Agriculture versus wastewater pollution as drivers of macroinvertebrate community structure in streams.

Water pollution is ubiquitous globally, yet how the effects of pollutants propagate through natural ecosystems remains poorly understood. This is because the interactive effects of multiple stressors are generally hard to predict. Agriculture and municipal wastewater treatment plants (WWTPs) are often major sources of contaminants for streams, but their relative importance and the role of different pollutants (e.g. nutrients or pesticides) are largely unknown. Using a 'real world experiment' with sampling locations up- and downstream of WWTPs, we studied how effluent discharges affected water quality and macroinvertebrate communities in 23 Swiss streams across a broad land-use gradient. Variation partitioning of community composition revealed that overall water quality explained approximately 30% of community variability, whereby nutrients and pesticides each independently explained 10% and 2%, respectively. Excluding oligochaetes (which were highly abundant downstream of the WWTPs) from the analyses, resulted in a relatively stronger influence (3%) of pesticides on the macroinvertebrate community composition, whereas nutrients had no influence. Generally, the macroinvertebrate community composition downstream of the WWTPs strongly reflected the upstream conditions, likely due to a combination of efficient treatment processes, environmental filtering and organismal dispersal. Wastewater impacts were most prominently by the Saprobic index, whereas the SPEAR index (a trait-based macroinvertebrate metrics reflecting sensitivity to pesticides) revealed a strong impact of arable cropping but only a weak impact of wastewater. Overall, our results indicate that agriculture can have a stronger impact on headwater stream macroinvertebrate communities than discharges from WWTP. Yet, effects of wastewater-born micropollutants were clearly quantifiable among all other influence factors. Improving our ability to further quantify the impacts of micropollutants requires highly-resolved water quality and taxonomic data with adequate spatial and temporal sampling. These improvements would help to better account for the underlying causal pathways that drive observed biological responses, such as episodic contaminant peaks and dispersal-related processes.

Comparative profiling of lipid-soluble antioxidants and transcripts reveals two phases of photo-oxidative stress in a xanthophyll-deficient mutant of Chlamydomonas reinhardtii.

Excess light can impose severe oxidative stress on photosynthetic organisms. We have characterized high-light responses in wild-type Chlamydomonas reinhardtii and in the npq1 lor1 double mutant. The npq1 lor1 strain lacks two photoprotective carotenoids, lutein and zeaxanthin, and experiences acute photo-oxidative stress upon exposure to excess light. To examine the ability of npq1 lor1 cells to respond to photo-oxidative stress, we measured changes in lipid-soluble antioxidants following a shift from low light to high light in the wild type and the double mutant. The size of the xanthophyll cycle pool increased in both the wild type and mutant during the first 6 h of exposure to high light levels, but then decreased in the mutant during photo-oxidative bleaching. The level of alpha-tocopherol (vitamin E) was constant in the wild type and mutant during the first 6 h; then it increased by three-fold in the wild type but declined in npq1 lor1 cells. We also used cDNA microarrays and RNA gel-blot analysis to monitor differences in gene expression. Both strains showed an initial light-stress response in the form of a transient increase in expression of (1) GPXH, a glutathione peroxidase gene that has been shown to respond specifically to singlet oxygen and lipid peroxidation; (2) SMT1, a gene for a putative sterol C-methyltransferase; and (3) LI818r, a stress-responsive member of the light-harvesting complex superfamily. These transient changes in gene expression in high light were followed by a second series of changes in npq1 lor1, coincident with declines in lipid-soluble antioxidants but preceding detectable photo-oxidative damage to proteins and lipids. Thus, the response of npq1 lor1 to high light is unexpectedly complex, with initial changes in lipid-soluble antioxidants and RNA levels that are associated with acclimation in the wild type and a second wave of changes that accompanies photo-oxidative bleaching.

The glutathione peroxidase homologous gene from Chlamydomonas reinhardtii is transcriptionally up-regulated by singlet oxygen.

