Are there molecules of nucleoprotamine?

A short critical review of the data related to protamine and nucleoprotamine (DNP) structure is given. A new model is proposed for DNP structure in which protamine molecules are located in channels between the DNA molecules. DNA molecules are arranged hexagonally in the x–y plane, whereas their relative positions with respect to the z-axis are shifted by 0, 1/3, and 2/3 of the pitch of the double helix. As a result, large cavities are formed in three out of six channels surrounding each DNA molecule where the large grooves are juxtaposed. Protamine molecules are also proposed to have some secondary/tertiary structure prior to complex formation. Inside the channels, a protamine molecule modifies its shape to fill the large grooves of all of the three surrounding DNA molecules simultaneously, and might possibly be in touch with other protamine molecules in neighbouring positions as well. This disposition allows the protamine molecules to be located between DNA molecules without a significant increase in the lattice parameters. BioEssays 21:440–448, 1999. © 1999 John Wiley & Sons, Inc.     

Dynamics of protamine 1 binding to single DNA molecules

Protamine molecules bind to and condense DNA in the sperm of most vertebrates, packaging the sperm genome in an inactive state until it can be reactivated following fertilization. By using methods that enable the analysis of protamine binding to individual DNA molecules, we have monitored the kinetics of DNA condensation and decondensation by protamine 1 (P1) and synthetic peptides corresponding to specific segments of the bull P1 DNA binding domain. Our results show that the number of clustered arginine residues present in the DNA binding domain is the most important factor affecting the condensation and stability of the DNA-protamine complex prior to the formation of inter-protamine disulfide cross-links. The high affinity of P1 for DNA is achieved by the coordinated binding of three anchoring domains, which together in bull P1 contain 19 Arg residues. The single DNA molecule experiments show that sequences containing two or more anchoring domains have an off-rate that is at least 3 orders of magnitude slower than those containing a single domain. The use of Arg, rather than Lys residues, and the inclusion of Tyr or Phe residues in the hinge regions between anchoring domains provide additional stability to the complex.     

Interaction of protamine fragments with DNA

Applying the N å O acyl rearrangement the herring protamine Clupein Y II was cleaved into defined fragments, in order to investigate the properties of the different segments of the protamine molecule. The interaction of the peptide fragments with DNA was studied by thermal denaturation, light scattering and in one case by X-ray diffraction. Furthermore, the labelling with fluorescein isothiocyanate allowed us to study the binding at equilibrium conditions. The data obtained were compared with those of the whole protamine molecule. The results for the different peptide fragments reflect their primary structure, i.e. their content of neutral or hydrophobic residues which interrupt the arginine clusters. The contribution of the two central proline residues and the importance of β-turn formation within the protamine molecule is discussed.     

Identification of bull protamine disulfides

We have identified the disulfide cross-links in bull protamine by titrating intact bull sperm with dithiothreitol (DTT) and following the modification of each cysteine residue with tritiated iodoacetate. The derivatization of each cysteine was monitored by a combination of HPLC, peptide mapping, and protein sequencing. Analyses of total free sulfhydryls show that all seven of the bull protamine cysteines are cross-linked as disulfides in mature sperm. The first disulfide is reduced at a DTT:protamine cysteine (DTT:Cys) ratio of 0.3 and the last at a ratio of 2.0. Intra- and intermolecular disulfides were identified by correlating the reduction of specific disulfides with the dissociation of protamine from DNA in partially reduced sperm and sperm treated with N,N'-ethylenedimaleimide, a bifunctional disulfide cross-linking agent. Three intermolecular and two intramolecular disulfides were identified. The results of these experiments demonstrate that the amino- and carboxy-terminal ends of the bull protamine molecule are folded inward toward the center of the molecule and are locked in place, each by a single intramolecular disulfide bridge. Three intermolecular disulfides cross-link neighboring protamine molecules around the DNA helix in such a manner that the protamines cannot be dissociated from DNA without first reducing the interprotamine disulfides.     

