CAPE 1: carbohydrates

Carbohydrates  

Carbohydrates contain only the elements carbon, hydrogen and oxygen. The group includes monomers, dimers and polymers, as shown in this diagram:

Review Table

Monosaccharides (simple sugars) 

These all have the formula (CH₂O)_n, where n can be 3-7. The most common and important monosaccharide is glucose, which is a six-carbon or hexose sugar, so has the formula C₆H₁₂O₆. Its structure is:

a-glucose (used to make starch and glycogen)	or more simply
b-glucose (used to make cellulose)

 Glucose forms a six-sided ring, although in three-dimensions it forms a structure that looks a bit like a chair. The six carbon atoms are numbered as shown, so we can refer to individual carbon atoms in the structure. In animals glucose is the main transport sugar in the blood, and its concentration in the blood is carefully controlled. There are many isomers of glucose, with the same chemical formula (C₆H₁₂O₆), but different structural formulae. These isomers include fructose and galactose.

Common five-carbon, or pentose sugars (where n = 5, C₅H₁₀O₅) include ribose and deoxyribose (found in nucleic acids and ATP) and ribulose (which occurs in photosynthesis).

Disaccharides (double sugars) 

Disaccharides are formed when two monosaccharides are joined together by a glycosidic bond. The reaction involves the formation of a molecule of water (H₂O) and is known as dehydration or condensation: 

see animation: dehydration or condensation of monosaccharides

This shows two glucose molecules joining together to form the disaccharide maltose. Because this bond is between carbon 1 of one molecule and carbon 4 of the other molecule it is called a 1-4 glycosidic bond. Bonds between other carbon atoms are possible, leading to different shapes, and branched chains.

This kind of reaction, where H₂O is formed, is called a condensation reaction. 

The reverse process, when bonds are broken by the addition of water (e.g. in digestion), is called a hydrolysis reaction. 

see animation:hydrolysis of carbohydrates (di- and polysaccharides 

In general:

polymerisation reactions are condensations breakdown reactions are hydrolyses

 There are three common disaccharides:

• Maltose (or malt sugar) is glucose 1-4 glucose. It is formed on digestion of starch by amylase, because this enzyme breaks starch down into two-glucose units. Brewing beer starts with malt, which is a maltose solution made from germinated barley. Maltose is the structure shown above.
• Sucrose (or cane sugar) is glucose 1-2 fructose. It is common in plants because it is less reactive than glucose, and it is their main transport sugar. It is the common table sugar that you put in your tea.
• Lactose (or milk sugar) is galactose 1-4 glucose. It is found only in mammalian milk, and is the main source of energy for infant mammals.

Polysaccharides 

Polysaccharides are long chains of many monosaccharides joined together by glycosidic bonds. There are three important polysaccharides:

• Starch is the plant storage polysaccharide. It is insoluble and forms starch granules inside many plant cells. Being insoluble means starch does not change the water potential of cells, so does not cause the cells to take up water by osmosis (more on osmosis later). It is not a pure substance, but is a mixture of amylose and amylopectin.

Amylose is simply poly-(1-4) glucose, so is a straight chain. In fact the chain is floppy, and it tends to coil up into a helix.
Amylopectin is poly(1-4) glucose with about 4% (1-6) branches. This gives it a more open molecular structure than amylose. Because it has more ends, it can be broken more quickly than amylose by amylase enzymes.
Both amylose and amylopectin are broken down by the enzyme amylase into maltose, though at different rates.

Glycogen is similar in structure to amylopectin. It is poly (1-4) glucose with 9% (1-6) branches. It is made by animals as their storage polysaccharide, and is found mainly in muscle and liver. Because it is so highly branched, it can be mobilised (broken down to glucose for energy) very quickly.

•  Cellulose is only found in plants, where it is the main component of cell walls. It is poly (1-4) glucose, but with a different isomer of glucose. Starch and glycogen contain a-glucose, in which the hydroxyl group on carbon 1 sticks down from the ring, while cellulose contains b-glucose, in which the hydroxyl group on carbon 1 sticks up. This means that in a chain alternate glucose molecules are inverted.

