Decolorization and degradation of textile dyes with biosulfidogenic hydrogenases

Successful decolorization of azo dyes (Orange II, Amido Black 10, Reactive Black 5, and Reactive Red 120) and industrial textile dye influents and effluents with sulfate-reducing bacteria from within a biosulfidogenic reactor was achieved with decolorizations ranging from 96% to 49% over 144 h. Concomitant with the decrease in absorbance of the dye in the visible region (480-620 nm) was an increase in the absorbance at 280 nm, over 48 h, suggesting an increase in concentration of single aromatic amines. With an extended period of time there was a subsequent decrease in the absorbance at 280 nm indicating that the aromatic amines had been degraded. The anthraquinone dye, Reactive Blue 2, remained unchanged after 144 h of incubation in the biosulfidogenic reactor and was only rapidly decolored at 192 h, implying that certain factors are induced in the reactor to break down this non-azo dye. The fastest decolorization/degradation rates and highest hydrogenase enzyme production were observed with Orange II, while the slowest decolorization/degradation rate and least enzyme production were with Reactive Blue 2, suggesting that these processes are controlled, to a certain degree, by an enzymatic mechanism. With sulfate-reducing bacteria that had been cultured on a lactate medium, there was complete decolorization of both authentic dyes and industrial influents and effluents as monitored by the decrease of absorbance in the visible region (480-620 nm). There was, however, very little breakdown of the single aromatic compounds as the absorbance at 280 nm remained fairly significant. This supports the suggestion that, within the biosulfidogenic reactor, there are factors other than the identified hydrogenases that are responsible for degradation of the aromatic compounds.     

代谢工程改造大肠杆菌提高乙醇酸产率

乙醇酸(Glycolate)是一种在工业上有多种用途的重要化合物。本研究首先在大肠杆菌MG1655(DE3)中敲除了ldh A(乳酸脱氢酶),获得菌株Mgly1,作为出发菌株。然后通过调节乙醇酸合成途径的关键酶——异柠檬酸裂解酶(ace A)、乙醛酸还原酶(ycd W)、异柠檬酸脱氢酶激酶/磷酸化酶(ace K)的表达水平,得到乙醇酸产率为0.24 g/g葡萄糖(占理论产率的28.2%)。过量表达柠檬酸合成酶(glt A),乙醇酸产率提高到0.326 g/g葡萄糖(占理论产率的38.3%)。然后在Mgly1中敲除了glc B和ace B(苹果酸合成酶),减少了乙醇酸合成的前体乙醛酸的消耗。最终获得的工程菌株Mgly335乙醇酸产率达到0.522 g/g葡萄糖(占理论产率的61.4%)。     

固定化漆酶对染料酸性紫43的脱色和降解

采用自制复合型载体丙烯酸酯类聚合物固定的漆酶对染料酸性紫43进行脱色处理。研究了固定化酶的用量、底物浓度、温度、pH对其降解效果的影响。结果表明,固定化漆酶脱色降解酸性紫43的适宜条件为:酶用量12.5 U/mL,染料浓度150 mg/L,反应的温度范围在45~55℃,pH值范围在4.5~5.0。在上述条件下降解4h,染料酸性紫43脱色率能达到98.5%。重复分批使用固定化漆酶处理染料酸性紫43,在使用8批次后,脱色率仍然能保持在90%以上,其催化效率得到了很大提高。     

Decolorization of sulfonated azo dyes with two photosynthetic bacterial strains and a genetically engineered Escherichia coli strain

Sulfonated azo dyes were decolorized by two wild type photosynthetic bacterial (PSB) strains (Rhodobacter sphaeroides AS1.1737 and Rhodopseudomonas palustris AS1.2352) and a recombinant strain (Escherichia coli YB). The effects of environmental factors (dissolved oxygen, pH and temperature) on decolorization were investigated. All the strains could decolorize azo dye up to 900 mg l⁻¹, and the correlations between the specific decolorization rate and dye concentration could be described by Michaelis–Menten kinetics. Repeated batch operations were performed to study the persistence and stability of bacterial decolorization. Mixed azo dyes were also decolorized by the two PSB strains. Azoreductase was overexpressed in E. coli YB; however, the two PSB strains were better decolorizers for sulfonated azo dyes.     

