Marinomonas mediterranea MMB-1 transposon mutagenesis: isolation of a multipotent polyphenol oxidase mutant

Marinomonas mediterranea is a melanogenic marine bacterium expressing a multifunctional polyphenol oxidase (PPO) able to oxidize substrates characteristic for laccases and tyrosinases, as well as produce a classical tyrosinase. A new and quick method has been developed for screening laccase activity in culture plates to detect mutants differentially affected in this PPO activity. Transposon mutagenesis has been applied for the first time to M. mediterranea by using different minitransposons loaded in R6K-based suicide delivery vectors mobilizable by conjugation. Higher frequencies of insertions were obtained by using mini-Tn10 derivatives encoding kanamycin or gentamycin resistance. After applying this protocol, a multifunctional PPO-negative mutant was obtained. By using the antibiotic resistance cassette as a marker, flanking regions were cloned. Then the wild-type gene was amplified by PCR and was cloned and sequenced. This is the first report on cloning and sequencing of a gene encoding a prokaryotic enzyme with laccase activity. The deduced amino acid sequence shows the characteristic copper-binding sites of other blue copper proteins, including fungal laccases. In addition, it shows some extra copper-binding sites that might be related to its multipotent enzymatic capability.     

Location and catalytic characteristics of a multipotent bacterial polyphenol oxidase.

The melanogenic marine bacterium Marinomonas mediterranea contains a multipotent polyphenol oxidase (PPO) able to oxidize substrates characteristic for tyrosinase and laccase. Thus, this enzyme shows tyrosine hydroxylase activity and it catalyzes the oxidation of a wide variety of o-diphenol as well as o-methoxy-activated phenols. The study of its sensitivity to different inhibitors also revealed intermediate features between laccase and tyrosinase. It is similar to tyrosinases in its sensitivity to tropolone, but it resembles laccases in its resistance to cinnamic acid and phenylthiourea, and in its sensitivity to fluoride anion. This enzyme is mostly membrane-bound and can be solubilized either by non-ionic detergent or lipase treatments of the membrane. The expression of this enzymatic activity is growth-phase regulated, reaching a maximum in the stationary phase of bacterial growth, but L-tyrosine, Cu(II) ions, or 2,5-xylidine do not induce it. This enzyme can be separated from a second PPO form by gel permeation chromatography. The second PPO is located in the soluble fraction and shows a sodium dodecyl sulfate (SDS)-activated action on the characteristic substrates for tyrosinase, L-tyrosine, and L-dopa, but it does not show activity towards laccase-specific substrates. The involvement of the multipotent PPO in melanogenesis and its relationship with the SDS-activated form and with the alternative functions proposed for multicopper oxidases in other microorganisms are discussed.     

Dimethoxyphenol oxidase activity of different microbial blue multicopper proteins

2,6-Dimethoxyphenol is a versatile substrate for Pyricularia oryzae laccase, PpoA from Marinomonas mediterranea, phenoxazinone synthase from Streptomyces antibioticus and mammalian ceruloplasmin. In addition, in cellular extracts of microorganisms expressing other blue multicopper proteins with no enzymatic activity previously described, such as Escherichia coli (copper resistance CueO), Pseudomonas syringae and Xanthomonas campestris (copper resistance CopA), Bacillus subtilis (sporulation protein CotA) and Saccharomyces cerevisiae (iron transporter Fet3p), laccase activity is detected under appropriate conditions. This oxidase activity can be spectrophotometrically followed by the oxidation of 2,6-dimethoxyphenol. Specific staining after SDS-PAGE is also possible for some of these proteins. This detection assay can facilitate the study of the multiple functions that such proteins seem to carry out in a variety of microorganisms.     

Complete genome sequence of the melanogenic marine bacterium Marinomonas mediterranea type strain (MMB-1(T))

Marinomonas mediterranea MMB-1(T) Solano & Sanchez-Amat 1999 belongs to the family Oceanospirillaceae within the phylum Proteobacteria. This species is of interest because it is the only species described in the genus Marinomonas to date that can synthesize melanin pigments, which is mediated by the activity of a tyrosinase. M. mediterranea expresses other oxidases of biotechnological interest, such as a multicopper oxidase with laccase activity and a novel L-lysine-epsilon-oxidase. The 4,684,316 bp long genome harbors 4,228 protein-coding genes and 98 RNA genes and is a part of the Genomic Encyclopedia of Bacteria and Archaea project.     

