Adsorption and desorption of metolachlor and metolachlor metabolites in vegetated filter strip and cultivated soil.

Previous studies have indicated that dissolved-phase metolachlor [2-chloro-N-(2-ethyl-6-methylphenyl)-N-(methoxy-1-methylethyl) acetamide] transported in surface runoff is retained by vegetative filter strips to a greater degree than either metolachlor oxanilic acid 12-[(2-ethyl-6-methylphenyl) (2-methoxy-1-methylethyl)amino]-2-oxo-acetic acid] (OA) or metolachlor ethanesulfonic acid [2-[(2-ethyl-6-methylphenyl) (2-methoxy-1-methylethyl-1)amino]-2-oxoethanesul-fonic acid] (ESA), two primary metabolites of metolachlor. Adsorption-desorption of ESA and OA in vegetated filter strip soil (VFSS) has not been evaluated, yet these data are required to assess the mobility of these compounds in VFSS. The objective of this experiment was to compare metolachlor, ESA, and OA adsorption and desorption parameters between VFSS and cultivated soil (CS). Adsorption and desorption isotherms were determined using the batch equilibrium procedure. With the exception of a 1.7-fold increase in organic carbon content in the VFSS, the evaluated chemical and physical properties of the soils were similar. Sorption coefficients for metolachlor were 88% higher in VFSS than in CS. In contrast, sorption coefficients for ESA and OA were not different between soils. Relative to metolachlor, sorption coefficients for ESA and OA were at least 79% lower in both soils. Metolachlor desorption coefficients were 59% higher in the VFSS than in the CS. Desorption coefficients for ESA and OA were not different between soils. Relative to metolachlor, desorption coefficients for ESA and OA were at least 66% lower in both soils. These data indicate that the mobility of ESA and OA will be greater than metolachlor in both soils. However, higher organic carbon content in VFSS relative to CS may limit the subsequent transport of metolachlor from the vegetated filter strip.

Infiltration and adsorption of dissolved atrazine and atrazine metabolites in buffalograss filter strips.

Vegetated filter strips (VFS) potentially reduce the off-site movement of herbicides from adjacent agricultural fields by increasing herbicide mass infiltrated (Minf) and mass adsorbed (Mas) compared with bare field soil. However, there are conflicting reports in the literature concerning the contribution of Mas to the VFS herbicide trapping efficiency (TE). Moreover, no study has evaluated TE among atrazine (6-chloro-N-ethyl-N'-isopropyl-[1,3,5]triazine-2,4-diamine) and atrazine metabolites. This study was conducted to compare TE, Minf, and Mas among atrazine, diaminoatrazine (DA, 6-chloro[1,3,5]triazine-2,4-diamine), deisopropylatrazine (DIA, 6-chloro-N-ethyl-[1,3,5]triazine-2,4-diamine), desethylatrazine (DEA, 6-chloro-N-isopropyl-[1,3,5]triazine-2,4-diamine), and hydroxyatrazine (HA, 6-hydroxy-N-ethyl-N'-isopropyl-[1,3,5]triazine-2,4-diamine) in a buffalograss VFS. Runoff was applied as a point source upslope of a 1- x 3-m microwatershed plot at a rate of 750 L h(-1). The point source was fortified at 0.1 microg mL(-1) atrazine, DA, DIA, DEA, and HA. After crossing the length of the plot, water samples were collected at 5-min intervals. Water samples were extracted by solid phase extraction and analyzed by high performance liquid chromatography (HPLC) photodiode array detection. During the 60-min simulation, TE was significantly greater for atrazine (22.2%) compared with atrazine metabolites (19.0%). Approximately 67 and 33% of the TE was attributed to Minf and Mas, respectively. These results demonstrate that herbicide adsorption to the VFS grass, grass thatch, and/or soil surface is an important retention mechanism, especially under saturated conditions. Values for Mas were significantly higher for atrazine compared with atrazine's metabolites. The Mas data indicate that atrazine was preferentially retained by the VFS grass, grass thatch, and/or soil surface compared with atrazine's metabolites.

