Name Date Block__ Biology • So far in the course we have

... (A) always pairs with (T) A-T. Guanine (G) always pairs with Cytosine (C) G-C. This base pairing is called complementary. ...

DNA replication, transcription & translation

... Steps in DNA Replication 1. Helicase enzyme breaks the hydrogen bonds between base pairs. This unzips the double helix at a position called the replication fork. 2. There is an abundant supply of nucleotides in the nucleus for the formation of the new polynucleotides. 3. Nucleotides base pair to th ...

The-Human-Genome

... The primary concern is privacy. DNA profiles are different from fingerprints which are used only for identification. DNA can provide insight into many intimate aspects of people and their families including susceptibility to particular disease, legitimacy of birth and perhaps predispositions to cert ...

Molecular Theory of Inheritence

... Components of DNA are (i) deoxyribose sugar, (ii) a phosphate, and (iii) nitrogen containing organic bases. DNA contains four different bases called adenine (A), guanine (G) cytosine (C), and thymine (T). These are grouped into two classes on the basis of their chemical structure: (i) Purines (with ...

DNA: The genetic material

... Measured linearly, the Escherichia coli genome (4.6 Mb) would be 1,000 times longer than the E. coli cell. The human genome (3.4 Gb) would be 2.3 m long if stretched linearly. ...

Nucleic Acids-Structure, Central Dogma

... -disrupts H-bonding of the two strands  SSB (single-stranded DNA-binding proteins) – binds to the unwound strands, preventing re-annealing ...

DNA * Deoxyribonucleic Acid

... – This process produces a gel containing a banded pattern of DNA fragments that are used to compare individuals. This is used in forensics. ...

File

... oNew bases are added to the parental strands ◦ Each original strand is a template ◦ Complementarity makes it possible to recreate the other strand ...

Bell Work: What does DNA stand for?

... Experiment 1 Bacteria where infected with phages that had radioactive sulfur atoms in their protein. They then used a blender, to separate the bacteria from the phages that remained outside the bacteria. None of them showed evidence of radioactivity. Experiment 2 Bacteria tagged with radioac ...

DNA

... 5. Certain DNA sequences adopt unusual structures • In the DNA of living cells, sites recognized by many sequence-specific DNA-binding proteins are arranged as palindromes, and polypyrimidine or polypurine sequences that can form triplex helices or even H-DNA are found within regions involved in th ...

RNA and Protein Synthesis

... RNA Polymerase detaches from the DNA  Two other types of RNA – tRNA & rRNA are made in the same way ...

DNA - Quia

... 2. New strands are built • Enzyme = DNA polymerase • Joins individual nucleotides together to produce a new strand of DNA that is complementary to the other • Proofreads each new strand ...

Jeopardy Review #1 Chapter 12

... tracers in their experiments with bacteriophages. Which labeled virus compenent ended up in the bacteria, the radioactive sulfur on the protein or the radioactive phosphorus on the DNA? ANSWER BACK TO GAME ...

Chapter 14: DNA Structure and Function

... replication fork, a Y-shaped region where new DNA strands are elongating ...

Unit 13: Review Biotechnology Lab

... Restriction endonucleases or restriction enzymes (REs) are enzymes obtained by bacteria that physically cut DNA. REs are named according to the following guidelines. The first letter is the same letter as the first letter of the genus name of the organism from which is was isolated and is italicized ...

DNA - bainzbio11

... how much Cytosine is present? ...

HaeIII restriction endonuclease was used to digest the following

... 8. (2 pt) Give me the partial amino acid sequence, 3 letter code and 1 letter code, of the polypeptide containing the ten (10) amino acids that would be specified by the mRNA that you put in 7. Correctly label your peptide, amino end to carboxyl end. ...

DNA

... ★ Three classes carry out self-processing ...

here

... Relieves the tension produced when DNA is unzipped. ...

CH. 8

... • ________________ makes sure each new cell will have ____ complete set of genetic instructions & occurs only once during each round of the cell cycle. • ___________________ could make hundreds or thousands of copies of certain proteins or the rRNA or tRNA molecules need to make _______________ base ...

Strawberry DNA Extraction Lab (This promises to be berry interesting!)

... 8. Tilt your test tube slightly and slowly pipette ice-cold alcohol down the inside of the test tube. (About equal to the amount of the strawberry liquid.) Slowly and very gently rock the tube back and forth. DO NOT SHAKE THE TEST TUBE or your DNA will fragment. 9. Let the test tube sit for a minute ...

Transcription

... on the DNA encode the information necessary to produce transfer RNA. As the name implies tRNA transfers individual amino acids to the ribosome where they are assembled into polypeptides according to the information encoded in the mRNA. Slide 6 The process of transcription can be divided into three p ...

honors biology Ch. 10 Notes DNA

... 10.3 Explain how Chargaff’s rules relate to the structure of DNA. A=T, C=G 10.4 Explain how the structure of DNA facilitates its replication. ...

DNA strucutre and replication

... Discovering the structure of DNA • DNA = Deoxyribose nucleic acid • Made out of sugars (deoxyribose), phosphates and nitrogen bases ...

Protein Synthesis

... 1. Experiment: Like DNA, RNA follows base-pairing rules. Experiment to find which RNA nucleotide on the right side of the Gizmo will successfully pair with the thymine at the top of the template strand of DNA. (NOTE: The DNA on the right side is the template strand.) Which RNA base bonded with the t ...

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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