This apparently tiny difference makes a huge difference in structure and properties. While the a1-4 glucose polymer in starch coils up to form granules, the b14 glucose polymer in cellulose forms straight chains. Hundreds of these chains are linked together by hydrogen bonds to form cellulose microfibrils. These microfibrils are very strong and rigid, and give strength to plant cells, and therefore to young plants and also to materials such as paper, cotton and sellotape.

The b-glycosidic bond cannot be broken by amylase, but requires a specific cellulase enzyme. The only organisms that possess a cellulase enzyme are bacteria, so herbivorous animals, like cows and termites whose diet is mainly cellulose, have mutualistic bacteria in their guts so that they can digest cellulose. Humans cannot digest cellulose, and it is referred to as fibre.

Chitin - (poly glucose amine), found in fungal cell walls and the exoskeletons of insects. The structure resembles that of cellulose, except that the hydroxyl groups on C# 2 have been replaced by acetylamino groups. 

• Other polysaccharides that you may come across include:
• .Pectin (poly galactose uronate), found in plant cell walls.
• Agar (poly galactose sulphate), found in algae and used to make agar plates.
• Murein (a sugar-peptide polymer), found in bacterial cell walls.
• Lignin (a complex polymer), found in the walls of xylem cells, is the main component of wood.
  
  

Structure of Polysaccharides 

CAPE 1: Properties of Water

PROPERTIES OF WATER

CLICK HERE FOR: tutorial on properties on water

SOLVENT PROPERTY OF WATER

Ionic compounds dissolve in water:

• Charged regions of polar water molecules have an electrical attraction to charged ions.
• Water surrounds individual ions, separating and shielding them from one another.

Polar compounds in general, are water-soluble:

• Charged regions of polar water molecules have an affinity for oppositely charged regions of other polar molecules.

Hydrophobic { Nonpolar compounds (which have symmetric distribution in charge) are NOT water-soluble.

CLICK HERE FOR: salt vs. sugar dissolving in water animation

CAPILLARY ACTION OF WATER

Cohesion. Water molecules "stick together" due to their hydrogen bonds, so water has high cohesion. This explains why long columns of water can be sucked up tall trees by transpiration without breaking (capillarity). It also explains surface tension, which allows small animals to walk on water.

CLICK HERE FOR VIDEO ON: Cohesion and Adhesion

 CLICK HERE FOR ANIMATION: interactions in the phases of water

CAPE 1: Water - Introduction to it's BIOchemistry

WATER

A water molecule consists of one oxygen atom covalently bonded to two hydrogen atoms. 

• the electrons are not shared perfectly evenly: the oxygen atom is capable of pulling them towards itself and further away from the hydrogen atoms. 
• The result is that the oxygen part of the molecule becomes slightly negatively charged, and the hydrogen atoms slightly positively charged. (this makes oxygen the more electronegative atom)

Water is therefore described as a polar molecule (polar means: one end of the molecule has a partial positive charge while the section has a partial negative charge / means: charged internally).

Two atoms, connected by a covalent bond, may exert different attractions for the electrons of the bond. In such cases the bond is polar, with one end slightly negatively charged and the other slightly positively charged.

DELTA (δ) 
A partial charge. δ− represents a negative partial charge, and δ+ represents a positive partial charge chemistry


HYDROGEN BONDS

• Because they are polarized, two adjacent H2O molecules can form a linkage known as a hydrogen bond. 
• A hydrogen bond is NOT A BOND because no electrons are involved, instead it is a FORCE OF ATTRACTION.
• Hydrogen bonds have only about 1/20 the strength of a covalent bond.
• Hydrogen bonds are strongest when the three atoms lie in a straight line.

WATER STRUCTURE

• Molecules of water join together transiently in a hydrogen-bonded lattice. 
• Even at 37oC, 15% of the water molecules are joined to four others in a short-lived assembly known as a “flickering cluster.”
• The cohesive nature of water is responsible for many of its unusual properties, such as high surface tension, specific heat, and heat of vaporization.

HYDROPHILIC MOLECULES

Substances that dissolve readily in water are termed hydrophilic. 

• They are composed of ions or polar molecules that attract water molecules through electrical charge effects. 

• Water molecules surround each ion or polar molecule on the surface of a solid substance and carry it into solution.

HYDROPHOBIC MOLECULES

Molecules that contain a preponderance of non-polar bonds are usually insoluble in water and are
termed hydrophobic. 
This is true, especially, of hydrocarbons, which contain many C–H bonds.

