芳香烃龙胆酸降解途径蛋白质组学的研究*

芳香烃是一类重要的环境污染物,微生物降解是其主要的处理方法。研究显示降解过程中产生保守型和诱导型的各一组同工酶。目前,仅有保守型的龙胆酸加双氧酶(GDOI)及其下游片段被克隆。产碱假单胞菌NC IB9867(P25X)的突变株--SNZ28 GDO I被打断,在龙胆酸诱导的情况下,该突变株仍能检测到龙胆酸加双氧酶活性。采用二维蛋白电泳分析突变株SNZ28在有和没有龙胆酸诱导条件下的蛋白质表达差异。电泳结果显示了两者存在有15个蛋白点的差异。通过MALD I-TOF和Q-TOF分析,其中的12个蛋白质点与数     

耐亚胺培南铜绿假单胞菌相关耐药基因的检测

目的对耐亚胺培南（IMP）的铜绿假单胞菌（IRPa）相关耐药基因进行检测。方法 2003年至2009年从临床标本中分离到（P.aeruginosa）共220株,采用三维试验筛选产β-内酰胺酶的铜绿假单胞菌,应用普通PCR和多重PCR分别检测碳青霉烯酶基因和质粒携带的C类头孢菌素酶（AmpC酶）耐药基因,应用荧光定量RT-PCR的方法检测oprD2基因的表达情况。结果共检出43株产β-内酰胺酶的菌株,其中产AmpC酶、超广谱β-内酰胺酶（ESBLs）、金属β-内酰胺酶（MBLs）和未知酶菌株的构成比分别58.14%（25/43）、18.60%（8/43）、4.65%（2/43）和16.28%（7/43）。74株耐亚胺培南的铜绿假单胞菌中,有2株菌携带IMP-9基因,1株菌携带DHA质粒型AmpC酶基因,其他碳青霉烯酶基因检测为阴性。40株菌株oprD2基因表达蛋白量降低,34株oprD2基因表达蛋白量正常。结论 oprD2基因的突变或蛋白表达量降低是IRPa对亚胺培南耐药的主要原因,AmpC酶可水解亚胺培南可能与铜绿假单胞菌对亚胺培南的耐药有一定的关系,而KPC-1酶和MBLs在铜绿假单胞菌对亚胺培南耐药机制中不是主要因素。     

黄孢原毛平革菌木素过氧化物酶类在天然木素降解中作用的研究

通过诱变得到十一株木素过氧化物酶酶活降低的黄孢原毛平革菌（Ｐｈａｎｅｒｏｃｈａｅｔｅｃｈｒｙｓｏｓｐｏｒｉｕｍ）突变株,用灰色理论分析了其木素过氧化物酶类的产生与木素降解能力间的相关性,并从中筛选到一株木素过氧化物酶缺陷、锰过氧化物酶酶活明显降低的突变株,其木素降解能力为原始菌株的８０％左右。该菌粗酶液作用于纤维素酶酶解杉木木素和天然褐腐木素,可产生小分子的木素降解产物,此反应不需Ｈ２Ｏ２参与。红外光谱分析表明粗酶液对木素的作用主要为氧化作用,因此推测此突变株粗酶液中含有不同于木素过氧化物酶和锰过氧化物酶的与木素氧化降解有关的酶类     

