Impact of estrogenic compounds on DNA integrity in human spermatozoa: evidence for cross-linking and redox cycling activities.

A great deal of circumstantial evidence has linked DNA damage in human spermatozoa with adverse reproductive outcomes including reduced fertility and high rates of miscarriage. Although oxidative stress is thought to make a significant contribution to DNA damage in the male germ line, the factors responsible for creating this stress have not been elucidated. One group of compounds that are thought to be active in this context are the estrogens, either generated as a result of the endogenous metabolism of androgens within the male reproductive tract or gaining access to the latter as a consequence of environmental exposure. In this study, a wide variety of estrogenic compounds were assessed for their direct effects on human spermatozoa in vitro. DNA integrity was assessed using the Comet and TUNEL assays, lesion frequencies were quantified by QPCR using targets within the mitochondrial and nuclear (beta-globin) genomes, DNA adducts were characterized by mass spectrometry and redox activity was monitored using dihydroethidium (DHE) as the probe. Of the estrogenic and estrogen analogue compounds evaluated, catechol estrogens, quercetin, diethylstilbestrol and pyrocatechol stimulated intense redox activity while genistein was only active at the highest doses tested. Other estrogens and estrogen analogues, such as 17beta-estradiol, nonylphenol, bisphenol A and 2,3-dihydroxynaphthalene were inactive. Estrogen-induced redox activity was associated with a dramatic loss of motility and, in the case of 2-hydroxyestradiol, the induction of significant DNA fragmentation. Mass spectrometry also indicated that catechol estrogens were capable of forming dimers that can cross-link the densely packed DNA strands in sperm chromatin, impairing nuclear decondensation. These results highlight the potential importance of estrogenic compounds in creating oxidative stress and DNA damage in the male germ line and suggest that further exploration of these compounds in the aetiology of male infertility is warranted.

Rapid resolution of hyperkinesis after exercise. Two-dimensional echocardiographic studies in normal subjects.

Abnormal wall motion detected with exercise echocardiography identifies ischemic myocardium, while normal myocardium exhibits hyperkinetic motion. The normal, hyperkinetic response to exercise is transient and is predictive of an excellent prognosis. However, there are few data on the duration of the hyperkinesis after peak exercise. Our purpose was to determine the time course of wall thickening after exercise in eight normal subjects with two-dimensional echocardiography. Percentage of wall thickening increased from 53 +/- 24 percent at baseline to 82 +/- 24 percent at 0 to 2 min postexercise (p < 0.001 vs baseline) and then decreased to 64 +/- 27 percent at 2 to 4 min, and 54 +/- 20 percent at 5 to 7 min (both NS vs baseline). We conclude that (1) systolic wall thickening is maximal within the initial 2 min following peak exercise, and (2) accurate identification of hyperkinetic, normal myocardium with exercise echocardiography requires immediate postexercise imaging.

Assignment of resonances of exchangeable protons in the NMR spectrum of the complex formed by Escherichia coli ribosomal protein L25 and uniformly nitrogen-15 enriched 5 S RNA fragment.

The downfield proton NMR spectrum of the aqueous nucleoprotein complex formed by Escherichia coli ribosomal protein L25 and uniformly nitrogen-15 enriched 5 S RNA fragment is presented. Many proton resonances show the effects of scalar coupling to nitrogen-15 and these resonances are assigned to nucleic acid imino protons. Selective nitrogen-15 decoupling difference proton spectroscopy revealed nitrogen-15 and proton chemical shift correlations from which the base types of nucleic acid imino proton resonances could be assigned because the nitrogen-15 chemical shifts of nucleic acid guanine and uracil imino nitrogens have separate small ranges for both nucleoproteins and isolated nucleic acids.

Assignment of resonances in the Escherichia coli 5 S RNA fragment proton NMR spectrum using uniform nitrogen-15 enrichment.

The downfield proton NMR spectrum of aqueous uniformly nitrogen-15 enriched 5 S RNA fragment is presented. Selective nitrogen-15 decoupling difference proton spectroscopy revealed nitrogen-15 chemical shifts of fragment imino nitrogens. Nitrogen chemical shifts of nucleic acid guanine and uracil imino nitrogens have separate small ranges. Nitrogen-15 and proton chemical shift correlation by the heteronuclear decoupling permitted the identification of the base type of some previously unassigned imino proton resonances in the 5 S RNA fragment spectrum. Corresponding resonances in the natural isotopic abundance 5 S RNA fragment spectrum are assigned to base types by comparison with the enriched sample spectrum.

Assignment of resonances in the downfield proton spectrum of Escherichia coli 5S RNA and its nucleoprotein complexes using components of a ribonuclease-resistant fragment.

The downfield (9-15 ppm) proton NMR spectra of oligonucleotides derived from the ribonuclease A resistant fragment of Escherichia coli 5S RNA have been examined in aqueous solution at 500 MHz. Comparison of these spectra with those of the 5S RNA fragment and intact 5S RNA using both chemical shift and nuclear Overhauser enhancement effect criteria indicates that several aspects of 5S RNA secondary structure are also present in the structures assumed in solution by these much smaller molecules. Analysis of these spectra permits the assignment of some imino proton resonances which could not be assigned with certainty on the basis of NMR data previously obtained on intact 5S RNA or its nucleoprotein complexes. Several previous resonance assignments are confirmed. Studies on oligonucleotide components of fragment and a reconstituted fragment show that at least two conformations of the procaryotic loop exist.

