The complete amino acid sequence of the basic nuclear protein of bull spermatozoa

Sperm DNA and detection of DNA fragmentations in sperm

The questionable effectiveness of routine sperm parameters in determining male factor infertility problems and increasing the success rates of assisted reproductive techniques have led to the investigation of more detailed sperm parameters that could affect the male fertility and reproduction. Thus, the effects of different sperm parameters such as sperm DNA integrity was started to be investigated thanks to the previously described methods such as single cell gel electrophoresis (COMET) assay, sperm chromatin structure assay (SCSA), acridine orange test (AOT), terminal deoxynucleotidyl transferase-mediated deoxyuridine (TdT) triphosphate (dUTP) nick end labeling (TUNEL) assay and sperm chromatin dispersion (SCD) test. However, studying on sperm DNA might be very complex because the sperm DNA differs from the somatic cell DNA with its unique structure. Also, the sperm DNA undergoes many changes during spermatogenesis and it is condensed by being packaged tightly with different types and numbers of protamines in different species. Despite all these difficulties, these methods provide important information about the reasons and consequences of DNA damages in sperm and the effects of these damages on reproduction.

Proposed mechanism for sperm chromatin condensation/decondensation in the male rat

Condensation of sperm chromatin occurs after spermatozoa have left the caput epididymis and are in transit to the cauda epididymis, during which time large numbers of disulfide bonds are formed. The formation of these disulfide bonds requires the repeated oxidation of the cofactor, NAD(P)H. To date, the means by which this oxidation is achieved has yet to be elucidated. Spermatozoa lose the bulk of their cytoplasm prior to leaving the testis; and, as a result, any shuttle systems for removing and transferring reducing equivalents into the mitochondria are unlikely to be operational. In an apparent preparation for the loss of cytoplasm, however, the following events occur during spermatogenesis. First, androgen-binding protein (ABP) is produced by the Sertoli cells of the testis; second, high affinity binding sites for ABP are inserted into the membrane surrounding the nucleus; and third, a nuclear location is acquired for the enzyme, 3alpha-hydroxysteroid dehydrogenase (3alpha-HSD). We propose that after the loss of cytoplasm, the nuclear region of spermatozoa is directly accessible to constituents contained in the lumen of the caput epididymis. As a consequence, luminal ABP attaches itself to the nuclear membrane via its binding sites, and is internalized. After internalization, ABP exerts its principle function, which is to bind to luminal 5alpha-dihydrotestosterone (5alpha-DHT), thereby ensuring its availability to the enzyme, 3alpha-HSD. In the conversion of 5alpha-DHT to 3alpha-androstanediol (3alpha-Diol), NAD(P)H is oxidized. Spermatozoa that reach the cauda epididymis have fully condensed chromatin. In addition, the nuclear region retains appreciable amounts of 5alpha-DHT and 3alpha-Diol, both bound to ABP. During fertilization, the bound 3alpha-Diol is converted back to 5alpha-DHT, reducing equivalents are transferred to NAD(P)+, and disulfide bonds are broken.IVF clinics report that spermatozoa with incompletely condensed chromatin have a low percentage of fertilization. If our proposed mechanism for chromatin condensation/decondensation is borne out by further research, IVF clinics might consider preincubating spermatozoa with 5alpha-DHT in order to increase the efficiency of fertilization.

Protamine 1: protamine 2 stoichiometry in the sperm of eutherian mammals

We have compared the relative proportion of protamine 1 (P1) and protamine 2 (P2) bound to DNA in the sperm of a variety of eutherian mammals to obtain insight into how these two proteins interact in sperm chromatin. Gel electrophoresis (combined with microdensitometry) and high performance liquid chromatography (HPLC) were used to determine the content of the two protamines, and the identity of each protein was confirmed by amino-terminal sequencing or amino acid analysis. The sperm of all species examined contained P1, but P2 was found to be present only in certain species. Unlike the fixed ratio of core histones that package DNA into nucleosomes in all somatic cells, the proportion of P2 present in mature sperm was found to be continuously variable from 0 to nearly 80%. These results show that P1 and P2 do not interact with each other or DNA to form a discrete complex or subunit structure that is dependent upon particular P1/P2 stoichiometries. Data obtained from a number of closely and distantly related species also indicate that while the P2 content of sperm chromatin is allowed to vary over a wide range during the course of evolution, the relative proportion of P1 and P2 are tightly regulated within a genus.