梯棱羊肚菌AA1_2家族多铜氧化酶基因的异源表达与生化鉴定

典型的漆酶通常属于辅助活性酶第一家族第一亚族（auxiliary activity family 1 subfamily 1,简称AA1_1家族）,而AA1_2家族的多铜氧化酶通常拥有将二价铁氧化成三价铁的活性,部分AA1_2家族酶蛋白兼具漆酶活性。梯棱羊肚菌全基因组只有一个AA1_2家族酶基因,该基因编码的酶蛋白是否拥有漆酶功能尚未清楚。本研究主要从酶生化特性的角度,结合酶基因的表达规律,对该基因的功能进行初探。对该AA1_2家族基因在梯棱羊肚菌生长发育不同阶段的表达水平进行实时定量PCR检测;将该基因编码序列克隆到表达载体中在大肠杆菌中异源表达,层析获得纯化的酶蛋白,对酶蛋白的生化特性进行了鉴定。发现该AA1_2多铜氧化酶基因在外源营养袋和土壤中的营养菌丝里低表达,在菇原基和子实体中表达较活跃。异源表达获得纯化的酶蛋白分子量约64kDa,表现出亚铁氧化酶（EC 1.16.3.1）与漆酶（EC 1.10.3.2）双重活性。其亚铁氧化酶活性在pH 4最高,漆酶活性在pH 6最高。亚铁氧化酶活性与漆酶活性的最适温度均为30℃左右,在30℃温育16h后仍保留70%以上活性。亚铁氧化酶和漆酶活性受Mn ²⁺、Hg ²⁺和Pb ²⁺抑制。对蛋白质变性剂SDS、尿素的耐受性较强。本研究通过酶学证据证实了梯棱羊肚菌AA1_2家族多铜氧化酶基因编码的酶蛋白具有亚铁氧化酶-漆酶双重活性,系在子囊菌大型真菌中首次发现,为进一步研究铁元素代谢与漆酶活性在羊肚菌子实体形成与发育过程中的作用提供了启示。     

植物多铜氧化酶及其亚家族成员SKS蛋白

多铜氧化酶包括抗坏血酸氧化酶、漆酶、血浆铜蓝蛋白等多种类型,是植物体内非常重要的一类金属氧化酶,并在植物多种生理过程中发挥着举足轻重的作用。SKS(The skewed5simliar)蛋白是多铜氧化酶家族中一类缺乏铜离子连接所必需的组氨酸残基的特殊成员,由于缺失正常的多铜氧化酶酶活性中心,可能在植物发育中被赋予了新的功能。本文就多铜氧化酶铜离子连接位点、底物选择、演化过程以及植物SKS家族基因的研究进行了阐述。     

Location and Catalytic Characteristics of a Multipotent Bacterial Polyphenol Oxidase

The melanogenic marine bacterium Marinomonas mediterranea contains a multipotent polyphenol oxidase (PPO) able to oxidize substrates characteristic for tyrosinase and laccase. Thus, this enzyme shows tyrosine hydroxylase activity and it catalyzes the oxidation of a wide variety of o-diphenol as well as o-methoxy-activated phenols. The study of its sensitivity to different inhibitors also revealed intermediate features between laccase and tyrosinase. It is similar to tyrosinases in its sensitivity to tropolone, but it resembles laccases in its resistance to cinnamic acid and phenylthiourea, and in its sensitivity to fluoride anion. This enzyme is mostly membrane-bound and can be solubilized either by non-ionic detergent or lipase treatments of the membrane. The expression of this enzymatic activity is growth-phase regulated, reaching a maximum in the stationary phase of bacterial growth, but l -tyrosine, Cu(II) ions, or 2,5-xylidine do not induce it. This enzyme can be separated from a second PPO form by gel permeation chromatography. The second PPO is located in the soluble fraction and shows a sodium dodecyl sulfate (SDS)-activated action on the characteristic substrates for tyrosinase, l -tyrosine, and l -dopa, but it does not show activity towards laccase-specific substrates. The involvement of the multipotent PPO in melanogenesis and its relationship with the SDS-activated form and with the alternative functions proposed for multicopper oxidases in other microorganisms are discussed.     

