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Humans are exposed to a plethora of microorganisms that reside on outer and inner body surfaces. These are collectively referred to as the human microbiome. The evolutionary relationship between humans and their microbiome is very complex. It is now widely accepted that these microorganisms are not just passive spectators but play an important role in health. The presence or absence of certain microbes is also linked to various diseases, including inflammatory bowel disease, cardiovascular disease, obesity, cancer, and allergies.
Allergies are several conditions caused by a misguided immune response to foreign antigens that are typically harmless. Common allergic diseases include atopic dermatitis (AD), allergic asthma, hay fever, and anaphylaxis. The incidences of allergic diseases are continuously rising, with up to 40% of the human population thought to be sensitised to environmental antigens. This increased incidence is not simply the result of societies becoming more aware and better at diagnosing these diseases. It is believed that the increases in allergies and sensitisation have environmental causes and are related to Western lifestyles. It is known that the rate of allergies is less frequent in developing countries. They are also more likely to occur in urban than rural areas. The prevailing view of the involvement of bacteria in allergies is described by the hygiene hypothesis. The hypothesis claims that decreased exposure to diverse microbial communities early in life increases the risk of developing allergic diseases. There are numerous examples to support this claim. For example, children born and raised in close contact to farm animals or in the presence of pets, and who are thus in direct and constant contact with a complex microbial environment, are protected from allergic diseases. On the other hand, colonisation or infection with certain bacteria increases allergic disease risks. This seems to contradict the hygiene hypothesis.
It appears that the members of the microbiome have different effects on allergy, and the hygiene hypothesis may not apply to every player in the complex microbial diversity that humans are in contact with. Therefore, a better understanding of the host bacterial interaction is required on the level of bacterial species.
This work studies the interplay between bacteria and the immune system to identify and characterise bacterial components with allergenic properties. In this quest, Staphylococcus aureus (S. aureus) and Staphylococcus epidermidis (S. epidermidis) were investigated for their allergenic properties and involvement in different allergic diseases. In the case of S. aureus, evidence is presented on allergic implications for two different components; serine protease-like proteins (Spls) and superantigens (SAg). Furthermore, experimental support is provided on the allergenic properties of the extracellular serine protease (Esp) from S. epidermidis. We argue that stimulating allergic reactions by staphylococci is an immune evasion mechanism that increases the survival chances of the bacteria within the host.
In chapter 1, an introduction is given to both S. aureus and S. epidermidis and their interactions with the immune system. Also, the bacterial components with allergenic properties and allergic diseases with known bacterial involvement are presented. Finally, the question of why bacteria cause allergy is discussed.
Chapter 2 describes allergic reactions to the Spls of S. aureus in a cohort of cystic fibrosis patients. Chapter 3 focuses on the SAgs of S. aureus. SAgs were discovered more than 30 years ago, but their physiological function is still under discussion. In this chapter, the allergenic properties of SAgs and their possible immunological mechanisms are reviewed, and a possible link between SAgs and allergic diseases is discussed. In chapter 4, the focus shifts to S. epidermidis and its involvement in AD. The human immune response to the Esp from S. epidermidis is characterised in healthy and AD individuals. The allergenic properties of Esp imply a detrimental role of S. epidermidis in AD. Finally, chapter 5 summarises and discusses the results of this thesis. In this section, the pieces are put together, and attention is brought back to the question of why bacteria cause allergies.
Wound healing disorders frequently occur due to biofilm formation on wound surfaces requiring conscientious wound hygiene. Often, the application of conventional liquid antiseptics is not sufficient and sustainable as (1) the borders and the surrounding of chronic wounds frequently consist of sclerotic skin, impeding an effectual penetration of these products, and (2) the hair follicles representing the reservoir for bacterial recolonization of skin surfaces are not affected. Recently, it has been reported that tissue-tolerable plasma (TTP), which is used at a temperature range between 35 and 45°C, likewise has disinfecting properties. In the present study, the effectivity of TTP and a standard liquid antiseptic was compared in vitro on porcine skin. The results revealed that TTP was able to reduce the bacterial load by 94%, although the application of the liquid antiseptic remained superior as it reduced the bacteria by almost 99%. For in vivo application, however, TTP offers several advantages. On the one hand, TTP enables the treatment of sclerotic skin as well, and on the other hand, a sustainable disinfection can be realized as, obviously, also the follicular reservoir is affected by TTP.