3 types of sperm proteins in eukaryotes

Basic spermal proteins of various species of hydrobionts attributed to Pisces and Cephalopoda are studied. It is established that chromatin of nine species referring to two Cypriniformes families includes the somatic histones. Histone H1 of Cypriniformes is attributed to the lysine-rich type histones and contains 35% mol. of lysine and 0.7% mol. of tyrosine. Chromatin of 14 species of fish referring to nine families of the percoid fish superorder includes protamines similar to salmin, a typical protamine of salmon. The amino acidic analysis of protamine from the sandre sperma has shown that it contains 59% mol. of arginine and no tyrosine. Chromatin of three species from squid superorder referring to Cephalopoda includes gametones -- proteins differing from histones and protamines both in the electrophoretic mobility and amino acidic composition (75% mol. of arginine, 3% mol. of tyrosine).     

Quail (Coturnix japonica) protamine, full-length cDNA sequence, and the function and evolution of vertebrate protamines

Using the chicken protamine gene as a probe, we have isolated and sequenced several positive clones from a quail testis cDNA library which reveal the complete sequence for the quail protamine cDNA. The predicted amino acid sequence for the quail protamine contains the N-terminal tetrapeptide ARYR present in the N-terminal region of the mammalian protamines as well as several conserved motifs and arginine clusters. In addition the size of the quail protamine (56 amino acids) is closer to that of mammals (50 amino acids) than that of the chicken (61 amino acids). Altogether this data strongly suggests the existence of an avian-mammalian protamine gene line during evolution. Southern blot analysis suggests a small number of copies (2) per haploid genome (similar to that of chicken). The reported quail protamine cDNA sequence is the second avian protamine for which the amino acid sequence is available so far and provides new insights into vertebrate protamine function and evolution.     

Vertebrate protamine gene evolution I. Sequence alignments and gene structure

Summary The availability of the amino acid sequence for nine different mammalian P1 family protamines and the revised amino acid sequence of the chicken protamine galline (Oliva and Dixon 1989) reveals a much close relationship between mammalian and avian protamines than was previously thought (Nakano et al. 1976). Dot matrix analysis of all protamine genes for which genomic DNA or cDNA sequence is available reveals both marked sequence similarities in the mammalian protamine gene family and internal repeated sequences in the chicken protamine gene. The detailed alignments of the cis-acting regulatory DNA sequences shows several consensus sequence patterns, particularly the conservation of a cAMP response element (CRE) in all the protamine genes and of the regions flanking the TATA box, CAP site, N-terminal coding region, and polyadenylation signal. In addition we have found a high frequency of the CA dinucleotide immediately adjacent to the CRE element of both the protamine genes and the testis transition proteins, a feature not present in other genes, which suggests the existence of an extended CRE motif involved in the coordinate expression of protamine and transition protein genes during spermatogenesis. Overall these findings suggest the existence of an avian-mammalian P1 protamine gene line and are discussed in the context of different hypotheses for protamine gene evolution and regulation.     

Analysis of hamster protamines: primary sequence and species distribution.

Basic nuclear proteins were isolated from the sperm of the Syrian hamster Mesocricetus auratus and characterized by gel electrophoresis, amino acid analysis, and sequencing. Analyses of the proteins by gel electrophoresis show that sperm of this species contain both protamines 1 and 2. The two proteins were purified by HPLC and the complete primary sequence of hamster protamine 1 was determined by automated amino acid sequence analysis. The protein sequence was subsequently confirmed by sequencing the PCR-amplified protamine 1 gene. The first forty-two residues of the hamster protamine 2 sequence were obtained by amino acid sequence analysis of the isolated protein, and this sequence was also confirmed and extended by sequencing the gene. Total basic nuclear protein was also isolated from sperm of six other species of hamsters, the protamines were identified by HPLC and amino acid analysis, and the proportion of protamines 1 and 2 in each species was determined. Marked differences in the protamine 2 content of sperm were observed among the different species of hamster. This variation and the high level of sequence similarity between mouse and hamster protamines provide insight into how the two protamines may be organized in sperm chromatin. Mol. Reprod. Dev. 54:273-282, 1999. Published 1999 Wiley-Liss, Inc.     

Factors affecting nucleosome disassembly by protamines in vitro. Histone hyperacetylation and chromatin structure, time dependence, and the size of the sperm nuclear proteins

Histone displaced in vitro from nuclei by protamine competition display a higher degree of hyperacetylation than the residual histones. In addition, hyperacetylated core particle pools are disassembled in vitro with a higher efficiency than control or nonacetylated core particles and when analyzed by electron microscopy display an elongated shape (length/width ratio = 1.52 +/- 0.19) instead of the round compact shape of control nucleosomes (length/width ratio = 1.06 +/- 0.06). In the absence of histone hyperacetylation, the fish protamines, salmine and iridine (32-33 residues), are relatively inefficient in disassembling nucleosomal core particles in vitro as compared to the large (65-70 residues), tyrosine-containing protamines from rooster (galline), squid, and cuttlefish which disassemble nucleosomes in a range of protamine concentrations close to physiological. The fact that an artificially cross-linked salmine dimer acquires the ability of the large protamines from rooster, squid, and cuttlefish to disassemble core particles in vitro and also binds more tightly to the DNA, suggests that the size of the sperm nuclear protamines is a critical factor in this process. Even when the core histones of spermatid chromatin are hyperacetylated in the trout testis, the replacement process by iridine or salmine is slow and time-dependent in vitro. However, since spermiogenesis in trout occurs over several weeks, the slow in vitro nucleosome disassembly process by salmine is sufficient to allow complete displacement, thus supporting the hypothesis that a protamine-mediated displacement of the histones from DNA in vivo may take place in the salmonid fishes by a mechanism similar to that in the rooster, squid, and cuttlefish.     