Uptake and degradation of EDTA by Escherichia coli

It was found that Escherichia coli exhibited a growth by utilization of Fe(III)EDTA as a sole nitrogen source. No significant growth was detected when Fe(III)EDTA was replaced by EDTA complexes with other metal ions such as Ca²⁺, Co²⁺, Cu²⁺, Mg²⁺, Mn²⁺, and Zn²⁺. When EDTA uptake was measured in the presence of various ions, it was remarkable only when Fe³⁺ was present. The cell extract of E. coli exhibited a significant degradation of EDTA only in the presence of Fe³⁺. It is likely that the capability of E. coli for the growth by utilization of Fe(III)EDTA results from the Fe³⁺-dependent uptake and degradation of EDTA.     

Model-based metabolic engineering enables high yield itaconic acid production by Escherichia coli

Itaconic acid is a high potential platform chemical which is currently industrially produced by Aspergillus terreus. Heterologous production of itaconic acid with Escherichia coli could help to overcome limitations of A. terreus regarding slow growth and high sensitivity to oxygen supply. However, the performance achieved so far with E. coli strains is still low.We introduced a plasmid (pCadCS) carrying genes for itaconic acid production into E. coli and applied a model-based approach to construct a high yield production strain. Based on the concept of minimal cut sets, we identified intervention strategies that guarantee high itaconic acid yield while still allowing growth. One cut set was selected and the corresponding genes were iteratively knocked-out. As a conceptual novelty, we pursued an adaptive approach allowing changes in the model and initially calculated intervention strategy if a genetic modification induces changes in byproduct formation. Using this approach, we iteratively implemented five interventions leading to high yield itaconic acid production in minimal medium with glucose as substrate supplemented with small amounts of glutamic acid. The derived E. coli strain (ita23: MG1655 ∆aceA ∆sucCD ∆pykA ∆pykF ∆pta ∆Picd::cam_BBa_J23115 pCadCS) synthesized 2.27 g/l itaconic acid with an excellent yield of 0.77 mol/(mol glucose). In a fed-batch cultivation, this strain produced 32 g/l itaconic acid with an overall yield of 0.68 mol/(mol glucose) and a peak productivity of 0.45 g/l/h. These values are by far the highest that have ever been achieved for heterologous itaconic acid production and indicate that realistic applications come into reach.     

理性设计和构建过量合成莽草酸的大肠杆菌代谢工程菌

利用代谢工程手段理性改造野生大肠杆菌的莽草酸(Shikimic acid,SA)合成途径及相关代谢节点,以构建高产莽草酸的工程菌株.根据细胞代谢网络分析,利用Red-Xer重组系统连续删除了野生型大肠杆菌CICIMB0013的莽草酸激酶基因(aroL、aroK),葡萄糖磷酸转移酶系统(PTS)的关键组分EIICBglc的编码基因(ptsG)以及奎宁酸/莽草酸脱氢酶基因(ydiB)并系统评价了基因删除对细胞的生长、葡萄糖代谢和莽草酸积累的影响.aroL、aroK的删除阻断了莽草酸进一步转化成为莽草酸-3-磷酸,初步提高莽草酸的累积.删除ptsG基因使大肠杆菌PTS系统部分缺失,细胞通过GalP-glk(半乳糖透性酶-葡萄糖激酶)途径,利用ATP将葡萄糖磷酸化后进入细胞.利用该途径运输葡萄糖能够减少PEP的消耗,使得更多的碳代谢流进入莽草酸合成途径,从而显著提高了莽草酸的产量.在此基础上删除ydiB基因,阻止了莽草酸合成的前体物质3-脱氢奎宁酸转化为副产物奎宁酸(Quinic acid,QA),进一步提高了莽草酸的累积.初步发酵显示4个基因缺失的大肠杆菌代谢工程菌生产莽草酸的能力比原始菌提高了90多倍.     

Regulation of gamma-aminobutyric acid degradation in Escherichia coli by nitrogen metabolism enzymes.

The possible role of glutamate dehydrogenase, glutamate synthase, and glutamine synthetase in the regulation of enzyme formation in the gamma-aminobutyric acid (GABA) catabolic pathway of Escherichia coli K-12 was investigated. Evidence is presented indicating that glutamine synthetase acts as a positive regulator in the E. coli GABA control system. Mutations impairing glutamate synthase activity prevent the depression of the enzymes of the GABA pathway in ammonia-limited glucose media. However, mutations resulting in constitutive synthesis of glutamine synthetase (GlnC) restore the ability of the glutamate synthase-less mutants to grow in glucose-GABA media and result in depressed synthesis of the GABA enzymes. It is suggested that the loss of glutamate synthesis activity affects the GABA control system indirectly by lowering glutamine synthetase levels.     