Effect of heparin-reduced glutathione on hamster sperm DNA unpacking and nuclear swelling

This study examined the kinetics of sperm nuclear decondensation induced by the action of physiological concentrations of heparin and glutathione in hamster sperm nuclei as a chromatin model that contains protamine P1 and P2. Sperm suspension was incubated at different temperatures (37, 40, 43, and 46 degrees C) in media, keeping constant the concentration of either heparin or GSH and increasing concentrations of the other reagent. Spermatozoa nuclei without any treatment, incubated for 72 h, appear densely condensed. Swelling of hamster spermatozoa nuclei was observed after 30 min of incubation in the presence of efficient concentrations of heparin-GSH. The extent of this time lag was significantly reduced at higher temperatures. DNA presence was verified by the use of ethidium bromide, acridine orange, and Feulgen stain. Phase-contrast microscopy shows that nuclear decondensation begins at the equatorial levels, with DNA highly condensed at the acrosome pole, and the basal pole as the DNA attachment point. Electron microscopy observations showed that hamster sperm nuclei initiates its decompaction at the peripheral regions and this behavior remains until late stages of decondensation, nevertheless, the chromatin is organized into "hub-like" nuclear bodies that measured 10-100 nm in diameter, joined by a network of chromatin fibers with apparent reduction in number. At the decondensation full stage, the network seems to be wide open with a reduced number of hub-like nuclear bodies present in the interlace. DNA is not organized into topologically constrained loop domains and is attached to the basal plate instead of to the nuclear matrix or any other structure.

Identification of the binding site of two monoclonal antibodies to human protamine

We have previously developed a number of monoclonal antibodies (Mabs) that bind to protamine. One of these antibodies, Hup1N, binds to human protamine 1 but not to protamine 2. In contrast, Mab HupA binds both protamine 1 and protamine 2. The epitopes for these two Mabs were observed to overlap, and were localized to the evolutionarily conservative amino-terminal region of protamine 1. This assignment is based on antibody binding to protamine from different species in which the protamine sequence is known, as well as analysis of antibody binding to synthetic peptides and synthetic peptides with specific amino acid substitutions.

Phosphorylation of human sperm protamines HP1 and HP2: identification of phosphorylation sites

Human sperm is characterized by a high heterogeneity of its basic nuclear protein complement of pro-protamines, protamines and histones. This heterogeneity is increased by the persistence of phosphorylated protamines in mature spermatozoa. Alkaline phosphatase treatment of whole protein indicated that protamines HP1 and HP2 were phosphorylated to various degrees. Presence of non-phosphorylated and phosphorylated protamines HP1 and HP2 was further demonstrated by electrospray mass spectrometry. Phosphorylation sites of mono- and di-phosphorylated protamine HP1 were identified by automatic Edman degradation of the protein after phosphoserine derivatization to S-ethylcysteine. In both phosphorylated forms, Ser-10 was found phosphorylated; in the di-phosphorylated form, Ser-8 was identified as the second site of phosphorylation. In protamine HP2, the unique site of phosphorylation (Ser-14) was located after limited acid hydrolysis of enzymic peptides and thin-layer electrophoresis.

Immunological evidence for a P2 protamine precursor in mature rat sperm

High molecular weight proteins in Rattus norvegicus that are immunoreactive with an anti-protamine 2 specific antibody but not with an anti-protamine 1 specific antibody are described. These proteins were detected by coupling high-performance liquid chromatography (HPLC) with an enzyme-linked immunosorbent assay (ELISA). Briefly, following HPLC separation of rat sperm nuclear proteins, the HPLC fractions were probed with the antibodies. We estimate that the antibody probes are 100-1000 times more sensitive than UV absorbance measurements. Immunoblot analysis following acid-urea electrophoretic separation of rat sperm nuclear proteins, and of the HPLC fractions, also detected putative protamine 2 precursor proteins. The proteins reactive with the anti-protamine 2 antibody are most likely not mature protamine 2, since they were detected in a region of the chromatogram where we would not expect protamine 2 to migrate based on the chromatographic locations of human and mouse protamine 2. Likewise, the immunoblotting experiments demonstrated that the anti-protamine 2 antibody recognized proteins with slower electrophoretic mobilities than would be expected for a mature protamine 2. An anti-protamine 1 monoclonal antibody, Hup1N, that binds rat protamine 1 is also described. Hup1N allowed for identification of the HPLC fractions that contained rat protamine 1. Finally, we demonstrated that Hup1N binds protamine 1 from a large number of species, suggesting a conserved epitope for Hup1N.

Small nuclear ribonucleoprotein polypeptides in rat sperm

1. Immunoblot analysis of rat sperm head proteins revealed the presence of polypeptides recognized by anti-Sm serum obtained from patients with systemic lupus erythematosus. 2. Two of these polypeptides have molecular weights of 26,000 and 15,000 and they were identified as small nuclear ribonucleoprotein components present in other rat tissues. 3. When the autoimmune serum was used in the immuno-gold procedure for electron microscopy, gold particles were found only on the sperm nucleus. 4. The results indicate that some polypeptides of the small nuclear ribonucleoprotein complex are components of the rat sperm chromatin.

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.

