L-tryptophan anaerobic fermentation for indole acetic acid production: Bacterial enrichment and effects of zero valent iron.

Indole acetic acid (IAA) as a plant hormone, was one of the valuable products of anaerobic fermentation. However, the enriching method remained unknown. Moreover, whether zero valent iron (ZVI) could enhance IAA production was unexplored. In this work, IAA producing bacteria Klebsiella (63 %) was enriched successfully. IAA average production rate and concentration were up to 3 mg/L/h and 56 mg/L. With addition of 1 g/L ZVI, IAA average production rate and concentration was increased for 2 and 3 folds. Mechanisms indicated ZVI increased Na+K+-ATP activity and electron transport activity for 2 folds and 1 fold. Moreover, macro transcription determined indole pyruvate pathway activity like primary-amine oxidase, indole pyruvate decarboxylase and aldehyde dehydrogenase were increased for 146 %, 187 %, and 557 %, respectively. Therefore, ZVI was suitable for enhancement IAA production from mixed culture anaerobic fermentation.

Dopamine promotes Klebsiella quasivariicola proliferation and inflammatory response in the presence of macrophages.

Background: Dopamine, a frequently used therapeutic agent for critically ill patients, has been shown to be implicated in clinical infections recently, however, the precise mechanisms underlying this association remain elusive. Klebsiella quasivariicola, a novel strain belonging to the Klebsiella species, exhibits potential pathogenic attributes. The impact of dopamine on K. quasivariicola infection has aroused our interest. Objective: Considering the contribution of host immune factors during infection, this study aimed to investigate the intricate interactions between K. quasivariicola, dopamine, and macrophages were explored. Methods: RAW264.7 cells and C57/BL6 mice were infected with K. quasivariicola, and the bacterial growth within macrophage, the production of inflammatory cytokines and the pathological changes in mice lungs were detected, in the absence or presence of dopamine. Results: Dopamine inhibited the growth of K. quasivariicola in the medium, but promoted bacterial growth when co-cultured with macrophages. The expression of proinflammatory cytokines increased in RAW 264.7 cells infected with K. quasivariicola, and a significant rise was observed upon the addition of dopamine. The infection of K. quasivariicola in mice induced an inflammatory response and lung injury, which were exacerbated by the administration of dopamine. Conclusions: Our findings suggest that dopamine may be one of the potential risk factors associated with K. quasivariicola infection. This empirical insight provides solid references for clinical precision medicine. Furthermore, an in vitro model of microbes-drugs-host immune cells for inhibitor screening was proposed to more accurately replicate the complex in vivo environment. This fundamental work had contributed to the present understanding of the crosstalk between pathogen, dopamine and host immune cells.

The capability of chloramphenicol biotransformation of Klebsiella sp. YB1 under cadmium stress and its genome analysis.

Co-contamination by antibiotics and heavy metal is common in the environment, however, there is scarce information about antibiotics biodegradation under heavy metals stress. In this study, Klebsiella sp. Strain YB1 was isolated which is capable of biodegrading chloramphenicol (CAP) with a biodegradation efficiency of 22.41% at an initial CAP of 10 mg L-1 within 2 days. CAP biodegradation which fitted well with the first-order kinetics. YB1 still degrades CAP under Cd stress, however 10 mg L-1 Cd inhibited CAP biodegradation by 15.1%. Biotransformation pathways remained the same under Cd stress, but two new products (Cmpd 19 and Cmpd 20) were identified. Five parallel metabolism pathways of CAP were proposed with/without Cd stress, including one novel pathway (pathway 5) that has not been reported before. In pathway 5, the initial reaction was oxidation of CAP by disruption of C-C bond at the side chain of C1 and C2 with the formation of 4-nitrobenzyl alcohol and CY7, then these intermediates were oxidized into p-nitrobenzoic acid and CY1, respectively. CAP acetyltransferase and nitroreductase and 2,3/4,5-dioxygenase may play an important role in CAP biodegradation through genome analysis and prediction. This study deepens our understanding of mechanism of antibiotic degradation under heavy metal stress in the environment.

