Solid phase bioremediation of pendimethalin in contaminated soil and evaluation of leaching potential.

Substrate leaching experiments were performed to study the relative leaching potential of pendimethalin in various types of soil matrices. Pendimethalin leaching showed up to a depth of 30 cm in all the studied soil matrices, irrespective of pH conditions used. The leaching potential of pendimethalin was assessed at various pH conditions. Comparatively higher leaching potential was observed in basic conditions compared to the neutral and acid conditions of soil. Soil phase bioremediation of pendimethalin was also performed on all the soil matrices. Among the studied variations, bioremediation experiments performed in presence of sunlight showed higher efficiency. Bioaugmentation along with sunlight showed higher remediation efficiency in all the studied soil matrices. Biostimulation did not respond positively on the progress of bioremediation.

Treatment of composite chemical wastewater by aerobic GAC-biofilm sequencing batch reactor (SBGR).

The performance of granular activated carbon (GAC)-biofilm configured sequencing batch reactor (SBGR) in aerobic environment was investigated for the treatment of composite chemical wastewater [low BOD/COD ratio ( approximately 0.3), high sulfate content (1.75 g/l) and high TDS concentration (11 g/l)]. Composite wastewater was a combined mixture of effluents from about 100 chemical based industries. Reactor was operated under anoxic-aerobic-anoxic microenvironment conditions with a total cycle period of 24 h (fill: 15 min; reaction (aeration with recirculation): 23 h; settle: 30 min; decant: 15 min) and the performance of the system was studied at organic loading rates (OLR) of 1.7 kg COD/cum-day, 3.5 kg COD/cum-day and 5.5 kg COD/cum-day. The reactor showed efficient performance with respect to substrate degradation rate and sustained its performance at higher operating OLR (5.5 kg COD/cum-day) and at low BOD/COD ratio. Substrate utilization was found to increase with increase in the operating OLR. Maximum non-cumulative substrate utilization of 1.837 kg COD/cum-h, 2.99 kg COD/cum-h and 3.821 kg COD/cum-h was observed after 15 h of the cycle operation for operating OLRs of 1.7 kg COD/cum-day, 3.5 kg COD/cum-day and 5.5 kg COD/cum-day, respectively. Sulfate removal efficiency of 11+/-2% was recorded in the SBGR due to the induced anoxic conditions prevailing during the sequence phase operation of the reactor and the existing internal anoxic zones in the biofilm. Effective performance of the reactor may be attributed to sorption capacity of GAC as carrier material facilitating low toxicant concentration in the mixed liquor. The existing high flow rates around the GAC particle results in good mass transfer of the substrate from the bulk liquid. The long retention of biofilm on GAC increases the potential for the treatment of recalcitrant industrial wastewater. GAC configured biofilm configuration coupled with sequencing batch mode operation appears to be promising for the effective treatment of complex industrial wastewater containing poorly degradable compounds.

Placement of the alpha-sarcin loop within the 50S subunit: evidence derived using a photolabile oligodeoxynucleotide probe.

We report the synthesis of a radioactive, photolabile oligodeoxyribonucleotide probe and its exploitation in identifying 50S ribosomal subunit components neighboring the alpha-sarcin loop. The probe is complementary to 23S rRNA nt 2653-2674. Photolysis of the complex formed between the probe and 50S subunits leads to site-specific probe photoincorporation into proteins L2, the most highly labeled protein, L1, L15, L16 and L27, labeled to intermediate extents, and L5, L9, L17 and L24, each labeled to a minor extent. Portions of each of these proteins thus lie within 23 A of nt U2653. These results lead us to conclude that the alpha-sarcin loop is located at the base of the L1 projection within the 50S subunit. Such placement, near the peptidyl transferase center, provides a rationale for the extreme sensitivity of ribosomal function to cleavage of the alpha-sarcin loop.

Ribosomal components neighboring the 2475 loop in Escherichia coli 50S subunits.

