Bio2B03 Module 1 Lecture 1 Script PDF

Summary

This document is a lecture script for a Biology module, likely for an undergraduate course. It covers the broad themes of proteins' creation, structure, function and how they exist in cells, along with responding to signals and undergoing cell division.

Full Transcript

BIO 2B03 Module scripts Module 1, lecture 1

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| | Script | Notes |
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| Slide 1 | Hi everyone, and | |
| | welcome to BIOLOGY | |
| | 2B03- Cell Biology. | |
| | As a blended learning | |
| | course, **BIO2B03** | |
| | Is course that will | |
| | cover a broad array | |
| | of interconnected | |
| | themes. This will | |
| | include considering | |
| | how proteins are | |
| | made, their | |
| | structure, their | |
| | function , and for | |
| | those who do so... | |
| | how some proteins | |
| | exit the cell. | |
| | | |
| | We will also explore | |
| | a number of ways that | |
| | a cell is able to | |
| | perceive signals from | |
| | each other and their | |
| | environment, and how | |
| | the response to these | |
| | signals often results | |
| | in short term or long | |
| | term cellular | |
| | changes. | |
| | | |
| | Finally, we will | |
| | explore how cell | |
| | division is a very | |
| | controlled and | |
| | regulated process | |
| | which eventually | |
| | results in mitosis | |
| | and the division of | |
| | one cell into two | |
| | identical daughter | |
| | cells.  This is a | |
| | process that's | |
| | especially important | |
| | for many tissues in | |
| | our body.  | |
| | | |
| | But, all cells also | |
| | have a shelf-life.  | |
| | During times of | |
| | stress, damage or | |
| | when triggered by | |
| | pre-programmed | |
| | cellular signals, a | |
| | cell will undergo | |
| | self-destruction | |
| | through a process | |
| | called apoptosis | |
| | | |
| | But before we get | |
| | started with these | |
| | interesting topics, | |
| | we have to start with | |
| | basic principles. | |
| | | |
| | Today, we will get | |
| | started with our | |
| | first Lecture for | |
| | Module 1, From | |
| | polypeptide to | |
| | protein, where we | |
| | will explore our | |
| | different amino acids | |
| | and their chemical | |
| | interactions. Let's | |
| | get started! | |
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| Slide 2 | The objectives for | |
| | this module are to | |
| | review the principles | |
| | of the primary | |
| | structure of a | |
| | polypeptide, to take | |
| | an overview of the of | |
| | the properties of | |
| | amino acid variable | |
| | side chains (or | |
| | R‐groups), and to | |
| | describe the chemical | |
| | interactions | |
| | essential to protein | |
| | structure. | |
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| Slide 3 | What is a protein? | |
| | What are the | |
| | functions of | |
| | proteins? I want you | |
| | to take a moment just | |
| | to pause and think | |
| | about your definition | |
| | of a protein and | |
| | think about what | |
| | proteins do in the | |
| | cell. | |
| | | |
| | You might've come up | |
| | with the definition | |
| | of proteins such as a | |
| | string of amino | |
| | acids, a polypeptide | |
| | chain or a polymer of | |
| | other small | |
| | molecules. | |
| | | |
| | When you think about | |
| | the function of | |
| | proteins, we can | |
| | basically answer that | |
| | by saying proteins do | |
| | everything. | |
| | | |
| | Some examples you | |
| | might have come up | |
| | with could include | |
| | the fact that | |
| | | |
| | - Proteins are | |
| | structural | |
| | components of the | |
| | cell, (tubules, | |
| | actins and | |
| | cytoskeletal | |
| | elements) | |
| | | |
| | - that proteins are | |
| | sensors for | |
| | environmental | |
| | change and that | |
| | they may help | |
| | with mechanisms | |
| | for relaying | |
| | information from | |
| | the outside of | |
| | the cell to the | |
| | inside of the | |
| | cell, initiating | |
| | changes in cell | |
| | behavior. | |
| | | |
| | - You may also | |
| | remember that | |
| | proteins are | |
| | enzymes that can | |
| | metabolize | |
| | chemical | |
| | reactions. | |
| | | |
| | - Or that proteins | |
| | can regulate gene | |