Caracterização molecular e fenotípica de Klebsiella spp. produtoras de NDM / Molecular and phenotypic characterization of Klebsiella spp. NDM producers

O perfil de resistência, que algumas das espécies do complexo Klebsiella pneumoniae podem expressar, representa uma grande ameaça à saúde humana, particularmente quando resistentes aos carbapenêmicos, que são amplamente utilizados no tratamento de infecções graves em pacientes hospitalizados. O principal mecanismo de resistência aos carbapenêmicos é a produção de carbapenemases, particularmente dos tipos KPC e NDM. Um dos compostos desenvolvidos para o tratamento de infecções causadas por cepas produtoras de KPC é a combinação ceftazidimaavibactam (CAZ-AVI), mas que não tem atividade inibitória sobre metalo-betalactamases, a exemplo das NDMs. Os objetivos deste trabalho foram determinar a frequência das espécies do complexo K. pneumoniae e da coprodução de KPC, avaliar a clonalidade dos isolados, a sensibilidade ao aztreonam-avibactam (ATM-AVI), o desempenho do disco de meropenem (MEM) com inibidores para detecção de coprodução de NDM e KPC e desenvolver um teste de triagem para prever a sensibilidade ao ATM-AVI. Um total de 113 isolados do complexo K. pneumoniae produtoras de NDM ou coprodutoras de NDM e KPC, provenientes da coleção de bactérias do Grupo Fleury, coletadas períodos pré e pós início do uso de CAZ-AVI no Brasil, foram utilizadas neste estudo. A identificação da espécie e a presença dos genes blaNDM e blaKPC foi confirmada por PCR multiplex. A clonalidade dos isolados foi avaliada por eletroforese em campos pulsados (PFGE) após clivagem com XbaI. A produção de carbapenemases foi confirmada utilizando-se o teste Blue Carba. O desempenho dos discos de meropenem e CAZ-AVI contendo um ou mais inibidores de carbapenemases foi comparado com o teste molecular. A pré-difusão combinada foi realizada pré-incubando-se o ágar não inoculado com disco de CAZ-AVI, e a seguir aplicando-se o inóculo bacteriano e um disco de ATM após remover o disco de CAZ-AVI. Após incubação, os halos foram aferidos e correlacionados com a concentração inibitória mínima para ATM-AVI. As CIMs para ATM e ATM-AVI foram determinadas segundo o EUCAST. A identificação das espécies por PCR evidenciou as seguintes frequências: K. pneumoniae 75,2% (n=85); K. quasipneumoniae 16,8% (n=19), e K. variicola 8% (n=9). Uma fração de 12,4% (n=14) dos isolados apresentaram os genes blaNDM e blaKPC e 87,6% (n=99) apenas blaNDM. A análise dos perfis de PFGE de K. pneumoniae evidenciou a presença de cinco grupos clonais predominantes. Isolados do principal grupo clonal Ap (n=15) foram detectados nas cidades de São Paulo e Porto Alegre durante todo o período analisado. O grupo clonal Lp foi detectado nas cidades de São Paulo e Recife em 2019. Os dois principais grupos clonais no período pré-CAZ-AVI continham maior número de isolados do que aqueles no período de uso do CAZ-AVI. Os perfis de PFGE de K. quasipneumoniae evidenciaram quatro grupos clonais predominantes, e presentes apenas no estado de São Paulo, com persistência do grupo clonal Aq desde 2017. Quanto à K. variicola, foram observados dois grupos clonais predominantes Av e Bv, o primeiro presente apenas em São Paulo desde 2018 e o segundo em Porto Alegre apenas em 2019. Calculando-se a diferença entre os diâmetros de halo do disco MEM contendo EDTA e ácido fenilborônico (AFB) e o maior dos halos obtidos para MEM com EDTA ou AFB, observou-se que todos os isolados com coexpressão de KPC e NDM apresentaram diferença ≥ 5 mm. Uma fração de 42,3% dos isolados positivos apenas para blaNDM apresentaram sensibilidade para ATM (CIM ≤ 4 mg/L). Todos os isolados testados apresentaram CIM para ATM-AVI ≤ 1/4 mg/L, sendo a CIM90 0,125/4 mg/l. No teste de pré-difusão combinada, o menor diâmetro de halo obtido foi de 23 mm. A espécie predominante na amostragem foi K. pneumoniae. A disseminação clonal, observada neste estudo, contrasta com a diversidade clonal descrita em outros locais do mundo para produtores de NDM, exceto Grécia e China. Considerando os pontos de corte atuais para ATM, é provável que haja resposta clínica adequada no uso de ATM-AVI no tratamento de infecções causadas por isolados produtores de NDM e coprodutores de KPC e NDM. Utilizando-se o valor de corte de ≤ 5 mm para a diferença entre halos de inibição, de MEM com AFB e EDTA e o segundo maior halo com inibidor, a sensibilidade foi de 100% e a especificidade foi de 96,1,0%. O método de pré-difusão com CAZ-AVI e ATM é um método simples e o diâmetro ≥ 23 mm tem excelente correlação com a CIM para ATM-AVI ≤ 1/4 mg/L

