Concept explainers
Videos
(a)
To explain: The reason behind the decrease in viscosity of a solution of DNA that occurs after treating it with nuclease.
Introduction:
Viscosity is defined as the thickness of a solution. It is due to the bonding between different molecules present inside the solution. Higher is the bonding, greater will be the viscosity.
(b)
To explain: The reason for the enzyme being an endonuclease or an exonuclease based on the experiment conducted.
Introduction:
Nucleases are of two types: endonuclease and exonuclease. Exonuclease cut the DNA and removes nucleotides one at a time and it cleaves the DNA at the terminals on the other hand; endonuclease cleaves the DNA from the middle of the strand.
(c)
To explain: The reason behind the nuclease cleavage that leaves the phosphate on the 5ʹ or the 3ʹ end of the DNA fragments.
Introduction:
The nuclease is responsible for breaking the phosphodiester bonds and removing the phosphate group. On the other hand, kinase is responsible for the attachment of phosphate group and the process is known as phosphorylation.
(d)
To determine: The consistency of results formed by the cleavage of T7 DNA by nuclease with the enzyme recognizing a specific sequence in DNA as opposed in making the double strand breaks randomly.
Introduction:
The organisms suffer double-strand breaks (DSBs) in their DNA due to the exposure with the ionizing radiations. DSBs can also occur when replication forks find DNA lesions or repair intermediates.
(e)
To explain: The type of model which is responsible for the given type of cleavage.
Introduction:
There are two models for creating fragments Random model resulting in random fragments example of such model is double stranded break. The second model is site specific cleavage; example of such cleavage is cleavage by restriction enzyme.
(f)
To explain: The recognition sequence of the nuclease and the position at which the DNA fragment is cleaved.
Introduction:
Nuclease breaks the phosphodiester bonds present between the nucleotides. Due to the loss of phosphodiester bonds present between the molecules, the DNA is divided into small fragments.
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Chapter 9 Solutions
EBK LEHNINGER PRINCIPLES OF BIOCHEMISTR
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- When 15.00 mL of 3.00 M NaOH was mixed in a calorimeter with 12.80 mL of 3.00 M HCl, both initially at room temperature (22.00 C), the temperature increased to 29.30 C. The resultant salt solution had a mass of 27.80 g and a specific heat capacity of 3.74 J/Kg. What is heat capacity of the calorimeter (in J/C)? Note: The molar enthalpy of neutralization per mole of HCl is -55.84 kJ/mol. Which experimental number must be initialled by the Lab TA for the first run of Part 1 of the experiment? a) the heat capacity of the calorimeter b) Mass of sample c) Ti d) The molarity of the HCl e) Tfarrow_forwardPredict products for the Following organic rxn/s by writing the structurels of the correct products. Write above the line provided" your answer D2 ①CH3(CH2) 5 CH3 + D₂ (adequate)" + 2 mited) 19 Spark Spark por every item. 4 CH 3 11 3 CH 3 (CH2) 4 C-H + CH3OH CH2 CH3 + CH3 CH2OH 0 CH3 fou + KMnDy→ C43 + 2 KMn Dy→→ C-OH ") 0 C-OH 1110 (4.) 9+3 =C CH3 + HNO 3 0 + Heat> + CH3 C-OH + Heat CH2CH3 - 3 2 + D Heat H 3 CH 3 CH₂ CH₂ C = CH + 2 H₂ → 2 2arrow_forwardWhen 15.00 mL of 3.00 M NaOH was mixed in a calorimeter with 12.80 mL of 3.00 M HCl, both initially at room temperature (22.00 C), the temperature increased to 29.30 C. The resultant salt solution had a mass of 27.80 g and a specific heat capacity of 3.74 J/Kg. What is heat capacity of the calorimeter (in J/C)? Note: The molar enthalpy of neutralization per mole of HCl is -55.84 kJ/mol.arrow_forward
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