| | expression | |
| | (acting as | |
| | activators or | |
| | silencers that | |
| | allow or inhibit | |
| | gene expression) | |
| | | |
| | - Proteins could | |
| | also be modifiers | |
| | that change the | |
| | function of other | |
| | proteins, turning | |
| | proteins on and | |
| | off. We also know | |
| | that proteins are | |
| | signals that are | |
| | produced by | |
| | cells, and are | |
| | required for | |
| | signaling between | |
| | cells. And of | |
| | course, proteins | |
| | are also | |
| | receptors that | |
| | receive those | |
| | signals, and they | |
| | are the | |
| | components of the | |
| | transduction | |
| | pathways that | |
| | interpret those | |
| | signals. | |
| | | |
| | - Or maybe you were | |
| | thinking, | |
| | proteins form | |
| | molecular motors, | |
| | in that they are | |
| | able to transport | |
| | components around | |
| | the cell. | |
| | | |
| | - Or that proteins | |
| | are important for | |
| | the unique | |
| | identity and | |
| | function of | |
| | membrane‐bound | |
| | organelles in the | |
| | cell. | |
| | | |
| | All of these | |
| | functions are true, | |
| | and all functions | |
| | outline the | |
| | importance of | |
| | proteins in all of | |
| | our cells! | |
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| Slide 4 | How can one type of | |
| | molecule accomplish | |
| | all of this? Unlike | |
| | RNA and DNA, which | |
| | assume a limited | |
| | number of structures, | |
| | there is a virtually | |
| | an unlimited number | |
| | of molecular | |
| | structures that | |
| | proteins can assume. | |
| | | |
| | Each protein has its | |
| | own unique, defined | |
| | structure that | |
| | enables it to carry | |
| | out a particular | |
| | function. | |
| | | |
| | If we look at the | |
| | structure of proteins | |
| | we could see that | |
| | there is a diverse | |
| | array of what | |
| | proteins can look | |
| | like: diversity in | |
| | size and diversity in | |
| | structure. The | |
| | | |
| | shape and structure | |
| | of a protein is | |
| | ultimately going to | |
| | | |
| | specify function of | |
| | the protein. | |
| | | |
| | We see here, some | |
| | examples of enzymes | |
| | such as glutamine | |
| | synthetase that forms | |
| | a large donut‐shape | |
| | structure with an | |
| | active domain in the | |
| | middle. | |
| | | |
| | We see smaller | |
| | globular proteins | |
| | such as the signal | |
| | insulin or the | |
| | oxygen‐ carrying | |
| | protein complex | |
| | hemoglobin. | |
| | | |
| | We also see here, the | |
| | typical Y shape of | |
| | the immunoglobulin | |
| | protein that is | |
| | necessary for | |
| | recognizing antigens, | |
| | viruses and bacteria, | |
| | in the cell and | |
| | removing them. | |
| | | |
| | Finally, we see a | |
| | smaller enzyme over | |
| | at the right hand | |
| | side, adenylate | |
| | kinase, containing a | |
| | structure that is | |
| | essential for | |
| | defining the | |
| | substrate binding | |
| | domain and the | |
| | activity domain for | |
| | this enzyme. | |
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| Slide 5 | Proteins are composed | |
| | of amino acids. | |
| | | |
| | The linear array of | |
| | amino acids is the | |
| | primary structure. We | |
| | see here, 5 amino | |
| | acids that have been | |
| | strung together to | |
| | form a small | |
| | polypeptide. One | |
| | amino acid residue in | |
| | the chain is circled | |
| | in green. Each core | |
| | central alpha carbon | |
| | is shown with the | |
| | associated variable | |
| | side chain. In this | |
| | primary sequence, | |
| | these variable side | |
| | chains are R~1~ R~2~ | |
| | R~3~, etc from left | |
| | to right or from | |
| | N‐terminus to | |
| | C‐terminus- that is, | |
| | amino end to carboxyl | |
| | end. | |
| | | |
| | Connecting each of | |
| | these amino acids | |
| | together to form a | |
| | chain of amino acid | |
| | residues are peptide | |
| | bonds. The peptide | |
| | bonds are represented | |
| | here by the orange | |
| | line between a | |
| | carboxyl group and | |
| | amino group. | |
| | | |
| | We have a total of 20 | |
| | possible different | |
| | amino acids that can | |
| | be incorporated into | |
| | newly synthesized | |
| | polypeptides or | |
| | proteins. We will see | |