The glutathione peroxidase homologous gene (Gpxh gene) in Chlamydomonas reinhardtii is up-regulated under oxidative stress conditions. The Gpxh gene showed a remarkably strong and fast induction by the singlet oxygen-generating photosensitizers neutral red, methylene blue and rose Bengal. The Gpxh mRNA levels strongly increased, albeit much more slowly, upon exposure to the organic hydroperoxides tert-butyl hydroperoxide (t-BOOH) and cumene hydroperoxide. In contrast, the Gpxh mRNA levels were only weakly induced by exposure to the superoxide-generating compound paraquat and by hydrogen peroxide. A comparison of the Gpxh mRNA levels with those of the heat shock protein HSP70A and the iron superoxide dismutase gene showed qualitative and quantitative differences for the three genes under oxidative stress conditions tested. The Gpxh gene is specifically induced by singlet-oxygen photosensitizers and the relative induction by other compounds is much weaker for Gpxh than for the other genes investigated. Using Gpxh promoter fusions with the arylsulfatase reporter gene, we have shown that the Gpxh was transcriptionally up-regulated by singlet-oxygen photosensitizers. It is also shown that the Gpxh promoter contains a region between 104 and 179 bp upstream of the transcription start that is responsible for the mRNA up-regulation upon exposure to 1O2 but not t-BOOH. Within this region a regulatory sequence homologous to the mammalian cAMP response element (CRE) and activator protein 1 (AP-1) binding site was identified within a 16 bp palindrome.

Acute toxicity of (chloro-)catechols and (chloro-)catechol-copper combinations in Escherichia coli corresponds to their membrane toxicity in vitro.

(Chloro-)catechols are toxic for bacteria and higher organisms, but the mode of action is not yet clearly understood. We have compared the acute toxicity of different chlorinated catechols to Escherichia coli with membrane toxic effects, namely narcosis and uncoupling that we have determined in an in vitro assay. In vitro membrane toxicity was quantified by measuring the accelerated decay of the membrane potential of chromatophores isolated from Rhodobacter sphaeroides. Both acute and membrane toxicity increased with increasing degree of chlorination. Analysis of dose-response curves, pH dependence, and estimated membrane concentrations gave a consistent picture of the mechanisms of membrane toxicity: At pH 7, the higher-chlorinated catechols acted as uncouplers of oxidative and photophosphorylation, and the lower-chlorinated catechols and catechol acted as narcotics. In the case of 3,5-dichlorocatechol and 4-monochlorocatechol at pH 8.8, both mechanisms appeared to contribute to the overall toxicity. Copper exhibited a diverging effect on the toxicity of catechols and of (chloro-)catechols to E. coli. Whereas the presence of copper increased the toxicity of catechol and 4-monochlorocatechol, the toxicity of 3,5-dichlorocatechol, 3,4,5-trichlorocatechol, and tetrachlorocatechol decreased. Again, the results obtained with in vitro assays agreed with the acute toxicity observed in E. coli: The presence of copper accelerated decay of the membrane potential of catechol and 4-monochlorocatechol; however, the effect was reversed by copper in experiments with 3,5-dichlorocatechol, 3,4,5-trichlorocatechol, and tetrachlorocatechol. We have proposed a mechanistic model to explain the diverging effects of copper on the uncoupling activities of the different catechols.

Chemical properties of catechols and their molecular modes of toxic action in cells, from microorganisms to mammals.

Catechols can undergo a variety of chemical reactions. In this review, we particularly focus on complex formations and the redox chemistry of catechols, which play an inportant role in the toxicity of catechols. In the presence of heavy metals, such as iron or copper, stable complexes can be formed. In the presence of oxidizing agents, catechols can be oxidized to semiquinone radicals and in a next step to o-benzoquinones. Heavy metals may catalyse redox reactions in which catechols are involved. Further chemical properties like the acidity constant and the lipophilicity of different catechols are shortly described as well. As a consequence of the chemical properties and the chemical reactions of catechols, many different reactions can occur with biomolecules such as DNA, proteins and membranes, ultimately leading to non-repairable damage. Reactions with nucleic acids such as adduct formation and strand breaks are discussed among others. Interactions with proteins causing protein and enzyme inactivation are described. The membrane-catechol interactions discussed here are lipid peroxidation and uncoupling. The deleterious effect of the interactions between catechols and the different biomolecules is discussed in the context of the observed toxicities, caused by catechols.