The resistance profile, which some species of the Klebsiella pneumoniae complex may express, represent a great threat to human health, particularly when resistant to carbapenems, which are widely used in the treatment of severe infections in hospitalized patients. The main mechanism of resistance to carbapenems is the production of carbapenemases, particularly KPCs and NDMs. One of the compounds developed for the treatment of infections caused by KPC-producing strains is the combination ceftazidime-avibactam (CAZ-AVI), but which has no inhibitory activity on metallobetalactamases, as is the case for NDMs. The objectives of this work were to determine the frequency of K. pneumoniae complex species and KPC co-production, evaluate the clonality of isolates, the susceptibility to aztreonam-avibactam (ATM-AVI), the performance of meropenem (MEM) disks with inhibitors for detecting NDM co-production and KPC and develop a screening test to predict sensitivity to ATM-AVI. A total of 113 NDM-producing or NDM and KPC co-producing K. pneumoniae complexes, from the Fleury Group's bacteria collection, collected in the pre- and post-starting periods of CAZ-AVI use in Brazil, were used in this study. Species identification and the presence of the blaNDM and blaKPC genes were confirmed by multiplex PCR. The clonality of the isolates was evaluated by pulsed field electrophoresis (PFGE) after cleavage with XbaI. Carbapenemase production was confirmed using the Blue Carba test. The performance of MEM and CAZ-AVI disks containing one or more carbapenemase inhibitors was compared with the molecular test. Combined pre-diffusion was performed by preincubating the uninoculated agar with a CAZ-AVI disk, and then applying the bacterial inoculum and na ATM disk after removal of the CAZ-AVI disk. After incubation, halos were measured and correlated with the minimum inhibitory concentration (MIC) for ATM-AVI. ATM and ATM-AVI MICs were determined according to EUCAST. The identification of species by PCR evidenced the following frequencies: K. pneumoniae 75.2% (n=85); K. quasipneumoniae 16.8% (n=19), and K. variicola 8% (n=9). A fraction of 12.4% (n=14) of the isolates had the blaNDM and blaKPC genes and 87.6% (n=99) had only blaNDM. The analysis of the PFGE profiles of K. pneumoniae evidenced the presence of five predominant clonal groups. Isolates from the main clonal group Ap (n=16) were detected in the cities of São Paulo and Porto Alegre throughout the analyzed period. The clonal group Lp was detected in the cities of São Paulo and Recife 2019. The PFGE profiles of K. quasipneumoniae showed four predominant clonal groups, present only in the state of São Paulo, with persistence of the clonal group Aq since 2017. As for K. variicola, two predominant clonal groups Av and Bv were observed, the first present only in São Paulo since 2018 and the second in Porto Alegre only in 2019. Calculating the difference between the inhibition zone diameters of the MEM disk containing EDTA and phenylboronic acid (AFB) and the largest of the inhibition zone diameters obtained for MEM with EDTA or AFB, it was observed that all isolates with co-expression of KPC and NDM showed a difference 5 ≥mm. A fraction of 42.3% of isolates positive only for blaNDM showed sensitivity to ATM (MIC ≤ 4 mg/L). All tested isolates presented MIC for ATM-AVI ≤ 1/4 mg/L, being the MIC90 0.125/4 mg/l. In the combined pre-diffusion test, the smallest inhibition zone diameter obtained was 23 mm. The predominant species in the sample was K. pneumoniae, but a significant fraction of the other species in the complex was also observed in the sample. The clonal spread observed in this study contrasts with the clonal diversity described elsewhere in the world for NDM-producing isolates, except Greece and China. Considering the current cut-off points for ATM, it is likely that there is an adequate clinical response in the use of ATM-AVI in infections caused by NDM-producing and KPC-NDM co-producing isolates in Brazil. Using the cutoff value of 5 mm for the difference between inhibition zones, of MEM with AFB and EDTA and the second largest zone of MEM with inhibitor, the sensitivity was 100% and the specificity was 96.1%. The pre-diffusion method with CAZ-AVI and ATM is a simple method and the diameter ≥ 23 mm has excellent correlation with the MIC for ATM-AVI ≤ 1/4 mg/L