Enhancing the adsorption capacities of acid dyes by chitosan nano particles

In the present study, nanochitosan emulsion has been produced in a suspension form by adding tripolyphosphate solution into a chitosan solution drop-wise. The adsorption capacities of four acid dyes, namely, Acid Orange 10 (AO10), Acid Orange 12 (AO12), Acid Red 18 (AR18) and Acid Red 73 (AR73) on nanochitosan, have been determined to be 1.77, 4.33, 1.37 and 2.13 mmol l(-1), respectively. The nanochitosan dye capacities were compared with normal chitosan capacities which were 1.54, 2.66, 1.11 and 1.25 mmol l(-1) for AO10, AO12, AR18 and AR73, respectively. In all cases, the nanochitosan has a higher capacity. The mechanism of acid dye adsorption and the effect of pH are also discussed.     

Agglutination of bacterial spheroplasts: agglutination-dependent degradation of Escherichia coli ribosomal ribonucleic acid

When Escherichia coli spheroplasts made by ethylenediaminetetraacetic acid and lysozyme were agglutinated by concanavalin A (con A), the degradation of ribosomal ribonucleic acid (rRNA) was found to occur proportionally to the degree of the agglutination, which was determined by microscopic examination or by a newly devised assay based on the slower settling of aggregates. Methyl-alpha-d-glucoside, low temperature or alkaline pH, all of which reverse the agglutination, also reduced the extent of rRNA degradation. This degradation was not due to the direct action of con A since a similar relationship was found in the case of spontaneous agglutination with concentrated spheroplasts in the absence of con A. The possible importance of a change in the cell membrane associated with the agglutination process is discussed in connection with the initiation of rRNA degradation.     

Decolorization of basic, direct and reactive dyes by pre-treated narrow-leaved cattail (Typha angustifolia Linn.)

The efficiency of basic, direct and reactive dye removal from water by narrow-leaved cattail (NLC) powder treated with distilled water (DW-NLC), 37% formaldehyde+0.2 N sulfuric acid (FH-NLC), or 0.1 N sodium hydroxide (NaOH-NLC) at various pH levels (3, 5, 7, and 9) was tested. Desorption of the adsorbed dyes was also investigated. The type of NLC treatment and pH of the dye solution had little effect on removal of basic dyes, and efficiencies ranged from 97% to 99% over the range of pH used. Over a wide range of pH levels, all types of treated cattail powder had negative charges and probably attracted the basic dyes possessing positive charges. Efficiency of removal by the three NLC treatments ranged from 37% to 42% for direct dyes and from 22% to 54% for direct dyes at pH 7. The pH of the dye solution had substantial effects on the efficiency of removal in direct and reactive dyes. Dye removal was highest at pH 3, with 99% for a direct dye (Sirius Red Violet RL) and 96% for a reactive dye (Basilen Red M-5B). There was mutual attraction between negatively charged direct dye molecules and positively charged molecules on the surface of the FH-treated cattail. In tests of desorption of dyes from cattail in distilled water, the desorption percentage for FH-NLC after adsorbing basic, direct and reactive dyes was 6%, 10% and 35%, respectively, which indicated a chemisorption mechanism for basic and direct dyes and some physiosorption for reactive dyes.     

进化代谢选育高浓度NH_4~+耐受型产丁二酸大肠杆菌

利用大肠杆菌厌氧制备丁二酸过程中,采用氨水作为p H调节剂不仅可以中和酸性产物还可提供无机氮,被菌体利用,然而高浓度NH_4~+的积累会抑制菌体生长及代谢产酸的能力。为增强大肠杆菌对高浓度NH_4~+的耐受性,以(NH4)2HPO4为NH_4~+供体,通过在连续培养装置中不断提高(NH_4)_2HPO4浓度,以获得可耐受0.53 mol/L NH_4~+的产丁二酸大肠杆菌。结果表明:突变株在0.53 mol/L NH_4~+胁迫下,摇瓶厌氧发酵72 h,细胞干质量浓度(DCW)可达1.82 g/L,丁二酸产量为11.72 g/L,分别比出发菌株提高了1.6和4.6倍。进一步地,在5 L发酵罐上考察其利用氨水调节p H生产丁二酸的能力,厌氧发酵90 h,丁二酸质量浓度达到27.32 g/L,生产强度为0.30g/(L·h),比出发菌株分别提高88.1%和87.5%。