Novel polyphenol oxidase mined from a metagenome expression library of bovine rumen: biochemical properties, structural analysis, and phylogenetic relationships

RL5, a gene coding for a novel polyphenol oxidase, was identified through activity screening of a metagenome expression library from bovine rumen microflora. Characterization of the recombinant protein produced in Escherichia coli revealed a multipotent capacity to oxidize a wide range of substrates (syringaldazine > 2,6-dimethoxyphenol > veratryl alcohol > guaiacol > tetramethylbenzidine > 4-methoxybenzyl alcohol > 2,2'-azino-bis(3-ethylbenzthiazoline-6-sulfonic acid) (ABTS) > phenol red) over an unusually broad range of pH from 3.5 to 9.0. Apparent Km and kcat values for ABTS, syringaldazine, and 2,6-dimetoxyphenol obtained from steady-state kinetic measurements performed at 40 degrees C, pH 4.5, yielded values of 26, 0.43, and 0.45 microm and 18, 660, and 1175 s(-1), respectively. The Km values for syringaldazine and 2,6-dimetoxyphenol are up to 5 times lower, and the kcat values up to 40 times higher, than values previously reported for this class of enzyme. RL5 is a 4-copper oxidase with oxidation potential values of 745, 400, and 500 mV versus normal hydrogen electrode for the T1, T2, and T3 copper sites. A three-dimensional model of RL5 and site-directed mutants were generated to identify the copper ligands. Bioinformatic analysis of the gene sequence and the sequences and contexts of neighboring genes suggested a tentative phylogenetic assignment to the genus Bacteroides. Kinetic, electrochemical, and EPR analyses provide unequivocal evidence that the hypothetical proteins from Bacteroides thetaiotaomicron and from E. coli, which are closely related to the deduced protein encoded by the RL5 gene, are also multicopper proteins with polyphenol oxidase activity. The present study shows that these three newly characterized enzymes form a new family of functional multicopper oxidases with laccase activity related to conserved hypothetical proteins harboring the domain of unknown function DUF152 and suggests that some other of these proteins may also be laccases.     

Redox potentials of the blue copper sites of bilirubin oxidases

The redox potentials of the multicopper redox enzyme bilirubin oxidase (BOD) from two organisms were determined by mediated and direct spectroelectrochemistry. The potential of the T1 site of BOD from the fungus Myrothecium verrucaria was close to 670 mV, whereas that from Trachyderma tsunodae was >650 mV vs. NHE. For the first time, direct electron transfer was observed between gold electrodes and BODs. The redox potentials of the T2 sites of both BODs were near 390 mV vs. NHE, consistent with previous finding for laccase and suggesting that the redox potentials of the T2 copper sites of most blue multicopper oxidases are similar, about 400 mV.     

Molecular cloning and nucleotide sequence of full-length cDNA for ascorbate oxidase from cultured pumpkin cells

A lambda gt11 cDNA expression library was constructed from size-fractionated poly(A)-rich RNA of cultured pumpkin cells. A full-length cDNA clone for ascorbate oxidase mRNA was selected from the library by screening with synthetic oligonucleotides designed from the amino-terminal sequence of ascorbate oxidase protein. The identity of the clone was confirmed by comparing the amino acid sequence deduced by nucleotide sequence analysis with that determined for the amino-terminal sequence of pumpkin ascorbate oxidase. The nucleotide sequence of the cDNA insert was found to contain an open reading frame of 579 codons corresponding to a signal peptide of 30 amino acids and the mature 549-residue ascorbate oxidase. Furthermore, it was found that the amino acid sequence deduced from the nucleotide sequence of the cDNA insert contained four potential N-glycosylation sites and copper-binding amino acid residues located in four regions where the sequence was identical or nearly identical to those of the other known blue multicopper oxidases Neurospora crassa laccase and human ceruloplasmin.     