DNA degradation by the mixture of copper and catechol is caused by DNA-copper-hydroperoxo complexes, probably DNA-Cu(I)OOH.

Free hydroxyl radicals (free (.)OH), singlet oxygen ((1)O(2)), or (. )OH produced by DNA-copper-hydroperoxo complexes are possible DNA-damaging reactive oxygen species (ROS) in the reaction system containing copper, catechol, and DNA. para-Chlorobenzoic acid (pCBA) degradation studies revealed that CuCl(2) mixed with catechol produced free (.)OH. In the presence of DNA, however, inhibition of the pCBA degradation suggested that another ROS is responsible for the DNA degradation. Of a series of ROS scavengers investigated, only KI, NaN(3), and Na-formate-all of the salts tested-strongly inhibited the DNA degradation, suggesting that the ionic strength rather than the reactivity of the individual scavengers could be responsible for the observed inhibition. The ionic strength effect was confirmed by increasing the concentration of phosphate buffer, which is a poor (.)OH scavenger, and was interpreted as the result of destabilization of DNA-copper-hydroperoxo complexes. Piperidine-labile site patterns in DNA degraded by copper and catechol showed that the mixture of Cu(II) and catechol degrades DNA via the intermediate formation of a DNA-copper-hydroperoxo complex. Replacement of guanine by 7-deazaguanine did not retard the DNA degradation, suggesting that the DNA-copper-hydroperoxo complexes do not bind to the guanine N-7 as proposed in the literature.

The oxidative stress-sensitive yap1 null strain of Saccharomyces cerevisiae becomes resistant due to increased carotenoid levels upon the introduction of the Chlamydomonas reinhardtii cDNA, coding for the 60S ribosomal protein L10a.

The Saccharomyces cerevisiae yap1 null strain was transformed with a Chlamydomonas reinhardtii cDNA expression library. A 688-bp cDNA fragment, coding for the 60S ribosomal protein L10a (RPL10a), restored the capacity of the S. cerevisiae yap1 null strain to resist oxidative stress. The rpl10a gene is a single-copy gene in C. reinhardtii and encodes a constitutively produced 1.35-kb mRNA. The deduced 214-residue amino acid sequence was highly related with RPL10a proteins from eukarya (between 46.1 and 63.7% identity) and archaea (between 24.5 and 29.2% identity). Resistant transformants were pink, due to increased carotenoid levels, with the same chemical structure as torularhodin, the main carotenoid of the pink yeast Rhodotorula mucilaginosa. The pink transformants showed high resistance levels against H(2)O(2), paraquat, menadione, and UV light. Partial inhibition of the carotenoid synthesis by diphenylamine reduced the resistance levels, demonstrating the role of excess carotenoid synthesis in the resistance mechanism.

Combinations of chlorocatechols and heavy metals cause DNA degradation in vitro but must not result in increased mutation rates in vivo.

Chlorocatechols introduced into the environment directly or as a result of degradation processes are highly toxic, particularly when combined with heavy metals. With in vitro DNA degradation assays, the high reactivity of chlorocatechols combined with heavy metals could be shown, whereby copper was shown to be more active than iron. Structure-activity analysis showed that the degradation potential of the chlorocatechols decreased with an increasing number of chloratoms. The addition of reactive oxygen species scavengers allowed the identification of hydrogen peroxide as an important agent leading to DNA damage in this reaction. The potential of other reactive compounds, however, can neither be determined nor excluded with this approach. Exposure of Escherichia coli and Salmonella typhimurium cultures to the same mixtures of chlorocatechols and copper surprisingly did not lead to an enhanced mutation rate. This phenomenon was explained by doing marker gene expression measurements and toxicity tests with E. coli mutants deficient in oxidative stress defense or DNA repair. In catechol-copper-exposed cultures an increased peroxide level could indeed be demonstrated, but the highly efficient defense and repair systems of E. coli avoid the phenotypical establishment of mutations. Increased mutation rates under chronic exposure, however, cannot be excluded.