| | later that even after | |
| | a polypeptide is | |
| | formed, post‐ | |
| | translational | |
| | modifications can | |
| | alter the properties | |
| | of | |
| | | |
| | individual amino | |
| | acids, and as a | |
| | result, the | |
| | properties of a | |
| | protein, as a whole. | |
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| Slide 6 | A single amino acid | |
| | is represented here. | |
| | The 20 possible amino | |
| | acids all have the | |
| | same basic structure. | |
| | The central alpha | |
| | carbon has four side | |
| | chains: | |
| | | |
| | - a hydrogen side | |
| | chain | |
| | | |
| | - an amino group | |
| | | |
| | - a carboxyl group | |
| | | |
| | - and the variable | |
| | R group. | |
| | | |
| | It is the variable R | |
| | group that is going | |
| | to define the | |
| | property of each | |
| | amino acid residue, | |
| | but it is the | |
| | accumulated R groups | |
| | that are going to | |
| | define the properties | |
| | of a polypeptide or | |
| | protein. | |
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| Slide 7 | Since the the | |
| | R-groups or side | |
| | chains of amino acids | |
| | are essential to | |
| | understanding the | |
| | properties of | |
| | proteins, we need to | |
| | think about how these | |
| | side chains differ | |
| | from one another. We | |
| | will look at the | |
| | properties of the | |
| | individual side | |
| | chains. But keep in | |
| | mind that what is | |
| | important are the | |
| | emergent properties | |
| | that come from the | |
| | **interactions** of | |
| | all the side chains | |
| | in a protein. | |
| | | |
| | These interactions | |
| | will determine how | |
| | the protein folds and | |
| | it will determine the | |
| | characteristics of | |
| | the whole protein. | |
| | | |
| | The amino acid side | |
| | chains differ in | |
| | their size, shape, | |
| | charge, | |
| | hydrophobicity, and | |
| | reactivity. Cell | |
| | biologists classify | |
| | these amino acid | |
| | residue side chains | |
| | into groups based | |
| | upon their solubility | |
| | in water or the | |
| | polarity of the side | |
| | chain. | |
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| Slide 8 | Solubility is a | |
| | physical property of | |
| | a molecule that | |
| | refers to its ability | |
| | to transiently | |
| | interact with water | |
| | through hydrogen | |
| | bonding. This is | |
| | thermodynamically | |
| | favorable. | |
| | | |
| | So- if hydrogen bonds | |
| | can form with water, | |
| | the molecule can be | |
| | soluble. If a | |
| | molecule cannot form | |
| | these hydrogen bonds, | |
| | then it is insoluble. | |
| | | |
| | A soluble protein | |
| | typically carries | |
| | hydrophilic amino | |
| | acid residues on the | |
| | external surface. In | |
| | contrast hydrophobic | |
| | molecules are not | |
| | polarized and cannot | |
| | form these hydrogen | |
| | bonds, so...water | |
| | repels these | |
| | molecules in favor of | |
| | bonding with itself. | |
+-----------------------+-----------------------+-----------------------+
| | What sorts of | |
| | molecules are | |
| | hydrophobic? Really, | |
| | anything that is | |
| | unable to form a | |
| | hydrogen bond. | |
| | | |
| | Typically we think of | |
| | oil or fats that do | |
| | not mix with water. | |
| | Now, why do they not | |
| | interact with water? | |
| | Well, because these | |
| | oils or fat contain | |
| | saturated hydrophobic | |
| | long carbon chains | |
| | called hydrocarbons. | |
| | | |
| | We can then extend | |
| | this to our amino | |
| | acid residues. We can | |
| | look for those amino | |
| | acid residue side | |
| | chains that have | |
| | these types of | |
| | hydrocarbon chains. | |
| | | |
| | Hydrophobic amino | |
| | acids have types of | |
| | non‐polar side chains | |
| | and are water | |
| | insoluble, or perhaps | |
| | only slightly | |
| | soluble. Because of | |
| | this, these amino | |
| | acids tend to be | |
| | found in the interior | |
| | of cytosolic proteins | |
| | and form a | |
| | hydrophobic core. | |
| | | |
| | But keep in mind, | |
| | that a protein found | |
| | in a hydrophobic | |
| | environment (such as | |
| | a protein that's | |
| | embedded in a | |
| | membrane), for these | |
| | proteins, they will | |