Insights into evolution and coexistence of the colibactin- and yersiniabactin secondary metabolite determinants in enterobacterial populations.

The bacterial genotoxin colibactin interferes with the eukaryotic cell cycle by causing dsDNA breaks. It has been linked to bacterially induced colorectal cancer in humans. Colibactin is encoded by a 54 kb genomic region in Enterobacteriaceae. The colibactin genes commonly co-occur with the yersiniabactin biosynthetic determinant. Investigating the prevalence and sequence diversity of the colibactin determinant and its linkage to the yersiniabactin operon in prokaryotic genomes, we discovered mainly species-specific lineages of the colibactin determinant and classified three main structural settings of the colibactin-yersiniabactin genomic region in Enterobacteriaceae. The colibactin gene cluster has a similar but not identical evolutionary track to that of the yersiniabactin operon. Both determinants could have been acquired on several occasions and/or exchanged independently between enterobacteria by horizontal gene transfer. Integrative and conjugative elements play(ed) a central role in the evolution and structural diversity of the colibactin-yersiniabactin genomic region. Addition of an activating and regulating module (clbAR) to the biosynthesis and transport module (clbB-S) represents the most recent step in the evolution of the colibactin determinant. In a first attempt to correlate colibactin expression with individual lineages of colibactin determinants and different bacterial genetic backgrounds, we compared colibactin expression of selected enterobacterial isolates in vitro. Colibactin production in the tested Klebsiella species and Citrobacter koseri strains was more homogeneous and generally higher than that in most of the Escherichia coli isolates studied. Our results improve the understanding of the diversity of colibactin determinants and its expression level, and may contribute to risk assessment of colibactin-producing enterobacteria.

Caseinolytic Proteins (Clp) in the Genus Klebsiella: Special Focus on ClpK.

Caseinolytic proteins (Clp), which are present in both prokaryotes and eukaryotes, play a major role in cell protein quality control and survival of bacteria in harsh environmental conditions. Recently, a member of this protein family, ClpK was identified in a pathogenic strain of Klebsiella pneumoniae which was responsible for nosocomial infections. ClpK is linked to the thermal stress survival of this pathogen. The genome wide analysis of Clp proteins in Klebsiella spp. indicates that ClpK is present in only 34% of the investigated strains. This suggests that the uptake of the clpk gene is selective and may only be taken up by a pathogen that needs to survive harsh environmental conditions. In silico analyses and molecular dynamic simulations show that ClpK is mainly α-helical and is highly dynamic. ClpK was successfully expressed and purified to homogeneity using affinity and anion exchange chromatography. Biophysical characterization of ClpK showed that it is predominantly alpha-helical, and this is in agreement with in silico analysis of the protein structure. Furthermore, the purified protein is biologically active and hydrolyses ATP in a concentration- dependent manner.

Cooperation between two strains of Enterobacter and Klebsiella in the simultaneous nitrogen removal and phosphate accumulation processes.

Two strains, Enterobacter sp. Z1 and Klebsiella sp. Z2, were exhibited great capacities for heterotrophic nitrification-aerobic denitrification (HNAD) and intracellular phosphate accumulation. Strikingly, the co-cultured strains enhanced the removal efficiency of total nitrogen and phosphate, with removal efficiencies of ammonia, nitrate, nitrite and soluble phosphate of 99.64%, 99.85%, 96.94% and 66.7% respectively. Furthermore, high removal efficiencies from wastewaters with high concentrations of ammonia (over 1000 mg/L) were achieved by inoculation with the co-strains, which left residual ammonia of less than 1 mg/L within 10 h. To elucidate the mechanism of HNAD in co-strains, quantitative PCR was carried out to examine the expression levels of hydroxylamine oxidase (Hao), nitrate reductase (NapA and NarG), nitrite reductase (NirS) and polyphosphate kinase (Ppk), and the results showed that the napA2, narG and ppk genes in the strains were significantly upregulated under the co-cultured conditions and provided an explanation for the nitrogen and phosphate removal.

