Kallikreins emerge as new regulators of viral infections.

Kallikrein-related peptidases (KLKs) or kallikreins have been linked to diverse (patho) physiological processes, such as the epidermal desquamation and inflammation, seminal clot liquefaction, neurodegeneration, and cancer. Recent mounting evidence suggests that KLKs also represent important regulators of viral infections. It is well-established that certain enveloped viruses, including influenza and coronaviruses, require proteolytic processing of their hemagglutinin or spike proteins, respectively, to infect host cells. Similarly, the capsid protein of the non-enveloped papillomavirus L1 should be proteolytically cleaved for viral uncoating. Consequently, extracellular or membrane-bound proteases of the host cells are instrumental for viral infections and represent potential targets for drug development. Here, we summarize how extracellular proteolysis mediated by the kallikreins is implicated in the process of influenza (and potentially coronavirus and papillomavirus) entry into host cells. Besides direct proteolytic activation of viruses, KLK5 and 12 promote viral entry indirectly through proteolytic cascade events, like the activation of thrombolytic enzymes that also can process hemagglutinin, while additional functions of KLKs in infection cannot be excluded. In the light of recent evidence, KLKs represent potential host targets for the development of new antivirals. Humanized animal models to validate their key functions in viral infections will be valuable.

Activity-Based Probes for Proteases Pave the Way to Theranostic Applications.

Proteases are important enzymes in health and disease. Their activities are regulated at multiple levels. In fact, proteases are synthesized as inactive proenzymes (zymogens) that are activated by proteolytic removal of their pro-peptide sequence and can remain active or their activity can be attenuated by complex formation with specific endogenous inhibitors or by limited proteolysis or degradation. Consequently, quite often, only a fraction of the protease molecules is in the active/functional form, thus, the abundance of a protease is not always linearly proportional to the (patho)physiological function(s). Therefore, assays to determine the active forms of proteases are needed, not only in research but also in molecular diagnosis and therapy. Activity-based probes (ABPs) are chemical entities that bind covalently to the active enzyme/protease. ABPs carry a detection tag to enable localization and quantification of specific enzymatic/proteolytic activities with applications in molecular imaging and diagnosis. Moreover, ABPs act as suicide inhibitors of proteases, which can be exploited for delineation of the functional role(s) of a given protease in (patho) biological context and as potential therapeutics. In this sense, ABPs represent new theranostic agents. We outline recent developments pertaining to ABPs for proteases with potential therapeutic applications, with the aim to highlight their importance in theranostics.

Physiological and pathological roles of kallikrein-related peptidases in the epidermis.

Identifying the function of kallikrein-related peptidases (KLKs) in the epidermis has elicited great interest over recent decades. KLKs comprise 15 serine proteases, and their activities are regulated by complex and fine-tuned mechanisms involving the proteolytic activation cascade, endogenous inhibitors, and environmental factors. When the balance is disrupted, excessive or insufficient protease activity can impair epidermal barrier homeostasis. KLKs are involved in various events, such as skin inflammation, wound healing, pruritus, anti-bacterial activity, and viral susceptibility. One of the primary roles of KLKs, mainly KLK5 and KLK7, is physiological desquamation. Both proteases are also involved in the development of inflammatory skin diseases with barrier abnormalities, e.g., Netherton syndrome and atopic dermatitis (AD). In Netherton syndrome, unrestricted activity of KLK5 due to loss of the major endogenous inhibitor, lymphoepithelial Kazal-type-related inhibitor (LEKTI), destroys the component molecules of corneodesmosome, leading to Th2 and Th17 inflammation. Meanwhile, the increased activity of KLK7 in the hyperkeratotic lesions of chronic AD is suppressed by upregulated LEKTI. The functions and implications of other KLKs including KLK6 and KLK8 in healthy and diseased skin such as psoriasis represent an exciting but relatively unexplored area. Clarifying the function of epidermal KLKs will enable development of disease-specific biomarkers and new therapeutic strategies.