Structure and substrate specificity of the pyrococcal coenzyme A disulfide reductases/polysulfide reductases (CoADR/Psr): implications for S(0)-based respiration and a sulfur-dependent antioxidant system in Pyrococcus.

FAD and NAD(P)H-dependent coenzyme A disulfide reductases/polysulfide reductases (CoADR/Psr) have been proposed to be important for the reduction of sulfur and disulfides in the sulfur-reducing anaerobic hyperthermophiles Pyrococcus horikoshii and Pyrococcus furiosus; however, the form(s) of sulfur that the enzyme actually reduces are not clear. Here we determined the structure for the FAD- and coenzyme A-containing holoenzyme from P. horikoshii to 2.7 Å resolution and characterized its substrate specificity. The enzyme is relatively promiscuous and reduces a range of disulfide, persulfide, and polysulfide compounds. These results indicate that the likely in vivo substrates are NAD(P)H and di-, poly-, and persulfide derivatives of coenzyme A, although polysulfide itself is also efficiently reduced. The role of the enzyme in the reduction of elemental sulfur (S(8)) in situ is not, however, ruled out by these results, and the possible roles of this substrate are discussed. During aerobic persulfide reduction, rapid recycling of the persulfide substrate was observed, which is proposed to occur via sulfide oxidation by O(2) and/or H(2)O(2). As expected, this reaction disappears under anaerobic conditions and may explain observations by others that CoADR is not essential for S(0) respiration in Pyrococcus or Thermococcus but appears to participate in oxidative defense in the presence of S(0). When compared to the homologous Npsr enzyme from Shewanella loihica PV-4 and homologous enzymes known to reduce CoA disulfide, the phCoADR structure shows a relatively restricted substrate channel leading into the sulfur-reducing side of the FAD isoalloxazine ring, suggesting how this enzyme class may select for specific disulfide substrates.

Identification of the copper-binding ligands of lysyl oxidase.

In order to identify the ligands coordinating with copper in lysyl oxidase, the enzyme was expressed in an E. coli expression system and active enzyme obtained after refolding in the presence of Cu(II). The five histidines found in the putative copper-binding region were sequentially mutated to alanines and the enzymatic activities of the resultant mutants were monitored, together with the copper content, the CD and fluorescence spectra, and the redox-cycling activity. The spectroscopic results show that in all cases the protein folded correctly but that the copper-content, enzymatic activity, and redox-cycling ability depended on the mutation. One mutant was fully functional, and two others completely lacked copper, the lysyl tyrosyl quinone (LTQ) cofactor, and activity. A fourth incorporated copper but lacked LTQ and enzymatic activity. The remaining mutant incorporated copper and had redox-cycling activity but no enzymatic activity. The results suggest that three of the five histidines in the putative copper-binding domain, H292, H294, H296, are the copper ligands and essential to the formation of LTQ. A fourth, H289, is not involved in LTQ formation or activity, while a fifth, H303, is suggested to be a general base in the catalytic mechanism.

Purification of high yields of catalytically active lysyl oxidase directly from Escherichia coli cell culture.

Lysyl oxidase is a highly insoluble enzyme requiring high concentrations of urea to solubilize. A method to obtain lysyl oxidase in high yields directly from an Escherichia coli culture without the need for refolding of inclusion bodies has been developed using nutrient rich media. pET21b was used to overexpress the lysyl oxidase enzyme and to introduce a C-terminal 6X histidine tag for purification. Lysyl oxidase yields of 10 mg of active and properly folded enzyme per liter of media have been obtained. Purification was achieved via affinity chromatography using a Ni-NTA column. Copper content was found to be 19%. LTQ cofactor formation in LOX is a self-processing event in the presence of copper. LTQ content was determined to be 24% based on reaction with phenylhydrazine to form a phenylhydrazone adduct. Quantification of this adduct was attained using the previously reported extinction coefficient of 15.4 mM(-1)cm(-1). LTQ presence was also verified by redox cycling. Specific enzymatic activity was measured to be 0.31 U/mg, one of the highest activities reported.

Lysyl oxidase in cancer inhibition and metastasis.