Three-dimensional graphene for electrochemical detection of Cadmium in Klebsiella michiganensis to study the influence of Cadmium uptake in rice plant.

Cadmium (Cd), as a hazardous pollutant present in the environment as well as within biological samples, needs to be detected and remediated at the same time. Although many types of Cd detection techniques have been developed globally, there is no evidence to analyse Cd2+ ion electrochemically using graphene-based electrode for bioaccumulation of Cd in bacteria and plants. The present study describes the fabrication and characterization of a three-dimensional reduced graphene oxide-based electrode to detect bioaccumulation of Cd within the bacterial cell and rice tissues applying differential pulse voltammetry (DPV) technique. In addition, X-ray fluorescence (XRF) and X-ray diffraction (XRD) studies were performed as supporting tools for this study in the selected Cd resistant plant growth promoting rhizobacterial (PGPR) strain, Klebsiella michiganensis MCC3089. This strain was characterized based on its plant growth promoting (PGP) traits and exhibited bioaccumulation of Cd both under high and low Cd concentrations, of which the latter is more environmentally significant. The Cd-sequestration ability of this strain was found to reduce Cd uptake within rice seedlings.

Decolorization and biodegradation of reactive Red 198 Azo dye by a new Enterococcus faecalis-Klebsiella variicola bacterial consortium isolated from textile wastewater sludge.

The present study investigated biodegradation and removal of Reactive Red 198 (RR198) dye from aqueous environments using a new bacterial consortium isolated from textile wastewater sludge on laboratory scale via batch study. Two bacterial species, Enterococcus faecalis (EF) and Klebsiella variicola (KV), were identified after isolation, through biochemical assays, Polymerase chain reaction (PCR), and 16S rRNA gene sequencing. To determine their ability to biodegrade RR198 dye, physicochemical parameters, including bacterial concentration, time, pH, and temperature, were tested; the results showed that the best conditions included a bacterial concentration of 3.5 mL × 105 cells/mL and incubation time of 72 h. Under such conditions, the removal efficiency of RR198 dye at an initial concentration of 10-25 mg/L was more than 98%; however, for concentrations of 50, 75, and 100 mg/L, removal efficiency was reduced to 55.62%, 25.82%, and 15.42%, respectively (p = 0.005). The highest removal efficiency occurred at pH 8.0, reaching 99.26% after 72 h of incubation. With increasing the incubation temperature from 25 °C to 37 °C, removal efficiency increased from 71.71 to 99.26% after 72 h of incubation, and increasing the temperature from 37 to 45 °C, the removal efficiency was reduced (p ≤ 0.001). Therefore, the EF-KV bacterial consortium can be used for efficient removal of RR198 dye from textile effluent.

Sugar and iron: Toward understanding the antibacterial effect of ciclopirox in Escherichia coli.

New antibiotics are needed against antibiotic-resistant gram-negative bacteria. The repurposed antifungal drug, ciclopirox, equally blocks antibiotic-susceptible or multidrug-resistant Acinetobacter baumannii, Escherichia coli, and Klebsiella pneumoniae clinical isolates, indicating that it is not affected by existing resistance mechanisms. Toward understanding how ciclopirox blocks growth, we screened E. coli mutant strains and found that disruption of genes encoding products involved in galactose salvage, enterobacterial common antigen synthesis, and transport of the iron binding siderophore, enterobactin, lowered the minimum inhibitory concentration of ciclopirox needed to block growth of the mutant compared to the isogenic parent strain. We found that ciclopirox induced enterobactin production and that this effect is strongly affected by the deletion of the galactose salvage genes encoding UDP-galactose 4-epimerase, galE, or galactose-1-phosphate uridylyltransferase, galT. As disruption of ECA synthesis activates the regulation of capsular synthesis (Rcs) phosphorelay, which inhibits bacterial swarming and promotes biofilm development, we test whether ciclopirox prevents activation of the Rcs pathway. Sub-inhibitory concentrations of ciclopirox increased swarming of the E. coli laboratory K12 strain BW25113 but had widely varying effects on swarming or surface motility of clinical isolate E. coli, A. baumannii, and K. pneumoniae. There was no effect of ciclopirox on biofilm production, suggesting it does not target Rcs. Altogether, our data suggest ciclopirox-mediated alteration of lipopolysaccharides stimulates enterobactin production and affects bacterial swarming.