A cytochemical and immunocytochemical study of DNA distribution in spermatid nuclei of mouse, rabbit, and bull

DNA distribution in mouse, rabbit and bull spermatids was analyzed by electron microscopy, after using a Feulgen-like HCl-osmium ammine procedure, and after immunocytochemistry with anti-DNA antibodies. In addition, nucleic acids were visualized with the intercalating dye ethidium bromide and phosphotungstic acid. The parts of DNA displaying a beta helix configuration (possibly A-T rich parts) were identified by epifluorescence microscopy after staining with Hoechst 33258. In all 3 species, young spermatid nuclei were seen to have large areas poor in DNA, as well as DNA-rich areas, which were mostly concentrated into a peripheral layer close to the acrosome and into one or several masses, displaying species-specific locations. These DNA-rich areas were stained with Hoechst 33258. Elongating spermatid nucleic contained homogeneously distributed DNA, and this was evident following both immunocytochemistry and nucleic acid histochemistry in all 3 species. However, the distribution appeared more heterogeneous after the Feulgen-like procedure, and was accompanied by a disappearance of Hoechst-fluorescence. In fully elongated spermatids, all nuclear areas stained with Hoechst 33258, while the 3 other techniques labeled either all or species-specific parts of the condensed chromatin. The reasons for these variable reactions are discussed in terms of technique specificities, DNA configuration and nucleoprotein moiety replacements.

In vitro decondensation of nuclear chromatin of human spermatozoa: assessing fertilizing potential

Spermatozoan nuclear chromatin is in a highly condensed state prior to fertilization. In vivo decondensation occurs in the ooplasm and is essential for successful fertilization and the formation of male pronucleus and the zygote to occur. The chromatin of spermatozoa and nucleus can undergo in vitro decondensation with sodium dodecyl sulfate (SDS) and 6 mM ethylene diamine tetraacetic acid (EDTA). The ability of sperm to decondense in vitro was compared with their ability to fertilize human oocytes in vitro. Spermatozoa from normal samples were studied for their decondensation ability as regards their fertilizing performance in an in vitro fertilization (IVF) program. Fertilization occurred when the decondensation percentage of sperm nuclear chromatin was more than 70%. The effective sperm count was significantly (p less than 0.05) lower in the unfertilized group. This is a new diagnostic technique to assess sperm-fertilizing potential at the initial evaluation of the male.

Nuclear transition protein 1 from ram elongating spermatids. Mass spectrometric characterization, primary structure and phosphorylation sites of two variants

The ram transition protein 1 (TP1) is present in spermatid cell nuclei in the nonphosphorylated, monophosphorylated and diphosphorylated forms. Its primary structure was determined by automated Edman degradation of S-carboxamidomethylated protein and of peptides generated by cleavage with thermolysin and endoproteinase Lys-C. The ram TP1 is a small basic protein of 54 residues and structurally very close to other mammalian TP1. The mass spectrometric data obtained from the protein and its fragments reveal that ram TP1 is indeed a mixture (approximately 5:1) of two structural variants (Mr 6346 and 6300). These variants differ only by the nature of the residue at position 27 (Cys in the major variant and Gly in the minor variant). The study of phosphorylation sites has shown that four different serine residues could be phosphorylated in the monophosphorylated TP1, at positions 8, 35, 36 or 39. From previous physical studies, it has been postulated that the Tyr32 surrounded by two highly conserved basic clusters was responsible for the destabilization of chromatin by intercalation of its phenol ring between the bases of double-stranded DNA. The presence of three phosphorylatable serine residues in the very conserved sequence 29-42 is another argument for the involvement of this region in the interaction with DNA.

The spermicidal effect of ethylene dibromide in bulls and rams

The spermicidal effect of ethylene dibromide (EDB) in bulls and rams is reviewed. Following oral or parenteral administration EDB was found to cause, by its alkylating effect in the testes of treated bulls and rams, lysis of the chromatin of the elongating spermatids during the time of somatin histones replacement by the sperm protamines. However, while in the bulls the abnormal spermatozoa issued from the affected spermatids were also collected in the ejaculates, this was not the case with treated rams. In the latter animals the abnormal spermatids seem to be phagocytized in the epididymis before their arrival in the ejaculate. In addition, whereas the alkylating effect of EDB occurred also in the upper parts of the epididymis of the bulls, causing tail and acrosome defects to the spermatozoa, in the rams such an effect seems to occur all along the epididymal duct. These differences between bulls and rams in the sites of the genital tract where the drug takes effect, and in the mechanism of this effect, reveal probable differences in the physiology of the reproductive tract between these species.