We report the synthesis of a radioactive, photolabile oligodeoxyribonucleotide probe and its exploitation in identifying 50S ribosomal subunit components neighboring its target site in 23S rRNA. The probe is complementary to 23S rRNA nucleotides 2475-2483, a single-stranded sequence (the 2475 loop) near the peptidyltransferase center of Escherichia coli ribosomes. On photolysis in the presence of 50S subunits, it site-specifically incorporates into proteins L1, L13, L16, L32, and L33 and into 23S rRNA nucleotides G2470, A2471, and G2472. These results provide clear evidence that C2475 in 23S rRNA is within 21 A (the distance between C2475 and the photogenerated nitrene) of proteins L1, L13, L16, L32, and L33. The implications of these results for the evolving model of the internal structure of the 50S subunit are considered.

Photolabile oligoDNA probes of internal Escherichia coli ribosomal structure.

We are examining the spatial arrangement of ribosomal components in the vicinity of rRNA sequences of particular significance for ribosome structure and function through the use of radioactive, photolabile derivatives of oligoDNAs complementary to such sequences. The oligoDNA probes bind to their target sequences in intact ribosomal subunits, and, on photolysis, incorporate into neighboring ribosomal components. Labeled ribosomal proteins are subsequently identified by SDS-PAGE, RP-HPLC and immunoprecipitation. Labeled rRNA is identified at the nucleotide level by RNase H cleavage and primer extension. The results obtained provide a description of the neighborhood surrounding a particular rRNA sequence and impose important constraints on the evolving three-dimensional models of both the 30S and 50S subunits, since they typically oblige several ribosomal components to fall within defined distances of the targeted rRNA. Our results will be discussed in terms of these models, emphasizing their consistency or inconsistency.

Ribosomal components neighboring the conserved 518-533 loop of 16S rRNA in 30S subunits.

We report the synthesis of a radioactive, photolabile oligodeoxyribonucleotide probe complementary to 16S rRNA nucleotides 518-526 and its exploitation in identifying 30S ribosomal subunit components neighboring its target site in 16S rRNA. Nucleotides 518-526 lie within an almost universally conserved single-stranded loop that has been linked to the decoding region of Escherichia coli ribosomes. On photolysis in the presence of activated 30S ribosomes, the probe site-specifically incorporates into proteins S3, S4, S7, and S12 (identified by SDS-PAGE, RP-HPLC, and immunological analysis); nucleotides C525, C526, and G527 adjacent to its target binding site; and the 3'-terminus of 16S rRNA. When the probe is photoincorporated into 30S subunits subjected to brief cold inactivation (SI subunits), S7 labeling is increased compared to activated subunit incorporation, while S3, S4, and S12 labeling is decreased, as is labeling to nucleotides C525, C526, and G527; labeling at the 16S rRNA 3'-terminus appears unchanged. Longer cold inactivation of the 30S subunits (LI subunits) leads to decreases in the labeling of all components. These results provide clear evidence that C526 lies within 24 A (the distance between C526 and the photogenerated nitrene) of proteins S3, S4, S7, and S12 and the 3'-terminus of 16S rRNA. The identity of the tryptic digestion patterns of S7 labeled with the probe complementary to 16S rRNA nucleotides 518-526 and with a probe complementary to nucleotides 1397-1405 [Muralikrishna, P., & Cooperman, B. S. (1994) Biochemistry 33, 1392-1398] also provides evidence for proximity between C526 and G1405. Our results support the conclusion of Dontsova et al. [Dontsova, O., et al. (1992) EMBO J. 11, 3105-3116] in placing the 530 loop in close proximity to the decoding center of the 30S subunit but are apparently inconsistent with some protein-protein distances determined by neutron diffraction [Capel, M. S., et al. (1988) J. Mol. Biol. 200, 65-87]. This inconsistency suggests that a multistate model of subunit conformation may be required to account for the totality of results pertaining to the internal structure of the 30S subunit.