Effects ofdirect current on Klebsiella spp. viability and corresponding resistance gene expression in simulative bio-electrochemical reactors.

The fate of antibiotic-resistant bacteria (ARB) and associated antibiotic-resistant gene (ARG) expression under electrolytic stimulation in bio-electrochemical reactors (BERs) was unknown. In this study, sulfadiazine resistant bacteria (Klebsiella spp.), which were isolated from a BER, were subjected to constant direct current (DC) stimulation in a simulated BER. With an increase of the current from 7 to 28 mA, it was found that lactic dehydrogenase (LDH) showed a 1.03-, 1.21-, 1.34-, and 1.46-fold value compared with the control at 48 h, indicating that the cell membrane permeability had increased. Since the adenosine triphosphate (ATP) concentration increased with the current, the specific growth rate of Klebsiella spp. increased (R = 0.98). The viable count of Klebsiella spp. reached a maximum at 19 mA and then decreased. The percentage of ARB lethality, which was reflected by flow cytometry analysis, increased from 18% (7 mA) to 37.8% (28 mA) at 48 h. Reactive oxygen species (ROS) produced from the electrolysis of water were greater with the increasing current (R = 0.94), which may be responsible for the high lethality rate of Klebsiella spp.. Scanning electronic microscope results showed that electrolytic stimulation changed the cell surface morphology with some cell disruption. An upregulation of sulII and int1 expression was observed. A significant correlation between int1 and the current (R = 0.97) were observed. Taken together, BERs possess potential risks in accelerating ARB multiplication and promoting ARG expression.

Degradation of euptox A by tannase-producing rumen bacteria from migratory goats.

AIMS: The gut microbiota capable of degrading plant biomass and antinutritional phytometabolites are of immense importance. This study reports isolation and characterization of tannase-producing rumen bacteria that could also degrade euptox A (9-oxo-10,11-dehydroageraphorone) present in Eupatorium adenophorum (Spreng). METHODS AND RESULTS: Migratory Gaddi goats were selected as source of inoculums for isolating rumen bacteria with ability to produce tannase which catalyses degradation of hydrolysable tannins (HTs). Three rumen bacterial isolates producing tannase were studied, and identified as Klebsiella variicola strain PLP G-17 LC, K. variicola strain PLP S-18 and Klebsiella pneumoniae strain PLP G-17 SC. The isolates exhibited optimal tannase activity at 40°C, and pH 6·0. The bacteria could also degrade euptox A, a potent hepatotoxin in E. adenophorum Spreng, a widely distributed noxious weed. CONCLUSIONS: The rumen bacteria could degrade antinutritional HTs and euptox A. Culture-independent metagenomic interventions are envisioned to completely decipher the rumen microbial ecology and exploit its genetic and metabolic potential. SIGNIFICANCE AND IMPACT OF THE STUDY: The bacteria producing tannase which catalyses degradation of HTs, and concurrently degrading euptox A, may have potential as microbial feed additives to increase utilization of plant biomass containing antinutritional phytometabolites.

Performance of the dominant bacterial species and microbial community in autotrophic denitrification coupled with iron cycle in immobilized systems.

We used three stable reactors to investigate the rates of nitrate removal coupled with iron cycle and the subsequent influence of the reaction on bacterial communities. The iron-reducing bacterium Klebsiella sp. FC61 was immobilized on the reactor columns of the experimental groups B (only Klebsiella) and C (Klebsiella+magnetite). With the fluctuation of Fe2+ to Fe3+ (iron cycle), the average nitrate removal efficiency increased from 73.22% to 93.91% and 86.92% to 97.84% in groups B and C, respectively, as the influent nitrate concentration decreased from 40 to 10mg/L. However, the average rate of nitrate removal showed the opposite trend (from 2.08mg/L/h to 0.67mg/L/h and 2.41mg/L/h to 0.69mg/L/h in groups B and C, respectively) as the influent nitrate concentration decreased. Analysis of microbial distribution and community structures indicated that the population of Klebsiella sp. increased in groups B (from 18.21% to 41.21%) and C (from 25.43% to 46.80%) and contributed to the effective removal of nitrate in the reactors.