Cloning and molecular characterization of a SDS-activated tyrosinase from Marinomonas mediterranea

The sequence of the tyrosinase gene cloned from Marinomonas mediterranea is reported. It is the second tyrosinase cloned from a Gram negative bacterium. Its size is higher than that of Gram positive tyrosinases from Streptomyces, and more similar to the eukaryotic enzymes. Its sequence shares the features of copper-binding sites found in all tyrosinases. Based in the comparison of tyrosinases from all types of organisms, an extension of the characteristic signatures existing at Prosite is proposed. This tyrosinase shares with some plant and amphibian tyrosinases a strong specific activation by submicellar concentrations of SDS. Intrinsic fluorescence and kinetic properties indicate that the activation is caused by an SDS-dependent conformational change that facilitates the substrate accessibility to the dicopper active site.     

A Cladistic Analysis of the Evolutionary Relationships of the Members of the Tyrosinase Gene Family Using Sequence Data

Recently, DNA sequence data have been published on tyrosinase and tyrosinase-related proteins (TRPs) in a wide variety of vertebrates ranging from Rana to Homo. These proteins are in turn members of a larger family of binuclear copper-binding proteins, which all contain two highly conserved copper-binding domains. This gene family also includes tyrosinases from fungi and bacteria as well as arthropodan and molluscan hemocyanins. Parsimony-based alignment and tree construction algorithms (Malign, vl.85 and PAUP, 3.1.1) were used to analyze the diversification of both the evolutionarily conserved copper-binding domains i6n copper-binding proteins in general as well as the diversification of the vertebrate tyrosinase gene family more specifically. These analyses show that the diversification of the vertebrate tyrosinase gene family minimally predates the diversification of vertebrates. Vertebrate tyrosinases proper first diverged from an ancestral tyrosinase-related protein (TRP) that then subsequently diverged to form tyrosinase-related protein-Is (TRP-1s) and tyrosinase-related protein-2s (TRP-2s).     

Redox potentials of the blue copper sites of bilirubin oxidases

The redox potentials of the multicopper redox enzyme bilirubin oxidase (BOD) from two organisms were determined by mediated and direct spectroelectrochemistry. The potential of the T1 site of BOD from the fungus Myrothecium verrucaria was close to 670 mV, whereas that from Trachyderma tsunodae was > 650 mV vs. NHE. For the first time, direct electron transfer was observed between gold electrodes and BODs. The redox potentials of the T2 sites of both BODs were near 390 mV vs. NHE, consistent with previous finding for laccase and suggesting that the redox potentials of the T2 copper sites of most blue multicopper oxidases are similar, about 400 mV.     

Enhanced archaeal laccase production in recombinant Escherichia coli by modification of N-terminal propeptide and twin arginine translocation motifs

Laccases are multicopper oxidases that couple the oxidation of phenolic polymers to the reduction of molecular oxygen. While an archaeal laccase has only recently been described (LccA from the culture broth of Haloferax volcanii), this enzyme appears promising for biotechnology applications based on its robust bilirubin oxidase and laccase activities as well as its ability to withstand prolonged exposure to extreme conditions. To further optimize LccA productivity and develop an option for LccA purification from whole cells, the encoding gene was modified through deletion of the twin-arginine translocation motif and N-terminal propeptide, and the modified genes were expressed in Escherichia coli. With this approach, LccA was readily purified (overall yield up to 54?%) from the soluble fraction of E. coli as a 74-kDa monomer with syringaldazine oxidizing activity as high as 33?U?mg(-1). LccA proteins prepared from H. volcanii culture broth and the soluble fraction of E. coli cells were compared by ICP-AES, EPR, DSC, CD, and UV-Vis spectroscopy and found to have a similar folding pattern with T (m) values and a rich β-sheet structure analogous to other multicopper oxidases. However, in contrast to the H. volcanii-purified LccA, which was loaded with copper, copper was not fully incorporated into the type-I Cu center of E. coli purified LccA, thus, providing insight into avenues for further optimization.     

