Pseudomonas aeruginosa PilY1 Binds Integrin in an RGD- and Calcium-Dependent Manner

PilY1 is a type IV pilus (tfp)-associated protein from the opportunistic pathogen Pseudomonas aeruginosa that shares functional similarity with related proteins in infectious Neisseria and Kingella species. Previous data have shown that PilY1 acts as a calcium-dependent pilus biogenesis factor necessary for twitching motility with a specific calcium binding site located at amino acids 850–859 in the 1,163 residue protein. In addition to motility, PilY1 is also thought to play an important role in the adhesion of P. aeruginosa tfp to host epithelial cells. Here, we show that PilY1 contains an integrin binding arginine-glycine-aspartic acid (RGD) motif located at residues 619–621 in the PilY1 from the PAK strain of P. aeruginosa; this motif is conserved in the PilY1s from the other P. aeruginosa strains of known sequence. We demonstrate that purified PilY1 binds integrin in vitro in an RGD-dependent manner. Furthermore, we identify a second calcium binding site (amino acids 600–608) located ten residues upstream of the RGD. Eliminating calcium binding from this site using a D608A mutation abolished integrin binding; in contrast, a calcium binding mimic (D608K) preserved integrin binding. Finally, we show that the previously established PilY1 calcium binding site at 851–859 also impacts the protein's association with integrin. Taken together, these data indicate that PilY1 binds to integrin in an RGD- and calcium-dependent manner in vitro. As such, P. aeruginosa may employ these interactions to mediate host epithelial cell binding in vivo

Motor unit characteristics after selective nerve transfers

Selective nerve transfers are used in biological and bionic extremity reconstruction to restore and improve extremity function. Here, peripheral nerves are rerouted to various target muscles, and thereby the structural composition of motor units is surgically altered. Previous studies have shown a high success rate of successful reinnervation of above 90% after these nerve transfers. In targeted muscle reinnervation, nerve transfers are applied to reroute amputated nerves to more proximal muscles in the stump and thereby increase the number of prosthetic control signals. Because donor nerves physiologically supply multiple muscles but are transferred to a single target muscle, the innervation ratio between donor and recipient is substantially altered. This changes the characteristics of the motor unit of the target muscles that we extensively investigated in a novel nerve transfer animal model. In this chapter, we illustrate this model, the effect of nerve transfers on motor unit physiology, as well as the implications on improving the interface between man and machine in prosthetic extremity reconstruction. In addition, first results on the effect of targeted muscle reinnervation on human motor unit physiology are described

Role of troponin T and AMP deaminase in the modulation of skeletal muscle contraction

In fast muscle, isoforms of troponin T (TnT) contain an N-terminal hypervariable region that does not bind any protein of the thin filament. The N-terminal domain of TnT is removed by calpain during stress conditions and so could modulate the role of TnT in the regulation of contraction by affecting the TnT-binding affinity for tropomyosin (Tm) depending on the sequence and charge within the domain. During skeletal muscle contraction, the myokinase reaction is displaced by AMP deaminase (AMPD), an allosteric metalloenzyme, toward the formation of ATP. An unrestrained AMPD activity follows the proteolytic cleavage of the enzyme in vivo that releases a 97 aa N-terminal fragment, removing the inhibition exerted by the binding of ATP to a zinc site in the N-terminal region. Rabbit fast TnT or its phosphorylated 50-aa residue N-terminal peptide restores in AMPD the inhibition by ATP, removed in vitro by the release of a 95 aa N-terminal fragment by trypsin. Since the N-terminal region of fast rabbit TnT contains a putative zinc-binding motif, it can be inferred that TnT mimics the regulatory action exerted in native AMPD by the N-terminal domain that holds the enzyme in a less active conformation due to the presence of a zinc ion connecting the N-terminal and C-terminal regions. Together with evidence that AMPD is localized on the myofibril, the data reported in this review on the interactions between AMPD and TnT strongly suggest that these proteins mutually combine to fine-tune the regulation of muscle contraction in fast muscle