Formation of intraprotamine disulfides in vitro.

When mammalian protamine is dissolved in aqueous buffers at neutral or alkaline pH, both ends of the protein fold inward toward the center of the molecule and form disulfide crosslinks that stabilize several different structures. In the absence of reducing agents, these folded forms of protamine may be visualized and quantitated by gel electrophoresis. Using this technique, we have examined the formation of bull protamine disulfides in solution and describe a variety of factors that affect this process. At pH 8, disulfide-stabilized folded forms of protamine appear within minutes after solubilization of the fully reduced protein. Five different monomers are detected by electrophoresis. Each of these monomers is stabilized by at least one disulfide crosslink and migrates with a distinct mobility, ahead of the fully reduced and extended protein. Under certain conditions, dimers of these folded structures crosslinked by interprotamine disulfides are also formed. The appearance of these disulfide-crosslinked forms of protamine is effected by air oxidation, accelerated at alkaline pH, inhibited upon lowering the pH below pH 7 and eliminated by modifying the protein's cysteine residues. Similar intramolecular disulfides are also produced after the protamine molecule binds to DNA. These results suggest that only those cysteines located within the amino- and carboxyterminal ends of the protein appear to participate in forming intramolecular disulfides in vitro.     

Role of amino acid insertions on intermolecular forces between arginine peptide condensed DNA helices: implications for protamine-DNA packaging in sperm

In spermatogenesis, chromatin histones are replaced by arginine-rich protamines to densely compact DNA in sperm heads. Tight packaging is considered necessary to protect the DNA from damage. To better understand the nature of the forces condensing protamine-DNA assemblies and their dependence on amino acid content, the effect of neutral and negatively charged amino acids on DNA-DNA intermolecular forces was studied using model peptides containing six arginines. We have previously observed that the neutral amino acids in salmon protamine decrease the net attraction between protamine-DNA helices compared with the equivalent homo-arginine peptide. Using osmotic stress coupled with x-ray scattering, we have investigated the component attractive and repulsive forces that determine the net attraction and equilibrium interhelical distance as a function of the chemistry, position, and number of the amino acid inserted. Neutral amino acids inserted into hexa-arginine increase the short range repulsion while only slightly affecting longer range attraction. The amino acid content alone of salmon protamine is enough to rationalize the forces that package DNA in sperm heads. Inserting a negatively charged amino acid into hexa-arginine dramatically weakens the net attraction. Both of these observations have biological implications for protamine-DNA packaging in sperm heads.     

Sexual selection drives weak positive selection in protamine genes and high promoter divergence,enhancing sperm competitiveness

Phenotypic adaptations may be the result of changes in gene structure or gene regulation, but little is known about the evolution of gene expression. In addition, it is unclear whether the same selective forces may operate at both levels simultaneously. Reproductive proteins evolve rapidly, but the underlying selective forces promoting such rapid changes are still a matter of debate. In particular, the role of sexual selection in driving positive selection among reproductive proteins remains controversial, whereas its potential influence on changes in promoter regions has not been explored. Protamines are responsible for maintaining DNA in a compacted form in chromosomes in sperm and the available evidence suggests that they evolve rapidly. Because protamines condense DNA within the sperm nucleus, they influence sperm head shape. Here, we examine the influence of sperm competition upon protamine 1 and protamine 2 genes and their promoters, by comparing closely related species of Mus that differ in relative testes size, a reliable indicator of levels of sperm competition. We find evidence of positive selection in the protamine 2 gene in the species with the highest inferred levels of sperm competition. In addition, sperm competition levels across all species are strongly associated with high divergence in protamine 2 promoters that, in turn, are associated with sperm swimming speed. We suggest that changes in protamine 2 promoters are likely to enhance sperm swimming speed by making sperm heads more hydrodynamic. Such phenotypic changes are adaptive because sperm swimming speed may be a major determinant of fertilization success under sperm competition. Thus, when species have diverged recently, few changes in gene-coding sequences are found, while high divergence in promoters seems to be associated with the intensity of sexual selection.     

