A single-stranded nucleic acid-binding protein from Artemia salina. II. Interaction with nucleic acids

A helix-destabilizing protein, HD40 (Mr 40,000), isolated from the cytoplasm of Artemia salina (Marvil, D.K., Nowak, L., and Szer, W. (1980) J. Biol. Chem. 255, 6466-6472) stoichiometrically disrupts the secondary structures of synthetic single-stranded and helical polynucleotides (e.g. poly(rA), poly(dA), poly(rC), poly(dC), and poly(rU)) as well as those of natural polynucleotides (e.g. MS2 RNA and phi X174 viral DNA). The conformations of double-stranded DNA and double- or triple-stranded synthetic polynucleotides are not affected by the protein. Formation of duplexes, e.g. poly(rA . rU), is prevented by HD40 at 25 to 50 mM but not at 100 to 140 mM NaCl. The unwinding of the residual secondary structure of RNA and DNA by HD40 is not highly cooperative and has a stoichiometry of one HD40 per 12 to 15 nucleotides. The addition of HD40 in excess of 1 molecule per 12 to 15 nucleotides results in the cooperative formation of distinct bead-like structures along the nucleic acid strand. The beads are about 20 nm in diameter with a center to center distance of about 40 nm. The appearance of the beads is not accompanied by any spectral changes (CD and UV) beyond those obtained at a stoichiometry of one HD40 molecule per 12 to 15 nucleotides.     

Poly(rA) binds poly(rG).poly(rC) to form a triple helix.

Poly(rA) binds poly(rG).poly(rC) to form a triple helix. Evidence for this structure includes ultraviolet absorbance mixing curves and melting curves, and circular dichroism spectroscopy. The formation of the triple helix depends on the length of the poly(rC) strand. Triple helix forms when the average length is around 100 nucleotides but does not form when the average length is about 500 nucleotides.     

New wrinkles on polynucleotide duplexes

Most fibrous polynucleotides of general sequence exhibit secondary structures that are described adequately by regular helices with a repeated motif of only one nucleotide. Such helices exploit the fact that A:T, T:A, G:C, and C:G pairs are essentially isomorphous and have dyadically-related glycosylic bonds. Polynucleotides with regularly repeated base-sequences sometimes assume secondary structures with larger repeated motifs which reflect these base-sequences. The dinucleotide units of the Z-like forms of poly d(As4T):poly d(As4T), poly d(AC):poly d(GT) and poly d(GC):poly d(GC) are dramatic instances of this phenomenon. The wrinkled B and D forms of poly d(GC):poly d(GC) and poly d(AT):poly d(AT) are just as significant but more subtle examples. It is possible also to trap more exotic secondary structures in which the molecular asymmetric unit is even larger. There is, for example, a tetragonal form of poly d(AT):poly d(AT) which has unit cell dimensions a = b = 1.71nm, c = 7.40nm, gamma = 90 degrees. The c dimension corresponds to the pitch of a molecular helix which accommodates 24 successive nucleotide pairs arranged as a 4(3) helix of hexanucleotide duplexes. The great variety of nucleotide conformations which occur in these large asymmetric units has prompted us to describe them as pleiomeric, a term used in botany to describe whorls having more than the usual number of structures. Pleiomeric DNAs need not contain nucleotide conformations that are very different from one another. On the other hand, DNAs carrying nucleotides of very different conformation must be pleiomeric. This is because 4 nucleotides of different conformation are needed to join patches of secondary structure which are as different as A or B or Z. Differences in nucleotide structures may occur also between chains rather than within chains. In poly d(A):poly d(T), the purine nucleotides all contain C3'-endo furanose rings and the pyrimidine nucleotides C2'-endo rings. Analogous heteronomous structures may exist in DNA-RNA hybrids although these duplexes are also found to have symmetrical A-type conformations.     

Distinct RNP complexes of shuttling hnRNP proteins with pre-mRNA and mRNA: candidate intermediates in formation and export of mRNA