Lysyl oxidase is an extracellular matrix, copper - dependent amine oxidase that catalyzes a key enzymatic step in the crosslinking of collagen and elastin. The enzyme is synthesized as a propeptide that is cleaved by procollagen - C - proteinase into two distinct parts: the mature form and the LOX propeptide. The mature enzyme plays a key role in modifying the extracellular matrix and as a result has been implicated in playing a role in the formation of cancer "niches" where tumors will develop and eventually metastasize. On the other hand, the LOX propeptide has been shown to have an inhibitory effect in the development of cancer tumors. New approaches are being developed to test the use of small molecule inhibitors on LOX; however, the lack of a crystal structure has hampered these efforts as it is extremely difficult to design selective inhibitors without knowing what the target receptor looks like. In this mini review we discuss the lysyl oxidase enzyme and its role several types of cancers.

Identification of Histidine 303 as the Catalytic Base of Lysyl Oxidase via Site-Directed Mutagenesis.

Lysyl oxidase (LOX) is a copper-dependent amine oxidase enzyme that catalyzes the formation of crosslinkages of collagen and elastin in connective tissues by oxidative deamination of lysine. Using site-directed mutagenesis, Histidine 303 has been shown to be a key residue that acts as the necessary catalytic base for this enzyme to function properly. Histidine 303 was mutated to isoleucine to remove catalytic activity and to aspartate and glutamate, respectively, in order to provide alternate residues that could act as a general base that could maintain catalytic activity. Overexpression of the H303I mutant yielded 3.9 mg of enzyme per liter of media, the H303D mutant yielded 3.3 mg of enzyme per liter of media, and the H303E mutant yielded 3.0 mg/L of media. Overexpression of wildtype LOX yielded 4.5 mg/L of media, which is a slight improvement from previous yields. Total copper incorporation for H303I was calculated to be 68% and no copper was detected for the H303D and H303E mutants. As LOX requires the self-processed cofactor lysyl tyrosyl quinone (LTQ) for activity, total LTQ content was obtained by reacting the enzyme with phenylhydrazine and using the previously reported extinction coefficient of 15.4 mM/cm. LTQ content for the wildtype enzyme was determined to be 92%, for H303I the total LTQ content was determined to be 36%, and no LTQ was detected for the H303D and H303E mutants. No catalytic activity was detected for any mutants when compared to the wildtype which has a previously reported activity of 0.11 U/mg. Comparison of excitation-emission matrices (EEM) of each of the mutants as compared to the wildtype indicate that all the mutations cause a change in the internal environment of the enzyme, albeit to varying degrees, as evidenced by the observed shifts.

Overexpression of Soluble Recombinant Human Lysyl Oxidase by Using Solubility Tags: Effects on Activity and Solubility.

Lysyl oxidase is an important extracellular matrix enzyme that has not been fully characterized due to its low solubility. In order to circumvent the low solubility of this enzyme, three solubility tags (Nus-A, Thioredoxin (Trx), and Glutathione-S-Transferase (GST)) were engineered on the N-terminus of mature lysyl oxidase. Total enzyme yields were determined to be 1.5 mg for the Nus-A tagged enzyme (0.75 mg/L of media), 7.84 mg for the Trx tagged enzyme (3.92 mg/L of media), and 9.33 mg for the GST tagged enzyme (4.67 mg/L of media). Enzymatic activity was calculated to be 0.11 U/mg for the Nus-A tagged enzyme and 0.032 U/mg for the Trx tagged enzyme, and no enzymatic activity was detected for the GST tagged enzyme. All three solubility-tagged forms of the enzyme incorporated copper; however, the GST tagged enzyme appears to bind adventitious copper with greater affinity than the other two forms. The catalytic cofactor, lysyl tyrosyl quinone (LTQ), was determined to be 92% for the Nus-A and Trx tagged lysyl oxidase using the previously reported extinction coefficient of 15.4 mM(-1 )cm(-1). No LTQ was detected for the GST tagged lysyl oxidase. Given these data, it appears that Nus-A is the most suitable tag for obtaining soluble and active recombinant lysyl oxidase from E. coli culture.