Formation of supramolecular assemblies and liquid crystals by purine nucleobases and cyanuric acid in water: implications for the possible origins of RNA.

The free nucleobases and mononucleotides of RNA do not form Watson-Crick base pairs in water, a fact that presents several challenges for the prebiotic synthesis of RNA. 2,6-Diaminopurine and adenosine-5'-monophosphate (AMP) are shown to form supramolecular assemblies with cyanuric acid in water. These assemblies and their propensity to form liquid crystals suggest a possible means by which non-covalent structures might have originally selected the shape of the Watson-Crick base pairs.

Cryoelectron microscopy of lambda phage DNA condensates in vitreous ice: the fine structure of DNA toroids.

DNA toroids produced by the condensation of lambda phage DNA with hexammine cobalt (III) have been investigated by cryoelectron microscopy. Image resolution obtained by this technique has allowed unprecedented views of DNA packing within toroidal condensates. Toroids oriented coplanar with the microscope image plane exhibit circular fringes with a repeat spacing of 2.4 nm. For some toroids these fringes are observed around almost the entire circumference of the toroid. However, for most toroids well-defined fringes are limited to less than one-third of the total toroid circumference. Some toroids oriented perpendicular to the image plane reveal DNA polymers organized in a hexagonal close-packed lattice; however, for other toroids alternative packing arrangements are observed. To aid interpretation of electron micrographs, three-dimensional model toroids were generated with perfect hexagonal DNA packing throughout, as well as more physically realistic models that contain crossover points between DNA loops. Simulated transmission electron microscopy images of these model toroids in different orientations faithfully reproduce most features observed in cryoelectron micrographs of actual toroids.

DNA-cation interactions: The major and minor grooves are flexible ionophores.

Several crystallographic, solution-state and theoretical studies carried out this past year provide new support for the sequence-specific nature of monovalent and divalent cation coordination within the DNA major and minor grooves. Correlations observed between groove width and cation coordination indicate that the grooves are flexible and respond to cation binding.

Intercalation-mediated synthesis and replication: a new approach to the origin of life.

We propose that a molecular midwife, a flat molecule approximately 10 Ax10 A with two hydrophobic faces, was essential to the origin of life. This molecule was positively charged, water soluble and did not strongly associate with itself in solution. It may have been a derivative of phthalocyanine that no longer exists on the Earth today, and might have been formed solely from hydrogen cyanide and formaldehyde. The midwife tended to intercalate between side groups (bases, similar to those in RNA) of polymers to form stacks, which incorporated bare bases. The midwife alternated in these stacks with hydrogen-bonded tetrads of bases. Under conditions of low water activity, as in a desert during the day, bare bases in the stacks were joined together by neutral and chemically heterogeneous backbones of no fixed chirality. The components of the backbones were the products of the formose reaction of formaldehyde, and were involved in the reversible formation of N -glycosides and acetals catalysed by divalent metal ions. The final product of this assemblage was a fully intercalated quadruplex of four information-containing polymer strands (four proto -RNA molecules). This process constituted replication of the original polymer that had seeded the formation of the stack. The stack structure ensured that the polymer's base sequence was replicated faithfully despite the lack of both homochirality and chemical homogeneity in the backbone. At night, water from condensing dew would suddenly come in contact with these products, quenching all chemical reactions and releasing midwife molecules and single- or double-stranded proto-RNA. Evaporation of water during the day then gave new stacks containing one or two proto-RNA strands, bare bases, and midwife molecules, which could begin a new replication cycle. Our model also allows for the generation of new stacks and the extension of existing ones, without restricting the base sequence of either, thereby providing a source of genetic information. The proto-RNA replication cycle is driven purely by concentration changes caused by the Sun and the rotation of the Earth. We propose that this system as a whole could have gradually evolved into the RNA World.

The effect of sodium, potassium and ammonium ions on the conformation of the dimeric quadruplex formed by the Oxytricha nova telomere repeat oligonucleotide d(G(4)T(4)G(4)).