Molecular structure of human protamine P4 (HP4), a minor basic protein of human sperm nuclei

Protamine HP4 is a minor protein which was purified from human sperm nuclei. It was characterized by its amino acid composition, peptide mapping after digestion with highly specific endoproteinases and finally by its amino acid sequence. Protamine HP4 contains high amounts of arginine, cysteine and histidine. The primary structure of the protein was established by sequence analysis of intact protamine and of its fragments. HP4 is a P2-type protamine of 58 residues (Mr 7783) structurally related to human protamines HP2 and HP3 from which it only differs by an amino-terminal extension of one and four residues, respectively. These three protamines exhibit a close structural relationship with mouse protamine mP2. The heterogeneity of protamines in human sperm nuclei is discussed.     

A model for the structure of chromatin in mammalian sperm

DNA in mammalian, and most vertebrate sperm, is packaged by protamines into a highly condensed, biochemically inert form of chromatin. A model is proposed for the structure of this DNA-protamine complex which describes the site and mode of protamine binding to DNA and postulates, for the first time, specific inter- and intraprotamine interactions essential for the organization of this highly specialized chromatin. In this model, the central polyarginine segment of protamine binds in the minor groove of DNA, crosslinking and neutralizing the phosphodiester backbone of DNA while the COOH- and NH2-terminal ends of protamine participate in the formation of inter- and intraprotamine hydrogen, hydrophobic, and disulfide bonds. Each protamine segment is of sufficient length to fill one turn of DNA, and adjacent protamines are locked in place around DNA by multiple disulfide bridges. Such an arrangement generates a neutral, insoluble chromatin complex, uses all protamine sulfhydryl groups for cross linking, conserves volume, and effectively renders the chromatin invulnerable to most external influences.     

Primary structure of the ram (Ovis aries) protamine

The amino acid sequence of the protamine isolated from mature sperm nuclei of the ram (Ovis aries) has been established from automated sequence analysis of the S-carboxymethylated protamine. Ram and bull protamines differ only by two point changes and the deletion in bull protamine of the tripeptide Cys39-Arg-Arg41. In mammalian protamines the central region (residues 13-36) consisting mainly of arginine clusters appears to be conserved whereas the N-terminal and C-terminal regions are more variable.     

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.     

Characterization and evolutionary relevance of the sperm nuclear basic proteins from stickleback fish

We have characterized the sperm nuclear basic proteins (SNBPs) of the sticklebacks in the suborder Gasterosteoidei. The complete amino acid sequence of the protamines from Aulorhynchus flavidus, Pungitius pungitius, Gasterosteus aculeatus, (anadromous) and G. wheatlandi, as well as the sequences of the protamines of several species pairs of freshwater G. aculeatus, have been determined. Analysis of the primary structure of these proteins has shown that: a) despite the relatively low amino acid complexity and small molecular mass of these basic proteins, they are very good molecular markers at the generic level. The bootstrap parsimony analysis using their sequences provides a phylogenetic relationship for the old anadromous species of Gasterosteoidei which is identical to that obtained from morphological and behavioral analysis; b) the comparison of the sequences also suggests that protamines from the suborder Gasterosteoidei have most likely evolved from a common gene in the early Acanthopterygii by an extension of the carboxy terminal portion of the molecule; c) protamines are not good markers for recent postglacial freshwater isolates of G. aculeatus. However, in the unique case of Enos Lake (British Columbia), we have been able to detect an additional minor protamine component in the benthic forms of G. aculeatus that is not present in the limnetic forms. Thus, this new protamine must have appeared during the past 12,000 years concomitantly with the speciation of benthics and limnetics in this lake.     

High-performance liquid chromatographic separation and partial characterization of human protamines 1, 2, and 3

A method for separating the three human protamines by HPLC of underivatized, total protamine extracts on a Nucleosil RP-C18 column is described. The identities of the three proteins have been confirmed by a combination of disc gel electrophoresis, amino acid composition, and primary sequence analysis. The results show that human protamine 3 elutes first, closely followed by protamine 2. Protamine 1 elutes later. The amino acid compositions and partial amino terminal sequences of human protamines 2 and 3 indicate that these two proteins are very closely related and suggest that they differ only by three amino-terminal amino acids.     