Electrophoretic patterns of spermatozoal nucleoproteins (NP) in fertile men and infertility patients and comparison with NP of somatic cells

During spermatogenesis in mammals the evolutionary early histones are replaced step by step by more species specific nucleoproteins (protamines). The protamines protect the genetic information of the male against mutagenic or other damaging influences and possibly play a role in male fertility. A method was presented to study the nucleoproteins (NP) of single human ejaculates. This procedure was checked concerning its usability and validity by bull spermatozoa. The NP of cryopreserved human spermatozoa of fertile men and of infertility patients were investigated and compared with the electrophoretic patterns of NP of somatic hepatocytes of rat and mouse. A total of 48 semen samples were studied. Ten of these samples were obtained from semen donors of proven fertility and 38 samples were collected from male partners of infertile couples. Photodensitometrically it could be distinguished between percentages of non-protamines (PNP) and percentages of protamines (PP). The PP varied intra-individually with a mean standard deviation of 34%, analogously to the alterations of classical semen parameters. The PP of fertile men did not significantly differ from the infertility patients with normal spermiogram parameters but showed a significantly higher value compared with the semen samples with pathological spermiograms. On average the PP of all infertile patients were significantly lower than the PP of fertile semen donors.

Vertebrate protamine gene evolution I. Sequence alignments and gene structure

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.

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.

Haploid-specific transcription of protamine-myc and protamine-T-antigen fusion genes in transgenic mice

The protamines are small, basic, arginine-rich proteins synthesized postmeiotically in the testes. Analysis of the regulation of synthesis of the protamine mRNA and protein is restricted by the difficulty in culturing and manipulating the cells in which transcription and translation occur. To avoid these problems, we have produced transgenic mice carrying fusion genes in which sequences 5' to the mouse protamine-2 gene have been linked to exons 2 and 3 of the mouse c-myc gene and, separately, to the simian virus 40 (SV40) early region. We show here that the prot.myc gene is correctly regulated; transcription is detected only in the round spermatids. In one family of transgenic mice carrying the 5' protamine-SV40 T-antigen fusion gene, SV40 early-region mRNA accumulated to the highest level in the testes but was also detected in the thymuses, brains, hearts, and preputial glands of the animals. Although we have demonstrated specific transcription of these fusion genes in the round spermatids, we were not able to detect the SV40 T-antigen protein.

Sequence homologies in the mouse protamine 1 and 2 genes

To identify candidates for cis-acting sequences that regulate the stage and cell-specific expression of the two coordinately regulated protamine genes in the mouse, genomic clones were isolated and the nucleotide sequences of the 5' flanking regions and coding regions were compared. Unlike most histone genes and the multigene family of trout protamine genes which are intronless, each mouse protamine gene has a single, short intervening sequence. Although the coding regions do not share significant nucleotide homology, the 5' flanking regions contain several short homologous sequences that may be involved in gene regulation. An additional shared sequence is present in the 3' untranslated region surrounding the poly(A) addition signal in both genes.

Haploid-specific transcription of protamine-myc and protamine-T-antigen fusion genes in transgenic mice

The protamines are small, basic, arginine-rich proteins synthesized postmeiotically in the testes. Analysis of the regulation of synthesis of the protamine mRNA and protein is restricted by the difficulty in culturing and manipulating the cells in which transcription and translation occur. To avoid these problems, we have produced transgenic mice carrying fusion genes in which sequences 5' to the mouse protamine-2 gene have been linked to exons 2 and 3 of the mouse c-myc gene and, separately, to the simian virus 40 (SV40) early region. We show here that the prot.myc gene is correctly regulated; transcription is detected only in the round spermatids. In one family of transgenic mice carrying the 5' protamine-SV40 T-antigen fusion gene, SV40 early-region mRNA accumulated to the highest level in the testes but was also detected in the thymuses, brains, hearts, and preputial glands of the animals. Although we have demonstrated specific transcription of these fusion genes in the round spermatids, we were not able to detect the SV40 T-antigen protein.

Differential distribution of the P1 and P2 protamine gene sequences in eutherian and marsupial mammals and a monotreme

At the protein level, the P1 protamine is the predominant form of mammalian protamine, present in all mammalian spermatozoa analyzed to date. An additional variant, the P2 protamine, has been detected only in spermatozoa of the mouse, hamster and human. Southern blot analysis of a group of restriction enzyme-digested mammalian DNAs has revealed the presence of sequences homologous to the P1 and P2 mouse protamine genes in diverse species. In agreement with protein studies, nucleotide sequences homologous to the mouse P1 protamine cDNA are widespread, being present in the genomic DNAs of human, rat, dog, ram, horse, bull, hamster, baboon, flying fox (megabat), microbat, boar, North American opossum, and wallaby. Although we detect genomic sequences with strong homology to the mouse protamine 2 cDNA in rat and hamster, we also find weaker but reproducible hybridization to the genomic DNA of human, boar, dog, bull, microbat, wallaby, and platypus. With the exception of the human, the P2 protamine has not been detected in the spermatozoa of these latter species.