• Water molecules are not attracted to such molecules and so have little tendency to surround them and carry them into solution. 

• This is known as formation of micelles. One very good example is shown below.

CSEC - Movement of substances

Movement of Substances

Here are the links to see an animation of each movement process discussed in class.

Things to know before we begin

1. Substances move throughout, in and out of cells by passive and active media. 
2. A concentration gradient is required to direct the movement
3. Substances moved are varied and they include small, large, charged and neutral particles

Lets put all this together with a concept map                                                                                    

Now for the details:

• A concentration gradient exists when molecules are not evenly distributed. that means you will have a region having more molecules than another. This difference in the amount of molecules is the concentration gradient.                                                    

• Movement along a concentration gradient - from an area of high concentration to an area of low concentration.

• Movement against a concentration gradient - from an area of low concentration to an area of high concentration.

• Passive processes do not require energy. These include:
• Diffusion - 
• Osmosis

• Active processes require ATP energy.
• active transport 

1. Diffusion - movement of uncharged molecules along a concentration gradient, until evenly distributed. eg. perfume in air, red dye in water, oxygen in cells.                   CLICK HERE to see diffusion                                                                                              
2. Osmosis - movement of water molecules through a selectively permeable membrane, along a concentration gradient, until evenly distributed.                                      CLICK HERE to see osmosis                                                                                            
3. Active Transport - movement of charged particles (ions) against a concentration gradient through carrier proteins (gates) with the help of energy.                             CLICK HERE to see active transport                                                                             
4. Endocytosis - the intake of substances into a cell by the folding of the membrane (invagination) into a vacuole.                                                                             > phagocytosis - intake of solid material into a cell                                             >pinocytosis - intake of liquid material into the cell                                                                                                                               
5. Exocytosis - the release of the contents of a cell vacuole to the outside of the cell by fusion of the vacuole with the cell membrane.                                                         CLICK HERE to see endocytosis & exocytosis 

CAPE 1: ENZYMES IN ANIMATION

​Good Morning All, 

I hope these help​....see links below

CLICK HERE for: How enzymes work

CLICK HERE for: basic enzyme introduction

• note the key terms and the concepts being explained
• do NOT click next until the menu bar at the bottom of the page changes its colour from grey to yellow

CLICK HERE for: competitive vs non-competitive inhibitor

• note the difference with how they work

CLICK HERE for: Allosteric regulation of a chemical reaction

• select narration
• read conclusion
• select home button at the bottom of the animation
• click step by step and go back through the animation
• select the "Q" from the bottom of the animation to complete quiz

CLICK HERE for: What happens during denaturation of proteins 

• pay attention to what happens to the secondary and tertiary arrangement of the protein
• most non-specific inhibitors work in this way

CLICK HERE for: How a biochemical pathway of an enzyme-catalysed reaction works

CLICK HERE for: Feedback inhibition of a biochemical pathway

CSEC: CELLS - simple but important.......LEARN IT!

Parts of the UNSPECIALISED cell

"It is important that you learn to DRAW & EXPLAIN the function of these cell organelles" 
Circles and dots will not work when you are representing cell organelles...... 

DIAGRAM OF AN UNSPECIALISED PLANT CELL

Cell Membrane This is a thin, flexible layer round the outside of all cells made of phospholipids and proteins. The function of the cell membrane is to allow waste material to exit the cell. The cell membrane forms a barrier between the inside of the cell and the outside, so that the chemical environments on both sides can be different. It regulates the movement of materials into and out of the cell.

Cell Wall The function of the cell wall is to provide structural support. It gives rigid support due to its strong cellulose component. It has plasmodesmata which are small breaks in the wall itself. They allow substances to enter and leave the cell.

Golgi Body The Golgi body stores, packages, and distributes the lipids and proteins made in the endoplasmic reticulum. It puts proteins into packages, called vesicles.

Rough Endoplasmic Reticulum (RER) The RER is generally a series of connected flattened sacs, studded with numerous ribosomes, which give it its rough appearance. The ribosomes synthesise proteins, which are processed in the RER 

Smooth Endoplasmic Reticulum (SER) Makes lipids and steroids and package proteins for transport.

