A U G A A C C A U U C A G U A U G G

Translation:

Translate the mRNA into the corresponding amino acids.

mRNA MOLECULE:

AMINO ACID:

Using the DNA sequence provided, determine the amino acids.

Next, take each codon (3-base set) to the table and record the corresponding protein:

A U G = Methionine (start)

A A C = Asparagine

C A U = Histidine

U C A = Serine

Explanation:

1.

Original: ATG AAC CAT TCA

Complimentary: TAC TTG GTA AGT

Transcription: AUG AAC CAU UCA

Amino Acid: Met Asn His Ser

(Start)

2.

Original: ATG GGT CTA GCG AAA GAT

Complimentary: TAC CCA GAT CGC TTT CTA

Transcription: AUG GGU CUA GCG AAA GAU

Amino Acid: Met - Gly - Leu - Ala - Lys - Asp

Question 1:

mRNA transcribes the DNA. This means that it carries the information or instructions of DNA that determines what protein needs to be produced. This is why it is called the messenger RNA because it delivers the message to the site of protein production, the ribosomes.

Question 2:

tRNA is also known as transfer RNA. It transfers the amino acids to the mRNA template. It acts as an adaptor to translate the RNA sequence and they carry the amino acid with it.

Question 3:

During transcription, the DNA gives its instructions to the mRNA and it transcribes it in a sort of code that links to a specific amino acid. This occurs in the nucleus. When transcription is done, it then takes it out of the nucleus and into the cytoplasm. This transcribed message is then brought to the ribosome, where it will stay to be translated into amino acids.

Question 4:

During translation, the DNA code that was transcribed into mRNA code will be in the ribosome, where the tRNA will bring the amino acid it carries that is specific to the sequence of the mRNA sequence. The tRNA line up specific to the sequence and the amino acids they carry will bond together in a sort of chain, and create a protein together.

Question 5:

DNA is used to make protein based on the code it carries. Whatever the mRNA transcibes will be from the DNA, so even if the RNA is what produces the proteins, it will be based on the DNA sequence given.

Explanation:

When making a DNA complimentary strand for the original strand, all you need to remember are the base pairs:

Guanine (G) - Cytosine (C)

Adenine (A) - Thymine (T)

This is known as the Chargaff's Rule.

So taking your first strand example:

ORIGINAL: ATG AAC CAT TCA

COMPL: TAC TTG GTA AGT

However, when it comes to RNA, there is no Thymine in RNA. So instead of Thymine, Uracil is used. The base pairs would then be:

Thymine (T) - Adenine (A)

Adenine (A) - Uracil (U)

Guanine (G) - Cytosine (C)

Again, taking your example:

ORIGINAL: ATG AAC CAT TCA

COMPL: TAC TTG GTA AGT

Transcription: AUG AAC CAU UCA

During translation, the amino acids are code for specific codons, or groups of 3 bases. The chart given to you shows what each codon codes for.

Original: ATG AAC CAT TCA

Complimentary: TAC TTG GTA AGT

Transcription: AUG AAC CAU UCA

Amino Acid: Met Asn Hist Ser

(Start)

Met - Methionine (Start codon)

Asn - Asparagine

His - Histidine

Ser - Serine

1st template:

Original DNA: ATG AAC CAT TCA GTA TGG

Complimentary DNA: TAC TTG GCA AGT CAT ACC

mRNA molecule: AUG AAC CGU UCA GUA UGG

AMINO ACID: Methionine (Start) - Aspargine (Asn) - Arginine (Arg) - Serine (Ser)- Valine (Val) - Tryprophan (STOP)

2nd template:

Original DNA: ATG GGT CTA GCG AAA GAT

Complimentary DNA: TAC CCA GAT CGC TTT CTA

mRNA molecule: AUG GGU CUA GCG AAA GAU

AMINO ACID: Methionine (Start) - Glycine (Gly) - Leucine (Leu) - Alanine (Ala) - Lysine (Lys) - Apspartic Acid (Asp)

Explanation:

When you are forming the DNA complimentary strand you need to remember that they come in base pairs, and each base pairs up with a specific base. In the case of DNA the base pairs are the following:

A - T ; T - A

C - G; G - C

So:

For every A, its complimentary is T. For every T, it's complimentary is A.