Comparision of atrazine and metolachlor affinity for bermudagrass ( Cynodon dactylon L.) and two soils.

Given that bermudagrass is being used as one of the grasses of choice in grass filter strip plantings as an acceptable grass to reduce off-target losses of herbicides, laboratory experiments were conducted to determine and compare the relative affinity of bermudagrass, a Weswood soil, and a Houston Black soil for atrazine (6-chloro- N-ethyl- N-isopropyl-1,3,5-triazine-2,4-diamine) and metolachlor (2-chloro- N-(2-ethyl-6-methylphenyl)- N-(2-methoxy-1-methyethyl) acetamide). Experiments were also conducted to determine if the presence of one herbicide affects the relative affinity of the other compound to these sorbents. The experiments were carried out using radiolabeled atrazine and metolachlor. Results were reported in disintegrations min(-1) (dpms) and converted to K(d) to determine and compare relative affinity. Both K(d) values for relative affinity of atrazine (86.2) and metolachlor (131.5) to bermudagrass were significantly greater than those of the two soils, Weswood (atrazine, 20.0 and metolachlor, 28.4) and Houston Black (atrazine, 35.8 and metolachlor, 33.5). The two compounds were also mixed together to mimic the common practice of applying atrazine and metolachlor simultaneously as a tank mix. Relative affinity of atrazine to any of the sorbents was not affected by the presence of metolachlor. Similarly, when comparing the affinity of metolachlor alone to that of metolachlor with atrazine present in the solution, no significant differences were observed for bermudagrass or the Weswood soil. However, on the Houston Black soil, the presence of atrazine significantly increased the soil's affinity for metolachlor.

Structure and dynamics of translation initiation factor aIF-1A from the archaeon Methanococcus jannaschii determined by NMR spectroscopy.

Translation initiation factor 1A (aIF-1A) from the archaeon Methanococcus jannaschii was expressed in Escherichia coli, purified, and characterized in terms of its structure and dynamics using multidimensional NMR methods. The protein was found to be a member of the OB-fold family of RNA-associated proteins, containing a barrel of five beta-strands, a feature that is shared with the homologous eukaryotic translation initiation factor 1A (eIF-1A), as well as the prokaryotic translation initiation factor IF1. External to the beta barrel, aIF-1A contains an alpha-helix at its C-terminal and a flexible loop at its N-terminal, features that are qualitatively similar to those found in eIF-1A, but not present in prokaryotic IF1. The structural model of aIF-1A, when used in combination with primary sequence information for aIF-1A in divergent species, permitted the most-conserved residues on the protein surface to be identified, including the most likely candidates for direct interaction with the 16S ribosomal RNA and other components of the translational apparatus. Several of the conserved surface residues appear to be unique to the archaea. Nitrogen-15 relaxation and amide exchange rate data were used to characterize the internal motions within aIF-1A, providing evidence that the protein surfaces that are most likely to participate in intermolecular interactions are relatively flexible. A model is proposed, suggesting some specific interactions that may occur between aIF-1A and the small subunit of the archaeal ribosome.

Peptide bis-intercalator binds DNA via threading mode with sequence specific contacts in the major groove.

BACKGROUND: We previously described a general class of DNA polyintercalators in which 1,4,5,8-naphthalenetetracarboxylic diimide (NDI) intercalating units are connected via peptide linkers, resulting in the first known tetrakis- and octakis-intercalators. We showed further that changes in the composition of the peptide tether result in novel DNA binding site specificities. We now examine in detail the DNA binding mode and sequence specific recognition of Compound 1, an NDI bis-intercalator containing the peptide linker gly-gly-gly-lys. RESULTS: 1H-NMR structural studies of Compound 1 bound to d(CGGTACCG)(2) confirmed a threading mode of intercalation, with four base pairs between the diimide units. The NMR data, combined with DNAse I footprinting of several analogs, suggest that specificity depends on a combination of steric and electrostatic contacts by the peptide linker in the floor of the major groove. CONCLUSIONS: In view of the modular nature and facile synthesis of our NDI-based polyintercalators, such structural knowledge can be used to improve or alter the specificity of the compounds and design longer polyintercalators that recognize correspondingly longer DNA sequences with alternating access to both DNA grooves.