Lysosomes These are small membrane-bound vesicles formed from the RER containing a mixture of digestive enzymes. They are used to break down unwanted chemicals, toxins, organelles or even whole cells, so that the materials may be recycled. They can also fuse with a feeding vacuole to digest its contents. Lysosomes are the cell’s garbage disposal system. They clean up while patrolling the cell. This organelle breaks down large molecules into many smaller molecules by using their special proteins. Lysosomes also kill and digest invading organisms.

Cytoplasm The function of the cytoplasm is to distribute oxygen and food (nutrients) to other parts of the cell and it supports all parts inside the cell. It has three main functions: storage, energy, and manufacturing. The cytoplasm contains nutrients that have been dissolved which help for the dissolving of waste products.

DIAGRAM OF AN UNSPECIALISED ANIMAL CELL

Vacuole These are membrane-bound sacs containing water or dilute solutions of salts and other solutes. Most cells can have small vacuoles that are formed as required, but plant cells usually have one very large permanent vacuole that fills most of the cell, so that the cytoplasm (and everything else) forms a thin layer round the outside. Plant cell vacuoles are filled with cell sap, and are very important in keeping the cell rigid, or turgid. Some unicellular protoctists have feeding vacuoles for digesting food, or contractile vacuoles for expelling water.

Ribosomes - Ribosomes are the protein builders or protein synthesizers of the cell.

Chloroplast Chloroplasts are the food producers of the cell. They contain chlorophyll, the green pigment that is needed for photosynthesis. Through the process of photosynthesis, green plants use the energy from the sun to convert it into sugar. The main purpose of this organelle is to produce sugars and starches.

Nucleus This is the largest organelle. Surrounded by a nuclear envelope, which is a double membrane with nuclear pores - large holes containing proteins that control the exit of genetic substances and ribosomes from the nucleus. The interior is called the nucleoplasm, which is full of chromatin- a DNA/protein complex. During cell division the chromatin becomes condensed into discrete observable chromosomes.

Nuclear Envelope The nuclear envelope (double membrane) surrounds the nucleus and all of its contents. It is similar to the cell membrane around the whole cell. There are pores and spaces for RNA (genetic materials) and proteins to pass through while the nuclear envelope keeps all of the chromatin and the nucleolus inside.

Nucleolus The nucleolus is where ribosomes are made. The nucleolus disappears during cell reproduction. This is because ribosomes are not needed when cells reproduce.

Mitochondria The function of the mitochondria is to provide the cell with energy. Through the process of respiration, the mitochondria uses oxygen to change sugar into energy. It gives out energy by combining sugar molecules with oxygen to make carbon dioxide and water.

CAPE 1: Enzymes and Enzyme Activity

What are enzymes?

Enzymes are globular proteins (biological catalysts). They speed up catalyse) chemical reactions in all living things, and allow them to occur more easily.

They are too small to be seen either when they are inside cells or after they have been released from them, for example in the digestive system.

Each particular enzyme has a unique, 3-dimensional shape shared by all its molecules. Within this shape there is an area called the active site where the chemical reactions occur. 

The active site makes an enzyme specific as it fits only one type of substrate.

How do enzymes work?

Enzymes work by 2 mechanisms:

1. The Lock and Key Model 

    --The enzyme is like a lock with a specific shape into which the key (substrate) fits.

    --Enzymes are usually larger than the substrates that they act on.

     --Once formed, the products cannot fit into the active site and are thus released, leaving the site free.

Click the link to see: the lock and key model in action

2. Induce Fit Model

     --The active site is not rigid and there is no exact fit, instead it can be modified as the substrate interacts with it.

      --The active site is moulded into the shape of the substrate on contact, improving the fit (makes a tighter fit).

Click the link to see: the induce fit model in action

What do enzymes do?

Enzymes lowers the amount of energy required for a chemical reaction to take place. (This energy is called the activation energy.) This causes a reaction involving enzymes to speed up in other words it takes a shorter time for this reaction to form products.

Some enzymes help to break down large molecules. Others build up large molecules from small ones. While many others help turn one molecule into another.

Properties of Enzymes ?