Nascent pre-mRNAs associate with hnRNP proteins in hnRNP complexes, the natural substrates for mRNA processing. Several lines of evidence indicate that hnRNP complexes undergo substantial remodeling during mRNA formation and export. Here we report the isolation of three distinct types of pre-mRNP and mRNP complexes from HeLa cells associated with hnRNP A1, a shuttling hnRNP protein. Based on their RNA and protein compositions, these complexes are likely to represent distinct stages in the nucleocytoplasmic shuttling pathway of hnRNP A1 with its bound RNAs. In the cytoplasm, A1 is associated with its nuclear import receptor (transportin), the cytoplasmic poly(A)-binding protein, and mRNA. In the nucleus, A1 is found in two distinct types of complexes that are differently associated with nuclear structures. One class contains pre-mRNA and mRNA and is identical to previously described hnRNP complexes. The other class behaves as freely diffusible nuclear mRNPs (nmRNPs) at late nuclear stages of maturation and possibly associated with nuclear mRNA export. These nmRNPs differ from hnRNPs in that while they contain shuttling hnRNP proteins, the mRNA export factor REF, and mRNA, they do not contain nonshuttling hnRNP proteins or pre-mRNA. Importantly, nmRNPs also contain proteins not found in hnRNP complexes. These include the alternatively spliced isoforms D01 and D02 of the hnRNP D proteins, the E0 isoform of the hnRNP E proteins, and LRP130, a previously reported protein with unknown function that appears to have a novel type of RNA-binding domain. The characteristics of these complexes indicate that they result from RNP remodeling associated with mRNA maturation and delineate specific changes in RNP protein composition during formation and transport of mRNA in vivo.     

A structural model for the polyadenylic acid single helix.

In the crystal, the poly(A) fragment ApApA assumes a conformation with the 5′-terminal and middle adenosines in a single helical arrangement. From the atomic co-ordinates of these two nucleotides the structure of the poly(A) single helix was derived mathematically. The helix has a pitch height of 25.4 Å, nine nucleotides per turn and the normals to the adenine bases form an angle of 66 ° with the helix axis.     

New Wrinkles on Polynucleotide Duplexes

Abstract

Most fibrous polynucleotides of general sequence exhibit secondary structures that are described adequately by regular helices with a repeated motif of only one nucleotide. Such helices exploit the fact that A:T, T:A, G:C, and C:G pairs are essentially isomorphous and have dyadically-related glycosylic bonds. Polynucleotides with regularly repeated base-sequences sometimes assume secondary structures with larger repeated motifs which reflect these base-sequences. The dinucleotide units of the Z-like forms of poly d(As⁴T):poly d(As⁴T), poly d(AC):poly d(GT) and poly d(GC):poly d(GC) are dramatic instances of this phenomenon. The wrinkled B and D forms of poly d(GC):poly d(GC) and poly d(AT):poly d(AT) are just as significant but more subtle examples. It is possible also to trap more exotic secondary structures in which the molecular asymmetric unit is even larger. There is, for example, a tetragonal form of poly d(AT):poly d(AT) which has unit cell dimensions a = b = 1.71nm, c= 7.40nm, γ = 90°. The C dimension corresponds to the pitch of a molecular helix which accommodates 24 successive nucleotide pairs arranged as a 4₃ helix of hexanucleotide duplexes. The great variety of nucleotide conformations which occur in these large asymmetric units has prompted us to describe them as pleiomeric, a term used in botany to describe whorls having more than the usual number of structures. Pleiomeric DNAs need not contain nucleotide conformations that are very different from one another. On the other hand, DNAs carrying nucleotides of very different conformation must be pleiomeric. This is because 4 nucleotides of different conformation are needed to join patches of secondary structure which are as different as A or B or Z. Differences in nucleotide structures may occur also between chains rather than within chains. In poly d(A):poly d(T), the purine nucleotides all contain Ci'-endo furanose rings and the pyrimidine nucleotides C2 '-endo rings. Analogous heteronomous structures may exist in DNA-RNA hybrids although these duplexes are also found to have symmetrical A-type conformations.     

Right-handed and left-handed helices of poly(dA-dC) X (dG-dT).

The secondary structures of poly(dA-dC) X (dG-dT) were studied using CD and IR spectroscopies. We give spectroscopic evidence of secondary structure transitions of poly(dA-dC) X (dG-dT) from a B to a Z-like helix, induced by transition metal ions (Ni2+) in presence of high concentrations of Cs+ and Na+. In the presence of Na+, the B in equilibrium Z transition occurs at any temperature, whereas premelting conditions are required in presence of Cs+. For these two alkali ions the Z-like form is only induced by Ni2+ ions through their specific interactions at N7 of purines, under conditions of low water activity due to the high alkali salt concentration. We also show that the CD spectrum obtained in presence of Cs+ ions and characterized by a negative band at 275 nm, cannot be interpreted in terms of Z-like left-handed helix but reflects a modified B right-handed helix.     

