About 50,000 different protein molecules are recognized in the human body, the function of which is determined by their amino acid sequence. Through a whole series of reactions our body is able to autonomously synthesize the proteins it needs starting from the single amino acids contained in food. Since proteins are too large to be absorbed as such and transported into the circulation, some enzymes present in the lumen of the gastrointestinal tract intervene in their digestion by breaking them down into individual amino acids.
most of the proteins are completely reduced in the single amino acids. The digestion of these macromolecules begins in the stomach where the combined action of pepsinogen and hydrochloric acid leads to the formation of oligopeptides (short chains of amino acids formed by less than ten units).
Hydrochloric acid, in addition to transforming pepsinogen into pepsin, destroys a large part of the bacterial load, favors the absorption of iron and the synthesis of enteric juice, bile, bicarbonates and pancreatic enzymes. The secretion of the stomach is influenced by nerve factors (smell, taste of food and conditioning), mechanical (distension of the gastric walls), chemical (presence of oligopeptides) and hormonal (gastrin) factors.
The digestion of proteins is completed by intestinal proteases of pancreatic origin (poured into the duodenum) and produced by the membrane of the same intestine (placed on the brush border). For this reason, protein digestion is normal even after surgical removal of the stomach.
Proteases are divided into endoproteases (hydrolyze the peptide bonds inside proteins: chymotrypsin, elastase, trypsin) and exopeptidases (hydrolyze the terminal amino acid of the protein: carboxypeptidase, aminopeptidase, dipeptidase).
At the intestinal level, the digestion of proteins is completed and the single amino acids, dipeptides and tripeptides, can be absorbed and transported to the liver by specific carriers.
A small amount of protein present in food is not absorbed and is eliminated as such with the faeces (5%). Some peptides formed by more than three amino acids are absorbed by transcytosis and as such can represent a significant factor for the development of food allergies and intolerances.
Only in the newborn is it possible to absorb whole, undigested proteins. This phenomenon is fundamental for the absorption of antibodies transmitted through breast milk.
, in the transmission of nerve impulses, in the production of energy and as catalysts in many metabolic processes)
- Protein digestion is a demanding process that strains the body. Excessive protein intake therefore translates into unnecessary and dangerous stress on the liver and kidneys.
- Consuming large quantities of protein with the diet does not, in itself, promote weight loss or increase in muscle mass
- If this intake takes place in a high-calorie context, there will inevitably be an increase in adipose accumulations
- If a low-calorie and high-protein diet is followed, a part of the individual amino acids will be converted into glucose; the slimming effects will be good (increased thermogenesis and a sense of satiety) but in the long run the excessive protein intake will cause many problems for the organism (osteoporosis, decreased immune defenses, ketosis, gastrointestinal problems and dehydration).
- Protein (or peptide) hormones such as IGF-1 and growth hormone (somatotropin or GH) can only be taken in injectable form. If they were ingested, our body would treat them like any other protein molecule, breaking them down into individual amino acids or eliminating them with the feces (chains longer than 4 AA cannot be absorbed as such and need to be previously reduced into smaller chains).
- Taking large quantities of a single amino acid hinders the transport of other amino acids by saturation of the common carrier. Also for this reason it is rather optimistic to hope that the massive intake of a particular amino acid can favor muscle anabolism.
