The
cysteine protease cathepsin K is a target for the treatment
of diseases associated with high bone turnover. Cathepsin K is mainly
expressed in osteoclasts and responsible for the destruction of the
proteinaceous components of the bone matrix. We designed various fluorescent
activity-based probes (ABPs) and their precursors that bind to and
inactivate cathepsin K. ABP 25 exhibited extraordinary
potency (k
inac/K
i = 35,300 M–1s–1)
and selectivity for human cathepsin K. Crystal structures of cathepsin
K in complex with ABP 25 and its nonfluorescent precursor 21 were determined to characterize the binding mode of this
new type of acrylamide-based Michael acceptor with the particular
orientation of the dibenzylamine moiety to the primed subsite region.
The cyanine-5 containing probe 25 allowed for sensitive
detection of cathepsin K, selective visualization in complex proteomes,
and live cell imaging of a human osteosarcoma cell line, underlining
its applicability in a pathophysiological environment.
The hard tick Ixodes ricinus is a vector of Lyme disease and tick-borne encephalitis. Host blood protein digestion, essential for tick development and reproduction, occurs in tick midgut digestive cells driven by cathepsin proteases. Little is known about the regulation of the digestive proteolytic machinery of I. ricinus. Here we characterize a novel cystatin-type protease inhibitor, mialostatin, from the I. ricinus midgut. Blood feeding rapidly induced mialostatin expression in the gut, which continued after tick detachment. Recombinant mialostatin inhibited a number of I. ricinus digestive cysteine cathepsins, with the greatest potency observed against cathepsin L isoforms, with which it co-localized in midgut digestive cells. The crystal structure of mialostatin was determined at 1.55 Å to explain its unique inhibitory specificity. Finally, mialostatin effectively blocked in vitro proteolysis of blood proteins by midgut cysteine cathepsins. Mialostatin is likely to be involved in the regulation of gut-associated proteolytic pathways, making midgut cystatins promising targets for tick control strategies.
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