Characterization of the major hnRNP proteins from Drosophila melanogaster

To better understand the role(s) of hnRNP proteins in the process of mRNA formation, we have identified and characterized the major nuclear proteins that interact with hnRNAs in Drosophila melanogaster. cDNA clones of several D. melanogaster hnRNP proteins have been isolated and sequenced, and the genes encoding these proteins have been mapped cytologically on polytene chromosomes. These include the hnRNP proteins hrp36, hrp40, and hrp48, which together account for the major proteins of hnRNP complexes in D. melanogaster (Matunis et al., 1992, accompanying paper). All of the proteins described here contain two amino-terminal RNP consensus sequence RNA-binding domains and a carboxyl-terminal glycine-rich domain. We refer to this configuration, which is also found in the hnRNP A/B proteins of vertebrates, as 2 x RBD-Gly. The sequences of the D. melanogaster hnRNP proteins help define both highly conserved and variable amino acids within each RBD and support the suggestion that each RBD in multiple RBD-containing proteins has been conserved independently and has a different function. Although 2 x RBD-Gly proteins from evolutionarily distant organisms are conserved in their general structure, we find a surprising diversity among the members of this family of proteins. A mAb to the hrp40 proteins crossreacts with the human A/B and G hnRNP proteins and detects immunologically related proteins in divergent organisms from yeast to man. These data establish 2 x RBD-Gly as a prevalent hnRNP protein structure across eukaryotes. This information about the composition of hnRNP complexes and about the structure of hnRNA-binding proteins will facilitate studies of the functions of these proteins.     

Two types of tripeptide conformation in collagen. Calculation of the structure of (Gly-Pro-Ser)n and (Gly-Val-Hyp)n polytripeptides

Conformational analysis of polypeptides (Gly-Pro-Ser)n and (Gly-Val-Hyp)n was carried out for collagen-like triple helical complexes (coiled coils with screw symmetry). The lowest energy structure of the first polymer (helical parameters t 52,8, h 0,282 nm) is very close to that of (Gly-Pro-Hyp)n. The hydroxyl group of a serine residue does not form any intramolecular hydrogen bonds in this structure. (Gly-Val-Hyp)n triple complex is shown to unwind to t 7,7, h 0,297 nm as a result of optimization procedure. These findings confirm the assumption, made earlier on the basis of conformational analysis of (Gly-Pro-Hyp)n, (Gly-Pro-Ala)n, (Gly-Ala-Hyp)n, (Gly-Ala-Ala)n, that the collagen triple helix contains stable wound triplets with proline in the second position, while the absence of imino acid in the 2nd position facilitates the unwinding of the triple helix. Thus, a collagen helix appears to have different parameters for the sites differing in the amino acid sequence. The values measured in the X-ray experiments (h 0,29 nm, t' 36) should be considered as a result of averaging. The model allows to reconcile the X-ray data for collagen and crystalline (Gly-Pro-Pro)10 oligomer.     

The region of tobacco mosaic virus RNA involved in the nucleation of assembly.

The interaction of TMV RNA with the disk aggregate of TMV protein at the initiation of assembly has been studied by using the techniques of RNA sequencing. The 5' end group has been identified, and shown not to be protected in the early stages of assembly from accessibility to nuclease digestion. A population of RNA fragments of average length 250 nucleotides, originating from a unique region of TMV RNA, is encapsidated by limited assembly, and sufficient sequence information is available to identify certain unusual features. The protected region does not contain highly reiterated simple repeating sequences, but may contain more complicated repeats. The length and complexity of the nucleation region may reflect adaptation to the efficient mediation of the conformational change from disk to helix of TMV protein, besides a requirement for binding to the disk, and this may be an important part of the mechanism of specificity in the nucleation of assembly.     

Heterogeneous nuclear ribonucleoprotein complexes from Xenopus laevis oocytes and somatic cells.

HnRNP proteins have been implicated in most stages of cellular mRNA metabolism, including processing, nucleocytoplasmic transport, stability, and localization. Several hnRNP proteins are also known to participate in key early developmental decisions. In order to facilitate functional studies of these pre-mRNA- and mRNA-binding proteins in a vertebrate organism amenable to developmental studies and experimental manipulation, we identified and purified the major hnRNP proteins and isolated the hnRNP complex from Xenopus laevis oocytes and somatic cells. Using affinity chromatography and immunological methods, we isolated a family of >15 abundant single-stranded nucleic acid-binding proteins, which range in apparent molecular weight from approximately 20 kDa to >150 kDa, and with isoelectric points from <5 to >8. Monoclonal antibodies revealed that a subset of these proteins are major hnRNP proteins in both oocytes and somatic cells in culture, and include proteins related to human hnRNP A2/B1/B2 and hnRNP K. UV crosslinking in living cells demonstrated that these proteins bind poly(A)+ RNA in vivo. Immunopurification using a monoclonal antibodyto X. aevishnRNPA2 resulted in the isolation of RNP complexes that contain a specific subset of single-stranded nucleic acid-binding proteins. The protein composition of complexes isolated from somatic cells and from oocyte germinal vesicles was similar, suggesting that the overall properties and functions of hnRNP proteins in these two cell types are comparable. These findings, together with the novel probes generated here, will also facilitate studies of the function of vertebrate RNA-binding proteins using the well characterized X. laevis oocyte and early embryo as experimental systems.     