A photolabile oligodeoxyribonucleotide probe of the decoding site in the small subunit of the Escherichia coli ribosome: identification of neighboring ribosomal components.

In this work we report the synthesis of a radioactive, photolabile oligodeoxyribonucleotide probe complementary to 16S rRNA nucleotides 1397-1405 and its exploitation in identifying 30S ribosomal subunit components neighboring its target site in 16S rRNA. Nucleotides 1397-1405 lie within a single-stranded sequence that has been linked to the decoding region of Escherichia coli ribosomes. On photolysis in the presence of activated 30S subunits, the photolabile oligodeoxyribonucleotide probe site-specifically incorporates into proteins S1, S7, S18, and S21 (identified by SDS-PAGE, RP-HPLC, and antibody affinity chromatography) and into three separate 16S rRNA regions, specifically, nucleotides A-1396, G-1405-A-1408, and A-1492 and A-1493. These results provide clear evidence that G-1405 in 16S rRNA is within 24 A (the distance between G-1405 and the photogenerated nitrene) of proteins S1, S7, S18, and S21 and each of the other nucleotides mentioned above, consistent with other studies of 30S internal structure. Although the probe binds to inactive 30S subunits about as well as to activated 30S subunits, photolysis of the inactive 30S.probe complex leads to a very different pattern of protein labeling, providing strong evidence, at the protein level, that the inactive to activated transition is accompanied by conformational change in the 1400 region of 16S rRNA.

A photolabile oligodeoxyribonucleotide probe of the peptidyltransferase center: identification of neighboring ribosomal components.

In this work we report the synthesis of a radioactive, photolabile oligodeoxyribonucleotide probe and its exploitation in identifying 50S ribosomal subunit components neighboring its target site in 23S rRNA. The probe is complementary to 23S rRNA nucleotides 2497-2505, a single-stranded sequence that has been shown to fall within the peptidyltransferase center of Escherichia coli ribosomes [Cooperman, B. S., Weitzmann, C. J., & Fernandez, C. L. (1990) in The Ribosome: Structure, Function, & Evolution (Hill, W. E., Dahlberg, A., Garrett, R. A., Moore, P. B., Schlesinger, D., & Warner, J. R., Eds.) pp 491-501, American Society of Microbiology, Washington]. On photolysis in the presence of 50S ribosomes, it site-specifically incorporates into protein L3 (identified by both SDS-PAGE and immunological methods) and into three separate 23S rRNA regions: specifically, nucleotides 2454; 2501, 2502, 2505, 2506; and 2583, 2584. These results provide clear evidence that G-2505 in 23S rRNA is within 24 A (the distance between G-2505 and the photogenerated nitrene) of protein L3 and of each of the nucleotides mentioned above and are of obvious importance in the construction of detailed three-dimensional models of ribosomal structure. The approach we present is general and can be applied to determining ribosomal components neighboring regions of rRNA that are susceptible to binding by complementary oligodeoxyribonucleotides, both in intact 30S and 50S subunits and in subunits at various stages of reconstitution.

Escherichia coli initiation factor 3 protein binding to 30S ribosomal subunits alters the accessibility of nucleotides within the conserved central region of 16S rRNA.