Resolution of the 1H-1H NOE spectrum of RNA into three dimensions using 15N-1H two-bond couplings.

The feasibility of using two-bond 15N-1H couplings to resolve the 1H-1H nuclear Overhauser effect spectrum of RNA into a third dimension was investigated, using the 36-nucleotide gene 32 messenger RNA pseudoknot of bacteriophage T2 as an example. The two-bond 15N-1H couplings present in adenosine and guanosine were found to be suitable for generating a three-dimensional 1H-1H-15N NOESY-HSQC spectrum with reasonably good sensitivity, as well as favorable chemical shift dispersion in the nitrogen dimension. The described NMR experiment provides a tool that can be used to complement other heteronuclear methods in the analysis of RNA structure.

An examination of coaxial stacking of helical stems in a pseudoknot motif: the gene 32 messenger RNA pseudoknot of bacteriophage T2.

The RNA pseudoknot located at the 5' end of the gene 32 messenger RNA of bacteriophage T2 contains two A-form helical stems connected by two loops, in an H-type pseudoknot topology. A combination of multidimensional NMR methods and isotope labeling were used to investigate the pseudoknot structure, resulting in a more detailed structural model than provided by earlier homonuclear NMR studies. Of particular significance, the interface between the stacked helical stems within the pseudoknot motif is described in detail. The two stems are stacked in a coaxial manner, with an approximately 18 degrees rotation of stem1 relative to stem2 about an axis that is parallel to the helical axis. This rotation serves to relieve what would otherwise be a relatively close phosphate-phosphate contact at the junction of the two stems, while preserving the stabilizing effects of base stacking. The ability of the NMR data to determine pseudoknot bending was critically assessed. The data were found to be a modestly precise indicator of pseudoknot bending, with the angle between the helical axes of stem1 and stem2 being in the range of 15+/-15 degrees. Pseudoknot models with bend angles within this range are equally consistent with the data, since they differ by only small amounts in the relatively short-range interproton distances from which the structure was derived. The gene 32 messenger RNA pseudoknot was compared with other RNA structures with coaxial or near-coaxial stacked helical stems.

An investigation of the dynamics of ribosomal protein L9 using heteronuclear NMR relaxation measurements.

The dynamic properties of ribosomal protein L9 from Bacillus stearothermophilus were investigated in solution using an analysis of nitrogen-15 longitudinal and transverse relaxation rates and amide nitrogen-proton nuclear Overhauser effects. The relaxation rates of the amide nitrogen nuclei were found to be correlated with the angle between the amide nitrogen-proton bond vectors and the long axis of the protein. This directional dependence of the nuclear relaxation rates is consistent with the protein having a highly elongated shape in solution, consistent with that observed in previous X-ray crystallographic studies of the crystalline form. Analysis of the nuclear relaxation data shows that the solvent-exposed nine-turn alpha helix connecting the two domains has a relatively high degree of order, in contrast to the connecting helix in the similarly shaped, but functionally different, calmodulin protein. The rotational correlation times associated with the amide nitrogen atoms of the N-terminal domain are on average slightly shorter than those of the C-terminal domain and connecting helix, providing evidence that the N-terminal domain exhibits some degree of independence in tumbling, in addition to other fast internal motions. The putative RNA-binding surfaces in each of the protein domains are characterized by relatively low order parameters, indicating that these are the most flexible regions of the molecule. Overall, the picture of the internal dynamics provided by nuclear relaxation measurements is similar to that obtained from a detailed study of amide proton exchange rates, but differs markedly from the picture provided by crystallographic temperature factors. The present study describes a molecule with unusual and complex dynamic properties, and supports a model where the protein functions as a "molecular strut" within the ribosome.

Non-nearest neighbor effects on the thermodynamics of unfolding of a model mRNA pseudoknot.