生理pH条件下精氨酸脱亚胺酶的分子改造研究

精氨酸脱亚胺酶（arginine deiminase,EC 3.5.3.6,ADI）因其可作为精氨酸营养缺陷型肿瘤细胞的靶向治疗药物而受到广泛关注. 目前,支原体来源的重组ADI处于肝癌和黑素瘤的三期临床研究阶段. 作为药用酶,当前报道的ADI在体内生理条件下普遍存在酶活低、半衰期短、底物亲和性弱等局限性.本研究结合随机突变及基于理性设计的定点突变两种方法,对研究室前期自主筛选得到的变形假单胞菌Pseudomonas plecoglossicida来源的ADI经一轮定向进化后所获优势突变株M314(A128T/H404R/I410L)进行分子改造.通过对随机突变法获得的1480个突变株进行96孔板高通量筛选,得到优良突变株M173(A128T/H404R/I410L/K272R);同时,基于同源序列比对及ADI蛋白三维结构同源建模,采用PyMOL软件理性预测和分析其活性中心及附近保守区域氨基酸位点对蛋白功能的影响,选择了6个位点D78E、L223I、P230I、S245D、A275N、R400M分别在M314的基础上进行定点突变,最终获得优势突变株M04(A128T/H404R/I410L/S245D). 通过对突变株的酶学性质以及动力学参数分析发现：生理pH值下,突变株M173的酶比活（12.32 U/mg）在M314（9.02 U/mg）的基础上提升3659%,Kcat/Km提高5236%;而突变株M04的最适pH由6.5升高至7.0,更接近体内生理pH,其比酶活（14.66 U/mg）较M314提升62.53 %,Kcat/Km提高了37.12%. 综上结果,本研究结合两种分子改造方法成功地对该ADI在生理pH条件下的酶活和酶学性质进行了改良,并为蛋白质的分子改造策略提供了理论基础和实验依据.     

木质素降解条件下黄孢原毛平革菌lip基因转录调控序列的筛选与鉴定

用DNA-蛋白质体外结合实验和凝胶迁移率变动分析技术筛选黄孢原毛平革菌（Phanerochaete chrysosporium）木质素过氧化物酶基因lipA、lipC、lipF的5′-端调控区内能与该菌在木质素降解条件下形成的蛋白特异结合的顺式作用元件。结果表明,来自lipC、lipF基因的5′-端片段LG2P3(396 bp)和 LG6S1-2（738 bp）能特异结合培养于Kirk低氮培养基中的菌丝体蛋白;而来自于lipF基因的5′-端的LG6S2 (226 bp) DNA片段能特异结合培养于天然冷杉木片中的菌丝体蛋白。对这些片段的DNA序列分析表明,它们均存在各种顺式作用元件,由此推测它们可能是被一些木质素过氧化物酶基因转录调控相关的蛋白质所结合的序列。     

分段DNA shuffling: 一种大分子海藻糖合酶有效的定向进化方法

[目的]红色亚栖热菌(Meiothermus ruber)海藻糖合酶(Trehalose synthase,M-TreS)将麦芽糖转化生成海藻糖只需一步反应,且具有很好的热稳定性及pH耐受性,是潜在的工业生产海藻糖的酶源.为了提高该酶的性能,有必要对其进行定向进化.[方法]M-TreS基因(M-treS)大小为2 889bp.该蛋白质分子本身具有很大的进化空间,但是却不宜进行全长基因Shuffling.分段DNA shuffling是为大分子蛋白质(基因≥2 000 bp)的进化而设计的一种方法.该方法分为三步:(1)用两对引物分别扩增目的基因的上游片段和下游片段;(2)上下游片段各自进行Shuffling; (3)利用重叠延伸PCR连接上下游突变群,建立完整基因的突变文库.[结果]结合易错PCR,通过该方法经一轮进化获得一株酶活力是野生型1.6倍、催化效率是野生型2倍的突变株.序列分析表明,该突变株共有6个位点发生了氨基酸的替代,其中一个来自易错突变,2个来自同源重组,3个为随机突变.[结论]分段DNA shuffling是进化大分子蛋白质的有效方法.     

