Cross Reactions in Allergy
Cross Reactions in Allergy
For the rabbi’s doctor, discussing the results of the allergy tests with his patient, it was an embarrassing moment. An allergy is not inborn, it is an acquired reaction — a response by the immune system to a substance it has already encountered at least once. So, in theory, nobody can be allergic to a food they have never eaten.
Naturally enough, the rabbi had never eaten shellfish - like pork, it is a forbidden food in Judaism. But the nurse carrying out the skin-prick tests was unaware of this, and she had been told to test for all the common food allergens, so shrimp allergen was included. The test came up positive.
Fortunately, the rabbi had also been tested for inhaled allergens and had given a very strong positive reaction to house-dust mite. The likely explanation was clear: the rabbi had formed antibodies to a muscle protein of house-dust mite called tropomyosin, which is also found in shrimps and prawns. His antibodies against house-dust mite had cross-reacted with shrimp tropomyosin.
This does not mean that everyone who is allergic to house-dust mite will also react to shrimp. Firstly, they must have made antibodies to tropomyosin, rather than some other dust-mite antigen. Secondly, the antibodies must be recognising a particular feature of dust-mite tropomyosin that closely resembles (chemically speaking) a particular feature of shrimp tropomyosin.
The important point about antibodies is that, on the one hand, they achieve results by being specific for their antigen , but on the other, they do make mistakes. In the case of allergies, this is sometimes an added problem for patients but is rarely life threatening. More seriously, there are other conditions, like coeliac disease, where cross-reactions initiate attacks on the body’s own components, causing severe symptoms.
Antibodies make mistakes because they recognise antigens by homing in on tiny chemical markers, not by looking at the antigen as a whole (see box on p. 15). Although this is a nuisance for allergy sufferers, it can be a bonus in fighting diseases. For example,
Antigens and allergens
An antigen is anything which elicits an antibody reaction. Each antibody is specific for a particular antigen.
When they tend to cause allergies (by provoking IgE antibodies rather than other kinds of antibody - these antigens are called allergens. Something such as grass pollen is both an antigen (because it elicits an antibody reaction) and an allergen (because it often elicits IgE antibodies in those who are allergy-prone).
when viruses (such as those that cause influenza) revamp their outer coat proteins to evade the immune system, the chances are that some antibodies will still recognise them because a few of the original chemical markers persist.
Understanding cross-reactions
Many cross-reactions are between related species, and this makes sense in biological terms. The tropomyosin story is a good example - not only is tropomyosin found in dust mite and shrimps, but it also occurs in other crustacean shellfish, such as crabs and lobsters, in molluscan shellfish such as clams and oysters, and in insects. If one goes back over 300 million years, all these animals were just a twinkle in the eye of some primeval invertebrate, the common ancestor of them all.
Tropomyosin is one of those triumphs of the evolutionary process - a protein that reached near-perfection hundreds of millions of years ago, in the long-vanished ancestral species, and remains so good at its job that it has only been tinkered with by natural selection since then, never radically altered. In other words, because it works so well, it has been ‘conserved’ by the various animal groups descended from the shared ancestor. Although there are some differences between the tropomyosins from different descendants, the similarities are considerable.
Relatedness counts here. Shrimps and prawns are pretty closely related, as anyone can see by looking at them. Their tropomyosins are extremely similar, as are many other allergens. You’re unlikely to be allergic to prawn but not shrimp. The more distant the relationship, the more differences accumulate in the antigens, so a cross-reaction between dust mite and shrimp is far less likely (the rabbi was unlucky).
Another conserved protein, parvalbumin, explains why people who are allergic to one type of fish are usually allergic to all kinds of fish (in spite of the fact that fish belong to several different families which are only distantly related). Those allergic to hen’s eggs will probably be allergic to the eggs of all birds, because the primary allergens (e.g, ovalbumin) are so similar.
These conserved proteins produce cross-reactions across huge gulfs, in terms of zoological and botanical relationships. Far more easily understood are the cross-reactions between close cousins, such as dust mite and storage mites, wheat and rye, pine pollen and pine nuts, or ragweed and sunflower (both members of the daisy family).
Relatedness can be useful in explaining cross-reactions, but often fails when it comes to predicting them. Some related species do not show as many cross-reactions as one might expect. Peanuts are legumes, and highly allergenic. One would expect some peanut-allergic individuals to be allergic to other members of the legume family, such as peas, beans, carob and soya. In fact, although some patients give positive skin-prick tests, very few show actual symptoms when they eat these foods. Where symptoms do occur, they tend to be mild.
Paradoxically, those who are allergic to peanuts very often develop an allergy to tree nuts, and this usually spans several different kinds of tree nuts – yet botanically all these are very distant relatives. No tree nut is a legume and while walnuts and pecans belong to one plant family, almonds belong to another, hazelnuts to another, cashews to a fourth, and Brazils to a fifth different plant family. Here relatedness seems irrelevant, and it is shared lifestyle (surviving as a nut-producing plant) that is crucial.
A nut is just an over-sized seed that has to survive being buried in the soil – either by the plant itself (in the case of peanuts) or by a nut-eating animal such as a squirrel. All nuts must resist rotting in the soil until the following spring, and therefore contain powerful bactericidal and fungicidal compounds. Some of these may have chemical similarities that cause cross-reactions.
These functional ‘lifestyle’ allergens of nuts may be even more widely shared, with many seeds having something similar: recent research shows potentially cross-reacting allergens in wheat, rye, hazelnuts, sesame and poppy. It is interesting that many of those developing new allergies to sesame or poppy are already allergic to wheat and nuts.
A few cross-reactions seem to defy any explanation, such as that between house-dust mite and kiwi fruit – this appears to be just a case of chemical coincidence. Other cross-reactions can appear equally bizarre but actually have a biological basis, notably that between latex (as used in medical gloves) and various fruits and vegetables, principally chestnut, banana, avocado and kiwi fruit. This cross-reaction is due to a shared enzyme called a chitinase that protects plants against insect pests. Latex, of course, comes from the sap of the rubber tree: the tree needs such insect-protection and its sap is richly laced with chitinase.
How antibodies work - and why they make errors
Antibodies are catapult-shaped, with two antigen binding sites at the ends of the two arms. The other end of the antibody molecule – the handle of the catapult – is free to bind to cell receptors.
When an antibody binds to its antigen there is a ‘chemical handshake’: a very specific recognition event involving one of the antigen binding sites and a particular small site on the antigen molecule called the epitope. The two lock together. Different antibodies may recognise different epitopes.
The antibody is recognising its antigen, but it is as if we recognised other people by homing in on one small part of them, choosing a different feature for each person, whatever is most distinctive about them – the quirky right eyebrow, the hook in the nose, or the mole on the cheek. The antibody does not ‘look at’ the whole antigen molecule, but simply recognises a characteristic cluster of chemical features at the epitope.
Cross-reactions can occur so readily because an antigen molecule only has to resemble another molecule in one or two small areas (the epitopes) for a mistake to occur.
antigen antibody molecule binding sites
cell receptor antigen molecule
epitope
surface of immune cell
(e.g. a mast cell)