The upstream autoregulatory mRNA leader sequence of gene 32 of 17 T-even and related bacteriophages folds into a simple tertiary structural motif, a hairpin-type RNA pseudoknot. In phage T4, the pseudoknot is contained within 28 contiguous nucleotides which adopt a pseudocontinuous helical structure derived from two coaxially stacked helical stems of four (stem 1) and seven (stem 2) base-pairs connected by two inequivalent single-stranded loops of five and one nucleotide(s). These two loops cross the minor and major grooves of stems 1 and 2, respectively. In this study, the equilibrium unfolding pathway of a 35-nucleotide RNA fragment corresponding to the wild-type and sequence variants of the T4 gene 32 mRNA has been determined through analysis of dual-wave-length, equilibrium thermal melting profiles via application of a van't Hoff model based on multiple sequential, two-state transitions. The melting profile of the wild-type RNA is well-described by two sequential melting transitions over a wide range of magnesium concentration. Compensatory base-pair substitutions incorporated into helical stems 1 and 2 were used to assign the first low enthalpy, moderate tm melting transition to the denaturation of the short three to four base-pair stem 1, followed by unfolding of the larger seven base-pair stem 2. We find that loop 1 substitution mutants (A10 to G10, C10, U10 or GA10) strikingly uncouple the melting of stems 1 and 2, with the U10 substitution and the GA10 loop expansion more destabilizing than the G10 and C10 substitutions. A significant increase in the extent of cleavage by RNase T1 following the conserved G26 (the 3' nucleotide in loop 2) in the U10, G10, and GA10 mutants suggests that an altered helix-helix junction region in this mutant may be responsible, at least in part, for this uncoupling. In addition to a modest destabilization of stem 2, the major effect of deletion or nucleotide substitution in the 3' single-stranded tail is a destabilization of stem 1, a non-nearest neighbor tertiary structural effect, which may well be transmitted through an altered loop 1-core helix interaction. In contrast, truncation of the 5' tail has no effect on the stability of the molecule.

Base-pairings within the RNA pseudoknot associated with the simian retrovirus-1 gag-pro frameshift site.

Frameshift and readthrough sites within retroviral messenger RNAs are often followed by nucleotide sequences that have the potential to form pseudoknot structures. In the work presented here, NMR methods were used to characterize the base-pairings and structural features of the RNA pseudoknot downstream of the gag-pro frameshift site of simian retrovirus type-1 (SRV-1) and a functional mutant of the SRV-1 pseudoknot. Evidence is presented that these pseudoknots contain two A-form helical stems of six base-pairs each, connected by two loops, in a classic H-type pseudoknot topology. A particularly interesting feature is that the shorter of the two connecting loops, loop 1, consists of only a single adenosine nucleotide that spans the major groove of stem 2. In this respect, the frameshift-associated pseudoknots are structurally similar to the pseudoknot within the gene 32 mRNA of bacteriophage T2, previously characterized by NMR methods. Despite having similar nucleotide sequences, the solvent exchange rates of the imino protons at the junction of the helical stems in the wild-type and mutant frameshifting pseudoknots differ from each other and from the bacteriophage T2 pseudoknot. The implications of this finding are discussed.

Therapeutic drug monitoring of risperidone and 9-hydroxyrisperidone in serum with solid-phase extraction and high-performance liquid chromatography.

This laboratory developed a simple and efficient solid-phase extraction method that is combined with high-performance liquid chromatography for rapid and precise therapeutic monitoring of risperidone (Risperdal) in blood concentrations. The solid-phase extraction uses a mixed bed column. Sensitivity of the chromatographic method is 0.5 ng/ml (180 pmol/ml) of drug in serum, and separations can be performed in a 15-minute chromatographic run. Advantages of this approach include enhanced speed, sensitivity, and efficiency. A high level of sensitivity may be achieved because of the absence of interference from other drugs, metabolites, or serum components.

The stability and dynamics of ribosomal protein L9: investigations of a molecular strut by amide proton exchange and circular dichroism.

