Decoding the information in DNA

... The process of taking the information in DNA and making a protein with it is a two step process. We have already looked at the first step (remember transcription where we made a mRNA copy of DNA). This information must now be translated into the language of protein synthesis (remember synthesis mean ...

dna technology

... • The final base at the end of each fragment is identified. This process recreates the original sequence of As, Ts, Cs, and Gs for each short piece generated in the first step. • Automated sequencers analyze the resulting electropherograms and the output is a four-color chromatogram showing peaks ...

transcription, translation

... important for genetic information? 3. Whys is RNA important to the cell? How does an mRNA molecule carry information from DNA? 4. If DNA strand read AAC GTC GCG TAC, what would the mRNA strand be? ...

Dia 1

... depending on the input data and the algorithm used, trees can be scaled to time or not ...

Chapter 17 DNA and RNA

... - The average gene consists of 3,000 bases. • Most of the human genome still remains a mystery. - Humans share 99% of their genes with mice. - Almost 99.9% of all nucleotide bases are identical from person to person. - Over 50% of human genes have no known function. ...

SAM Teacher`s Guide DNA to Proteins Overview Students examine

... Transcription and translation both happen in the nucleus. Information is stored somewhere within the nucleotides and not in their sequence. ...

Systems Biology Notes (Chapter 15, pp

... How many different amino acids could be used to form a single protein or polypeptide? ______________ ...

Liu-2-DNA and RNA

... The answer: by means of transfer RNA molecules, each specific for one amino acid and for a particular triplet of nucleotides in mRNA called a codon. The family of tRNA molecules enables the codons in a mRNA molecule to be translated into the sequence of amino acids in the protein. ...

DETERMINING THE METHOD OF DNA REPLICATION LAB

... After the publication of the structure of DNA, several possible hypotheses were advanced to describe how the DNA replicated. Three hypotheses were considered the most likely candidates to correctly explain replication: conservative, semiconservative, and dispersive. During conservative replication, ...

Introduction to Organic Chemistry and Biochemistry

... Proteins fold into complex three-dimensional shapes to form an opening (active site) where the reactant molecule or molecules fit and the protein (called an enzyme) helps weaken some bonds to break more easily and form new bonds leading to the product(s) which then diffuse out of active site. The re ...

Human Genomics

... To determine the sequences of the 3 billion chemical base pairs which make up human DNA. Store this information in databases. The sequence is not that of one person, but is a composite derived from several individuals. Therefore, it is a ‘representative’ or generic sequence. Sequencing DNA A proport ...

DNA - Midlakes

... combination of their genes. However if we were to compare your DNA to your parents it would be similar. ...

Purine-pyrimidine symmetry, determinative degree and DNA

... First of all we observe that all real sequences have high purine-pyrimidine symmetry (smallness of parameter q). Also we see that the relation of purines and pyrimidines in one DNA strand kn is very close to unity, therefore we have a new small parameter in the DNA theory (kn − 1) (or q), which char ...

Chapter 16.

... DNA Replication  DNA used to make DNA  Making an exact copy of the DNA before the cell divides  original strand serves as a template for the new strand  Each resulting double-stranded DNA molecule is made of one original and ...

RNA & PROTEIN SYNTHESIS - Anderson School District One

... of 3 bases that are complimentary to the codon on mRNA ...

Transcription and Translation of DNA

... The mRNA is called the ‘primary transcript’ at this stage Stages of Transcription Stage 1 – DNA double helix unwinds Stage 2 – weak hydrogen bonds breaking between bases, causing DNA strands to separate Stage 3 – free RNA nucleotides (moving freely in the nucleus) find complimentary pair on the DNA ...

DNA Replication

...  Single-Strand Binding Proteins attach and keep the 2 DNA strands separated and untwisted ...

Carboxylic acids

... Citric acid E330 Sitruunahappo– lemons, oranges, limes Ascorbic acid E300 – vitamin C ...

Engage: Hox Gene Activity

... DNA provides the instructions for the production of proteins through a process called protein synthesis. DNA is housed inside of the nucleus and is too large to exit the nucleus. In order to make proteins, the cell relies on another nucleic acid, ribonucleic acid (RNA). The RNA molecule has several ...

DNA vs. RNA

... 1. What is the complimentary mRNA sequence to DNA sequence A-T-T-G-C-A? A. T-A-A-C-G-T C. U-A-A-C-G-T B. U-A-A-C-G-U D. T-A-A-G-C-U 2. What causes the two sides of the double helix of DNA to stay joined together? A. joining of phosphate molecules C. joining of base pairs B. joining of sugar molecu ...

- Dr. Maik Friedel

... http://www.fli-leibniz.de/tsb ...

Chapter 1 Genes Are DNA

... • Closed DNA is either circular DNA or linear DNA in which the ends are anchored so that they are not free to rotate. • A closed DNA molecule has a linking number (L), which is the sum of twist (T) and writhe (W). • The linking number can be changed only by breaking and reforming bonds in the DNA ba ...

Macromolecules ( Carbohydrates, Lipids, Proteins and Nucleic Acids )

... • Amino acids have carboxyl and amino groups—the R group/side chain differs and determines the amino acid’s properties. ...

Central dogma

... – Carries protein-building codes from DNA to ribosomes • Ribosomal RNA (rRNA) – Forms ribosomes (where polypeptide chains are assembled) • Transfer RNA (tRNA) – Delivers amino acids to ribosomes ...

Central dogma

... Transcription: Enzymes uses base sequence of a gene as template to make strand of RNA Two DNA strands unwind in a specific region RNA polymerase assembles strand of RNA ...

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DNA nanotechnology

DNA nanotechnology is the design and manufacture of artificial nucleic acid structures for technological uses. In this field, nucleic acids are used as non-biological engineering materials for nanotechnology rather than as the carriers of genetic information in living cells. Researchers in the field have created static structures such as two- and three-dimensional crystal lattices, nanotubes, polyhedra, and arbitrary shapes, as well as functional devices such as molecular machines and DNA computers. The field is beginning to be used as a tool to solve basic science problems in structural biology and biophysics, including applications in crystallography and spectroscopy for protein structure determination. Potential applications in molecular scale electronics and nanomedicine are also being investigated.The conceptual foundation for DNA nanotechnology was first laid out by Nadrian Seeman in the early 1980s, and the field began to attract widespread interest in the mid-2000s. This use of nucleic acids is enabled by their strict base pairing rules, which cause only portions of strands with complementary base sequences to bind together to form strong, rigid double helix structures. This allows for the rational design of base sequences that will selectively assemble to form complex target structures with precisely controlled nanoscale features. A number of assembly methods are used to make these structures, including tile-based structures that assemble from smaller structures, folding structures using the DNA origami method, and dynamically reconfigurable structures using strand displacement techniques. While the field's name specifically references DNA, the same principles have been used with other types of nucleic acids as well, leading to the occasional use of the alternative name nucleic acid nanotechnology.

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DNA nanotechnology