PRACTICAL 3

Digestive enzymes, specificity and pH: Theory


3.1 Introduction

The aims of this practical are:


3.2 Theory and background

Proteins, enzymes and proteases

Proteins are large polymers of amino acids joined by peptide bonds. The peptide bond is an amide linkage joining the amino group of one amino acid to the carboxyl group of another (Fig. 1). There are 20 different amino acids found in proteins. They differ in the chemical nature of the "side chain", R. When several amino acids are joined in this way, the result is a peptide. When large numbers (e.g. 100’s) are joined together, the product is called a polypeptide. Proteins consist of one or more polypeptide chains held together, usually by non-covalent interactions. All polypeptides have an N-terminus (where the amino group of the end amino acid is unlinked) and a C-terminus (where the carboxyl group of the end amino acid is unlinked) (Fig. 1).

Figure 1: Peptides, peptide bonds and amino acids


Enzymes are biological catalysts that carry out all the reactions within a cell. Virtually all enzymes are proteins and the molecules upon which they act are known as their substrates.

Proteases are proteolytic enzymes i.e. enzymes that break the peptide bonds in other proteins and polypeptides to generate smaller peptide fragments and individual amino acids. They have numerous functions, one of which is to generate amino acids from protein in food for reutilisation. Pepsin is a protease that is secreted from the gastric mucosa into the stomach where the conditions are very acidic due to the presence of HCl in gastric secretions. Thus pepsin must be able to operate at very low pH (high acidity), something that is unusual for an enzyme. Once the gastric contents pass into the duodenum, the pH is increased above 7 into the slightly alkaline region by bicarbonate in the pancreatic secretions. These secretions also contain proteases such as trypsin, chymotrypsin and elastase which break down dietary proteins further. These proteases must be able to operate at alkaline pH.

 

Substrate specificity of proteases

Some proteases (exopeptidases) start at the end of a polypeptide chain and sequentially remove one amino acid at a time. Others (endopeptidases) break internal peptide bonds and initially produce peptide fragments. Trypsin, chymotrypsin and pepsin are all endopeptidases. Some endopeptidases are relatively non-specific and hydrolyse the peptide bond between any two of the 20 amino acids while others have a strong or absolute preference for certain amino acids. Thus, trypsin only cleaves the peptide bonds after (on the C-terminal side of) the basic amino acids lysine and arginine while chymotrypsin prefers cleaving after large hydrophobic amino acids such as phenylalanine, tyrosine and tryptophan, and also leucine and methionine (Fig. 2). This difference in specificity depends on the nature of the amino acid side chains present in the active site of the proteases that bind to their substrates. Pepsin is relatively non-specific although it does have a preference for cleaving after hydrophobic amino acids. In digestion, a combination of exopeptidases and endopeptidases with different substrate specificities will reduce most dietary proteins to individual amino acids.

Figure 2: Peptide bond cleavage specificity of trypsin and chymotrypsin.


 

Chromogenic reactions and colorimetry

"Chromogenic" means "producing colour". The intensity (or absorbance) of a solution of a coloured compound is directly proportional to the concentration of that compound. Thus, if a chemical or biochemical reaction produces a coloured product from colourless reactants, then the rate and extent of the reaction is very easily measured by measuring the absorbance of the reaction after a given time.

Absorbance is most simply measured in an instrument called a colorimeter. This simply consists of a white light source and a light detector and the coloured solution is placed between these to see how much light is absorbed by it. Sensitivity is increased by providing the range of colour wavelengths that the solution is known to absorb, e.g. red solutions absorb blue light (that's why they look red), so by placing a blue filter after the light source only blue light is provided to the solution, so a greater percentage of this incident light will be absorbed, thus increasing the sensitivity of detection. Greatest sensitivity and specificity is provided by spectrophotometers, which deliver single wavelengths of light (e.g. 410 nm or 650 nm) rather than wavelength ranges (blue, green etc).

Unfortunately, most reactions we would like to measure do not produce coloured products directly, so we have to adapt them. There are three main ways of doing this, and you will use two of these in this practical and see an example of the third in a later practical.

  1. The first is to replace the natural substrate with a synthetic one that will generate a colour when it undergoes the reaction. N-a-benzoyl-DL-arginine-p-nitroanilide (BAPNA) is a simple colourless ester which is recognised by trypsin as a substrate (trypsin is an esterase as well as a protease). Trypsin cleaves the bond between the arginine (remember the specificity of trypsin from above) and the p-nitroaniline to release free p-nitroaniline, which is yellow and easily measured in a colorimeter. Because of its different substrate specificity, chymotrypsin will not cleave BAPNA. On the other hand, chymotrypsin will cleave N-succinyl-L-phenylalanine p-nitroanilide (NSLPN) as it has a large hydrophobic amino acid (phenylalanine) in the correct position. As expected, trypsin does not cleave NSLPN so these two simple compounds can be used to demonstrate the different substrate specificities of these two proteases as well as being useful for measuring their pH optima (Experiments A, B and C).
  2. The second method is to treat the colourless product with a chemical that then produces a colour, i.e. if compound AB breaks down to A + B (both colourless), but B reacts with C to produce D (coloured), then the amount of D can be used to indicate the amount of B produced. Ninhydrin is a compound that reacts with amines to produce an intense blue-purple colour. All proteins have a single free amino group at their N-terminus, but when they are hydrolysed the total number of free amino groups increases as peptides and amino acids are produced. You will use the ninhydrin reaction to measure the hydrolysis of the protein haemoglobin by pepsin at different pH values (Experiment D).
  3. (Technical note: In addition to the free N-terminal amino group, most proteins have free amino groups on the side chain of the amino acid lysine. These also react with ninhydrin and can produce a high background colour. Hence, the haemoglobin substrate used has been pre-treated with formaldehyde to chemically block these extra amino groups. The slight blue background you will still see is due to the pepsin, which is of course a protein. It cannot be pre-treated as this would destroy its enzyme activity).

  4. The third method is to couple the first reaction to a second (and sometimes third), which finally produces a coloured product (more later).

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