Nuclear magnetic resonance and circular dichroism experiments were used to investigate the stability and dynamic aspects of ribosomal protein L9 from Bacillus stearothermophilus in solution. This unusually shaped protein, with its two widely spaced RNA-binding domains linked by a connecting helix, has been hypothesized to serve as a "molecular strut", most likely playing a role in ribosome assembly and/or maintaining the catalytically active conformation of ribosomal RNA. Protection factors for amide proton exchange were quantitatively measured in an extensive series of NMR experiments, providing probes of the stability and dynamics of localized regions of the protein. Results show that each of the two RNA-binding domains contains a highly stable core. The exposed central helix that connects the two domains is helical in solution, albeit not rigid, a result that is supported by amide proton protection factors, circular dichroism measurements, and carbon-13 and proton chemical shift index values. A conserved glycine and lysine-rich loop in the N-terminal domain is ordered and quite stable, a surprising result, since this loop had been presumed to be disordered in the original crystallographic analysis. Interestingly, the most dynamic parts of the protein are the regions that contain the likely RNA-binding residues in each of the two domains. The present results add further support to the notion that the L9 protein plays an architectural role within the ribosome, with the central helix serving as a molecular strut, or perhaps a spring, linking the two widely spaced RNA-binding domains.

An NMR and mutational study of the pseudoknot within the gene 32 mRNA of bacteriophage T2: insights into a family of structurally related RNA pseudoknots.

NMR methods were used to investigate a series of mutants of the pseudoknot within the gene 32 messenger RNA of bacteriophage T2, for the purpose of investigating the range of sequences, stem and loop lengths that can form a similar pseudoknot structure. This information is of particular relevance since the T2 pseudoknot has been considered a representative of a large family of RNA pseudoknots related by a common structural motif, previously referred to as 'common pseudoknot motif 1' or CPK1. In the work presented here, a mutated sequence with the potential to form a pseudoknot with a 6 bp stem2 was shown to adopt a pseudoknot structure similar to that of the wild-type sequence. This result is significant in that it demonstrates that pseudoknots with 6 bp in stem2 and a single nucleotide in loop1 are indeed feasible. Mutated sequences with the potential to form pseudoknots with either 5 or 8 bp in stem2 yielded NMR spectra that could not confirm the formation of a pseudoknot structure. Replacing the adenosine nucleotide in loop1 of the wild-type pseudoknot with any one of G, C or U did not significantly alter the pseudoknot structure. Taken together, the results of this study provide support for the existence of a family of similarly structured pseudoknots with two coaxially stacked stems, either 6 or 7 bp in stem2, and a single nucleotide in loop1. This family includes many of the pseudoknots predicted to occur downstream of the frameshift or readthrough sites in a significant number of viral RNAs.

Ribosomal protein L9: a structure determination by the combined use of X-ray crystallography and NMR spectroscopy.

The structure of protein L9 from the Bacillus stearothernophilus ribosome has been determined at 2.5 A resolution by refinement against single crystal X-ray diffraction data with additional constraints provided by NMR data. This highly elongated protein consists of two domains separated by a nine-turn connecting helix. Conserved aromatic and positively charged amino acid residues on the surface of each domain are likely to be directly involved in binding 23 S ribosomal RNA. The shape of the protein, with its two widely spaced RNA-binding sites, suggests that it may serve as a "molecular strut", most likely playing a role in ribosome assembly and/or maintaining the catalytically active conformation of the ribosomal RNA. The combined use of X-ray and NMR data in the refinement procedure was essential in defining the N-terminal domain of the protein, which was relatively poorly determined by the X-ray data alone. In addition to resolving the ambiguities in defining the hydrophobic core and side-chain conformations with the N-terminal domain, this combined NMR-X-ray analysis provides the first detailed and accurate view of the N-terminal RNA-binding site. NMR data also showed that the N-terminal domain is stable in solution, indicated by amide protons that are protected from solvent exchange. The lack of definition of the N-terminal domain in the X-ray structure is therefore likely due to packing disorder within the crystal rather than structural instability. This combined NMR-X-ray analysis provides a useful model as to how X-ray and NMR data can be practically and logically combined in the determination of the structure of a single protein molecule.