Characterization of Klebsiella sp. strain S1: a bacterial producer of secoisolariciresinol through biotransformation.

Secoisolariciresinol (SECO) is a lignan of potential therapeutic value for diseases such as cancer, but its use has been limited by the lack of ideal production methods, even though its precursors are abundant in plants, such as flaxseeds. Here, we report the characterization of a bacterial strain, S1, isolated from the human intestinal flora, which could produce secoisolariciresinol by biotransformation of precursors in defatted flaxseeds. This bacterium was a Gram-negative and facultatively anaerobic straight rod without capsules. Biochemical assays showed that it was negative for production of oxidase, lysine decarboxylase, ornithine decarboxylase, arginine dihydrolase, and ß-glucolase. The G + C content of genomic DNA was 57.37 mol%. Phylogenetic analysis by 16S rRNA and rpoB gene sequences demonstrated S1's close relatedness to Klebsiella. No homologues were found for wzb or wzc (capsular genes), which may explain why Klebsiella sp. strain S1 does not have the capsule and was isolated from a healthy human individual. Based on the percentages of homologous genes with identical nucleotide sequences between the bacteria in comparison, we found that clear-cut genetic boundaries had been formed between S1 and any other Klebsiella strains compared, dividing them into distinct phylogenetic lineages. This work demonstrates that the intestinal Klebsiella, well known as important opportunistic pathogens prevalent in potentially fatal nosocomial infections, may contain lineages that are particularly beneficial to the human health.

A novel microbe-based treatment that attenuates the inflammatory profile in a mouse model of allergic airway disease.

There is an unmet need for effective new and innovative treatments for asthma. It is becoming increasingly evident that bacterial stimulation can have beneficial effects at attenuating allergic airway disease through immune modulation. Our aim was to test the ability of a novel inactivated microbe-derived therapeutic based on Klebsiella (KB) in a model of allergic airway disease in mice. BALB/c mice were exposed intranasally to house dust mite (HDM) for two weeks. Mice were treated prophylactically via subcutaneous route with either KB or placebo for one week prior to HDM exposure and throughout the two week exposure period. 24 hours after the last exposure, lungs were analysed for inflammatory cell infiltrate, gene expression, cytokine levels, goblet cell metaplasia, and serum was analysed for allergen-specific serum IgE levels. HDM exposed mice developed goblet cell hyperplasia, elevated allergen-specific serum IgE, airway eosinophilia, and a concomitant increase in TH2 cytokines including IL-4, IL-13 and IL-5. Treatment with KB attenuated HDM-mediated airway eosinophilia, total bronchoalveolar lavage (BAL) cell numbers, BAL TH2 cytokine production, and goblet cell metaplasia. Our prophylactic intervention study illustrates the potential of subcutaneous treatment with bacterial derived biologics as a promising approach for allergic airway disease treatment.

Analysis for the presence of determinants involved in the transport of mercury across bacterial membrane from polluted water bodies of India

Abstract Mercury, which is ubiquitous and recalcitrant to biodegradation processes, threatens human health by escaping to the environment via various natural and anthropogenic activities. Non-biodegradability of mercury pollutants has necessitated the development and implementation of economic alternatives with promising potential to remove metals from the environment. Enhancement of microbial based remediation strategies through genetic engineering approaches provides one such alternative with a promising future. In this study, bacterial isolates inhabiting polluted sites were screened for tolerance to varying concentrations of mercuric chloride. Following identification, several Pseudomonas and Klebsiella species were found to exhibit the highest tolerance to both organic and inorganic mercury. Screened bacterial isolates were examined for their genetic make-up in terms of the presence of genes (merP and merT) involved in the transport of mercury across the membrane either alone or in combination to deal with the toxic mercury. Gene sequence analysis revealed that the merP gene showed 86–99% homology, while the merT gene showed >98% homology with previously reported sequences. By exploring the genes involved in imparting metal resistance to bacteria, this study will serve to highlight the credentials that are particularly advantageous for their practical application to remediation of mercury from the environment.