A cloned ompR-like gene of Streptomyces lividans 66 suppresses defective melC1, a putative copper-transfer gene

Expression of tyrosinase in Streptomyces requires functional MelC1 protein, which is postulated to transfer copper to apotyrosinase. We have previously isolated a mutant of Streptomyces lividans, HT32, that phenotypically suppressed mutations in cloned melC1 (H.-C. Tseng and C. W. Chen, in preparation). Plasmid pLUS132, containing an ATG to ATA transition at the initiation codon of melC1, was used for cloning the suppressor gene from HT32. A 1687 bp suppressor DNA was isolated that contained two characteristic Streptomyces coding sequences: a 217-amino-acid open reading frame (cutR) and a truncated open reading frame (cutS) downstream. Subcloning analysis attributed the phenotypic suppression activity to the putative cutR gene from HT32. The putative CutR exhibited similarity to the response regulator OmpR of the osmoregulatory signal-transduction system in Escherichia coli. The truncated CutS resembled, to a lesser degree, the N-terminus of EnvZ, the histidine protein kinase counterpart of OmpR. DNA hybridizing to the cloned cutR-cutS sequence was detected in 16 other Streptomyces species. We postulate that the putative cutR-cutS operon regulates copper metabolism in Streptomyces.     

Characterization, molecular cloning, and differential expression analysis of laccase genes from the edible mushroom Lentinula edodes.

The effect of different substrates and various developmental stages (mycelium growth, primordium appearance, and fruiting-body formation) on laccase production in the edible mushroom Lentinula edodes was studied. The cap of the mature mushroom showed the highest laccase activity, and laccase activity was not stimulated by some well-known laccase inducers or sawdust. For our molecular studies, two genomic DNA sequences, representing allelic variants of the L. edodes lac1 gene, were isolated, and DNA sequence analysis demonstrated that lac1 encodes a putative polypeptide of 526 amino acids which is interrupted by 13 introns. The two allelic genes differ at 95 nucleotides, which results in seven amino acid differences in the encoded protein. The copper-binding domains found in other laccase enzymes are conserved in the L. edodes Lac1 proteins. A fragment of a second laccase gene (lac2) was also isolated, and competitive PCR showed that expression of lac1 and lac2 genes was different under various conditions. Our results suggest that laccases may play a role in the morphogenesis of the mushroom. To our knowledge, this is the first report on the cloning of genes involved in lignocellulose degradation in this economically important edible fungus.     

Direct electron transfer between copper-containing proteins and electrodes

The electrochemistry of some copper-containing proteins and enzymes, viz. azurin, galactose oxidase, tyrosinase (catechol oxidase), and the “blue” multicopper oxidases (ascorbate oxidase, bilirubin oxidase, ceruloplasmin, laccase) is reviewed and discussed in conjunction with their basic biochemical and structural characteristics. It is shown that long-range electron transfer between these enzymes and electrodes can be established, and the mechanistic schemes of the DET processes are proposed.     

Sequential reconstitution of copper sites in the multicopper oxidase CueO

CueO belongs to the family of multicopper oxidases which are characterized by the presence of multiple copper-binding sites with different structural and functional properties. These enzymes share the ability to couple the one-electron oxidation of substrate to reduction of oxygen to water by way of a functional unit composed of a mononuclear type 1 blue copper site, which is the entry site for electrons, and of a trinuclear copper cluster formed by type 2 and binuclear type 3 sites, where oxygen binding and reduction take place. The mechanism of copper incorporation in CueO has been investigated by optical and EPR spectroscopy. The results indicate unambiguously that the process is sequential, with type 1 copper being the first to be reconstituted, followed by type 2 and type 3 sites.     

Sensitive detection of sequence similarity using combinatorial pattern discovery: a challenging study of two distantly related protein families

We investigate the performance of combinatorial pattern discovery to detect remote sequence similarities in terms of both biological accuracy and computational efficiency for a pair of distantly related families, as a case study. The two families represent the cupredoxins and multicopper oxidases, both containing blue copper-binding domains. These families present a challenging case due to low sequence similarity, different local structure, and variable sequence conservation at their copper-binding active sites. In this study, we investigate a new approach for automatically identifying weak sequence similarities that is based on combinatorial pattern discovery. We compare its performance with a traditional, HMM-based scheme and obtain estimates for sensitivity and specificity of the two approaches. Our analysis suggests that pattern discovery methods can be substantially more sensitive in detecting remote protein relationships while at the same time guaranteeing high specificity.