Transfection of Escherichia coli Spheroplasts I. General Facilitation of Double-Stranded Deoxyribonucleic Acid Infectivity by Protamine Sulfate

The addition of 25 mug of protamine sulfate per ml to lysozyme-ethylenediamine-tetraacetic acid spheroplasts of Escherichia coli stimulates transfection not only for T1 phage deoxyribonucleic acid (DNA; Hotz and Mauser, 1969) but also for the following phage DNA species: lambda, 10,000-fold to an efficiency of 10(-3) infective centers per DNA molecule; phiX174 replicative form, 300-fold to an efficiency of 5 x 10(-2); fd replicative form, 300-fold to 10(-6); T7, 300-fold to 3 x 10(-7). Three native phage DNA species were not infective at all in the absence of protamine sulfate but were infective in the presence of protamine sulfate with the following efficiencies: T4, 10(-5); T5, 3 x 10(-6); and P22, 3 x 10(-9). The effect of protamine sulfate is specific for double-stranded DNA. The application of infectivity assays to the study of phage DNA replication, recombination, prophage integration, prophage excision, and interspecies transfection are discussed.     

Conformation of the fowl protamine, galline, and its binding properties to DNA

1. CD spectra showed that the fowl protamine, galline, has an unordered structure rich in reverse turns in neutral solution. Eight reverse turns were predicted to be present in the galline molecule on the basis of its amino acid sequence. Spectrophotometric analyses revealed that galline efficiently bound to DNA in 0.25 mM EDTA/10 mM Tricine-HCl, pH 7.4, but hardly so in 30 mM NaCl/3 mM sodium citrate, pH 7.0. Citrate ions bound specifically to the galline molecule, causing a conformational change in it. As a result, galline could not interact with DNA. 2. The concentration of unbound galline in a mixture of DNA and galline in 100 mM NaCl/50 mM Tricine-HCl, pH 7.4, at 37 C was determined by measurement of the intrinsic fluorescence of tyrosine residues of galline in the supernatant after ultracentrifugation of the mixture. The Scatchard plot showed positive co-operativity in the binding of galline to DNA and the binding parameters were determined: the co-operative binding constant (Kc) = 3.3 X 10(7)M-1, the co-operativity factor (q) = 800, and the number of nucleotides of DNA occupied by one galline molecule (n) = 28. The Kc and q values were intermediate between those for clupeine Z from herring sperm and S-methyl protamine from boar sperm. That is, the binding constants of protamine as to DNA decrease in the order of herring, fowl, and boar, while the co-operativities in binding increase in that order.     

Zinc is sufficiently abundant within mammalian sperm nuclei to bind stoichiometrically with protamine 2

Although studies have demonstrated that zinc can bind to sperm nuclear proteins, specifically protamine 2, it has not been shown that the metal is sufficiently abundant inside the sperm nucleus to interact stoichiometrically with these proteins. In this study proton-induced X-ray emission (PIXE) has been used to measure the amount of sulfur and zinc within the nuclei of individual sperm cells to infer the stoichiometry of zinc binding to protamine 2 in six species of mammal: bull, chinchilla, stallion, hamster, human, and mouse (protamine 2 comprises from 0% (bull) to 67% (mouse) of the protamine present in the sperm of these animals). Using the sulfur mass and electrophoretic data on the relative proportion of protamine 1 and protamine 2 in the sperm chromatin of these species, the protamine 1, protamine 2, and total protamine contents within each species sperm nuclei have been determined. The PIXE measurements reveal that the zinc content of the sperm nucleus varies proportionately with the protamine 2 content of sperm chromatin. PIXE analyses of hamster protamines extracted under conditions that appear to at least partially preserve zinc binding also confirm that the majority of the metal is bound to protamine. In five of the species examined, sufficient zinc is present for each protamine 2 molecule to bind one zinc. The results obtained for chinchilla sperm, conversely, indicate the chinchilla protamine 2 molecule may interact differently with zinc. Chinchilla sperm only contain enough zinc for one atom to be bound to two protamine 2 molecules.     

