Understanding the Mechanism of Short-Range Electron TransferUsing an Immobilized Cupredoxin

The hydrophobic patch of azurin (AZ)from Pseudomonas aeruginosa is an important recognitionsurface for electron transfer (ET) reactions. The influenceof changing the size of this region, by mutating the Cterminalcopper-binding loop, on the ET reactivity of AZadsorbed on gold electrodes modified with alkanethiol selfassembledmonolayers (SAMs) has been studied. Thedistance-dependence of ET kinetics measured by cyclicvoltammetry using SAMs of variable chain length,demonstrates that the activation barrier for short-rangeET is dominated by the dynamics of molecular rearrangementsaccompanying ET at the AZ-SAM interface. Theseinclude internal electric field-dependent low-amplitudeprotein motions and the reorganization of interfacial watermolecules, but not protein reorientation. Interfacialmolecular dynamics also control the kinetics of shortrangeET for electrostatically and covalently immobilizedcytochrome c. This mechanism therefore may be utilizedfor short-distance ET irrespective of the type of metalcenter, the surface electrostatic potential, and the nature ofthe protein−SAM interaction

Structural and biological studies on bacterial nitric oxide synthase inhibitors

Nitric oxide (NO) produced by bacterial NOS functions as a cytoprotective agent against oxidative stress in Staphylococcus aureus, Bacillus anthracis, and Bacillus subtilis. The screening of several NOS-selective inhibitors uncovered two inhibitors with potential antimicrobial properties. These two compounds impede the growth of B. subtilis under oxidative stress, and crystal structures show that each compound exhibits a unique binding mode. Both compounds serve as excellent leads for the future development of antimicrobials against bacterial NOS-containing bacteria

Bacillus anthracis-derived nitric oxide is essential for pathogen virulence and survival in macrophages

Phagocytes generate nitric oxide (NO) and other reactive oxygen and nitrogen species in large quantities to combat infecting bacteria. Here, we report the surprising observation that in vivo survival of a notorious pathogen—Bacillus anthracis—critically depends on its own NO-synthase (bNOS) activity. Anthrax spores (Sterne strain) deficient in bNOS lose their virulence in an A/J mouse model of systemic infection and exhibit severely compromised survival when germinating within macrophages. The mechanism underlying bNOS-dependent resistance to macrophage killing relies on NO-mediated activation of bacterial catalase and suppression of the damaging Fenton reaction. Our results demonstrate that pathogenic bacteria use their own NO as a key defense against the immune oxidative burst, thereby establishing bNOS as an essential virulence factor. Thus, bNOS represents an attractive antimicrobial target for treatment of anthrax and other infectious diseases