• Enzymes are catalysts → speed up chemical reactions
• Reduce activation energy required to start a reaction between molecules
• Substrates (reactants) are converted into products
• Reaction may not take place in absence of enzymes (each enzyme has a specific catalytic action)
• Enzymes remain unchanged at the end of a reaction. [E + S → ES → P + E]
• Enzymes are specific 

Factors affecting enzyme activity

Enzyme activity is  how fast an enzyme is working and is also called the "Rate of Reaction". It is affected by the following factors Temperature, pH, substrate concentration and enzyme concentration.

Although they can do fantastic things they are sensitive and work best under specific conditions.

Each type of enzyme has its own specific optimum conditions under which it works best.

Enzymes work best when they have a high enough substrate concentration for the reaction they catalyse. If too little substrate is available the rate of the reaction is slowed and cannot increase any further.

Sometimes, if too much product accumulates, the reaction can also be slowed down. So it is important that the product is removed.

The pH must be correct for each enzyme. If the conditions are too alkaline or acidic then the activity of the enzyme is affected (it slows down). This happens because the enzyme's shape, especially the active site, is changed. It is denatured, and cannot hold the substrate molecule.

Graph of enzyme activity verses temperature

As the temperature rises, reacting molecules have more and more kinetic energy. This increases the chances of a successful collision and so the rate increases. There is a certain temperature at which an enzyme's catalytic activity is at its greatest (see graph above). This optimal temperature is usually around human body temperature (37.5 oC) for the enzymes in human cells.

Above this temperature the enzyme structure begins to break down (denature) since at higher temperatures intra- and intermolecular bonds are broken as the enzyme molecules gain even more kinetic energy. At very low temperature enzymes are inactive.

Concentration of enzyme and substrate

Graph of enzyme activity verses enzyme concentration           Graph of enzyme activity verses substrate concentration

           

The rate of an enzyme-catalysed reaction depends on the concentrations of enzyme and substrate. As the concentration of either is increased the rate of reaction increases (see graphs).

For a given enzyme concentration, the rate of reaction increases with increasing substrate concentration up to a point, above which any further increase in substrate concentration produces no significant change in reaction rate. This is because the active sites of the enzyme molecules at any given moment are virtually saturated (occupied) with substrate. The enzyme/substrate complex has to dissociate before the active sites are free to accommodate more substrate. (See graph above on the right)

Provided that the substrate concentration is high and that temperature and pH are kept constant, the rate of reaction is proportional to the enzyme concentration. (See graph above on the left).

Inhibition of Enzyme Activity

Some substances reduce or even stop the catalytic activity of enzymes in biochemical reactions. They block or distort the active site. These chemicals are called inhibitors, because they inhibit reaction.

Inhibitors that occupy the active site and prevent a substrate molecule from binding to the enzyme are said to be active site-directed (or competitive, as they 'compete' with the substrate for the active site).

Inhibitors that attach to other parts of the enzyme molecule, perhaps distorting its shape, are said to be non-active site-directed (or non competitive).

CLICK HERE FOR ANIMATION: see for yourself how changing factors affect enzyme activity

• All enzymes are globular proteins and round in shape
• They have the suffix "-ase"
• Intracellular enzymes are found inside the cell
• Extracellular enzymes act outside the cell (e.g. digestive enzymes)
• Enzymes are catalysts → speed up chemical reactions
  • Reduce activation energy required to start a reaction between molecules
  • Substrates (reactants) are converted into products
  • Reaction may not take place in absence of enzymes (each enzyme has a specific catalytic action)
  • Enzymes catalyse a reaction at max. rate at an optimum state
• Induced fit theory
  • Enzyme's shape changes when substrate binds to active site
  • Amino acids are moulded into a precise form to perform catalytic reaction effectively
  • Enzyme wraps around substrate to distort it
  • Forms an enzyme-substrate complex → fast reaction
  • E + S → ES → P + E
• Enzyme is not used up in the reaction (unlike substrates)

Changes in pH

• Affect attraction between substrate and enzyme and therefore efficiency of conversion process
• Ionic bonds can break and change shape / enzyme is denatured
• Charges on amino acids can change, ES complex cannot form
• Optimum pH
  • pH 7 for intracellular enzymes
  • Acidic range (pH 1-6) in the stomach for digestive enzymes (pepsin)
  • Alkaline range (pH 8-14) in oral cavities (amylase)
• pH measures the conc. of H+ ions - higher conc. will give a lower pH

Enzyme Conc. is proportional to rate of reaction, provided other conditions are constant. Straight line
Substrate Conc. is proportional to rate of reaction until there are more substrates than enzymes present. Curve becomes constant.