Mouse protamine 2 is synthesized as a precursor whereas mouse protamine 1 is not

The nuclei of mouse spermatozoa contain two protamine variants, mouse protamine 1 (mP1) and mouse protamine 2 (mP2). The amino acid sequence predicted from mP1 cDNAs demonstrates that mP1 is a 50-amino-acid protein with strong homology to other mammalian P1 protamines. Nucleotide sequence analysis of independently isolated, overlapping cDNA clones indicated that mP2 is initially synthesized as a precursor protein which is subsequently processed into the spermatozoan form of mP2. The existence of the mP2 precursor was confirmed by amino acid composition and sequence analysis of the largest of a set of four basic proteins isolated from late-step spermatids whose synthesis is coincident with that of mP1. The sequence of the first 10 amino acids of this protein, mP2 precursor 1, exactly matches that predicted from the nucleotide sequence of cDNA and genomic mP2 clones. The amino acid composition of isolated mP2 precursor 1 very closely matches that predicted from the mP2 cDNA nucleotide sequence. Sequence analysis of the amino terminus of isolated mature mP2 identified the final processing point within the mP2 precursor. These studies demonstrated that mP2 is synthesized as a precursor containing 106 amino acids which is processed into the mature, 63-amino-acid form found in spermatozoa.

Isolation and characterization of two protamines St1 and St2 from stallion spermatozoa, and amino-acid sequence of the major protamine St1

Two protamines, St1 and St2, were isolated from stallion sperm nuclei, where they represent about 75 and 25%, respectively, of the total basic protein complement. The primary structure of protamine St1 (49 residues; Mr approximately equal to 6600) has been determined. The structure of this protamine is compared to the amino-acid sequence of other mammalian protamines already known.

Isolation and characterization of a cDNA clone encoding testis protamine Z1 from the dog-fish Scylliorhinus caniculus

A clone containing a 445-bp cDNA insert was isolated from a cDNA library synthesized from dog-fish testes mRNA. The nucleotide sequence was determined and corresponded to a 50-amino-acid protein. The known five-amino-acid N-terminal sequence corresponded exactly to our deduced amino acid sequence. After in vitro transcription of this cDNA using SP6 RNA polymerase, the translated polypeptide comigrated with the Z1 scylliorhinine marker. Analysis of the cDNA 3' flanking region of our Scylliorhinus protamine Z1 revealed an inverted repeat sequence, an ACAA motif and a CAGGAAAGA box known as regulatory signals for transcription termination in histone genes. In addition, sequences homologous to the simian virus (SV 40) and polyoma virus core enhancer elements were identified in the 5' and 3' flanking regions.

Monoclonal antibodies to human protamines

Nine monoclonal antibodies to human protamine, hup1a, 1b, 1c, 1d, 1e, 2a, 2b, A, and B, have been isolated and partially characterized. Enzyme-linked immunoabsorption assay analyses with HPLC-separated human protamine 1 and protamine 2+3 mixture identified five of these antibodies as specific for human protamine 1, two antibodies specific for protamine 2+3 mixture and two monoclonal antibodies reactive with all three human protamines. These findings were confirmed by immunoblotting. None of the antibodies reacted with poly-arginine or somatic histone proteins. Additional analyses with bull, boar, and ram protamines indicated that all of the monoclonal antibodies except hupA are specific for human protamine. HupA reacted with protamines from all of the species tested. These studies suggest that each of the antibodies recognizes one of at least four distinct epitopes on protamine.

Mouse protamine 2 is synthesized as a precursor whereas mouse protamine 1 is not

The nuclei of mouse spermatozoa contain two protamine variants, mouse protamine 1 (mP1) and mouse protamine 2 (mP2). The amino acid sequence predicted from mP1 cDNAs demonstrates that mP1 is a 50-amino-acid protein with strong homology to other mammalian P1 protamines. Nucleotide sequence analysis of independently isolated, overlapping cDNA clones indicated that mP2 is initially synthesized as a precursor protein which is subsequently processed into the spermatozoan form of mP2. The existence of the mP2 precursor was confirmed by amino acid composition and sequence analysis of the largest of a set of four basic proteins isolated from late-step spermatids whose synthesis is coincident with that of mP1. The sequence of the first 10 amino acids of this protein, mP2 precursor 1, exactly matches that predicted from the nucleotide sequence of cDNA and genomic mP2 clones. The amino acid composition of isolated mP2 precursor 1 very closely matches that predicted from the mP2 cDNA nucleotide sequence. Sequence analysis of the amino terminus of isolated mature mP2 identified the final processing point within the mP2 precursor. These studies demonstrated that mP2 is synthesized as a precursor containing 106 amino acids which is processed into the mature, 63-amino-acid form found in spermatozoa.

