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Lipoxygenases (LOXs) are a family of metalloenzymes that oxidize polyunsaturated fatty acids producing cell-signaling hydroperoxides. Fungal LOXs have drawn interest because of their roles in plant and animal pathogenesis. A new subfamily of annotated fungal LOXs has been predicted. One of its unique structural features is the presence of a cysteine amino acid encoded at the invariant leucine clamp. Herein, we isolate three representatives of this LOX subfamily from recombinant expressions in both yeast and bacterial cultures. Metal analysis indicates that the proteins accommodate a mononuclear manganese ion center, similar to other eukaryotic LOXs, but have nominal LOX activity. The functional consequence of the non-conservative mutation is further explored using a Leu-to-Cys (L546C) variant of soybean lipoxygenase, a model plant orthologue. While this L546C variant has comparable structural integrity and metal content to the native enzyme, the variant is associated with a 50-fold decrease in the first-order rate constant. The presence of cysteine at 546, compared to leucine, alanine, or serine, also results in a distinctive kinetic lag phase and product inhibition. The collective data highlight that Cys encoded at the Leu clamp is detrimental to LOX activity. Potential biological functions of these annotated fungal LOXs are discussed. 

Fibrin forms the structural scaffold of blood clots and has great potential for biomaterial applications. Creating recombinant expression systems of fibrinogen, fibrin’s soluble precursor, would advance the ability to construct mutational libraries that would enable structure–function studies of fibrinogen and expand the utility of fibrin as a biomaterial. Despite these needs, recombinant fibrinogen expression systems, thus far, have relied on the time-consuming creation of stable cell lines. Here we present tests of a transient fibrinogen expression system that can rapidly generate yields of 8–12 mg/L using suspension HEK Expi293TM cells. We report results from two different plasmid systems encoding the fibrinogen cDNAs and two different transfection reagents. In addition, we describe a novel, affinity-based approach to purifying fibrinogen from complex media such as human plasma. We show that using a high-affinity peptide which mimics fibrin’s knob ‘A’ sequence enables the purification of 50–75% of fibrinogen present in plasma. Having robust expression and purification systems of fibrinogen will enable future studies of basic fibrin(ogen) biology, while paving the way for the ubiquitous use of fibrin as a biomaterial. 

Fluorinated 5-hydroxytryptophans (F n -5HOWs) were synthesized in gram scale quantities and incorporated into a β-hairpin peptide and the protein azurin. The redox-active F n -5HOWs exhibit unique radical spectroscopic signatures that expand the function of 5HOW as probes for biological electron transfer. 

Previous comparative kinetic isotope effects have inferred an allosteric site for fatty acids and their derivatives that modulates substrate selectivity in 15‐lipoxygenases. Hydrogen–deuterium exchange also previously revealed regionally defined enhanced protein flexibility, centred at helix α2 – a gate to the substrate entrance. Direct evidence for allosteric binding and a complete understanding of its mechanism remains elusive. In this study, we examine the binding thermodynamics of the fatty acid mimic, oleyl sulfate (OS), with the monomeric model plant 15‐LOX, soybean lipoxygenase (SLO), using isothermal titration calorimetry. Dynamic light scattering and differential scanning calorimetry rule out OS‐induced oligomerization or structural changes. These data provide evidence that the fatty acid allosteric regulation of SLO is controlled by the dynamics of helix α2.