Visualization of RecA protein and its complexes with DNA by quick-freeze/deep-etch electron microscopy

Freeze-etch electron microscopy of pure RecA protein aggregates, as well as of RecA protein complexes on single-stranded and double-stranded DNA formed with various nucleotides, has permitted a clearer discrimination between the two different helical polymers that this protein forms. Both are continuous, single-start, right-handed helices; however, the form observed when ATP or non-hydrolyzable ATP analogs are present has a pitch of 9.5 nm and a diameter of 10 nm, while the other form, observed in the absence of ATP or its analogs, or in the presence of ADP, has a pitch of 6 nm and a diameter of 12 nm. The former "long pitch" helix is found only when RecA protein is bound to DNA. The latter "short pitch" helix is also observed in pure RecA protein polymers (also termed rods) and in the needle-like paracrystals of RecA protein that form in the presence of magnesium or spermidine ions, representing bundles of rods closely packed in register. Addition of ATP or non-hydrolyzable ATP analogs in the absence of DNA dissociates the pure RecA protein crystals, as well as individual helical rods, into short curvilinear chains of attached monomers. These chains typically form closed, circular rings of 7(+/- 1) protein monomers, similar in construction to a single turn of the RecA protein helix, but significantly broader in diameter. The role of ATP in interconverting the various polymeric forms of RecA protein is discussed within the context that ATP functions as a reversible allosteric effector of RecA protein, much as it mediates reversible conformational changes in other vectoral motor proteins such as myosin, dynein, kinesin and the 70,000 Mr "heat shock" ATPases. We discuss how cyclic conversions back and forth between the short- and long-pitch conformations of RecA protein could mediate in reversible single-stranded and double-stranded DNA interactions during the search for homology.     

500-MHz 1H NMR study of poly(dG).poly(dC) in solution using one-dimensional nuclear Overhauser effect

Secondary structures of poly(dG).poly(dC) and poly(dG).poly(dm5C) in solution are determined by nuclear Overhauser effect (NOE) measurements on GH8-deuterated and -nondeuterated DNAs with low presaturation pulse lengths (10-25 ms) and low-power and prolonged accumulations in the range of 50,000-72,000 scans. Under these conditions, the NOE difference spectra were free from diffusion. Primary NOEs between base protons GH8/CH6 and sugar protons H1', H2'/H2', and H3' suggest that in poly(dG).poly(dC) both guanine and cytosine nucleotides adopt a C3'-endo, low anti X = 200-220 degrees conformation. Computer modeling of the NOE data enable identification for the first time, in terms of the geometry of the nucleotide repeat, handedness, and helix geometry, of the structure of poly(dG).poly(dC) to be the A form, and the derived structure for the polymer duplex is very close to the single crystal structure of the double-helical d-GGGGCCCC [McCall, M., Brown, T., & Kennard, O. (1985) J. Mol. Biol. 183, 385-396]. Similar nuclear Overhauser effect data on poly(dG).poly(dm5C) revealed that G and m5C adopt a C2'endo, anti X = 240-260 degrees conformation, which indicates that this DNA exhibits the B form in solution. In summary, the results presented in this paper demonstrate that methylation of cytosines in poly(dG).poly(dC) causes A----B transition in the molecule.     

Monoclonal antibodies specific for poly(dG) X poly(dC) and poly(dG) X poly(dm5C)

Most duplex DNAs that are in the "B" conformation are not immunogenic. One important exception is poly(dG) X poly(dC), which produces a good immune response even though, by many criteria, it adopts a conventional right-handed helix. In order to investigate what features are being recognized, monoclonal antibodies were prepared against poly(dG) X poly(dC) and the related polymer poly(dG) X poly(dm5C). Jel 72, which is an immunoglobulin G, binds only to poly(dG) X poly(dC), while Jel 68, which is an immunoglobulin M, binds approximately 10-fold more strongly to poly(dG) X poly(dm5C) than to poly(dG) X poly(dC). For both antibodies, no significant interaction could be detected with any other synthetic DNA duplexes including poly[d(Gm5C)] X poly[d(Gm5C)] in both the "B" and "Z" forms, poly[d(Tm5Cm5C)] X poly[d(GGA)], and poly[d(TCC)] X poly[d(GGA)], poly(dI) X poly(dC), or poly(dI) X poly(dm5C). The binding to poly(dG) X poly(dC) was inhibited by ethidium and by disruption of the DNA duplex, confirming that the antibodies were not recognizing single-stranded or multistranded structures. Furthermore, Jel 68 binds significantly to phage XP-12 DNA, which contains only m5C residues and will precipitate this DNA in the absence of a second antibody. The results suggest that (dG)n X (dm5C)n sequences in natural DNA exist in recognizably distinct conformations.