Cloning of bovine P1 protamine cDNA and the evolution of vertebrate P1 protamines

A bovine P1 protamine cDNA from a bull testis cDNA library was isolated utilizing a series of oligonucleotide probes. Sequence analysis showed that the cloned cDNA insert extended 317 bp to the poly(A) tail. The 51-residue 6750-dalton protamine primary translated protein is encoded within a 156-bp segment. The protamine sequence predicted from the cDNA sequence differs from that previously reported for the amino acid sequence of bovine protamine P1 by the insertion of the tripeptide Cys-Arg-Arg from residues 39-41 in the carboxy-terminal region of the mature protein. Consistent with previous hybridization analysis, nucleotide sequence comparisons showed that trout protamine cDNA was more closely related to that of bovine than to that of mouse. However, bovine P1 protamine cDNA shared greater sequence homology with mouse P1. A common nucleotide sequence of 30 bp is conserved among all three of these species. Primer extension analysis revealed that, as with trout protamine mRNAs, the majority of the untranslated portion of the mRNA lies 3' to the coding segment. Comparisons of their mRNA secondary structures by computer modeling indicate that the mRNAs fold back onto themselves, producing similar, extensively hydrogen-bonded, convoluted forms. These models support the view that translational regulation of protamine mRNA may be partially dependent on secondary structure. Southern analysis suggests that the bovine protamine P1 gene is not sex-linked and is present as one (or relatively few) copy within the bovine genome.

Purification and characterization of nuclear basic proteins of human sperm

Highly purified nuclei were obtained from human sperm without protein loss through the use of CHAPS (3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonate), a newly available detergent. The basic protein complement of these nuclei is highly heterogeneous and comprises histones (some of which are testis-specific), protamines and proteins of intermediate basicity and molecular size. The protamines belong to two different classes of protein. Microheterogeneity observed in some of these protamines originates from slight variations in their amino acid composition as well as from post-synthetic modifications. Two of these protamines previously considered as two different proteins are in fact the same protein with different degrees of phosphorylation. All these protamines and intermediate basic proteins are characterized by high amounts of arginine and cysteine. Three of the protamines and all five intermediate basic proteins are also histidine-rich.

Nucleotide sequence of a cDNA clone encoding Scylliorhinus caniculus protamine Z2

A cDNA library was constructed from a protamine-enriched fraction of dogfish (Scylliorhinus caniculus) mRNA. The nucleotide sequence of a 440-bp insert was determined, and its produced protein sequence confirmed its identification as a cysteine-rich protamine Z2 [Martinage, A., Gusse, M., Belaiche, D., Sautiere, P. and Chevaillier, P. (1985) Biochim. Biophys. Acta 831, 172-178]. The frequency of utilization of the different triplets coding for arginine, which represents 30-70% of the total amino acid residues for trout, mouse and dogfish protamines, is discussed. An alternative repetitive sequence of CGC-AGG was found in the N terminus of the protein. Analysis of the 3' flanking region after the mRNA-terminating TAA codon identified an inverted repeat sequence and an ACCA sequence, which may be possible vestiges of a histone-like termination signal.

A corrected primary sequence for bull protamine

We have redetermined the primary sequence for bull protamine using HPLC peptide mapping and automated amino-acid sequencing techniques and report, on the basis of these findings, that the previously published amino-acid sequence for this protein is incorrect. The correct protamine sequence is 50 amino acids in length and differs from the original published sequence by the tripeptide -Cys-39-Arg-40-Arg-41-. Analyses of protamine tryptic peptides derived from nine diverse breeds of Bos tarus and Bos indicus indicate that this sequence is present in the protamine of each breed and that it does not represent a variant or mutation.

Oligonucleotides as probes for mammalian protamine mRNAs

Protamine-like sequences have been identified in poly A(+)mRNAs from mammalian testes by the use of a common, complementary oligonucleotide (GCAGCANCKPTANCKNGCCAT; predicted from the common N-terminal amino acid sequence, MARYRCC, seen in several mammalian P1 protamines [D.J. McKay, B.S. Renaux and G.H. Dixon, Bioscience Reports 5:383-391 (1985)]). This oligonucleotide was utilized to prepare species-specific, primer-extended transcripts for use as Northern blotting probes. Analysis of the mRNA primer-extended transcripts revealed a discrete and similar set of products common to both bull and rat testis mRNAs which were distinct from those obtained from human testis mRNA. Northern analysis of total poly A(+) mRNAs from the corresponding mammalian testis was consistent with these results and suggests that bull and rat protamine mRNAs are more closely related to each other than to human protamine mRNA.