Structural features and stability of an RNA triple helix in solution.

A 30 nt RNA with a sequence designed to form an intramolecular triple helix was analyzed by one-and two-dimensional NMR spectroscopy and UV absorption measurements. NMR data show that the RNA contains seven pyrimidine-purine-pyrimidine base triples stabilized by Watson-Crick and Hoogsteen interactions. The temperature dependence of the imino proton resonances, as well as UV absorption data, indicate that the triple helix is highly stable at acidic pH, melting in a single sharp transition centered at 62 degrees C at pH 4.3. The Watson-Crick and Hoogsteen pairings are disrupted simultaneously upon melting. The NMR data are consistent with a structural model where the Watson-Crick paired strands form an A-helix. Results of model building, guided by NMR data, suggest a possible hydrogen bond between the 2' hydroxyl proton of the Hoogsteen strand and a phosphate oxygen of the purine strand. The structural model is discussed in terms of its ability to account for some of the differences in stability reported for RNA and DNA triple helices and provides insight into features that are likely to be important in the design of RNA binding compounds.

Thermodynamics of folding of the RNA pseudoknot of the T4 gene 32 autoregulatory messenger RNA.

Nucleotides U(-67) to C(-40) at the extreme 5' end of the gene 32 mRNA in bacteriophage T4 have been shown to fold into an RNA pseudoknot proposed to be important for translational autoregulation. The thermal denaturation of three in vitro transcribed RNAs corresponding to the pseudoknot region has been investigated as a function of Mg2+ concentration to begin to elucidate the determinants of the structure and stability of this conformation. T4-35 is a 35-nucleotide RNA containing a 5' G followed by the natural T4 sequence starting with the mature 5' end of the mRNA, nucleotides A(-71) to C(-38). A 32-nucleotide RNA, termed T4-32, contains the native sequence form U(-67) to C(40) with 5'GC and 5'CA single-stranded regions appended to the 5' and 3' ends of the core sequence, respectively. T4-28 contains only the 28 core nucleotides, and the predicted closing U(-67)-A(-52) base pair in stem 1 has been replaced with a phylogenetically allowed G(-67)-C(-52) base pair. Ribonuclease mapping of T4-32 and imino proton NMR experiments of T4-35 show that both sequences adopt a pseudoknotted conformation. At pH 6.9 and 50 mM NaCl, T4-35 and T4-32 RNAs are characterized by a single major melting transition over a wide range of [Mg2+] (0-6 mM). The delta H degree of unfolding for T4-35 and T4-32 shows a large dependence on Mg2+ concentration; the maximum delta H degree occurs at about 2.0 mM Mg2+ with further addition of Mg2+ simply increasing the tm. Investigation of the [Mg2+] dependence of the tm suggests that a net of one Mg2+ ion is released upon denaturation of T4-35 and T4-32 RNAs. Over the entire [Mg2+] range, the delta G degree (37 degrees C) for the folding of T4-35 is consistently 1-1.5 kcal mol(-1) more negative than T4-32 due to a higher stabilization enthalpy for the natural sequence molecule. In contrast to this behavior, T4-28 gives consistently higher tm's but less negative enthalpies and is destabilized (at 37 degrees C) by about 0.5-1.5 kcal mol(-1) relative to T4-32 and by about 2-3 kcal mol(-1) relative to T4-35, depending upon cation concentration. (1)H NMR experiments suggest that, even in the presence of 4.0 mM Mg2+, T4-28 RNA does not adopt a stable pseudoknotted conformation. These data show that the stability of the pseudoknot in the gene 32 mRNA encoded by the 28-nucleotide core sequence is significantly influenced by the number and nature of the immediately adjacent "single-stranded" 5' and/or 3' nucleotides appended to the core structure. These findings are discussed within the context of the structural model for the evolutionarily related phage T2 and T6 gene 32 mRNA pseudoknots presented in the following paper [Du, Z., Giedroc, D. P., & Hoffman, D. W. (1996) Biochemistry 35, 4187-4198].