一株多环芳烃降解菌的鉴定及GST基因克隆和序列分析

由石油污染土壤中分离到一株能以多环芳烃（菲、芴、萘）为唯一碳源的细菌,经形态观察、生理生化（BiologGN）和 G+C mol%分析,鉴定该菌为少动鞘氨醇单胞菌(Sphingomonas paucimobilis)。与16S rDNA序列同源性的比较进一步确证了鉴定结果。经菲诱导后的细菌谷胱甘肽S转移酶（Glutathione Stransferase, GST）酶活明显高于未诱导前,表明谷胱甘肽S转移酶可能与多环芳烃的降解有关。根据该酶基因的同源性序列设计引物,PCR扩增出编码谷胱甘肽S转移酶基因片段,进一步证实在该菌中有GST的存在。测序后基于编码GST的基因所进行的系统发育分析表明,该多环芳烃降解菌与其它多环芳烃降解菌在进化上亲缘关系较近。     

香港海鸥菌OsmC蛋白的原核表达、纯化及活性研究

[目的]原核表达纯化香港海鸥菌OsmC蛋白,并检测其抗氧化功能。[方法]通过PCR法扩增香港海鸥菌OsmC基因,将目的片段进行双酶切后连接到pET28a,构建重组质粒pET28a-OsmC并转化大肠杆菌,诱导OsmC蛋白表达,亲和层析纯化目的蛋白并利用氧化铁二甲酚橙实验检测其过氧化物酶活性。[结果]克隆得到全长基因,大小为441bp,编码147个氨基酸。得到重组表达质粒pET28a-OsmC,表达并纯化获得重组OsmC蛋白,OsmC蛋白能够降解H2O2。[结论]Osm C蛋白具有过氧化物酶活性,为研究香港海鸥菌的抗氧化机制奠定了基础。     

弗氏2a志贺菌htrA基因突变体的构建

目的:构建弗氏2a志贺菌2457T的htrA基因缺失突变株及HtrA酶失活突变株,以便进一步研究HtrA蛋白的功能。方法:用PCR扩增htrA基因上下游同源臂,构建含有kan基因的打靶片段,采用λ-Red重组系统对htrA基因进行缺失,用PCR进行验证;通过定点突变的方法构建HtrA酶失活突变株,并测序验证。结果与结论:构建了2457T htrA缺失突变株和2457T/htrAFSA酶失活突变株。     

草苷膦抗性新基因的克隆、序列分析及其蛋白高级结构预测

利用错误倾向PCR（error-prone PCR）突变技术,以可变盐单胞菌（Halomonas variabilis）HTG7的5-烯醇丙酮莽草酸-3-磷酸(EPSP)合酶基因为模板进行随机PCR扩增,得到目的基因片段（约1.35 kb）.将该基因片段与pACYC184载体连接后转化EPSP合酶缺陷型菌株大肠杆菌ER2799.利用功能互补筛选法得到了2株不具有草苷膦抗性的EPSP合酶阳性克隆突变株,记为Pmu1和Pmu2.序列分析表明,突变体Pum1的EPSP合酶编码区与突变前基因相比,核苷酸有2处发生突变,导致氨基酸残基1处发生了改变;突变体Pmu2的EPSP合酶编码区与突变前基因相比,核苷酸有5处发生突变,导致氨基酸残基2处发生了改变.对突变前后EPSP合酶进行比较预测发现,其三级结构及蛋白中心骨架是大致相同的,但突变前后氨基酸位点肽平面和Cα相连的N键之间形成的扭转角度存在一定的差别.这些结果表明,酶的功能主要由蛋白的构象决定,二肽链形成后肽平面和N键之间角度的变化,造成高级结构构象细微的差别,致使草苷膦抗性功能丢失.     