Protamine precursors in human spermatozoa

Basic proteins isolated from human sperm nuclei are highly heterogeneous. Three groups of nuclear basic proteins have been characterized: somatic-type as well as testis-specific histones, protamines and basic proteins with an electrophoretic mobility which is intermediate between that of histones and that of protamines. Human protamines can be separated into 2 protein families with different amino acid composition and amino-acid sequence. Protamines HP1 differ in their degree of phosphorylation. Protamines HP2, 3 and 4 differ by their amino-terminal sequence. Intermediate basic proteins (HPI1, HPI2, HPS1, HPS2) share a common C-terminal sequence of 54 residues identical to the amino-acid sequence of protamine HP3; only their N-terminal regions are different. Taking into account these structural homologies, the intermediate basic protein HPI1 appears as a precursor of protamines HP2 and HP3.     

Amino acid sequence of the unique protamine from yellow perch.

By the criteria of gel electrophoresis, ion-exchange chromatography, and reverse-phase HPLC, yellow perch protamine behaves as a single component. This observation was confirmed by automated Edman degradation which gave a single unambiguous amino acid sequence PRRRRHAARPVRRRRRTRRSSRVHRRRRAVRRRR. Yellow perch protamine has 34 amino acids, including 21 arginines. It has two histidines, neither of which interrupts an arginine tract. It is unusual among fish protamines in not having a serine or threonine N-terminal to the second arginine tract, and is unique in not being a mixture of components.     

The protamine family of sperm nuclear proteins

The protamines are a diverse family of small arginine-rich proteins that are synthesized in the late-stage spermatids of many animals and plants and bind to DNA, condensing the spermatid genome into a genetically inactive state. Vertebrates have from one to 15 protamine genes per haploid genome, which are clustered together on the same chromosome. Comparison of protamine gene and amino-acid sequences suggests that the family evolved from specialized histones through protamine-like proteins to the true protamines. Structural elements present in all true protamines are a series of arginine-rich DNA-anchoring domains (often containing a mixture of arginine and lysine residues in non-mammalian protamines) and multiple phosphorylation sites. The two protamines found in mammals, P1 and P2, are the most widely studied. P1 packages sperm DNA in all mammals, whereas protamine P2 is present only in the sperm of primates, many rodents and a subset of other placental mammals. P2, but not P1, is synthesized as a precursor that undergoes proteolytic processing after binding to DNA and also binds a zinc atom, the function of which is not known. P1 and P2 are phosphorylated soon after their synthesis, but after binding to DNA most of the phosphate groups are removed and cysteine residues are oxidized, forming disulfide bridges that link the protamines together. Both P1 and P2 have been shown to be required for normal sperm function in primates and many rodents.     

Sequence and phylogenetic analysis of squid myosin-V: a vesicle motor in nerve cells

We have shown that vesicles in the axoplasm of the squid giant axon move on actin filaments and that movement is inhibited by myosin V-specific antibodies [Tabb et al., 1998]. In the study reported in this article, experiments were performed to clone and sequence the cDNA for squid brain myosin V. Five proteolytic fragments of purified squid brain myosin V were analyzed by direct protein sequencing [Tabb et al., 1998]. Based on this sequence information, degenerate primers were constructed and used to isolate cDNA clones by PCR. Five clones, representing overlapping segments of the gene, were sequenced. The sequence data and the previous biochemical characterization of the molecule support the classification of this vesicle-associated myosin as a member of the class V myosins. Motif analysis of the head, neck, and tail domains revealed that squid MyoV has consensus sequences for all the motifs found in vertebrate members of the myosin V family of motor proteins. A phylogenetic tree was constructed from a sequence alignment by the neighbor-joining method, using Megalign (DNAStar, Madison, WI); the resulting phylogenetic tree showed that squid MyoV is more closely related to vertebrate MyoV (mouse dilute, chicken dilute, rat myr6, and human myo5a) than Drosophila and yeast (myo2, and myo4) myosins V. These new data on the phylogenetic relationships of squid myosin V to vertebrate myosin V strengthens the argument that myosin V functions as a vesicle motor in vertebrate neurons.     

A walk though vertebrate and invertebrate protamines

An updated comparative analysis of protamines and their corresponding genes is presented, including representative organisms from each of the vertebrate classes and one invertebrate (squid, Loligo opalescens). Special emphasis is placed on the implications for sperm chromatin organization and the evolutionary significance. The review is based on some of the most recent publications in the field and builds upon previously published reviews on this topic.     

Nucleotide sequence of a bovine protamine cDNA

The nucleotide sequence of a 441-base cDNA encoding the bovine protamine has been determined. This insert, isolated from a bovine spermatid-specific cDNA library, encodes a polypeptide of 50 amino acids of which 26 are arginine, 7 are cysteine, and 2 are tyrosine. The insert contains the complete 3'-noncoding region of 150 bases and most of the 5'-noncoding region. The predicted amino-acid sequence of bovine protamine is about 96% homologous to ram protamine, 76% to boar protamine, 64% to mouse protamine 1 and 52% to human protamine 1 and contains the central, highly basic domain of four arginine clusters found in the trout protamines. Our results show that bovine protamine is 50 amino-acid residues in length and not 47 residues as previously published (Coelingh, J.P. et al. (1972) Biochim. Biophys. Acta 285, 1-14).