| | have the opposite | |
| | structure with the | |
| | hydrophobic amino | |
| | acids accumulating on | |
| | the exterior of the | |
| | protein, facing | |
| | towards the | |
| | phospholipid tails of | |
| | the membrane layer. | |
+-----------------------+-----------------------+-----------------------+
| | We can divide the | |
| | hydrophobic amino | |
| | acid residues into 2 | |
| | categories: aromatic | |
| | amino acids and | |
| | aliphatic amino | |
| | acids. | |
| | | |
| | Phenylalanine, | |
| | tyrosine and | |
| | tryptophan have | |
| | hydrophobic aromatic | |
| | rings in their | |
| | R-groups. These | |
| | aromatic rings are | |
| | very hydrophobic. | |
| | Note that as cell | |
| | biologists, we have | |
| | placed tyrosine into | |
| | this hydrophobic | |
| | category, yet it does | |
| | have a hydroxyl group | |
| | on the end of its | |
| | R-group, a group that | |
| | is capable of forming | |
| | a hydrogen bond. So | |
| | really tyrosine falls | |
| | into both categories, | |
| | both hydrophobic and | |
| | hydrophilic. | |
| | | |
| | At the right, we have | |
| | our 5 hydrophobic, | |
| | aliphatic amino | |
| | acids. Notice that | |
| | the R-groups for | |
| | these amino acids | |
| | have long hydrocarbon | |
| | chains. | |
| | | |
| | Alanine has just one | |
| | methyl side chain, | |
| | valine isoleucine, | |
| | leucine, and | |
| | methionine all have | |
| | longer hydrocarbon | |
| | chains. Notice also | |
| | that methionine has a | |
| | | |
| | sulfur within its | |
| | chain. | |
| | | |
| | Overall, amino acids | |
| | with aromatic or | |
| | aliphatic R-groups | |
| | (or side chains) will | |
| | be classified as | |
| | hydrophobic. | |
+-----------------------+-----------------------+-----------------------+
| | What about | |
| | hydrophilic amino | |
| | acid residues? | |
| | | |
| | Hydrophilic molecules | |
| | are water soluble, | |
| | and for that reason | |
| | we find our | |
| | hydrophilic amino | |
| | acid residues on the | |
| | exterior of soluble | |
| | cytosolic proteins. | |
| | Water soluble | |
| | molecules have | |
| | portions that are | |
| | charge- polarized and | |
| | capable of forming | |
| | hydrogen bonds. | |
| | | |
| | Remember this is | |
| | relevant to our cells | |
| | at a physiological | |
| | pH- a pH of 7. So | |
| | we're looking at | |
| | molecules with a | |
| | hydroxyl group or a | |
| | charged oxygen at pH | |
| | 7, or molecules that | |
| | have this amino group | |
| | with a positive | |
| | charge at a pH of 7. | |
+-----------------------+-----------------------+-----------------------+
| | Here we see examples | |
| | of amino acids that | |
| | carry | |
| | | |
| | charged side chains. | |
| | | |
| | On the left, amino | |
| | acids with positively | |
| | charged side chains, | |
| | lysine and arginine. | |
| | | |
| | On the right, amino | |
| | acids with negatively | |
| | charged side chains, | |
| | aspartic acid and | |
| | glutamic acid. | |
| | | |
| | These four amino | |
| | acids are | |
| | hydrophilic, and are | |
| | prime contributors to | |
| | the overall charge of | |
| | a protein or a domain | |
| | of a protein. | |
+-----------------------+-----------------------+-----------------------+
| | There are also | |
| | uncharged, polar | |
| | hydrophilic amino | |
| | acid residues. | |
| | | |
| | Shown here are the | |
| | amino acids threonine | |
| | and serine, with | |
| | polar hydroxyl groups | |
| | that can participate | |
| | in hydrogen bonds, | |
| | and asparagine and | |
| | glutamine that are | |
| | uncharged but have | |
| | these polar amine | |
| | groups. | |
+-----------------------+-----------------------+-----------------------+
| | Finally, we have a | |
| | collection of special | |
| | amino acid residues. | |
| | | |
| | - Cysteine is a | |
| | special amino | |
| | acid, because it | |
| | is able to form | |
| | covalent bonds, | |
| | through its | |
| | sulfur atom, with | |
| | other cysteine | |
| | amino acids. | |
| | These covalent | |
| | bonds are called | |
| | disulfide bridges | |
| | or cysteine | |
| | bridges | |
| | | |
| | - Glycine is | |
| | special because | |
| | it is very small. | |
| | The side chain is | |
| | a single | |
| | hydrogen. The | |
| | small size of | |