Proteome analysis of gentisate-induced response in Pseudomonas alcaligenes NCIB 9867

Pseudomonas alcaligenes NCIB 9867 (P25X wild-type) is capable of degrading aromatic hydrocarbons via the gentisate pathway. Biochemical characterization of P25X mutants indicated that it has isofunctional enzymes for the mono- and dioxygenase-catalyzed reactions. One set of the enzymes is constitutive whereas the other is strictly inducible. To date, only the gene encoding the constitutively-expressed gentisate dioxygenase had been cloned and characterized. A mutant strain of P25X, designated G56, which had the constitutive copy of the gentisate 1,2-dioxygenase gene interrupted by a streptomycin/spectinomycin resistance gene cassette, was found to express gentisate dioxygenase, but only when the cells were induced by gentisate. The proteome profiles of P. alcaligenes P25X and mutant G56 cells grown in the presence and absence of gentisate were compared after two-dimensional polyacrylamide gel electrophoresis. Eight distinctive protein spots (designated M1-M8) which were observed only in induced cells of strain G56 but absent in noninduced cells were further analyzed by matrix-assisted laser desorption/ionization-time of flight, quadrupole-TOF and N-terminal sequencing. Of the 15 proteins (including seven up-regulated) examined, 13 showed sequence similarities to proteins with assigned functions in other microorganisms. The identification of protein M5 which showed high homology to a gentisate dioxygenase from Ralstonia sp. U2 indicated the putative function of this protein being consistent with the inducible gentisate 1,2-dioxygenase in P. alcaligenes. In addition, the induction of stress proteins and other adaptation phenomena were also observed.     

Proteome investigation of the global regulatory role of sigma 54 in response to gentisate induction in Pseudomonas alcaligenes NCIMB 9867

Pseudomonas alcaligenes NCIMB 9867 (strain P25X) utilizes the gentisate pathway for the degradation of aromatic hydrocarbons. The gene encoding the alternative sigma (sigma) factor sigma(54), rpoN, was cloned from strain P25X and a rpoN knock-out strain, designated G54, was constructed by insertional inactivation with a kanamycin resistance gene cassette. The role of sigma(54) in the physiological response of P. alcaligenes P25X to gentisate induction was assessed by comparing the global protein expression profiles of the wild-type P25X with the rpoN mutant strain G54. Analysis of two-dimensional polyacrylamide gel electrophoresis gels showed that 39 out of 355 prominent protein spots exhibited differential expression as a result of the insertional inactivation of rpoN. Identification of the protein spots by matrix-assisted laser desorption/ionization-time of flight/time of flight revealed a wide diversity of proteins that are affected by the sigma(54) mutation, the largest group being proteins that are involved in carbon metabolism. The strictly inducible gentisate 1,2-dioxygenase, one of two isofunctional copies of the key enzyme in the gentisate pathway, and enzymes of the TCA cycle, pyruvate metabolism and gluconeogenesis were part of this group. Other proteins that are part of the sigma(54) regulon include enzymes implicated in nitrogen metabolism, transport proteins, stress-response proteins and proteins involved in cell motility. The results of this study showed that sigma(54) plays a global regulatory role in the expression of a wide variety of genes in P. alcaligenes, including the wild-type response to the presence of the aromatic inducer, gentisate.     

Regulation of isofunctional enzymes in Pseudomonas alcaligenes mutants defective in the gentisate pathway

The regulation of the inducible set of gentisate pathway enzymes used by Pseudomonas alcaligenes (P25X1) has been studied in strains derived from mutant strains of P25X1 that had lost the constitutive enzymes that degrade m –cresol, 2,5–xylenol and 3,5–xylenol. The enzyme, 3-hydroxybenzoate 6-hydroxylase II, that catalyzes the oxidation of 3-hydroxybenzoate to gentisate is substrate- and product-induced while gentisate dioxygenase II is substrate induced. Neither 3-hydroxybenzoate nor gentisate could induce the synthesis of maleylpyruvate hydrolase II and fumarylpyruvate hydrolase II. The results suggest that the structural genes encoding these four inducible enzymes and maleylpyruvate hydrolase I (a constitutive enzyme) exist in at least four operons. There is strict induction specificity of expression of this inducible set of gentisate pathway enzymes. 3-Hydroxy-4-methyl-benzoate failed to induce whilst 3-hydroxybenzoate and 3-hydroxy-5-methylbenzoate served as inducers of 6-hydroxylase II. Degradation of 2,5-xylenol is mediated by constitutive enzymes whereas the inducible set of enzymes are responsible for the metabolism of m -cresol and 3,5-xylenol.     