Escherichia coli ribosomal 5S RNA-protein L25 nucleoprotein complex: effects of RNA binding on the protein structure and the nature of the interaction.

The complexes of three variants of Escherichia coli 5S RNA with ribosomal protein L25 have been studied by high-field proton nuclear magnetic resonance. A spectroscopic method is demonstrated to help distinguish the macromolecular sources of proton resonances in nucleoprotein complexes. The effects of L25 binding on the three RNAs tested were small; the presence of the L25 did not strongly influence the conformation of the RNA. The interaction of L25 with 5S RNA produced modest, but distinctive, alterations in the protein spectrum, in both the aromatic region and the upfield spectrum. As judged by these changes, the mechanism of binding was the same in all three cases. The changes seen in the spectrum of L25 indicate that its conformation is not altered in a major way upon RNA binding. Arginine residues appear to be involved in the binding mechanism. Intercalation of L25 aromatic residues with RNA bases does not appear to play a role in the interaction.

Physical studies on a nucleoprotein from the ribosome of E. coli.

Bacterial 5S RNA and its cognate proteins constitute an attractive system to study nucleoprotein interactions. The molecular weights of the components involved are modest and they can be prepared in the quantities necessary to permit the application of material-intensive techniques like NMR and X-ray crystallography. 5S RNA is being examined by proton NMR at 500 MHz with special attention paid to the downfield NH proton region. A substantial number of assignments can be suggested in this region based on nuclear Overhauser results. The binding of protein L25 (E. coli) to the RNA gives rise to a highly characteristic set of perturbations in the spectrum of the RNA. The data suggest a localized and assignable alteration in RNA structure upon formation of the complex. In addition we have grown large crystals of RNAs related to 5S RNA and their complexes with a cognate protein. The properties of these crystals and the progress made in analyzing their structure are discussed.

Nuclear Overhauser experiments at 500 MHz on the downfield proton spectrum of a ribonuclease-resistant fragment of 5S ribonucleic acid.

The downfield (9-15 ppm) proton NMR spectrum of a RNase A resistant fragment of E. coli 5S RNA has been studied by nuclear Overhauser methods. The fragment comprises bases 1-11 and 69-120 of the parent molecule [Douthwaite, S., Garrett, R.A., Wagner, R., & Feunteun, J. (1979) Nucleic Acids Res. 6, 2453-2470]. The nuclear Overhauser data identify two double helical structures in the fragment whose sequences are (GC)3(AU)(GC)3 and (GC)2(AU)(GU). These structures correspond exactly to the central portions of the terminal stem and procaryotic loop helices which should exist in the fragment sequences according to the Fox-Woese model [Fox, G.E., & Woese, C. R. (1975) Nature (London) 256, 505-506] of 5S RNA secondary structure. The significance of these and other nuclear Overhauser effects detected for the structure of 5S RNA and its fragment is discussed.

Nuclear Overhauser experiments at 500 MHz on the downfield proton spectra of 5S ribonucleic acid and its complex with ribosomal protein L25.

The downfield (9-15 ppm) proton spectrum of Escherichia coli 5S RNA has been examined at 500 MHz by using nuclear Overhauser methods. The data confirm the existence of the terminal and procaryotic loop helices within the molecule [Fox, G. E., & Woese, C. R. (1975) Nature (London) 256, 505-506]. Very little stable, double-helical structure is detectable in the third loop of the molecule, the one comprising bases 12-68. The downfield spectrum of 5S RNA is perturbed in a highly specific manner upon addition of protein L25 to the system. The changes seen strongly suggest that the binding site for L25 on 5S RNA includes the procaryotic loop helix, but not the terminal stem helix. Similar complexes formed between L25 and the 5S RNA fragment consisting of bases 1-11, 69-87, and 89-120 show exactly the same spectral alterations. A number of downfield resonances appear in the spectra of these complexes which have no counterparts in the free RNA, suggesting the stabilization of new RNA structures by the protein. There are some indications of protein-nucleic acid nuclear Overhauser effects.

NMR evidence for the existence of two native conformations of 5S RNA.

NMR spectra of the non-exchangeable protons in 5S RNA from E. coli show the existence of two distinct conformers of the molecule which meet the operational definition of "A form" or native 5S RNA. Both are easily distinguished spectroscopically from denatured, "B form" 5S RNA. The conditions which interconvert the two A form conformers strongly suggest that the transition between them gives rise to the low temperature optical melting transition first reported in 5S RNA by Kao and Crothers (1).

A proton NMR study of ribosomal protein L25 from Escherichia coli.

A highly folded form of the ribosomal protein L25 from Escherichia coli can be obtained from urea-denatured preparations. Proton NMR data show that this form of the molecule must have a compact, globular tertiary structure. Spectroscopically it is indistinguishable from L25 prepared by methods which avoid denaturing solvents. Thus L25 is a protein which can be reversibly denatured. The stability and solubility of the folded form of the protein are discussed and primary assignments made for a number of resonances in its NMR spectrum. The paper shows that this folded form of the protein can be characterised using NMR spectroscopy. High-resolution NMR spectroscopy provides a sensitive and general way for the characterisation of protein folds.

On the renaturation of ribosomal protein L11.

When urea-denatured preparations of protein L11 from the ribosome of Escherichia coli are introduced into physiological buffers, two completely different configurations can be obtained. One form, by NMR criteria, shows little evidence of stable tertiary interactions; the other shows strong indications of a distinctive folding pattern. The configuration obtained depends on minor details of the method used for returning samples to non-denaturing conditions.