| | glycine allows | |
| | for it to tuck in | |
| | small places in a | |
| | folding protein | |
| | and allow for | |
| | bends in a | |
| | polypeptide | |
| | chain. | |
| | | |
| | - Proline is | |
| | special because | |
| | it's R- group | |
| | forms a covalent | |
| | bond with the | |
| | amino group of | |
| | the amino acid. | |
| | This can lead to | |
| | a kink or bend | |
| | forming in a | |
| | polypeptide | |
| | chain, that is | |
| | essential for the | |
| | structure of many | |
| | proteins | |
| | | |
| | - And finally, we | |
| | have our amino | |
| | acid histidine, | |
| | which has an | |
| | amino diethyl | |
| | side chain, that | |
| | shifts between a | |
| | positive charge | |
| | and neutral | |
| | charge, depending | |
| | on the pH of the | |
| | environment | |
| | | |
| | For our course, make | |
| | sure you review all | |
| | of the properties of | |
| | the amino acid side | |
| | chains. We will not | |
| | ask you to draw the | |
| | structures of these | |
| | amino acids, but you | |
| | should be able to | |
| | recognize and know | |
| | the unique properties | |
| | of all 20 amino | |
| | acids. Knowing these | |
| | properties will be | |
| | essential for us to | |
| | understand the unique | |
| | structure and | |
| | function of different | |
| | proteins. | |
+-----------------------+-----------------------+-----------------------+
| | To make a protein, | |
| | amino acids must be | |
| | covalently bound | |
| | together through | |
| | peptide bonds. A | |
| | peptide bond is | |
| | formed by a | |
| | condensation | |
| | reaction, which | |
| | simply means that | |
| | water is released | |
| | during the formation | |
| | of this covalent | |
| | bond. | |
| | | |
| | Here we have two | |
| | amino acids side by | |
| | side. We can see the | |
| | carboxyl group of the | |
| | amino acid on the | |
| | left and the amino | |
| | group of the amino | |
| | acid on the right. | |
| | Through a | |
| | condensation | |
| | reaction, one | |
| | molecule of water is | |
| | released and a | |
| | peptide bond is | |
| | formed. | |
+-----------------------+-----------------------+-----------------------+
| | Protein chains are | |
| | typically depicted | |
| | from left to right, | |
| | from N‐terminus (or | |
| | amino end) to | |
| | C‐terminus (or | |
| | carboxyl end). | |
| | Protein synthesis | |
| | takes place during | |
| | the process of | |
| | translation. During | |
| | this process of | |
| | translation, new | |
| | amino acid residues | |
| | are added to the | |
| | carboxyl end. As a | |
| | result, the | |
| | N‐terminus of any | |
| | protein is the first | |
| | amino acid in the | |
| | chain and subsequent | |
| | amino acids are added | |
| | to the carboxyl end, | |
| | that is, the right | |
| | hand end of the | |
| | growing chain. | |
+-----------------------+-----------------------+-----------------------+
| | Translation happens | |
| | in the ribosome. | |
| | Shown here is a video | |
| | animation of the | |
| | process of | |
| | translation from | |
| | | |
| | the Howard Hughes | |
| | Medical Institute's | |
| | collection of | |
| | BioInteractives. | |
+-----------------------+-----------------------+-----------------------+
| | Video, no script | |
+-----------------------+-----------------------+-----------------------+

+-----------------------+-----------------------+-----------------------+
| | Let's think a little | |
| | bit about how we get | |
| | from a polypeptide to | |
| | something that is | |
| | actually functional | |
| | in the cell. Seen | |
| | here, on the left | |
| | hand side we have a | |
| | representation of a | |
| | polypeptide string, a | |
| | linear array of amino | |
| | acids that is not | |
| | functional yet in the | |
| | cell. We need a | |
| | three‐dimensional | |
| | protein such as the | |
| | one on the right that | |
| | has a series of loops | |
| | and bends and sheets | |
| | that define | |
| | structural and | |
| | functional domains | |
| | within the protein. | |
| | The structure on the | |
| | right is dependent | |
| | upon the amino acid | |
| | sequence that we see | |
| | on the left. But\-- | |
| | it is not simply that | |
| | amino acid sequence | |
| | that is going to | |
| | allow us to get to | |
| | our three- | |
| | dimensional | |