Purification and characterization of gentisate 1,2-dioxygenases from Pseudomonas alcaligenes NCIB 9867 and Pseudomonas putida NCIB 9869

Two 3-hydroxybenzoate-inducible gentisate 1,2-dioxygenases were purified to homogeneity from Pseudomonas alcaligenes NCIB 9867 (P25X) and Pseudomonas putida NCIB 9869 (P35X), respectively. The estimated molecular mass of the purified P25X gentisate 1, 2-dioxygenase was 154 kDa, with a subunit mass of 39 kDa. Its structure is deduced to be a tetramer. The pI of this enzyme was established to be 4.8 to 5.0. The subunit mass of P35X gentisate 1, 2-dioxygenase was 41 kDa, and this enzyme was deduced to exist as a dimer, with a native molecular mass of about 82 kDa. The pI of P35X gentisate 1,2-dioxygenase was around 4.6 to 4.8. Both of the gentisate 1,2-dioxygenases exhibited typical saturation kinetics and had apparent Kms of 92 and 143 microM for gentisate, respectively. Broad substrate specificities were exhibited towards alkyl and halogenated gentisate analogs. Both enzymes had similar kinetic turnover characteristics for gentisate, with kcat/Km values of 44.08 x 10(4) s-1 M-1 for the P25X enzyme and 39.34 x 10(4) s-1 M-1 for the P35X enzyme. Higher kcat/Km values were expressed by both enzymes against the substituted gentisates. Significant differences were observed between the N-terminal sequences of the first 23 amino acid residues of the P25X and P35X gentisate 1,2-dioxygenases. The P25X gentisate 1,2-dioxygenase was stable between pH 5.0 and 7.5, with the optimal pH around 8.0. The P35X enzyme showed a pH stability range between 7.0 and 9.0, and the optimum pH was also 8.0. The optimal temperature for both P25X and P35X gentisate 1, 2-dioxygenases was around 50 degrees C, but the P35X enzyme was more heat stable than that from P25X. Both enzymes were strongly stimulated by 0.1 mM Fe2+ but were completely inhibited by the presence of 5 mM Cu2+. Partial inhibition of both enzymes was also observed with 5 mM Mn2+, Zn2+, and EDTA.     

Evidence for isofunctional enzymes used in m-cresol and 2,5-xylenol degradation via the gentisate pathway in Pseudomonas alcaligenes.

Study of the reaction sequence by which Pseudomonas alcaligenes (P25X1) and derived mutants degrade m-cresol, 2,5-xylenol, and their catabolites has provided indirect evidence for the existence of two or more isofunctional enzymes at three different steps. Maleylpyruvate hydrolase activity appears to reside in two different proteins with different specificity ranges, one of which (MPH1) is expressed constitutively; the other (MPH11) is strictly inducible. Two gentisate 1,2-dioxygenase activities were found, one of which is constitutively expressed and possesses a broader specificity range than the other, which is inducible. From oxidation studies with intact cells, there appear to be two activities responsible for the 6-hydroxylation of 3-hydroxybenzoate, and again a broadly specific activity is present regardless of growth conditions; the other is inducible by 3-hydroxybenzoate. Three other enzyme activities are also detected in uninduced cells, viz., xylenol methylhydroxylase, benzylalcohol dehydrogenase, and benzaldehyde dehydrogenase. All apparently possess broad specificity. Fumarylpyruvate hydrolase was also detected but only in cells grown with m-cresol, 3-hydroxybenzoate, or gentisate. Mutants, derived either spontaneously or after treatment with mitomycin C, are described, certain of which have lost the ability to grow with m-cresol and 2,5-xylenol and some of which have also lost the ability to form the constitutive xylenol methylhydroxylase, benzylalcohol dehydrogenase, benzaldehyde dehydrogenase, 3-hydroxybenzoate 6-hydroxylase, and gentisate 1,2-dioxygenase. Such mutants, however, retain ability to synthesize inducibly a second 3-hydroxybenzoate 6-hydroxylase and gentisate 1,2-dioxygenase, as well as maleylpyruvate hydrolase (MPH11) and fumarylpyruvate hydrolase; MPH1 was still synthesized. These findings suggest the presence of a plasmid for 2,5-xylenol degradation which codes for synthesis of early degradative enzymes. Other enzymes, such as the second 3-hydroxybenzoate 6-hydroxylase, gentisate 1,2-dioxygenase, maleylpyruvate hydrolase (MPH1 and MPH11), and fumarylpyruvate hydrolase, appear to be chromosomally encoded and, with the exception of MPH1, strictly inducible.     