Adaptive responses in Chlamydomonas reinhardtii.

The photosynthetic single cellular alga Chlamydomonas reinhardtii has been used as a model organism to examine in detail the physiological, biochemical and molecular processes of photosynthesis, flagella synthesis and movement, mineral stress, interactions between nucleus, chloroplasts and mitochondria and other processes. In this review we summarize part of the current knowledge on adaptive responses in C. reinhardtii when it is exposed to oxidative stress and to changes in light intensity, concentration of minerals, herbicides and metals. The individual responses are linked in order to understand the response of the cell, which is continuously subjected to fluctuations, as a whole.

Glutamate dehydrogenase from the hyperthermophilic bacterium Thermotoga maritima: molecular characterization and phylogenetic implications.

The hyperthermophilic bacterium Thermotoga maritima, which grows at up to 90 degrees C, contains an L-glutamate dehydrogenase (GDH). Activity of this enzyme could be detected in T. maritima crude extracts, and appeared to be associated with a 47-kDa protein which cross-reacted with antibodies against purified GDH from the hyperthermophilic archaeon Pyrococcus woesei. The single-copy T. maritima gdh gene was cloned by complementation in a glutamate auxotrophic Escherichia coli strain. The nucleotide sequence of the gdh gene predicts a 416-residue protein with a calculated molecular weight of 45,852. The gdh gene was inserted in an expression vector and expressed in E. coli as an active enzyme. The T. maritima GDH was purified to homogeneity. The NH2-terminal sequence of the purified enzyme was PEKSLYEMAVEQ, which is identical to positions 2-13 of the peptide sequence derived from the gdh gene. The purified native enzyme has a size of 265 kDa and a subunit size of 47kDa, indicating that GDH is a homohexamer. Maximum activity of the enzyme was measured at 75 degrees C and the pH optima are 8.3 and 8.8 for the anabolic and catabolic reaction, respectively. The enzyme was found to be very stable at 80 degrees C, but appeared to lose activity quickly at higher temperatures. The T. maritima GDH shows the highest rate of activity with NADH (Vmax of 172 U/mg protein), but also utilizes NADPH (Vmax of 12 U/mg protein). Sequence comparisons showed that the T. maritima GDH is a member of the family II of hexameric GDHs which includes all the GDHs isolated so far from hyperthermophiles. Remarkably, phylogenetic analysis positions all these hyperthermophilic GDHs in the middle of the GDH family II tree, with the bacterial T. maritima GDH located between that of halophilic and thermophilic euryarchaeota.

Isolation and characterization of the hyperthermostable serine protease, pyrolysin, and its gene from the hyperthermophilic archaeon Pyrococcus furiosus.

The hyperthermostable serine protease pyrolysin from the hyperthermophilic archaeon Pyrococcus furiosus was purified from membrane fractions. Two proteolytically active fractions were obtained, designated high (HMW) and low (LMW) molecular weight pyrolysin, that showed immunological cross-reaction and identical NH2-terminal sequences in which the third residue could be glycosylated. The HMW pyrolysin showed a subunit mass of 150 kDa after acid denaturation. Incubation of HMW pyrolysin at 95 degrees C resulted in the formation of LMW pyrolysin, probably as a consequence of COOH-terminal autoproteolysis. The 4194-base pair pls gene encoding pyrolysin was isolated and characterized, and its transcription initiation site was identified. The deduced pyrolysin sequence indicated a prepro-enzyme organization, with a 1249-residue mature protein composed of an NH2-terminal catalytic domain with considerable homology to subtilisin-like serine proteases and a COOH-terminal domain that contained most of the 32 possible N-glycosylation sites. The archaeal pyrolysin showed highest homology with eucaryal tripeptidyl peptidases II on the amino acid level but a different cleavage specificity as shown by its endopeptidase activity toward caseins, casein fragments including alphaS1-casein and synthetic peptides.

Carbon monoxide dehydrogenase from Methanosarcina frisia Gö1. Characterization of the enzyme and the regulated expression of two operon-like cdh gene clusters.