| | structure. We are | |
| | going to see that the | |
| | polypeptide has to be | |
| | modified in various | |
| | ways in | |
| | | |
| | order to allow for | |
| | this folding to | |
| | occur. | |
+=======================+=======================+=======================+
| | There are four levels | |
| | of organization to | |
| | get from a sequence | |
| | of amino acids to a | |
| | functional 3‐ | |
| | dimensional protein. | |
| | The primary structure | |
| | is that | |
| | | |
| | linear array of amino | |
| | acids. | |
+-----------------------+-----------------------+-----------------------+
| | The primary structure | |
| | of the polypeptide is | |
| | the linear array or | |
| | sequence of amino | |
| | acids and is | |
| | determined by the | |
| | sequence of | |
| | nucleotides in the | |
| | coding DNA. | |
| | | |
| | This image represents | |
| | the processes of | |
| | transcription and | |
| | translation that lead | |
| | to the synthesis of a | |
| | polypeptide chain. | |
| | | |
| | - To start, a | |
| | sequence from the | |
| | double‐ stranded | |
| | DNA helix is | |
| | transcribed into | |
| | a single‐ | |
| | stranded | |
| | messenger RNA. | |
| | | |
| | - That messenger | |
| | RNA is processed | |
| | to remove introns | |
| | and produce a | |
| | mature messenger | |
| | RNA, which | |
| | essentially | |
| | contains only the | |
| | codons that are | |
| | required for the | |
| | synthesis of the | |
| | protein. | |
| | | |
| | - The mature | |
| | messenger RNA | |
| | molecule is then | |
| | exported out of | |
| | the nucleus into | |
| | the cytosol of | |
| | the cell, where | |
| | it is translated | |
| | by the ribosome. | |
| | | |
| | So, the amino acid | |
| | sequence is | |
| | determined by that | |
| | nucleotide sequence | |
| | in the original | |
| | associated gene. | |
| | | |
| | The number of | |
| | different polypeptide | |
| | sequences is limited | |
| | by two factors: | |
| | | |
| | 1\) there are 20 | |
| | distinct amino | |
| | acids that can | |
| | become incorporated | |
| | into a polypeptide, | |
| | | |
| | 2\) the number of | |
| | amino acid found in | |
| | that polypeptide. | |
| | | |
| | So for any | |
| | polypeptide string | |
| | that is "n" amino | |
| | acids long, the | |
| | number of different | |
| | arrangements of amino | |
| | acids in a chain | |
| | would be defined by | |
| | 20 to the power of | |
| | "n". Given this, we | |
| | can see that there | |
| | are infinite number | |
| | of polypeptide | |
| | sequences that could | |
| | be produced in a | |
| | cell. | |
+-----------------------+-----------------------+-----------------------+

+-----------------------+-----------------------+-----------------------+
| | Polypeptides fold | |
| | spontaneously and | |
| | assume what is called | |
| | a random‐coil | |
| | structure. A | |
| | random‐coil is best | |
| | described as a | |
| | periodically ordered | |
| | structure of the | |
| | protein. Proteins | |
| | might not have a | |
| | single stable | |
| | structure, but a | |
| | collection of related | |
| | structures that they | |
| | switch between. The | |
| | term **statistical | |
| | coil** is a | |
| | representation of | |
| | this idea and | |
| | suggests that the | |
| | protein spends most | |
| | of its time in a | |
| | particular structure, | |
| | but not 100% of its | |
| | time. This structure | |
| | may be stabilized by | |
| | interactions within | |
| | the polypeptide, but | |
| | also interactions | |
| | with other proteins | |
| | and other molecules | |
| | as well. | |
| | | |
| | The structure that | |
| | the polypeptide | |
| | assumes most of the | |
| | time, or **native | |
| | structure**, is the | |
| | functional protein | |
| | structure. | |
| | | |
| | The local | |
| | interactions that | |
| | maintain protein | |
| | shape are for the | |
| | most part | |
| | non‐covalent | |
| | interactions that | |
| | include ionic bonds | |
| | and hydrogen bonds, | |
| | Van der Waals forces | |
| | and what is called | |
| | the hydrophobic | |
| | effect. Individually, | |
| | these are weak | |
| | attractive forces, | |
| | | |
| | but in their | |
| | aggregate they form a | |
| | very strong | |
| | association, and | |
| | provide stability to | |
| | the folded protein | |