Phosphorylated protamines. I. Binding stoichiometry and thermal stability of complexes in DNA.

To decipher on a molecular level the role of protamine phosphorylation in spermiogenesis, clupeine Z species containing one, two or three serine phosphates were prepared utilizing a recently developed chemical procedure. The melting of complexes with calf thymus DNA showed that thermal stability decreases with increasing degree of phosphorylation. The stoichiometry of the nucleoprotamine complexes was investigated analyzing the melting curves and using the fluorescamine assay recently described. Phosphorylation significantly reduces binding stoichiometry defined as DNA-nucleotides covered by a protamine molecule. Thus, phosphorylated protamines are more densely packed along DNA; the implications on processes occurring in spermiogenesis as i. e. histone replacement, are discussed. A general discussion on the variability in protein-DNA stoichiometry values obtained by different procedures is included.     

The lack of protamine 2 (P2) in boar and bull spermatozoa is due to mutations within the P2 gene.

The nuclei of spermatozoa in all mammals examined so far contain P1 protamine. A second protamine variant, protamine P2, has to date been isolated only from human and murine spermatozoa where it represents the major fraction of basic nuclear protein. In order to elucidate the reason for this unusual distribution of the protamine variants among mammals we have investigated the expression of protamine P2 in boar and bull. It can be shown that also in these species protamine 2 is transcribed and translated on low levels. Various mutational events though have altered the primary structure of the protein: In boar, a deletion of 8 aminoacids has removed a sequence motif from the amino-terminus of the molecule, which highly probable is of functional relevance. The bovine sequence, as a consequence of numerous point mutations has accumulated neutral and hydrophobic aminoacids which reduce the affinity of the protamine 2 to DNA.     

Deoxyribonucleoproteins of herring sperm nuclei. I. Chemical composition

The chemical composition of deoxyribonucleoproteins from herring sperm nuclei was analyzed and the results are summarized as follows: 1. Chemical analysis of nuclear proteins and nucleic acids revealed that arginine/P molar ratio in herring sperm nuclei is unity but the ratio of arginine residues in protamine to phosphorus in the total DNA is 0.86. 2. The deoxyribonucleoproteins were isolated and their composition showed that about 14% of the total DNA in herring sperm nuclei is free from protamine and is bound with nonprotamine proteins in the weight ratio of nonprotamine proteins to DNA of 0.25-0.30. The remaining 86% of the total DNA is combined mainly with protamine and a small amount of nonprotamine proteins; the weight ratios of protamine and nonprotamine proteins to DNA are 0.75 and 0.08, respectively. In the latter complex, the molar ratio of arginine residues in protamine to phosphorus in DNA is unity.     

Formation of native-like mammalian sperm cell chromatin with folded bull protamine

The DNA of most vertebrate sperm cells is packaged by protamines. The primary structure of mammalian protamine I can be divided into three domains, a central DNA binding domain that is arginine-rich and amino- and carboxyl-terminal domains that are rich in cysteine residues. In native bull sperm chromatin, intramolecular disulfide bonds hold the terminal domains of bull protamine folded back onto the central DNA binding domain, whereas intermolecular disulfide bonds between DNA-bound protamines help stabilize the chromatin of mature mammalian sperm cells. Folded bull protamine was used to condense DNA in vitro under various solution conditions. Using transmission electron microscopy and light scattering, we show that bull protamine forms particles with DNA that are morphologically similar to the subunits of native bull sperm chromatin. In addition, the stability provided by intermolecular disulfide bonds formed between bull protamine molecules within in vitro DNA condensates is comparable with that observed for native bull sperm chromatin. The importance of the bull protamine terminal domains in controlling the bull sperm chromatin morphology is indicated by our observation that DNA condensates formed under identical conditions with a fish protamine, which lacks cysteine-rich terminal domains, do not produce as uniform structures as bull protamine. A model is also presented for the bull protamine.DNA complex in native sperm cell chromatin that provides an explanation for the positions of the cysteine residues in bull protamine that form intermolecular disulfide bonds.     