The DNA sequence d(G(4)T(4)G(4)) [Oxy-1.5] consists of 1.5 units of the repeat in telomeres of Oxytricha nova and has been shown by NMR and X-ray crystallographic analysis to form a dimeric quadruplex structure with four guanine-quartets. However, the structure reported in the X-ray study has a fundamentally different conformation and folding topology compared to the solution structure. In order to elucidate the possible role of different counterions in this discrepancy and to investigate the conformational effects and dynamics of ion binding to G-quadruplex DNA, we compare results from further experiments using a variety of counterions, namely K(+), Na(+)and NH(4)(+). A detailed structure determination of Oxy-1.5 in solution in the presence of K(+)shows the same folding topology as previously reported with the same molecule in the presence of Na(+). Both conformations are symmetric dimeric quadruplexes with T(4)loops which span the diagonal of the end quartets. The stack of quartets shows only small differences in the presence of K(+)versus Na(+)counterions, but the T(4)loops adopt notably distinguishable conformations. Dynamic NMR analysis of the spectra of Oxy-1.5 in mixed Na(+)/K(+)solution reveals that there are at least three K(+)binding sites. Additional experiments in the presence of NH(4)(+)reveal the same topology and loop conformation as in the K(+)form and allow the direct localization of three central ions in the stack of quartets and further show that there are no specific NH(4)(+)binding sites in the T(4)loop. The location of bound NH(4)(+)with respect to the expected coordination sites for Na(+)binding provides a rationale for the difference observed for the structure of the T(4)loop in the Na(+)form, with respect to that observed for the K(+)and NH(4)(+)forms.

Localization of ammonium ions in the minor groove of DNA duplexes in solution and the origin of DNA A-tract bending.

Monovalent cation binding sites on nucleic acids in solution can be localized using the isotopically labeled ammonium ion (15NH4+) as a probe in high resolution NMR spectroscopy experiments. The application of this technique to a series of DNA duplexes reveals a preference for the binding of ammonium cations in the minor groove of A-tract sequences. These results are consistent with a recent report which indicates that some solvent electron densities previously identified as water molecules in DNA X-ray crystal structures are partially occupied by sodium ions. The sequence-specific nature of monovalent cation binding sites demonstrated here for A-tract DNA provides an explanation for the origin of sequence-directed bending.

Binding sites and dynamics of ammonium ions in a telomere repeat DNA quadruplex.

Guanine quartets are readily formed by guanine nucleotides and guanine-rich oligonucleotides in the presence of certain monovalent and divalent cations. The quadruplexes composed of these quartets are of interest for their potential roles in vivo, their relatively frequent appearance in oligonucleotides derived from in vitro selection, and their inhibition of template directed RNA polymerization under proposed prebiotic conditions. The requirement of cation coordination for the stabilization of G quartets makes understanding cation-quadruplex interactions an essential step towards a complete understanding of G quadruplex formation. We have used 15NH4+ as a probe of cation coordination by the four G quartets of the DNA bimolecular quadruplex [d(G4T4G4)]2, formed from oligonucleotides with the repeat sequence found in Oxytricha nova telomeres. 1H and 15N heteronuclear NMR spectroscopy has allowed the direct localization of monovalent cation binding sites in the solution state and the analysis of cation movement between the binding sites. These experiments show that [d(G4T4G4)]2 coordinates three ammonium ions, one in each of two symmetry related sites and one on the axis of symmetry of the dimeric molecule. The NH4+ move along the central axis of the quadruplex between these sites and the solution, reminiscent of an ion channel. The residence time of the central ion is determined to be 250 ms. The 15NH4+ is shown to be a valuable probe of monovalent cation binding sites and dynamics.

Random coil conformation for extended polyglutamine stretches in aqueous soluble monomeric peptides.