Carbon monoxide dehydrogenase (Cdh) has been anaerobically purified from Methanosarcina frisia Gö1. The enzyme is a Ni2+-, Fe2+-, and S2--containing alpha2beta2 heterotetramer of 214 kDa with a pI of 5.2 and subunits of 94 and 19 kDa. It has a Vmax of 0.3 mmol of CO min-1 mg-1 and Km values for CO and methyl viologen of approximately 0.9 mM and 0.12 mM, respectively. EPR spectroscopy on the reduced enzyme showed two overlapping signals: one indicative for 2 (4Fe-4S)+ clusters and a second signal that is atypical for standard Fe/S clusters. The latter was, together with high-spin EPR signals of the oxidized enzyme tentatively assigned to an Fe/S cluster of high nuclearity.

Rapid and sensitive method for the detection of Mycobacterium chlorophenolicum PCP-1 in soil based on 16S rRNA gene-targeted PCR.

A method based on 16S rRNA gene-targeted PCR and oligonucleotide probing was developed for detecting Mycobacterium chlorophenolicum PCP-1 in soil. The primers and probe were specific for PCP-1 in DNA extracts of three soils. The method allowed for PCP-1 detection in soil with a detection limit of 3 x 10(2) cells per g.

Exchange of domains of glutamate dehydrogenase from the hyperthermophilic archaeon Pyrococcus furiosus and the mesophilic bacterium Clostridium difficile: effects on catalysis, thermoactivity and stability.

The glutamate dehydrogenase gene from the hyperthermophilic archaeon Pyrococcus furiosus has been functionally expressed in Escherichia coli under the control of the lambda PL promoter. The P. furiosus glutamate dehydrogenase amounted to 20% of the total E. coli cell protein, and the vast majority consisted of hexamers. Following activation by heat treatment, an enzyme could be purified from E. coli that was indistinguishable from the glutamate dehydrogenase purified from P. furiosus. Hybrid genes, that consisted of the coding regions for the homologous glutamate dehydrogenases from P. furiosus and the mesophilic bacterium Clostridium difficile, were constructed and successfully expressed in E. coli. One of the resulting hybrid proteins, containing the glutamate binding domain of the C. difficile enzyme and the cofactor binding domain of the P. furiosus enzyme, did not show a detectable activity. In contrast, the complementary hybrid containing the P. furiosus glutamate and the C. difficile cofactor binding domain was a catalytically active hexamer that showed a reduced substrate affinity but maintained efficient cofactor binding with the specificity found in the Clostridium symbiosum enzyme. Compared with the C. difficile glutamate dehydrogenase, the archaeal-bacterial hybrid is slightly more thermoactive, less thermostable but much more stable towards guanidinium chloride-induced inactivation and denaturation.

Characterization of the celB gene coding for beta-glucosidase from the hyperthermophilic archaeon Pyrococcus furiosus and its expression and site-directed mutation in Escherichia coli.

The celB gene encoding the cellobiose-hydrolyzing enzyme beta-glucosidase from the hyperthermophilic archaeon Pyrococcus furiosus has been identified, cloned, and sequenced. The transcription and translation gene was overexpressed in Escherichia coli, resulting in high-level (up to 20% of total protein) production of beta-glucosidase that could be purified by a two-step purification procedure. The beta-glucosidase produced by E. coli had kinetic and stability properties similar to those of the beta-glucosidase purified from P. furiosus. The deduced amino acid sequence of CelB showed high similarity with those of beta-glycosidases that belong to glycosyl hydrolase family 1, implicating a conserved structure. Replacement of the conserved glutamate 372 in the P. furiosus beta-glucosidase by an aspartate or a glutamine led to a high reduction in specific activity (200- or 1,000-fold, respectively), indicating that this residue is the active site nucleophile involved in catalysis above 100 degrees C.

Regulated gene expression in methanogens.

