Multimerization of Drosophila sperm protein Mst77F causes a unique condensed chromatin structure

Despite insights on the cellular level, the molecular details of chromatin reorganization in sperm development, which involves replacement of histone proteins by specialized factors to allow ultra most condensation of the genome, are not well understood. Protamines are dispensable for DNA condensation during Drosophila post-meiotic spermatogenesis. Therefore, we analyzed the interaction of Mst77F, another very basic testis-specific protein with chromatin and DNA as well as studied the molecular consequences of such binding. We show that Mst77F on its own causes severe chromatin and DNA aggregation. An intrinsically unstructured domain in the C-terminus of Mst77F binds DNA via electrostatic interaction. This binding results in structural reorganization of the domain, which induces interaction with an N-terminal region of the protein. Via putative cooperative effects Mst77F is induced to multimerize in this state causing DNA aggregation. In agreement, overexpression of Mst77F results in chromatin aggregation in fly sperm. Based on these findings we postulate that Mst77F is crucial for sperm development by giving rise to a unique condensed chromatin structure.     

Loss of the cleaved-protamine 2 domain leads to incomplete histone-to-protamine exchange and infertility in mice

Protamines are unique sperm-specific proteins that package and protect paternal chromatin until fertilization. A subset of mammalian species expresses two protamines (PRM1 and PRM2), while in others PRM1 is sufficient for sperm chromatin packaging. Alterations of the species-specific ratio between PRM1 and PRM2 are associated with infertility. Unlike PRM1, PRM2 is generated as a precursor protein consisting of a highly conserved N-terminal domain, termed cleaved PRM2 (cP2), which is consecutively trimmed off during chromatin condensation. The carboxyterminal part, called mature PRM2 (mP2), interacts with DNA and together with PRM1, mediates chromatin-hypercondensation. The removal of the cP2 domain is believed to be imperative for proper chromatin condensation, yet, the role of cP2 is not yet understood. We generated mice lacking the cP2 domain while the mP2 is still expressed. We show that the cP2 domain is indispensable for complete sperm chromatin protamination and male mouse fertility. cP2 deficient sperm show incomplete protamine incorporation and a severely altered protamine ratio, retention of transition proteins and aberrant retention of the testis specific histone variant H2A.L.2. During epididymal transit, cP2 deficient sperm seem to undergo ROS mediated degradation leading to complete DNA fragmentation. The cP2 domain therefore seems to be a key aspect in the complex crosstalk between histones, transition proteins and protamines during sperm chromatin condensation. Overall, we present the first step towards understanding the role of the cP2 domain in paternal chromatin packaging and open up avenues for further research.     

The essential role of Drosophila HIRA for de novo assembly of paternal chromatin at fertilization

In many animal species, the sperm DNA is packaged with male germ line–specific chromosomal proteins, including protamines. At fertilization, these non-histone proteins are removed from the decondensing sperm nucleus and replaced with maternally provided histones to form the DNA replication competent male pronucleus. By studying a point mutant allele of the Drosophila Hira gene, we previously showed that HIRA, a conserved replication-independent chromatin assembly factor, was essential for the assembly of paternal chromatin at fertilization. HIRA permits the specific assembly of nucleosomes containing the histone H3.3 variant on the decondensing male pronucleus. We report here the analysis of a new mutant allele of Drosophila Hira that was generated by homologous recombination. Surprisingly, phenotypic analysis of this loss of function allele revealed that the only essential function of HIRA is the assembly of paternal chromatin during male pronucleus formation. This HIRA-dependent assembly of H3.3 nucleosomes on paternal DNA does not require the histone chaperone ASF1. Moreover, analysis of this mutant established that protamines are correctly removed at fertilization in the absence of HIRA, thus demonstrating that protamine removal and histone deposition are two functionally distinct processes. Finally, we showed that H3.3 deposition is apparently not affected in Hira mutant embryos and adults, suggesting that different chromatin assembly machineries could deposit this histone variant.     