Biochemical and molecular characterization of a ring fission dioxygenase with the ability to oxidize (substituted) salicylate(s) from Pseudaminobacter salicylatoxidans

The gene coding for a dioxygenase with the ability to cleave salicylate by a direct ring fission mechanism to 2-oxohepta-3,5-dienedioic acid was cloned from Pseudaminobacter salicylatoxidans strain BN12. The deduced amino acid sequence encoded a protein with a molecular mass of 41,176 Da, which showed 28 and 31% sequence identity, respectively, to a gentisate 1,2-dioxygenase from Pseudomonas alcaligenes NCIMB 9867 and a 1-hydroxy-2-naphthoate 1,2-dioxygenase from Nocardioides sp. KP7. The highest degree of sequence identity (58%) was found to a presumed gentisate 1,2-dioxygenase from Corynebacterium glutamicum. The enzyme from P. salicylatoxidans BN12 was heterologously expressed in Escherichia coli and purified as a His-tagged enzyme variant. The purified enzyme oxidized in addition to salicylate, gentisate, 5-aminosalicylate, and 1-hydroxy-2-naphthoate also 3-amino- and 3- and 4-hydroxysalicylate, 5-fluorosalicylate, 3-, 4-, and 5-chlorosalicylate, 3-, 4-, and 5-bromosalicylate, 3-, 4-, and 5-methylsalicylate, and 3,5-dichlorosalicylate. The reactions were analyzed by high pressure liquid chromatography/mass spectrometry, and the reaction products were tentatively identified. For comparison, the putative gentisate 1,2-dioxygenase from C. glutamicum was functionally expressed in E. coli and shown to convert gentisate but not salicylate or 1-hydroxy-2-naphthoate.     

Gentisate 1,2-dioxygenase from Xanthobacter polyaromaticivorans 127W

A putative gentisate 1,2-dioxygenase was encoded in the dibenzothiophene degradation gene cluster (dbd) from Xanthobacter polyaromaticivorans 127W. The deduced amino acid sequence showed high sequence similarity with gentisate dioxygenases from Pseudomonas alcaligenes (AAD49427, 65% identical), Bradyrhizobium japonicum (NP_766750, 64%), and P. aeruginosa (ZP_00135722, 54%), and moderate similarity with 1-hydroxy-2-naphthoate dioxygenase from Nocardioides sp. KP7 (BAA31235, 33%) and salicylate dioxygenase from Pseudaminobacter salicylatoxidans (AAQ91293, 33%). The enzyme, GDOxp, was heterologously produced in Escherichia coli and purified to homogeneity. GDOxp formed a tetramer and exhibited high dioxygenase activity against 1,4-dihydroxy 2-naphthoate as well as gentisate, suggesting unusually broad substrate specificity. GDOxp easily released ferrous ion under unfavorable temperature and pH conditions to become an inactive monomer protein. An inactive monomer protein can reconstitute a tetramer structure and restore enzyme activity in a cooperative manner upon the addition of ferrous ion. Chymotryptic digestion and protein truncation experiments suggested that the N-terminal region is important for the tetramerization of GDOxp.     