Methanogens form a very large and diverse group of microorganisms within the domain of the Archaea. Energy for their growth is obtained by the reduction of a variety of substrates into methane. Several genes, coding for enzymes involved in methanogenesis or in the central metabolism have been cloned and studied. The molecular features of their expression signals have been compared with bacterial and eukaryal expression signals. This indicated that the transcription process is an intermediate form between the specific processes known in Bacteria and Eukarya. The translation system that is used in Archaea is very similar with the process in Bacteria. Although the molecular features of genes and expression signals in Archaea are well-studied, investigations on the regulation of gene expression in these organisms are very scarce. In order to give insight into molecular regulatory mechanisms in methanogens, the current knowledge of regulated systems in methanogens will be reviewed in this manuscript.

Phylogenetic evidence for transfer of pentachlorophenol-mineralizing Rhodococcus chlorophenolicus PCP-I(T) to the genus Mycobacterium.

We determined the nucleotide sequence of a 16S rRNA gene of Rhodococcus chlorophenolicus PCP-I(T) (= DSM 43826T) (T = type strain). Sequence comparisons revealed that there was a close relationship between strain PCP-I(T) and strains belonging to the genus Mycobacterium. The sequence data were used to construct a phylogenetic tree, which showed that Mycobacterium chubuense is the closest relative of strain PCP-I(T). We propose that strain PCP-I(T) should be transferred to the genus Mycobacterium and renamed Mycobacterium chlorophenolicum PCP-I(T) comb. nov.

The glutamate dehydrogenase-encoding gene of the hyperthermophilic archaeon Pyrococcus furiosus: sequence, transcription and analysis of the deduced amino acid sequence.

Glutamate dehydrogenase (GDH) from the hyperthermophilic archaeon, Pyrococcus woesei, has been isolated, characterized and found to be very similar if not identical to the recently purified GDH from P. furiosus. Using a polymerase chain reaction, based on the N-terminal amino acid sequences of GDH, the P. furiosus gdh gene was identified, cloned into Escherichia coli and sequenced. The transcription start point of gdh has been mapped 1 nucleotide upstream from the ribosome-binding site. Using antiserum raised against purified GDH, expression of gdh was observed in E. coli. The deduced primary sequence of the P. furiosus GDH has been compared to various bacterial, archaeal and eukaryal GDHs and showed a high degree of similarity (32-52%).

Modular organization of related Archaeal plasmids encoding different restriction-modification systems in Methanobacterium thermoformicicum.

Nucleotide sequence comparison of the related 13513-bp plasmid pFV1 and the 11014-bp plasmid pFZ1 from the thermophilic archaeon Methanobacterium thermoformicicum THF and Z-245, respectively, revealed a homologous, approximately 8.2 kb backbone structure that is interrupted by plasmid-specific elements. Various highly conserved palindromic structures and an ORF that could code for a NTP-binding protein were identified within the backbone structure and may be involved in plasmid maintenance and replication. Each plasmid contains at comparable locations a module which specifies components of different restriction-modification (R/M) systems. The R/M module of pFV1 contained, in addition to the genes of the GGCC-recognizing R/M system MthTI, an ORF which may be involved in repair of G-T mismatches generated by deamination of m5C at high temperatures.

Cloning, sequence analysis, and functional expression of the acetyl coenzyme A synthetase gene from Methanothrix soehngenii in Escherichia coli.

In the acetoclastic methanogen Methanothrix soehngenii, acetate is activated to acetyl coenzyme A by acetyl coenzyme A synthetase (Acs). The acs gene, coding for the single Acs subunit, was isolated from a genomic library of M. soehngenii DNA in Escherichia coli by using antiserum raised against the purified Acs. After introduction in E. coli, the acs gene was expressed, resulting in the production of an immunoreactive protein of 68 kDa, which is approximately 5 kDa smaller than the known size of purified Acs. In spite of this difference in size, the Acs enzymes are produced in similar quantities in E. coli and M. soehngenii and show comparable specific activities. Upstream from the acs gene, consensus archaeal expression signals were identified. Immediately downstream from the acs gene there was a putative transcriptional stop signal. The amino acid sequence deduced from the nucleotide sequence of the acs gene showed homology with those of functionally related proteins, i.e., proteins involved in the binding of coenzyme A, ATP, or both.