Chromatin modification of imprinted H19 gene in mammalian spermatozoa

The allele-specific epigenetic markings of endogenously imprinted genes in placental mammals occur during gametogenesis. The identification of the molecular nature of gametic imprints is the first step towards understanding the mechanistic basis of epigenesis in embryonic and adult somatic tissues. The specific question addressed in this work is whether the closely positioned but oppositely imprinted insulin-like growth factor 2 (IGF 2) and H19 genes, which have similar temporal regulation during development, differ in chromatin structure in mammalian spermatozoa. During terminal differentiation of mammalian spermatozoa, about 3–15% of the haploid genome retains a quasisomatic-type chromatin structure, whereas the remaining genomes interact with protamines that are further cross-linked by -S-S- bridges. Micrococcal nuclease (MNase) and DNase I digestions of human (HSN) and porcine sperm nuclei (PSN) showed that the IGF 2 gene in both types of nuclei retained somatic-type nucleosomes that were close-packed with a periodicity of 150 bp. However, the H19 gene in both species was predominantly organised by unique structural repeats, which were 650–674 bp in PSN and 438–522 bp in HSN, condensing at least 20 kb of chromatin. These results, together with previous studies, suggest that epigenetic chromatin modification leading to preferential condensation of the paternal H19 allele in embryonic tissues is already present in the germ cells. Mol. Reprod. Dev. 50:474–484, 1998. © 1998 Wiley-Liss, Inc.     

Acinus-provoked protein kinase C delta isoform activation is essential for apoptotic chromatin condensation

Histone H2B phosphorylation tightly correlates with chromatin condensation during apoptosis. The caspase-cleaved acinus (apoptotic chromatin condensation inducer in the nucleus) provokes chromatin condensation in the nucleus, but the molecular mechanism accounting for this effect remains elusive. Here, we report that the active acinus p17 fragment initiates H2B phosphorylation and chromatin condensation by activating protein kinase C delta isoform (PKC-delta). We show that p17 binds to both Mst1 and PKC-delta, which is upregulated by apoptotic stimuli, enhancing their kinase activities. Acinus mutant susceptible to degradation elicits stronger chromatin condensation and higher H2B phosphorylation than wild-type acinus. Dominant-negative PKC-delta but not Mst1 robustly blocks acinus-initiated H2B phosphorylation. Surprisingly, depletion of Mst1 triggers caspase-3 activation, provoking H2B phosphorylation through activating PKC-delta. Further, acinus-elicited H2B phosphorylation and chromatin condensation are abrogated in PKC-delta-deficient mouse embryonic fibroblast cells and siRNA-knocked down PC12 cells. Thus, PKC-delta but not Mst1 acts as a physiological downstream kinase of acinus in promoting H2B phosphorylation and chromatin condensation.     

Targeted disruption of the transition protein 2 gene affects sperm chromatin structure and reduces fertility in mice

During mammalian spermiogenesis, major restructuring of chromatin takes place. In the mouse, the histones are replaced by the transition proteins, TP1 and TP2, which are in turn replaced by the protamines, P1 and P2. To investigate the role of TP2, we generated mice with a targeted deletion of its gene, Tnp2. Spermatogenesis in Tnp2 null mice was almost normal, with testis weights and epididymal sperm counts being unaffected. The only abnormality in testicular histology was a slight increase of sperm retention in stage IX to XI tubules. Epididymal sperm from Tnp2-null mice showed an increase in abnormal tail, but not head, morphology. The mice were fertile but produced small litters. In step 12 to 16 spermatid nuclei from Tnp2-null mice, there was normal displacement of histones, a compensatory translationally regulated increase in TP1 levels, and elevated levels of precursor and partially processed forms of P2. Electron microscopy revealed abnormal focal condensations of chromatin in step 11 to 13 spermatids and progressive chromatin condensation in later spermatids, but condensation was still incomplete in epididymal sperm. Compared to that of the wild type, the sperm chromatin of these mutants was more accessible to intercalating dyes and more susceptible to acid denaturation, which is believed to indicate DNA strand breaks. We conclude that TP2 is not a critical factor for shaping of the sperm nucleus, histone displacement, initiation of chromatin condensation, binding of protamines to DNA, or fertility but that it is necessary for maintaining the normal processing of P2 and, consequently, the completion of chromatin condensation.     