Translational initiation factor 3 (IF3) is an RNA helix destabilizing protein which interacts with strongly conserved sequences in 16S rRNA, one at the 3' terminus and one in the central domain. It was therefore of interest to identify particular residues whose exposure changes upon IF3 binding. Chemical and enzymatic probing of central domain nucleotides of 16S rRNA in 30S ribosomal subunits was carried out in the presence and absence of IF3. Bases were probed with dimethyl sulfate (DMS), at A(N-1), C(N-3), and G(N-7), and with N-cyclohexyl-N'-[2-(N-methyl-4-morpholinio)ethyl] carbodiimide p-toluenesulfonate (CMCT), at G(N-1) and U(N-3). RNase T1 and nuclease S1 were used to probe unpaired nucleotides, and RNase V1 was used to monitor base-paired or stacked nucleotides. 30S subunits in physiological buffers were probed in the presence and absence of IF3. The sites of cleavage and modification were detected by primer extension. IF3 binding to 30S subunits was found to reduce the chemical reactivity and enzymatic accessibility of some sites and to enhance attack at other sites in the conserved central domain of 16S rRNA, residues 690-850. IF3 decreased CMCT attack at U701 and U793 and V1 attack at G722, G737, and C764; IF3 enhanced DMS attack at A814 and V1 attack at U697, G833, G847, and G849. Many of these central domain sites are strongly conserved and with the conserved 3'-terminal site define a binding domain for IF3 which correlates with a predicted cleft in two independent models of the 30S ribosomal subunit.

Inducible high expression of the Escherichia coli infC gene subcloned behind a bacteriophage T7 promoter.

The gene for Escherichia coli translational initiation factor 3 (infC) has been inserted into an overexpression plasmid under the control of the bacteriophage T7 promoter. The infC plasmid was then used to transform a host with a chromosomal T7 RNA polymerase gene controlled by the lacUV5 promoter. Induction of T7 RNA polymerase expression in the host cells resulted in a 200-fold overexpression of infC mRNA and a 100-fold overproduction of initiation factor 3. Rapid batch purification of biologically active IF3 yielded predominantly the long form of IF3, implying that the short form is an artifact of purification by traditional methods.

Structural and immunochemical characterization of a ribosomal protein from gram-positive Micrococcus luteus which is functionally homologous to Escherichia coli ribosomal protein S1.

Ribosomes from gram-positive Micrococcus luteus contain an acidic protein (ML-S1). ML-S1 has been purified by chromatography of ribosomes on a poly(U)-Sepharose column and the purified protein has a mobility in sodium dodecyl sulphate/polyacrylamide gels similar to that of ribosomal protein S1 of Escherichia coli (apparent Mr 72,000). Protein ML-S1 reacted with E. coli anti-S1 serum with an immunological partial-identity reaction. ML-S1 also reacted with antibodies raised against two structural domains of E. coli S1 (the N-terminal ribosome-binding domain and central and C-terminal nucleic-acid-binding domain). Weak reaction with antiserum to the nucleic-acid-binding domain of E. coli S1 was observed. ML-S1 was digested with trypsin under mild and exhaustive conditions. Mild digestion resulted in the production of a trypsin-resistant core (ML-S1F1) like E. coli S1. The fragment pattern obtained after exhaustive digestion differed appreciably from that obtained with E. coli S1. ML-S1 bound to poly(U) as strongly as E. coli S1 and also showed appreciable binding to denatured DNA. Addition of ML-S1 to S1-depleted ribosomes from E. coli and M. luteus markedly stimulated the poly(U)-directed polyphenylalanine synthesis. Phage MS2-RNA-dependent translation was also found to be stimulated by ML-S1 although to a much lesser extent than the stimulation by E. coli S1. At a molar excess of ML-S1 to ribosomes the protein showed a similar inhibitory effect to E. coli S1 on polypeptide synthesis. Our data indicate that ML-S1 retained the structural domains important for its function despite certain structural differences from E. coli S1.

Comparison of ribosomes from gram-positive and gram-negative bacteria with respect to the presence of protein S1.

Ribosomes from Gram-positive and Gram-negative bacteria have been analysed for the presence of ribosomal protein S1 by three methods, sodium dodecyl sulfate polyacrylamide gel electrophoresis, immunoreaction with E. coli anti-S1 and chromatography on poly (U)-Sepharose. We observed that protein S1 is predominantly present in Gram-negative bacteria in comparison with Gram-positive bacteria. Exceptions are noted in both species.