Enhanced inhibition of HEDP on SRB-mediated corrosion with D-phenylalanine.

Microbiologically influenced corrosion (MIC) caused by biofilm is a serious problem in many industries. D-amino acids could be a potential strategy to enhance traditional corrosion inhibitors due to their roles in biofilm reduction. However, the synergistic mechanism of D-amino acids and inhibitors remains unknown. In this study, D-Phenylalanine (D-Phe) and 1-hydroxyethane-1,1-diphosphonic acid (HEDP) were selected as the typical D-amino acid and corrosion inhibitor to evaluate their effect on the corrosion caused by Desulfovibrio vulgaris. The combination of HEDP and D-Phe obviously slowed down the corrosion process by 32.25%, decreased the corrosion pit depth and retarded cathodic reaction. SEM and CLSM analysis indicated that D-Phe reduced the content of extracellular protein and thus inhibited the biofilm formation. The molecular mechanism of D-Phe and HEDP on corrosion inhibition was further explored via transcriptome. The combination of HEDP and D-Phe down-regulated the gene expression of peptidoglycan, flagellum, electron transfer, metalloregulatory proteins, and quorum sensing (QS) molecules, leading to less peptidoglycan synthesis, weaker electron transfer and stronger QS factor inhibition. This work provides a new strategy for improving traditional corrosion inhibitors, retarding MIC and mitigating subsequent water eutrophication.

[1]  Yuyang Long,et al.  Sulfate-reduction behavior in waste-leachate transition zones of landfill sites. , 2022, Journal of hazardous materials.

[2]  Etienne Z. Gnimpieba,et al.  Gene Sets and Mechanisms of Sulfate-Reducing Bacteria Biofilm Formation and Quorum Sensing With Impact on Corrosion , 2021, Frontiers in Microbiology.

[3]  M. Du,et al.  Investigation of mixed species biofilm on corrosion of X65 steel in seawater environment. , 2021, Bioelectrochemistry.

[4]  Dun Zhang,et al.  Electron donor dependent inhibition mechanisms of D-phenylalanine on corrosion of Q235 carbon steel caused by Desulfovibrio sp. Huiquan2017 , 2021 .

[5]  L. Lv,et al.  Degradation of phosphonates in Co(II)/peroxymonosulfate process: Performance and mechanism. , 2021, Water research.

[6]  J. Filip,et al.  Effect of Copresence of Zerovalent Iron and Sulfate Reducing Bacteria on Reductive Dechlorination of Trichloroethylene. , 2021, Environmental science & technology.

[7]  F. Bai,et al.  Flagella and Their Properties Affect the Transport and Deposition Behaviors of Escherichia coli in Quartz Sand. , 2021, Environmental science & technology.

[8]  W. Ke,et al.  Influence of cementite spheroidization on relieving the micro-galvanic effect of ferrite-pearlite steel in acidic chloride environment , 2021 .

[9]  Hong-Ying Hu,et al.  Assessment and mechanisms of microalgae growth inhibition by phosphonates: Effects of intrinsic toxicity and complexation. , 2020, Water research.

[10]  Dawei Zhang,et al.  Stress-assisted microbiologically influenced corrosion mechanism of 2205 duplex stainless steel caused by sulfate-reducing bacteria , 2020 .

[11]  B. Pan,et al.  Occurrence and transformation of phosphonates in textile dyeing wastewater along full-scale combined treatment processes. , 2020, Water research.

[12]  Zhiguo Yuan,et al.  Synergistic inhibitory effects of free nitrous acid and imidazoline derivative on metal corrosion in a simulated water injection system. , 2020, Water research.

[13]  Zhiguo Yuan,et al.  Decreasing microbially influenced metal corrosion using free nitrous acid in a simulated water injection system. , 2020, Water research.

[14]  A. Abdel-Wahab,et al.  Corrosion behavior of pure titanium anodes in saline medium and their performance for humic acid removal by electrocoagulation. , 2019, Chemosphere.

[15]  R. Lehmann,et al.  Effect of Quorum Sensing on the Ability of Desulfovibrio vulgaris To Form Biofilms and To Biocorrode Carbon Steel in Saline Conditions , 2019, Applied and Environmental Microbiology.

[16]  T. Wood,et al.  σ54 -Dependent regulator DVU2956 switches Desulfovibrio vulgaris from biofilm formation to planktonic growth and regulates hydrogen sulfide production. , 2019, Environmental microbiology.

[17]  S. Correa,et al.  Chitosan disrupts biofilm formation and promotes biofilm eradication in Staphylococcus species isolated from bovine mastitis. , 2019, International journal of biological macromolecules.

[18]  Zhiguo Yuan,et al.  Physiological and transcriptomic analyses reveal CuO nanoparticle inhibition of anabolic and catabolic activities of sulfate-reducing bacterium. , 2019, Environment international.

[19]  T. Gu,et al.  Effects of d-Phenylalanine as a biocide enhancer of THPS against the microbiologically influenced corrosion of C1018 carbon steel , 2019, Journal of Materials Science & Technology.

[20]  Henny C van der Mei,et al.  Physico-chemistry from initial bacterial adhesion to surface-programmed biofilm growth. , 2018, Advances in colloid and interface science.

[21]  Xin Wei,et al.  Effect of residual dissolved oxygen on the corrosion behavior of low carbon steel in 0.1 M NaHCO3 solution , 2018 .

[22]  T. Gu,et al.  An enhanced oil recovery polymer promoted microbial growth and accelerated microbiologically influenced corrosion against carbon steel , 2018, Corrosion Science.