Structure of the autoregulatory pseudoknot within the gene 32 messenger RNA of bacteriophages T2 and T6: a model for a possible family of structurally related RNA pseudoknots.

A 36-nucleotide RNA with a sequence corresponding to the 5' end region of the gene 32 mRNA of bacteriophages T2 and T6 was analyzed by one- and two-dimensional NMR methods. NMR results provide clear evidence that the RNA is folded into a pseudoknot structure with two coaxial stems connected by two loops, in a classic pseudoknot topology. The pseudoknot is unusual in that one of the loops consists of only one nucleotide, which spans the major groove of a seven base pair helical stem. Imino proton resonances indicate the hydrogen bonding pattern within the pseudoknot, and two-dimensional NOE spectra provide information that describes many of the structural features. The temperature dependence of the UV absorption and imino proton exchange rates provides insight into the stability of the pseudoknot. A three-dimensional model of the pseudoknot that is consistent with our NMR data is presented, and features that may be important for stabilizing the pseudoknot structure are discussed. A substantial number of other putative RNA pseudoknots described in the literature have sequences and topologies that appear to be related to the T2 and T6 pseudoknots. We propose that these RNAs may be members of a family of pseudoknots related by a similar structural motif, which we refer to as "common pseudoknot motif 1" or CPK1. The bacteriophage T2/T6 pseudoknot can be considered a structural model for the CPK1 family. The common features of the CPK1 pseudoknots are a stem 2 with six or seven base pairs, a loop 1 consisting of a single adenosine, and a variable length stem 1 and loop 2. The first "dangling" nucleotide at the 3' end of the molecule probably stabilizes stem 2. The CPK1 family includes several of the retroviral pseudoknots associated with mRNA frameshifting and readthrough. The work presented here describes the first detailed NMR analysis of an RNA pseudoknot with an entirely natural nucleotide sequence.

NMR analysis of the trans-activation response (TAR) RNA element of equine infectious anemia virus.

Transcription of lentiviral DNA in the host cell is regulated by an interaction between the viral TAR RNA stem-loop and the viral Tat protein. Here we present a model of the three-dimensional structure of the TAR RNA stem-loop of the equine infectious anemia virus (EIAV), derived from two- and three-dimensional NMR data. This 25 nucleotide RNA consists of an A-form helical stem capped by two U-G base pairs and a four-nucleotide loop. Two loop cytidines are stacked into the loop interior and likely form a non-Watson-Crick C-C base-pair. The two nucleotides at the top of the loop, U13 and G14, appear to be excluded from the interior of the loop and solvent exposed. It is significant that now for the EIAV TAR-Tat system, three-dimensional structures are now known for both the RNA and protein components.

Inhibition of glutathione-related enzymes and cytotoxicity of ethacrynic acid and cyclosporine.

Glutathione (GSH) is an endogenous thiol that detoxifies active oxygen and reactive species formed during intermediary metabolism and drug detoxification. Compounds with a range of potential toxicities were tested for their abilities to affect GSH reductase and GSH S-transferase activities, which are each components of the two principal detoxification pathways in which GSH participates. A high performance liquid chromatographic method for determining oxidized and reduced GSH was modified to assay GSH reductase activity. With this method it was possible to demonstrate that ethacrynic acid, which inhibits GSH S-transferase, also inhibits the activity of GSH reductase. Inhibition of GSH reductase by ethacrynic acid was similar to that seen with carmustine (BCNU). GSH reductase activity was not affected by cis- or transplatin, buthionine sulfoximine, other loop diuretics, cyclosporine A or aminoglycosides. Cyclosporine inhibited GSH S-transferase at 50 microM and higher concentrations. These results support a role for GSH-mediated detoxification mechanisms in ethacrynic acid- and cyclosporine-associated cytotoxicity, which may mediate their toxicities and their potential as adjunctive agents in antineoplastic therapy. A better understanding of the mechanism of their toxicity can greatly extend the clinical usefulness of these agents, as this toxicity is the basis of both their therapeutic and antitherapeutic actions.