Human sperm protamines. Amino-acid sequences of two forms of protamine P2

Human protamine P2 was purified to homogeneity by solubilizing whole spermatozoa in guanidinium X HCl containing 2-mercaptoethanol, alkylating the resulting protamine thiols with vinylpyridine, removing acid-insoluble material by acid dialysis and using CM-cellulose chromatography to remove non-protamine basic proteins and separate protamines P1 and P2. The P2 preparation contained two components, P2a and P2b, which were sequenced completely without being separated. The peptides obtained from thermolysin and endoproteinase Lys-C digestions were purified by reverse-phase high-pressure liquid chromatography and sequenced using a gas-phase sequencer. P2a contains 57 amino acids and has a relative molecular mass of 7636 while P2b contains 54 amino acids, which are identical to residues 4-57 of P2a, and has a relative molecular mass of 7242. Protamine P2a is approximately 50% homologous with human protamine P1. The amino acid sequence of P2a is: (sequence; see text)

Nuclear proteins in spermatogenesis

Mammalian somatic type histone variants are replaced or supplemented in early primary spermatocytes and possibly spermatogonia by testis specific and testis enriched histone variants. The testis complement of histones is replaced entirely by transition basic proteins in mid-spermatids. This transition is accompanied by a dramatic reduction of thermal stability of mid-spermatid chromatin which may be due in part to hyperacetylation of histone H4. The transition basic proteins are replaced by protamines which are arginine-rich and contain cysteine.

Lability to acid hydrolysis in some different DNA-protein complexes of spermatozoa

The Feulgen hydrolysis kinetics was investigated in spermatozoa with different composition in DNA-protein complexes. The species used were: Bos taurus (arginine rich nuclear protein also containing cystine residues), Pichroplus bergi, Triatoma infestans (arginine-rich nuclear protein), Lytechinus variegatus and Apis mellifera (lysine-rich nuclear protein). The spermatozoa were subjected to Feulgen's reaction, after varying the fixative type and the hydrolysis times. Feulgen-DNA values were obtained with an automatic scanning cytophotometric procedure. Differences were demonstrated in the hydrolysis kinetics as a function of differences in composition of the DNA-protein complexes being present in the spermatozoon chromatin. Differences in the profiles of Feulgen hydrolysis curves, having for basis the fixation, were rather clear for bull, grasshopper, and blood-sucking insect spermatozoa than for the sea-urchin and bee spermatozoa. The different hydrolysis kinetics of chromatin of blood-sucking insect spermatozoa compared to that of grasshopper, sea-urchin, and bee sperm cells suggests that, although the first 2 materials contain an arginine-rich "germinative" protein and the latter 2 ones contain a lysine-rich protein, these differ to each other. The DNA depurination was obtained more quickly for T. infestans (20 min) and P. bergi (10 min) spermatozoa when they were fixed in the ethanol-acetic acid (EA) mixture. Morphologically anomalous bull spermatozoa fixed in the EA mixture presented a quicker depurination (30 min) as compared to the normal cells (1 h). The fast lability to acid hydrolysis in the abnormal cells is certainly due to anomalies in their basic nuclear "germinative" protein. In the formalin fixed materials the maximal depurination was obtained earlier in bull spermatozoa (30 min) followed by sperm cells of P. bergi, T. infestans, L. variegatus (all of them one-hour hydrolysis) and finally Apis mellifera (2 h hydrolysis). The presence of secondary peaks at the descending branch of the hydrolysis curves of grasshopper and sea-urchin spermatozoa, indicates for these, more than 1 kind of apurinic-acid protein complexes. The spermatozoa bearing arginine-and/or cystine-rich nuclear protein contain a more easily soluble apurinic acid protein complex. Due to the differences in hydrolysis kinetics of chromatin in spermatozoa containing different nuclear "germinative" proteins, this cellular type does not appear indicated as a haploid control for evaluation of Feulgen-DNA contents of diploid and polyploid somatic cells.

The amino acid sequence of human sperm protamine P1

Human sperm protamines have been extracted from spermatozoa pooled from several donors, converted to their S-pyridylethylated derivatives and resolved into two major components, P1 and P2, by Bio-Rex 70 chromatography. Protamine P1 was further purified by Bio-Gel P-10 chromatography and sequenced directly on a gas phase protein sequencer for 43 residues. To complete the sequence, P1 was cleaved at methionine 36 and the C-terminal tetradecapeptide was purified by h.p.l.c. and sequenced completely. The 50 residue sequence is: (sequence see text) This sequence has a calculated molecular weight of 6674 and is homologous with four other published mammalian protamine sequences.

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.

Isolation and in vitro translation of a mammalian protamine mRNA

mRNA was isolated from sexually mature rat, rabbit, and bovine testes. Poly(A+) and (A-) RNAs were prepared and hybridized to a rainbow-trout protamine probe. The bovine (A+) fraction showed significant hybridization compared to the other species and these related sequences were also found in total bovine DNA. Bovine mRNA programmed the in vitro synthesis of a basic protein that possessed protamine-like properties. The mRNA was fractionated by agarose-gel electrophoresis and the fractions hybridized to the trout protamine probe. A significant hybridization signal was observed corresponding to a mRNA of approximately 400 nucleotides in length which coded for the protamine-like protein. The data support the view that we have isolated a mammalian (bovine) protamine mRNA.