For every C, it's complimentary is G. For every G, it's complimentary is C.

Air notes app. So in the case of your 1st DNA template:

Original DNA: ATG AAC CAT TCA GTA TGG

Complimentary DNA: TAC TTG GCA AGT CAT ACC

During transcription however, mRNA is formed. RNA does not have thymine (T), but Uracil (U) instead. So the base pairs would be different in the case of Adenine(A), thymine and Uracil.

A - U; T - A

C - G; G -C

So:

For every A, it's complimentary is U. For every T, it's complimentary is A.

For every C, it's complimentary is G. For every G, it's complimentary is C.

Going back to your 1st DNA template:

Original DNA: ATG AAC CAT TCA GTA TGG

Complimentary DNA: TAC TTG GCA AGT CAT ACC

mRNA molecule: AUG AAC CGU UCA GUA UGG

Duing translation, tRNA brings the amino acids to the mRNA strand. There is a specific RNA codon sequence that codes for a specific AMINO ACID. These codons are 3 bases grouped together. You can use the table attached to see the amino acid each combination.

Amino acids are the building blocks of protein. The DNA templates determines the type of protein that will be made. The tRNA brings the amino acid to the mRNA template. Then it drops the amino acid off, which will bond with the next amino acid coded to attach to it.

So if you take the first mRNA codon AUG, you can see in the table that it codes for Methionine, which is a start codon, meaning this is the start of a new protein. It will then attach to the next amino acid that codes for the next codon which is AAC that codes for Aspargin. They will continue until it reaches a STOP codon, which means it would be the end of that protein.

Again going back to the template:

mRNA AUG AAC CGU UCA GUA UGG

AMINOACID: Methionine (Start) - Aspargine (Asn) - Arginine (Arg) - Serine (Ser)- Valine (Val) - Tryprophan (STOP)

I hope this will help you to some degree.

DNA Replication:

Duplication of DNA molecule.

Replicate the following strand of DNA:

Original DNA A T G A A C C A T T C A G T A T G G

Complimentary DNA : T A C T T G G T A A G T C A T A C C

Transcription:

Conversion of DNA into mRNA

Transcribe the DNA to make an mRNA molecule

Complimentary DNA: T A C T T G G T A A G T C A T A C C

mRNA Molecule: A U G A A C C A U U C A G U A U G G

Translation:

Conversion of mRNA into proteins

Translate the mRNA into the corresponding amino acids.

mRNA Molecule: A U G A A C C A U U C A G U A U G G

Amino Acid: Methionine, Asparginine, Iso-leucine, Serine, Valine, Trptophan

Using the DNA sequence provided, determine the amino acids.

Original DNA A T G G G T C T A G C G A A A G A T

Complimentary DNA : T A C C C A G A T C G C T T T C T A

mRNA Molecule: A U G G G U C U A G C G A A A G A U

Amino Acid: Methionine, Glycine, Leucine, alanine, Lysine, aspartic acid

Questions:

Using what you have learned in the lesson and the experiment, answer the following questions in complete sentences.

What is the function of mRNA?

To being transcribed into protein

What is the function on tRNA?

To take the amino acids to mRNA

Describe what happens during transcription.

DNA is converted into mRNA

Describe what happens during translation.

mRNA is converted into proteins

Explain how DNA is used to make a protein.

DNA is transcribed into mRNA THAT IS CONVERTED INTO protein

DNA Replication:

Replicate the following strand of DNA:

Original DNA: A T G A A C CA T T C A G T A T G G

Complementary DNA:

Remember that the complimentary base pairs in DNA are Adenine-Thymine and Guanine-Cytosine, or A-T and G-C. This means that if the original sequence is:

A T G A A C C A T T C A G T A T G G

Then the compliment is (replace with the opposite base pairs):

T A C T T G G T A A G T C A T A C C

Transcription:

Transcribe the DNA to make an mRNA molecule

COMPLIMENTARY DNA:

mRNA Molecule:

So if our complimentary DNA (antisense stand) is T A C T T G G T A A G T C A T A C C then to transcribe, we basically create another complimentary strand, but for mRNA, we use Uracil instead of Thymine:

A U G A A C C A U U C A G U A U G G

Translation:

Translate the mRNA into the corresponding amino acids.

mRNA MOLECULE:

AMINO ACID:

Using the DNA sequence provided, determine the amino acids.