| | structure. | |
+=======================+=======================+=======================+
| | Let's step through | |
| | each of these | |
| | interactions. | |
| | | |
| | First of all, the | |
| | ionic bond. This is | |
| | an attraction between | |
| | a positively charged | |
| | cation and a | |
| | negatively charged | |
| | anion. Represented | |
| | here in this image, | |
| | is the interaction | |
| | between glutamate and | |
| | lysine, where we have | |
| | a positively charged | |
| | cation on the lysine | |
| | side chain and a | |
| | negatively charged | |
| | anion on the | |
| | glutamate side chain. | |
| | If we look at this in | |
| | the context of a | |
| | simple polypeptide, | |
| | we can see that this | |
| | ionic interaction is | |
| | assisting in holding | |
| | the two arms of the | |
| | polypeptide together | |
| | in this shape. | |
| | | |
| | Now one bond isn't | |
| | going to be enough to | |
| | do that, but we're | |
| | going to see how an | |
| | accumulation of these | |
| | interactions can | |
| | maintain | |
| | | |
| | protein shape. | |
+-----------------------+-----------------------+-----------------------+
| | A hydrogen bond is | |
| | the interaction | |
| | between a partially | |
| | charged hydrogen atom | |
| | in a molecular | |
| | dipole, such as what | |
| | we see in water, and | |
| | an unpaired electron | |
| | from another atom. | |
| | | |
| | Represented at the | |
| | bottom right hand | |
| | corner here is a | |
| | polarized covalent | |
| | bond, where there is | |
| | not a full charge, | |
| | but a partial charge | |
| | or dipole moment. In | |
| | a water molecule, | |
| | oxygen has a partial | |
| | negative charge, a | |
| | negative dipole, | |
| | whereas the hydrogen | |
| | is exhibiting a | |
| | partial positive | |
| | charge, or a positive | |
| | dipole. This can | |
| | happen not only in | |
| | water molecules, but | |
| | in other covalent | |
| | bonds as well. | |
| | Represented here as | |
| | well, is a hydrogen | |
| | bond that is forming | |
| | between the molecular | |
| | dipoles at different | |
| | side chains of two | |
| | distinct amino acid | |
| | residues. The | |
| | hydrogen bond | |
| | contributes here to | |
| | protein shape | |
+-----------------------+-----------------------+-----------------------+
| | Hydrophobic effects | |
| | are the aggregation | |
| | of nonpolar molecules | |
| | in aqueous medium, | |
| | simply to reduce the | |
| | number of | |
| | interactions with | |
| | water. An example of | |
| | this would be an oil | |
| | droplet in water. All | |
| | of the hydrophobic | |
| | molecules aggregate | |
| | together to minimize | |
| | the surface area that | |
| | is exposed to the | |
| | hydrophilic aqueous | |
| | environment. The | |
| | aqueous environment | |
| | of the cytosol can | |
| | similarly induce | |
| | these hydrophobic | |
| | effects for | |
| | hydrophobic amino | |
| | acids in proteins. | |
+-----------------------+-----------------------+-----------------------+
| | A Van der Waal's | |
| | interaction, which is | |
| | also known as London | |
| | Dispersion forces, is | |
| | a weak non‐specific | |
| | attractive force. It | |
| | results from a | |
| | transient dipole that | |
| | is induced when two | |
| | atoms are very close | |
| | together and they | |
| | perturb the | |
| | distribution of | |
| | electrons in each | |
| | other. This transient | |
| | dipole only exists | |
| | when these atoms are | |
| | close to one another. | |
| | The association that | |
| | occurs though is not | |
| | a strong one, it is | |
| | not as strong as a | |
| | hydrogen bond or | |
| | ionic bond, but if we | |
| | accumulate many of | |
| | these Van der Waal's | |
| | forces together, | |
| | these interactions | |
| | can be quite strong | |
| | together. | |
+-----------------------+-----------------------+-----------------------+
| | Let's take a look at | |
| | an organismal example | |
| | of Van der Waal's | |
| | interactions -- the | |
| | amazing ability of a | |
| | gecko to walk on | |
| | walls and ceilings. | |
| | How is this possible? | |
| | At the bottom of this | |
| | slide, we see a | |
| | close‐up of | |
| | | |
| | the gecko's foot. If | |
| | we take an even | |
| | closer look at the | |