Protamines in plant sperm

Sperm protamines have been isolated from representatives of three major plant groups: algae (Chara corallina ), bryophytes ( Marchantia polymorpha), and ferns ( Marsilea vestitia ). We previously reported the complete displacement of histones by protamines in Marchantia (Reynolds W F & Wolfe, S L, Exp cell res 116 (1978) 269 [8] ). Marchantia protamines appear as four components on acid-urea gels, whereas Chara and Marsilea protamines comigrate as a single band with a mobility comparable to salmon protamine. The amino acid compositions of the plant protamines show these to be arginine-rich, highly basic (35-42%) proteins which display overall similarity in amino acid composition (84-91%). The molecular weights of Chara and Marsilea protamines are approx. 4700-5300 D.

Structural function of the basic nuclear proteins in ram spermatids

The function of the cysteine-containing spermatidal proteins and of protamine in the packaging and stabilization of chromatin during ram spermiogenesis was investigated. Extractions of the histones and spermatidal proteins from the nonround spermatid nuclei decreases the nuclear stability (sonication resistance), decondenses the chromatin, and reduces the diameter of the largest chromatin threads (100-200 A vs. 380 A in the control nuclei). Extractions by acid, salt, or heparin have no effect on the protamine-containing electron-opaque chromatin. In contrast, treatment by dithiothreitol alone decondenses all the nonround spermatid nuclei at a rate which decreases with the maturation state of the nuclei. The electron-opaque chromatin is then resolved in 35-A-thick filaments. Experimentally induced fluctuations of the level of SS bonding appear to influence the chromatin stabilization and ultrastructure in most of the nonround spermatid nuclei. These data evidence that noncovalent interactions play a main structural role at the beginning of chromatin reorganization, and SS bonding between spermatidal proteins and then between protamine molecules increases progressively and becomes mainly responsible for the chromatin stabilization in the protamine-containing nuclei.

Protamine-DNA association in mammalian spermatozoa

We have previously identified two subsets of basic nuclear proteins of mouse sperm: the protamines and a group of less basic proteins and, with the aid of a polyvalent antiserum, we have demonstrated their differential extractibility by NaCl in reducing solution (Rodman et al., J cell sci 53 (1982) 227) [9]. By affinity purification with isolated mouse sperm protamines we have obtained a protamine-specific fraction of that antiserum and a fraction that contains antibodies to the subset of less basic proteins. With those immunochemical probes we have shown the following The antigenic sites recognized by the protamine-specific antibodies are accessible, intranuclearly, only after the DNA has been removed by DNase I. The antibodies and DNA compete for binding sites on the protamines. DNA removal and consequent availability of the antigenic sites of the protamine molecules to the antibodies are possible only after displacement of the less basic proteins and chromatin decondensation have been induced. Immunoreactivity by the less basic proteins takes place without intervention of DNase. Those data indicate that the protamines are DNA-bound but that the less basic proteins are not or, alternatively, their putative DNA-binding sites do not coincide with their immuno-reactive sites. Those data also suggest that a function of the subset of less basic proteins may be to provide a shield for the protamine-DNA complex. The mouse protamine-affinity-bound antibodies are highly cross-reactive with protamines of other mammalian sperm suggesting that, despite considerable molecular diversity among mammalian protamines, the DNA-binding sites are conserved.

Comparative studies on the chemical and immunochemical properties of human milk, human pancreatic juice and bovine milk lactoferrin

Lactoferrin from human milk, pancreatic juice and bovine milk were purified by heparin-Sepharose affinity chromatography procedure. Urea-sodium dodecylsulfate-polyacrylamide gel electrophoresis of these lactoferrin preparations indicated similar molecular weights (80,000). Metal analyses showed that lactoferrin of bovine milk contained the highest amount of iron while lactoferrin of human milk and human pancreatic juice were similar in content of iron, approximately four-fold lower than bovine milk. All these lactoferrin preparations were also found to contain minor amounts of copper and manganese. Double diffusion analyses indicated that lactoferrin of human milk was immunochemically identical to lactoferrin of human pancreatic juice. On the other hand, immunochemically, bovine milk lactoferrin was not identical to human milk lactoferrin. Sequence analyses of human milk and pancreatic juice lactoferrin indicated that they shared the same N-terminal sequence for the 16 residues analyzed. Although human milk and bovine milk lactoferrin had sequence homologies, bovine milk lactoferrin had a closer homology to ovotransferrin than to human milk lactoferrin.