Processing of laminin α chains generates peptides involved in wound healing and host defense.

Laminins play a fundamental role in basement membrane architecture and function in human skin. The C-terminal laminin G domain-like (LG) modules of laminin α chains are modified by proteolysis to generate LG1-3 and secreted LG4-5 tandem modules. In this study, we provide evidence that skin-derived cells process and secrete biologically active peptides from the LG4-5 module of the laminin α3, α4 and α5 chain in vitro and in vivo. We show enhanced expression and processing of the LG4-5 module of laminin α3 in keratinocytes after infection and in chronic wounds in which the level of expression and further processing of the LG4-5 module correlated with the speed of wound healing. Furthermore, bacterial or host-derived proteases promote processing of laminin α3 LG4-5. On a functional level, we show that LG4-5-derived peptides play a role in wound healing. Moreover, we demonstrate that LG4-derived peptides from the α3, α4 and α5 chains have broad antimicrobial activity and possess strong chemotactic activity to mononuclear cells. Thus, the data strongly suggest a novel multifunctional role for laminin LG4-5-derived peptides in human skin and its involvement in physiological processes and pathological conditions such as inflammation, chronic wounds and skin infection.

Peptides derived from the human laminin alpha4 and alpha5 chains exhibit antimicrobial activity.

Laminins are a family of heterotrimeric extracellular matrix glycoproteins in the basement membrane of different tissues and are composed of alpha, beta, and gamma chains. In mammals, five different alpha chains, three beta chains, and three gamma chains have been identified that assemble into 15 different laminins. Each alpha-chain possesses a C-terminal globular domain which can be subdivided into the five subdomains LG1-LG5. LG1-LG3 modules are connected to LG4-LG5 by a linker domain which is known to be sensitive to proteolytic processing. Here, we show that peptides derived from the human laminin alpha4 and alpha5 chain, exhibit a dose-dependent antimicrobial activity against gram-positive and gram-negative bacteria. Furthermore, we show that these peptides permeabilize the bacterial membrane and are able to bind to bacterial DNA. Interestingly, the ability to kill the microorganisms correlated with their ability to bind to heparin. These data suggest that extracellular matrix components are able to protect the respective tissues from invading pathogens and are part of the host defense response.

Dermcidin-derived peptides show a different mode of action than the cathelicidin LL-37 against Staphylococcus aureus.

Dermcidin (DCD) is an antimicrobial peptide which is constitutively expressed in eccrine sweat glands. By postsecretory proteolytic processing in sweat, the DCD protein gives rise to anionic and cationic DCD peptides with a broad spectrum of antimicrobial activity. Many antimicrobial peptides induce membrane permeabilization as part of their killing mechanism, which is accompanied by a loss of the bacterial membrane potential. In this study we show that there is a time-dependent bactericidal activity of anionic and cationic DCD-derived peptides which is followed by bacterial membrane depolarization. However, DCD-derived peptides do not induce pore formation in the membranes of gram-negative and gram-positive bacteria. This is in contrast to the mode of action of the cathelicidin LL-37. Interestingly, LL-37 as well as DCD-derived peptides inhibit bacterial macromolecular synthesis, especially RNA and protein synthesis, without binding to microbial DNA or RNA. Binding studies with components of the cell envelope of gram-positive and gram-negative bacteria and with model membranes indicated that DCD-derived peptides bind to the bacterial envelope but show only a weak binding to lipopolysaccharide (LPS) from gram-negative bacteria or to peptidoglycan, lipoteichoic acid, and wall teichoic acid, isolated from Staphylococcus aureus. In contrast, LL-37 binds strongly in a dose-dependent fashion to these components. Altogether, these data indicate that the mode of action of DCD-derived peptides is different from that of the cathelicidin LL-37 and that components of the bacterial cell envelope play a role in the antimicrobial activity of DCD.

The role of antimicrobial peptides in human skin and in skin infectious diseases.

Antimicrobial peptides or proteins (AMPs) represent an ancient and efficient innate defense mechanism which protects interfaces from infection with pathogenic microorganisms. In human skin AMPs are produced mainly by keratinocytes, neutrophils, sebocytes or sweat glands and are either expressed constitutively or after an inflammatory stimulus. In several human skin diseases there is an inverse correlation between severity of the disease and the level of AMP production. Skin lesions of patients with atopic dermatitis show a diminished expression of the beta-defensins and the cathelicidin LL-37. Furthermore, these patients have a reduced amount of the AMP dermcidin in their sweat which correlates with an impaired innate defense of human skin in vivo. In addition, decreased levels of AMPs are associated with burns and chronic wounds. In contrast, overexpression of AMPs can lead to increased protection against skin infections as seen in patients with psoriasis and rosacea, inflammatory skin-diseases which rarely result in superinfection. In other skin diseases, e.g. in patients with acne vulgaris, increased levels of AMPs are often found in inflamed or infected skin areas indicating a role of these peptides in the protection from infection. These data indicate that AMPs have a therapeutical potential as topical anti-infectives in several skin diseases. The broad spectrum of antimicrobial activity, the low incidence of bacterial resistance and their function as immunomodulatory agents are attractive features of AMPs for their clinical use.

An in vitro assay to study the transcriptional response during adherence of Candida albicans to different human epithelia.

Adhesion to mammalian epithelia is one of the prerequisites that are essential to accomplish pathogenesis of Candida albicans in the mammalian host. In this context C. albicans is able to adhere to a plethora of different cell types providing different microenvironments for colonization. To study the response of C. albicans adhering to different surfaces on the transcriptional level we have established an in vitro adhesion assay exploiting confluent monolayers of the human colorectal carcinoma cell line Caco-2 or epidermoid vulvo-vaginal A-431 cells. Candida albicans very efficiently adheres to these epithelia growing as hyphae. Using whole-genome DNA microarrays comprising probes for almost 7000 predicted ORFs we found that transcriptional profiles of C. albicans adhering to Caco-2 or to A-431 cells, although very similar, still significantly differ from those of Candida cells adhering to plastic surfaces. Differences became even more obvious when comparing C. albicans cells either growing in an adherent manner or in suspension culture. Correspondingly, we found for several cell surface genes, including PRA1, PGA23, PGA7 and HWP1, an adhesion-dependent induction of transcription. Obviously, C. albicans is able to respond specifically to very subtle differences in the environment during adhesion to various growth substrates.