[23]  Muhammad Zaheer Afzal,et al.  Mitigation of membrane biofouling by d-amino acids: Effect of bacterial cell-wall property and d-amino acid type. , 2018, Colloids and surfaces. B, Biointerfaces.

[24]  H. Steinmetz,et al.  Organophosphonates: A review on environmental relevance, biodegradability and removal in wastewater treatment plants. , 2018, The Science of the total environment.

[25]  Yan Sun,et al.  D-phenylalanine inhibits the corrosion of Q235 carbon steel caused by Desulfovibrio sp. , 2018 .

[26]  A. Okamoto,et al.  Multi-heme cytochromes provide a pathway for survival in energy-limited environments , 2018, Science Advances.

[27]  Dawei Zhang,et al.  Enhanced resistance of 2205 Cu-bearing duplex stainless steel towards microbiologically influenced corrosion by marine aerobic Pseudomonas aeruginosa biofilms , 2017, Journal of Materials Science & Technology.

[28]  H. Steinmetz,et al.  Removal of phosphonates from industrial wastewater with UV/FeII, Fenton and UV/Fenton treatment. , 2017, Water research.

[29]  T. Gu,et al.  Mitigation of a nitrate reducing Pseudomonas aeruginosa biofilm and anaerobic biocorrosion using ciprofloxacin enhanced by D-tyrosine , 2017, Scientific Reports.

[30]  T. Gu,et al.  Electrochemical Testing of Biocide Enhancement by a Mixture of d-Amino Acids for the Prevention of a Corrosive Biofilm Consortium on Carbon Steel , 2017 .

[31]  T. Gu,et al.  Corrosion inhibition and anti-bacterial efficacy of benzalkonium chloride in artificial CO2-saturated oilfield produced water , 2017 .

[32]  Kh. Rahmani,et al.  Evaluation of inhibitors and biocides on the corrosion, scaling and biofouling control of carbon steel and copper–nickel alloys in a power plant cooling water system , 2016 .

[33]  W. Ke,et al.  Sustained effect of remaining cementite on the corrosion behavior of ferrite-pearlite steel under the simulated bottom plate environment of cargo oil tank , 2016 .

[34]  E. Ilhan‐Sungur,et al.  Effects of Ag and Cu ions on the microbial corrosion of 316L stainless steel in the presence of Desulfovibrio sp. , 2016, Bioelectrochemistry.

[35]  Donghui Wen,et al.  Inhibition of biofilm formation by D-tyrosine: Effect of bacterial type and D-tyrosine concentration. , 2016, Water research.

[36]  Hang Yu,et al.  Artificial electron acceptors decouple archaeal methane oxidation from sulfate reduction , 2016, Science.

[37]  Zohar Bloom-Ackermann,et al.  Disturbance of the bacterial cell wall specifically interferes with biofilm formation. , 2015, Environmental microbiology reports.

[38]  Hongwei Liu,et al.  Study of corrosion behavior and mechanism of carbon steel in the presence of Chlorella vulgaris , 2015 .

[39]  A. Boetius,et al.  Intercellular wiring enables electron transfer between methanotrophic archaea and bacteria , 2015, Nature.

[40]  Zhengbo Yue,et al.  Competitive adsorption of heavy metal by extracellular polymeric substances (EPS) extracted from sulfate reducing bacteria. , 2014, Bioresource technology.

[41]  C. Fu,et al.  Effect of Sulfate-Reducing Bacteria and Iron-Oxidizing Bacteria on the Rate of Corrosion of an Aluminum Alloy in a Central Air-Conditioning Cooling Water System , 2014 .

[42]  F. Besenbacher,et al.  Filamentous bacteria transport electrons over centimetre distances , 2012, Nature.

[43]  Christopher L. Hemme,et al.  Functional Characterization of Crp/Fnr-Type Global Transcriptional Regulators in Desulfovibrio vulgaris Hildenborough , 2011, Applied and Environmental Microbiology.

[44]  Yu Liu,et al.  d-Amino acid mitigated membrane biofouling and promoted biofilm detachment , 2011 .

[45]  Fu-hui Wang,et al.  The effects of sulfate reducing bacteria on corrosion of carbon steel Q235 under simulated disbonded coating by using electrochemical impedance spectroscopy , 2011 .

[46]  N. Friedman,et al.  Comprehensive comparative analysis of strand-specific RNA sequencing methods , 2010, Nature Methods.

[47]  Roberto Kolter,et al.  d-Amino Acids Trigger Biofilm Disassembly , 2010, Science.

[48]  M. Waldor,et al.  D-Amino Acids Govern Stationary Phase Cell Wall Remodeling in Bacteria , 2009, Science.

[49]  L. Kennedy,et al.  Microbial degradation of simulated landfill leachate: solid iron/sulfur interactions , 2001 .

[50]  P. Mathur,et al.  Physico-chemical evaluation of corrosion inhibitors for carbon steel used in the process cooling water systems , 1996 .

[51]  M. de Pedro,et al.  Effect of D-amino acids on structure and synthesis of peptidoglycan in Escherichia coli , 1992, Journal of bacteriology.

[52]  T. Gu,et al.  Effects of biogenic H2S on the microbiologically influenced corrosion of C1018 carbon steel by sulfate reducing Desulfovibrio vulgaris biofilm , 2018 .

[53]  T. Gu,et al.  The corrosion behavior and mechanism of carbon steel induced by extracellular polymeric substances of iron-oxidizing bacteria , 2017 .