The binding mode of a mammalian (boar) protamine to DNA

The binding modes of mammalian and fish protamines to DNA were studied by reconstitution experiments from dansylated protamines and DNA, using fluorescence spectroscopy, thermal denaturation and sedimentation. Both boar and fish protamines showed strong positive cooperativity in binding to DNA. Binding parameters of the protamines were determined in 0.1 M NaCl, 50 mM Tricine-HCl, pH 7.4, at 37 degrees C: in the boar protamine, the cooperative binding constant (Kc) = 3.4 X 10(6) M-1 and the cooperative factor (q) = 667, in the fish protamine, Kc = 1.8 X 10(7) M-1 and q = 304. The boar protamines bound to DNA with two functional domains, but the fish protamines bound directly to DNA as a single linear molecule.     

Modification of histone binding in calf thymus chromatin by protamine.

When calf thymus chromatin is incubated with protamine, the protein binds to DNA, forming a chromatin-protamine complex. The binding reaches a saturating level at the weight ratio of protamine to DNA of approximately 0.5. Although the saturated binding of protamine to DNA does not cause major displacement of histones from calf thymus chromatin, examination of the dissociation profiles by salt in combination with urea of protamine-treated chromatin shows that the histone-DNA interactions are markedly altered by such binding. The dissociation of histones from the chromatin-protamine complex requires less NaCl but the same concentration of urea as that for untreated chromatin, suggesting that the electorstatic interactions between the histones and DNA are decreased as a result of protamine binding. When protamine concentration is increased beyond that required for saturated binding to DNA during in vitro exposure of calf thymus chromatin to protamine, lysine-rich histone is completely displaced.     

Cation-exchange displacement chromatography of proteins with protamine displacers: effect of induced salt gradients.

Protamine was investigated for its utility as a protein displacer in cation-exchange systems. Although the protamine solution contained several variants of the molecule, the high affinity of all of the components in this heterogeneous biopolymer enabled it to act as an efficient protein displacer. To facilitate parameter estimation of the protamine, a preliminary purification was carried out by preparative elution chromatography. Chromatographic parameters of both the feed proteins and protamine displacer were obtained for use in a multicomponent steric mass action ion-exchange displacement model. Model simulations were compared to displacement results under both moderate and intense induced salt gradient conditions. In both cases, excellent agreement was obtained between the displacement experiments and theoretical predictions. In addition, these studies serve to dramatize the importance of induced salt gradients in ion-exchange displacement systems.     

Physico-chemical properties of deoxyribonucleoprotamine from sturgeon sperm heads]

Deoxyribonucleoprotamine (DNPn) from sonicated nuclei of sturgeon sperm heads was studied by means of ring dichroism. A derivative analysis of DNA and DNPn melting curves in 1 mM Tris. HCl pH 8.0 revealed the fraction of protein-free DNA being about 30% and suggested the preferable binding of protamine molecules with AT-rich DNA regions. The latter is also confirmed by the data on ring dichroism of protein-poor soluble DNAPn fraction in 0,14 M NaCl. Ring dichroism of DNA and DNPn in 1 mM Tris coinsides at the wavelength of 310-240 nm at concentrations of 500-50 mkg/ml. Dilution of DNPn to 5 mkg-ml resulted in the decrease of the ellipticity at 275 nm and produced no effect at 260-210 nm. The effect observed is suggested to be due to a partial transition of DNA in DNPn into C-form under the dilution as a result of a higher molecule hydration and a destruction of some hydrogen bonds between guanidine residues of arginine and oxygen of phosphate groups, stabilyzing DNA in the B-form. Ring dichroism spectrum of protamine, calculated by the subtraction of DNA spectrum from DNPn spectrum at the region of 240-210 nm coinsides with that of free protamine and indicates the absence of an ordered structure in protamine molecules in DNPn.