Gentisate 1,2-dioxygenase from pseudomonas. Purification, characterization, and comparison of the enzymes from Pseudomonas testosteroni and Pseudomonas acidovorans

The 3-hydroxybenzoate inducible gentisate 1,2-dioxygenases have been purified to homogeneity from P. acidovorans and P. testosteroni, the two divergent species of the acidovorans group of Pseudomonas. Both enzymes exhibit a 40-fold higher specific activity than previous preparations and have an (alpha Fe)4 quaternary structure (holoenzyme Mr = 164,000 and 158,000, respectively). The enzymes have different amino terminal sequences, amino acid contents, and isoelectric points. Each enzyme contains essential active site iron that is EPR silent but binds nitric oxide quantitatively to give an EPR active complex (S = 3/2), showing that the iron is Fe2+ with coordination sites for exogenous ligands. The EPR spectra of these complexes are altered uniquely for each enzyme when gentisate is bound. This suggests that substrate binds to or near the iron and shows that the substrate-iron interactions of each enzyme are subtly different. The kinetic parameters for turnover of gentisate by the enzymes are nearly identical (kcat/Km = 4.3 x 10(6) s-1 M-1). Both enzymes cleave a wide range of gentisate analogs substituted in the 3 or 4 ring position, although at reduced rates relative to gentisate. Of the two enzymes, P. testosteroni gentisate 1,2-dioxygenase exhibits substantially lower kcat/Km values for the turnover of these compounds. Evidence for both steric and electronic substituent effects is obtained. In accord with the results of Wheelis et al. (Wheelis, M. L., Palleroni, N. J., and Stanier, R. Y. (1967) Arch. Mikrobiol. 59, 302-314), 3-hydroxybenzoate is shown to be metabolized by P. acidovorans through the gentisate pathway, and gentisate 1,2-dioxygenase is the only ring cleavage dioxygenase induced. In contrast, 3-hydroxybenzoate is metabolized by P. testosteroni exclusively through the protocatechuate pathway utilizing protocatechuate 4,5-dioxygenase, although gentisate 1,2-dioxygenase is coinduced. Growth of P. testosteroni on 3-O-methylbenzoate or 5-O-methylsalicylate is shown to result in a approximately 10-fold increase in the amount of gentisate 1,2-dioxygenase relative to protocatechuate 4,5-dioxygenase. Together, these results suggest that induction of gentisate 1,2-dioxygenase by 3-hydroxybenzoate in P. testosteroni may be adventitious and that this enzyme may function in fundamentally different metabolic pathways in the two related Pseudomonas species.     

Molecular and biochemical characterization of the xlnD-encoded 3-hydroxybenzoate 6-hydroxylase involved in the degradation of 2,5-xylenol via the gentisate pathway in Pseudomonas alcaligenes NCIMB 9867

The xlnD gene from Pseudomonas alcaligenes NCIMB 9867 (strain P25X) was shown to encode 3-hydroxybenzoate 6-hydroxylase I, the enzyme that catalyzes the NADH-dependent conversion of 3-hydroxybenzoate to gentisate. Active recombinant XlnD was purified as a hexahistidine fusion protein from Escherichia coli, had an estimated molecular mass of 130 kDa, and is probably a trimeric protein with a subunit mass of 43 kDa. This is in contrast to the monomeric nature of the few 3-hydroxybenzoate 6-hydroxylases that have been characterized thus far. Like other 3-hydroxybenzoate 6-hydroxylases, XlnD could utilize either NADH or NADPH as the electron donor. P25X harbors a second 3-hydroxybenzoate 6-hydroxylase II that was strictly inducible by specific aromatic substrates. However, the degradation of 2,5-xylenol and 3,5-xylenol in strain P25X was found to be dependent on the xlnD-encoded 6-hydroxylase I and not the second, strictly inducible 6-hydroxylase II.