Next, take each codon (3-base set) to the table and record the corresponding protein:

A U G = Methionine (start)

A A C = Asparagine

C A U = Histidine

U C A = Serine

G U A = Valine

U G G = Tryptophan

ORIGINAL DNA: A T G G G T C T A G C G A A A G A T

Complementary DNA:

mRNA DNA Molecule:

Amino Acid:

And we do it all again:

A T G G G T C T A G C G A A A G A T = original DNA

T A C C C A G A T C G C T T T C T A = complementry DNA

A U G G G U C U A G C G A A A G A U = mRNA

A U G = Methionine (start)

G G U = Glysine

C U A = Leucine

G C G = Alanine

A A A = Lysine

G A U = Aspartate

Explanation:

Explanation:

goku super saiyan blue good

I can not see clearly.

Explanation:

Thanks.

for the points

So basically, my best advice would be to look up some sort of site that makes DNA strands and base it off of one of those. I Forgot how to do the rest but maybe somebody else can help

hope it helps -_-

The correct answer will be:

Case I:

Original DNA: ATG AAC CAT TCA GTA TGG

Complimentary DNA: TAC TTG GCA AGT CAT ACC

Transcript mRNA molecule: AUG AAC CGU UCA GUA UGG

Translated sequence: Met- Asn - Arg - Ser - Val- Trp

Case II:

Original DNA: ATG GGT CTA GCG AAA GAT

Complimentary DNA: TAC CCA GAT CGC TTT CTA

Transcript mRNA molecule: AUG GGU CUA GCG AAA GAU

Translated sequence: Met -Gly- Leu- Ala- Lys - Asp

Explanation:

DNA replication is a process which produces a replica or exact copy of the DNA molecule by using one strand of the existing DNA as a template. The new strand is formed using Chargaff rule which states that purine binds pyrimidine that is adenine(A) will bind to thymine (T) and guanine (G) will bind to cytosine (C).

Transcription is a process which produces an mRNA molecule from one strand of DNA molecule. The mRNA acts as a messenger molecule which is formed with the same Chargaff rule except for a different nitrogenous base 'uracil'. In mRNA uracil (U) will bind complementarily to adenine (A) instead of thymine.

The translation is a process which synthesizes the protein by reading the bases of mRNA in the triplets called 'codons'. These codons code for a specific amino acid which bond to each other via peptide bond and form protein.

The correct order is:

4, 2, 1, 3

Explanation:

The list of options in this question depicts gene expression which involves transcription and translation processes.

Option 4 is simply describing the initial step of transcription where the enzyme RNA polymerase binds to the promoter region of a gene on the DNA and signals the initiation of transcription. RNA polymerase synthesizes a complementary strand of mRNA using the DNA it binds to as template.

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Option 2 is a post-transcriptional process called SPLICING, which is the removal of the non-coding regions of a gene called INTRONS by enzymes called SPLICEOSOMES. This occurs in eukaryotic cell before the mRNA leaves the nucleus for the cytoplasm where translation will take place.

Option 1 signals the commencement of translation where a complex of ribosomal RNA and other proteins called RIBOSOME attaches to the mRNA molecule and uses the anticodons present in the tRNA to read the mRNA codons in order to carry the corresponding amino acid to the ribosome. The anticodons of the tRNA are complementary to the mRNA codon. At the end of translation, an amino acid sequence called polypeptide (future protein) will be released.

Option 3 tells us what happens after the translation process. The amino acids in the newly released protein are arranged in such a way that they make the protein a primary structure. The amino acids undergo certain modifications like folding that changesges the protein's structure from primary to tertiary.

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