Increased Temperature

• Increases speed of molecular movement → chances of molecular collisions → more ES complexes
• At 0-42 °C rate of reaction is proportional to temp
• Enzymes have optimum temp. for their action (varies between different enzymes)
• Above ≈42°C, enzyme is denatured due to heavy vibration that break -H bonds
  • Shape is changed / active site can't be used anymore

Decreased Temperature

• Enzymes become less and less active, due to reductions in speed of molecular movement
• Below freezing point
  • Inactivated, not denatured
  • Regain their function when returning to normal temperature
• Thermophilic: heat-loving
• Hyperthermophilic: organisms are not able to grow below +70°C
• Psychrophiles: cold-loving

Inhibitors

• Slow down rate of reaction of enzyme when necessary (e.g. when temp is too high)
• Molecule present in highest conc. is most likely to form an ES-complex
• Competitive Inhibitors
  • Compete with substrate for active site
  • Shape similar to substrates / prevents access when bonded
  • Can slow down a metabolic pathway
• [EXAMPLE] Methanol Poisoning
  • Methanol CH3OH is a competitive inhibitor
  • CH3OH can bind to dehydrogenase whose true substrate is C2H5OH
  • A person who has accidentally swallowed methanol is treated by being given large doses of C2H5OH
  • C2H5OH competes with CH3OH for the active site
• Non-competitive Inhibitors
  • Chemical does not have to resemble the substrate
  • Binds to enzyme other than at active site
  • This changes the enzyme's active site and prevents access to it
• Irreversible Inhibition
• Chemical permanently binds to the enzyme or massively denatures the enzyme
• Nerve gas permanently blocks pathways involved in nerve message transmission, resulting in death
• Penicillin, the first of "wonder drug" antibiotics, permanently blocks pathways certain bacteria use to assemble their cell wall component (peptidoglycan)

End-product inhibition

• Metabolic reactions are multi-stepped, each controlled by a single enzyme
• End-products accumulate within the cell and stop the reaction when sufficient product is made
• This is achieved by non-competitive inhibition by the end-product
• The enzyme early in the reaction pathway is inhibited by the end-product

The metabolic pathway contains a series of individual chemical reactions that combine to perform one or more important functions. The product of one reaction in a pathway serves as the substrate for the following reaction.

Curves for reaction rates against substrate concentrations & How to read them

This graph is showing how substrate concentration affects the rate of reaction which is also the speed or velocity of the reaction. The maximum velocity is called Vmax.



The graph levels off at a maximum reaction rate of Vmax. This happens when all the enzyme molecules are working as fast as they can. Once that happens, increasing the concentration of the substrate can't make the reaction go any faster.

What happens to the graph in the presence of a competitive inhibitor?


At a relatively low substrate concentration, the rate of the reaction will be less in the presence of a competitive inhibitor. The competitive inhibitor is just getting in the way of the substrate by attaching itself to some of the active sites.

However, as the substrate concentration increases, the substrate out-competes the inhibitor. If there is a lot more substrate than inhibitor, the chances are far higher that a substrate molecule will hit an active site than an inhibitor molecule will.

That means that at a high enough substrate concentration, the maximum reaction rate will again be Vmax.



What happens to the graph in the presence of a non-competitive inhibitor?


This is quite different.

Once a non-competitive inhibitor has attached itself to the enzyme, that particular enzyme molecule won't work any more. The attachment may be reversible, but even if it is, there will be a proportion of the enzyme molecules which are out of action at any one time.

That means that however much you may increase the concentration of the substrate, you will never reach the original Vmax.

So a graph involving a non-competitive inhibitor looks like this:



There is now a new Vmax, lower than the one where there was no inhibitor present.

Combining these two graphs



In order to get the full mark for the non-competitive line, it had to start off more steeply than the other one, and then it may or may not cross - as I have shown in this diagram. This is so because "The initial rate of a non-competitively inhibited reaction could be greater or less than that of a competitively inhibited reaction. If greater, the curves will cross; if less, they won't cross.”