Several neurodegenerative diseases have been found to be strongly associated with proteins containing a polyglutamine stretch which is greatly expanded from approximately 20 glutamines in normal individuals to more than 40 in affected individuals. A conformational change in the expanded polyglutamine stretch has been suggested to form the molecular basis for disease onset. Model peptides containing polyglutamine tend to aggregate and become insoluble. We have synthesized readily water-soluble monomeric peptides by flanking polyglutamine stretches with sequences rich in alanine and lysine. Circular dichroism measurements show that polyglutamine stretches of length 9 or 17 adopt a random coil configuration in aqueous solution. We think that in the disease-associated peptides for normal individuals the stretches of approximately 20 glutamines are in a random coil conformation, whereas in affected individuals the polyglutamine stretch may be in some other conformation. Our method to design soluble monomeric peptides containing extended polyglutamine stretches may be generally useful in studying other highly aggregating peptides.

The selectivity for K+ versus Na+ in DNA quadruplexes is dominated by relative free energies of hydration: a thermodynamic analysis by 1H NMR.

We have studied the competition between Na+ and K+ for coordination by G quartets using the oligonucleotide d(G3T4G3) as a model system. d(G3T4G3) forms a dimeric foldback structure containing three G quartets in the presence of either NaCl or KCl. Proton chemical shifts, which are particular to the species of coordinated ion, have been used to monitor the conversion between the sodium and potassium forms under equilibrium conditions. Analysis of titration experiments indicates that at least two K+ are coordinated by the three quartets of the dimeric molecule, and perfect fits of the data are obtained for two Na+ being displaced by two K+. Our results also indicate that the conversion of [d(G3T4G3)]2 from the sodium to the potassium form is associated with a net free energy change (delta G degrees) of -1.7 +/- 0.15 kcal/mol. It has long been suggested that the greater thermal stability of DNA quadruplex structures in the presence of K+ is primarily a result of the optimal fit of this ion in the coordination sites formed by G quartets. However, a consideration of the relatively small change in free energy associated with the conversion from the sodium to the potassium form and the relatively large difference between the free energy of hydration for Na+ and K+ indicates that this cannot be correct. Rather, the preferred coordination of K+ over Na+ is actually driven by the greater energetic cost of Na+ dehydration with respect to K+ dehydration.

Arginine to tryptophan substitution in the active site of a human lactate dehydrogenase variant--LDHB GUA1: postulated effects on subunit structure and catalysis.

A variant of lactate dehydrogenase (LDHB GUA1) was previously identified among the Guaymi Indians of Panama and Costa Rica. The LDHB GUA1 variant is enzymatically inactive; however, the variant subunits alter the electrophoretic mobility of the tetramers that include active LDHA and LDHB subunits. The kinetic properties of the tetrameric enzyme, comprised of the inactive B plus active A subunits, are similar to properties of the heterotetramers with active B subunits, except for the reduced specific activity. We have determined that a single C.G to T.A transition changes an Arg to a Trp at amino acid residue 106. This substitution explains the increase in net negative charge observed by protein electrophoresis. This Arg 106 residue is absolutely conserved throughout evolution. Published high-resolution crystal structures of LDH reveal that this residue is within the hinge of a loop that closes over the active site of the subunit upon binding of substrate and cofactor and also has a direct role in catalysis. Computer modeling of the variant enzyme suggests that replacement of this Arg residue with a Trp does not induce significant change in the structure of the active site. However, this substitution would result in disruption of enzyme activity through the inability of the uncharged tryptophan side-chain to polarize the substrate carbonyl bond. This would explain the loss of the catalytic function with maintenance of normal kinetic properties in the heterotetramers containing the variant subunits. The ability to maintain normal, tissue-specific kinetic properties could explain the absence of clinical manifestations in the homozygous LDHB GUA1 individuals.

Double-stranded DNA organization in bacteriophage heads: an alternative toroid-based model.

