Zwitterion and Amino Acid Charge Given pH and pKa

Leah4sci MCAT

24 Mar 201616:44

Summary

TLDRThis video from Leah4sci explores zwitterions and the charge of amino acids, focusing on their structures and interactions in different pH environments. It explains how amino acids typically exist as zwitterions, with a protonated amine group and a deprotonated carboxyl group. The relationship between pH and pKa is crucial for determining the charge of amino acids, with specific examples like glycine illustrating how to calculate charges at various pH levels. Understanding these concepts is essential for studying biochemical reactions and protein behavior in physiological conditions.

Takeaways

😀 Amino acids exist primarily in the zwitterionic form due to the protonation of the amine group and deprotonation of the carboxy group.
😀 The neutral form of amino acids is not stable due to the acid-base interactions between the amine and carboxylic acid groups.
😀 The pKa value indicates the pH at which an acidic or basic group can gain or lose a proton.
😀 The Henderson-Hasselbalch equation is crucial for understanding the relationship between pH and pKa in determining the protonation state of molecules.
😀 A low pH means a higher concentration of protons, leading to a greater likelihood of protonation for molecules with higher pKa values.
😀 When the pH is less than the pKa, the molecule is protonated; when pH is greater, the molecule is deprotonated.
😀 At the pH equal to the pKa, there is a 50/50 distribution of protonated and deprotonated forms, resulting in a fractional charge.
😀 Glycine's carboxy group has a pKa of 2.3 and the amine group has a pKa of 9.6, which influences its charge at various pH levels.
😀 At physiological pH (around 7), glycine exists as a zwitterion with a net charge of zero.
😀 Understanding how to find the charge of amino acids across different pH levels is essential for studying their behavior in biological systems.

Q & A

What is a zwitterion?
-A zwitterion is a molecule that contains at least two charged groups, typically one positive and one negative charge, making it overall neutral. It is commonly found in amino acids.
How does the pH affect the charge of an amino acid?
-The pH influences the protonation or deprotonation of ionizable groups in an amino acid. If the pH is lower than the pKa, the group is protonated; if it is higher, the group is deprotonated.
What are the PKA values of the carboxy and amine groups in amino acids?
-In amino acids like glycine, the pKa of the carboxy group is approximately 2.3, while the pKa of the amine group is around 9.6.
How do you calculate the average charge of acetic acid at pH 4.8?
-At pH 4.8, which equals the pKa of acetic acid, half of the molecules are protonated (charge 0) and half are deprotonated (charge -1). The average charge is therefore -0.5.
What is the relationship between pH and pKa?
-The relationship between pH and pKa determines whether a molecule will hold onto or release protons. If pH < pKa, the molecule is more likely to be protonated; if pH > pKa, it will be deprotonated.
What happens to the charge of glycine at a pH of 1?
-At a pH of 1, which is lower than both pKa values, glycine is fully protonated, resulting in a net charge of +1.
What is Le Chatelier's principle, and how does it apply to acid-base reactions?
-Le Chatelier's principle states that a system at equilibrium will shift to counteract changes. In acid-base reactions, if excess protons are added (acidic solution), the reaction shifts towards the reactants, favoring protonation.
How does the Henderson-Hasselbalch equation relate pH and pKa?
-The Henderson-Hasselbalch equation states that pH = pKa + log([conjugate base]/[acid]), helping to determine the ratio of protonated to deprotonated species in a solution.
What trends can be observed when raising the pH of a solution containing glycine?
-As pH increases from below pKa to above, the net charge of glycine decreases from +1 to 0 to -0.5, and finally to -1, reflecting the deprotonation of the carboxy group and the amine group.
How does physiological pH (around 7) affect amino acids like glycine?
-At physiological pH (around 7), glycine exists predominantly in its zwitterion form, with a neutral overall charge due to the protonated amine group (+1) and deprotonated carboxy group (-1) cancelling each other out.