Reduction of ethylenediaminetetraacetic acid iron(III) by Klebsiella sp. FD-3 immobilized on iron(II, III) oxide poly (styrene-glycidyl methacrylate) magnetic porous microspheres: effects of inorganic compounds and kinetic study of effective diffusion in porous media.

Fe3O4 poly (styrene-glycidyl methacrylate) magnetic porous microspheres (MPPMs) were introduced to immobilize Klebsiella sp. FD-3, an iron-reducing bacterium applied to reduce Fe(III)EDTA. The effects of potential inhibitors (S(2-), SO3(2-), NO3(-), NO2(-) and Fe(II)EDTA-NO) on Fe(III)EDTA reduction were investigated. S(2-) reacted with Fe(III)EDTA as an electron-shuttling compound and enhanced the reduction. But Fe(III)EDTA reduction was inhibited by SO3(2-) and Fe(II)EDTA-NO due to their toxic to microorganisms. Low concentrations of NO3(-) and NO2(-) accelerated Fe(III)EDTA reduction, but high concentrations inhibited the reduction, whether by free or immobilized FD-3. The immobilized FD-3 performed better than freely-suspended style. The substrate mass transfer and diffusion kinetics in the porous microspheres were calculated. The value of Thiele modulus and effectiveness factors showed that the intraparticle diffusion was fairly small and neglected in this carrier. Fe(III)EDTA reduction fitted first-order model at low Fe(III)EDTA concentration, and changed to zero-order model at high concentrations.

Endosulfan induced alteration in bacterial protein profile and RNA yield of Klebsiella sp. M3, Achromobacter sp. M6, and Rhodococcus sp. M2.

Three bacterial strains identified as Klebsiella sp. M3, Achromobacter sp. M6 and Rhodococcus sp. M2 were isolated by soil enrichment with endosulfan followed by shake flask enrichment technique. They were efficiently degrading endosulfan in the NSM (non sulfur medium) broth. Degradation of endosulfan was faster with the cell free extract of bacterial cells grown in the sulfur deficient medium (NSM) supplemented with endosulfan than that of nutrient rich medium (Luria Bertani). In the cell free extract of NSM supplemented with endosulfan as sole sulfur source, a unique band was visualized on SDS-PAGE but not with magnesium sulfate as the sole sulfur source in NSM and LB with endosulfan. Expression of a unique polypeptide band was speculated to be induced by endosulfan under sulfur starved condition. These unique polypeptide bands were identified as OmpK35 protein, sulfate binding protein and outer membrane porin protein, respectively, in Klebsiella sp. M3, Achromobacter sp. M6 and Rhodococcus sp. M2. Endosulfan showed dose dependent negative effect on total RNA yield of bacterial strains in nutrient rich medium. Absence of plasmid DNA indicated the presence of endosulfan metabolizing gene on genomic DNA.

Bacterial succession and degradative changes by biofilm on plastic medium for wastewater treatment.

Biofilms contain a diverse range of microorganisms and their varying extracellular polysaccharides. The present study has revealed biofilm succession associated with degradative effects on plastic (polypropylene) and contaminants in sludge. The wet weight of biofilm significantly (p < 0.05) increased; from 0.23 ± 0.01 to 0.44 ± 0.01 g. Similarly, the dry weight of the biofilm increased from 0.02 to 0.05 g. Significant reduction in pathogens (E. coli and feacal coliforms) by MPN technique (>80%) and in chemical parameters (decrease in COD, BOD5 of 73.32 and 69.94%) representing diminution of organic pollutants. Energy dispersive X-ray spectroscopy (EDS) of plastic revealed carbon and oxygen contents, further surface analysis of plastic by scanning electron microscopy (SEM) revealed emergence of profound bacterial growth on the surface. Fourier transform infrared (FTIR) spectroscopy conforms its biotransformation under aerobic conditions after 8 weeks. New peaks developed at the region 1050 and 969 cm(-1) indicating CO and CC bond formation. Thus plastic with 6 weeks old aerobic biofilm (free of pathogens, max. weight, and OD, efficient COD & BOD removal ability) is suggested to be maintained in fixed biofilm reactors for wastewater treatment.