Studies of the organization of double-stranded DNA within bacteriophage heads during the past four decades have produced a wealth of data. However, despite the presentation of numerous models, the true organization of DNA within phage heads remains unresolved. The observations of toroidal DNA structures in electron micrographs of phage lysates have long been cited as support for the organization of DNA in a spool-like fashion. This particular model, like all other models, has not been found to be consistent will all available data. Recently we proposed that DNA within toroidal condensates produced in vitro is organized in a manner significantly different from that suggested by the spool model. This new toroid model has allowed the development of an alternative model for DNA organization within bacteriophage heads that is consistent with a wide range of biophysical data. Here we propose that bacteriophage DNA is packaged in a toroid that is folded into a highly compact structure.

A constant radius of curvature model for the organization of DNA in toroidal condensates.

Toroidal DNA condensates have received considerable attention for their possible relationship to the packaging of DNA in viruses and in general as a model of ordered DNA condensation. A spool-like model has primarily been supported for DNA organization within toroids. However, our observations suggest that the actual organization may be considerably different. We present an alternate model in which DNA for a given toroid is organized within a series of equally sized contiguous loops that precess about the toroid axis. A related model for the toroid formation process is also presented. This kinetic model predicts a distribution of toroid sizes for DNA condensed from solution that is in good agreement with experimental data.

Evidence of novel secondary structure in DNA-bound protamine is revealed by Raman spectroscopy.

Raman spectroscopy studies of protamine-DNA complexes are reported for samples in the solid state at 98% relative humidity. Previous reports utilizing other physical techniques have indicated the presence of B-form DNA in protamine-DNA complexes. The present Raman data support the assignment of a modified B-form which is characterized by appreciable unstacking of the bases. The quality of the present spectra has made it possible, for the first time, to obtain the Raman spectrum of DNA-bound protamine by digital spectral subtraction. The difference spectrum indicates that protamine adopts an unusual secondary structure upon binding to DNA. A dominant amide I band is observed at 1683 cm-1 which is indicative of neither an alpha-helix or beta-sheet conformation. An amide I band at this position has been associated with the 1-->3 hydrogen bond that occurs within a gamma-turn [Bandekar, J., & Krimm, S. (1985) Int. J. Pept. Protein Res. 26, 158-165]. On the basis of this assignment, as well as preliminary results obtained by computer modeling, we propose a new model for the secondary structure of DNA-bound protamine that is rich in 1-->3 hydrogen bonding. Spectral data demonstrate that this structure is absent in protamine molecules in solution. Analyses of spectra of polyarginine-DNA complexes suggest that polyarginine, although similar to protamine in primary structure, assumes a conformation when bound to DNA that is distinct from that adopted by protamine.

Identification of the elemental packing unit of DNA in mammalian sperm cells by atomic force microscopy.

DNA is packaged within the sperm cell nuclei of many vertebrates and all mammals in a highly condensed state by small basic proteins (protamines). Despite continuous investigation for nearly half a century, the actual packing arrangement of the DNA has remained unresolved. Atomic force and electron microscopy studies described in this report provide evidence that the fundamental packing unit for sperm DNA is a toroidal structure, 900A in outside diameter with a 150A diameter hole, which contains up to 60kb of DNA. Although the results presented here are based primarily upon investigations of mammalian sperm cells, they are expected to be valid for all sperm cells which utilize protamines to package DNA.

Tip-radius-induced artifacts in AFM images of protamine-complexed DNA fibers.

Isolated DNA fibers complexed with protamine (the chromosomal protein that packages DNA in mammalian sperm) have been produced by partially decondensing the highly compacted mouse sperm chromatin particle on a glass coverslip. These DNA fibers were then scanned with the atomic force microscope (AFM). While the smallest of the fibers appear in AFM images as ribbon-like structures 250-350 A wide and 10-25 A high, experiments indicate that these images are the result of a convolution of the imaging-tip's shape with the object's actual shape. In such convolutions the height of the object is affected only by the compressibility of the object, while the width is affected in addition by the sharpness of the tip. Images of polyamidoamine particles also appear to show this artifact. We have also deduced the tip's radius of curvature from images of sharp steps and attempt to demonstrate the artifacts associated with a relatively large imaging tip.