| | surface of its feet | |
| | (as we see on the | |
| | right), we can see | |
| | structures called | |
| | setae. These setae | |
| | are small little | |
| | fibers that are | |
| | present on the | |
| | surface of these | |
| | feet. Each one of | |
| | these little setae | |
| | induces a transient | |
| | dipole with the | |
| | underlying surface | |
| | causing a Van der | |
| | Waal's interaction. | |
| | Now one seta would | |
| | not be enough to hold | |
| | a gecko in place, | |
+-----------------------+-----------------------+-----------------------+
| |... but when there | |
| | are millions of these | |
| | together, all on the | |
| | entire surface of the | |
| | foot, we find a very | |
| | strong interaction. | |
| | It is the sum | |
| | strength of all of | |
| | these Van der Waals | |
| | interactions that | |
| | allow geckos to walk | |
| | along the ceiling. | |
| | This is a neat | |
| | observation, because | |
| | we can use this to | |
| | model adhesive | |
| | surfaces. We can do | |
| | this by looking at | |
| | nanotubes that are | |
| | mimicking the setae | |
| | that we find in gecko | |
| | feet. | |
| | | |
| | Similarly, in | |
| | proteins, individual | |
| | Van der Waal's | |
| | interactions are very | |
| | weak attractive | |
| | forces. But the | |
| | accumulated effect of | |
| | many bonds like | |
| | these, makes for a | |
| | very strong overall | |
| | association between | |
| | two different | |
| | proteins or within a | |
| | protein. | |
+-----------------------+-----------------------+-----------------------+
| | Folding is the result | |
| | of interactions | |
| | between amino acid | |
| | residues t hat hold a | |
| | polypeptide into | |
| | shape. | |
| | | |
| | Here is a short | |
| | animation that shows | |
| | a polypeptide | |
| | folding. Before we | |
| | get started, keep in | |
| | mind a few things: | |
| | | |
| | 1\) The color of the | |
| | spheres and the | |
| | type of | |
| | interactions that | |
| | can occur. Here, | |
| | red spheres are | |
| | representing amino | |
| | acids with | |
| | hydrophobic chains, | |
| | purple and blue | |
| | spheres are | |
| | representing amino | |
| | acids that can form | |
| | hydrogen bonds, and | |
| | yellow and green | |
| | represent amino | |
| | acids that can form | |
| | ionic bonds. These | |
| | interactions are | |
| | important in | |
| | allowing the | |
| | peptide to form a | |
| | three‐dimensional | |
| | structure. | |
| | | |
| | 2\) Remember that | |
| | folding is a random | |
| | process; bonds are | |
| | forming and bonds | |
| | are also breaking | |
| | as different bonds | |
| | form. Folding is | |
| | dynamic. | |
| | | |
| | 3\) Folding depends | |
| | upon the number and | |
| | the strength of | |
| | bonds and | |
| | interactions that | |
| | are maintaining | |
| | protein | |
| | conformation. | |
| | | |
| | 4\) Also, note that | |
| | for simplicity, in | |
| | this animation, the | |
| | arms of the | |
| | polypeptide move | |
| | through one | |
| | another, that would | |
| | be like us walking | |
| | | |
| | through a wall. It | |
| | doesn't happen in an | |
| | actual protein, but | |
| | it is just shown to | |
| | help us visualize the | |
| | animation. | |
+-----------------------+-----------------------+-----------------------+
| | I n this animation, | |
| | we start with a short | |
| | polypeptide. The grey | |
| | spheres are amino | |
| | acids, their specific | |
| | identities do not | |
| | affect folding. The | |
| | polypeptide begins to | |
| | fold and takes on a | |
| | shape. Again, keep in | |
| | mind that this is a | |
| | random process. The | |
| | polypeptide might | |
| | unfold, but then it | |
| | might fold again. The | |
| | hydrophobic side | |
| | chains in this | |
| | polypeptide are going | |
| | to aggregate together | |
| | in a hydrophobic | |
| | core, that | |
| | hydrophobic core is | |
| | also important in | |
| | stabilizing the | |
| | protein. Remember | |
| | that hiding those | |
| | hydrophobic side | |
| | chains is | |
| | thermodynamically | |
| | favorable. We see | |
| | bonds beginning to | |
| | form, blue and purple | |
| | form a hydrogen bond | |
| | that is holding those | |
| | arms together in | |
| | | |
| | that particular | |
| | conformation. Yellow | |
|