Differential chromatin condensation of female and male pronuclei in mouse zygotes

Mouse zygotes or halves of zygotes, containing either a female or a male pronucleus, were fused with ovulated metaphase II oocytes. In 59.7% of the resulting hybrid cells, the pronuclei underwent premature chromosome condensation (PCC). In some of these heterokaryons the 2 pronuclei differed in the dynamics of condensation. Detectability of differential PCC of pronuclei (dPCC) depended on the type of preparation. In hybrids with PCC, produced by fusion of intact zygotes with metaphase II oocytes and processed for whole-mount preparations, one pronucleus was more advanced in the condensation process in 47% of cases. In air-dried preparations dPCC was detected in as many as 94% of hybrids. Experiments with the fusion of halves of zygotes with metaphase II oocytes have shown that the differential reaction of pronuclei to condensation factor depended on their parental origin. Maternal chromatin responded faster to the condensation factor and attained more advanced stages of PCC than paternal chromatin. Different responses of the maternal and paternal pronucleus to the condensation factor suggests that the 2 pronuclei are not identical with regard to the organization of chromatin and/or the lamin composition of the nuclear envelope. © 1993 Wiley-Liss, Inc.     

Protamine 3 shows evidence of weak, positive selection in mouse species (genus Mus)--but it is not a protamine

Protamines are short and highly basic sperm-specific nuclear proteins that replace somatic histones during spermiogenesis in a process that is crucial for sperm formation and function. Many mammals have two protamine genes (PRM1 and PRM2) located in a gene cluster, which appears to evolve fast. Another gene in this cluster (designated protamine 3 [PRM3]) encodes a protein that is conserved among mammals but that does not seem to be involved in chromatin condensation. We have compared protein sequences and amino acid compositions of protamines in this gene cluster, searched for evidence of positive selection of PRM3, and examined whether sexual selection (sperm competition) may drive the evolution of the PRM3 gene. Nucleotide and amino acid analyses of mouse sequences revealed that PRM3 was very different from PRM1 and from both the precursor and the mature sequences of PRM2. Among 10 mouse species, PRM3 showed weak evidence of positive selection in two species, but there was no clear association with levels of sperm competition. In analyses from among mammalian species, no evidence of positive selection was found in PRM3. We conclude that PRM3 exhibits several clear differences from other protamines and, furthermore, that it cannot be regarded as a true protamine.     

Analyse de la structure chromatinienne du sperme par la cytométrie en flux à l’acridine orange. — intérêt clinique

During spermatozogenesis, sperm nucleosomal DNA type, linked to histones, is transformed into a special form bound to small basic proteins, the protamines. This process allows sperm nucleus to condense and mature. This maturation process is achieved in the epididymis. When a spermatozoon enters an oocyte, protamines are released and replaced by histones, enabling the sperm nucleus to expand into a male pronucleus. Flow cytometry using acridine orange staining is an objective and quantitative technique well-adapted for the investigation of the chromatin structure at the level of each spermatozoon, as well as the whole ejaculate. This technique allows tracing the young sperm cell nuclei from the diploid stage, through tetraploid until the final haploid stage in mature spermatozoa. It allows also following the sperm maturation process during the epididymal transit. It detects various sperm chromatin condensation defects, hypocondensation, hypercondensation or other aberrations, as well as decondensation defects by using an in vitro assay. These defects may impair sperm fertilizing ability, even after sperm microinjection into the oocyte. Better understanding of sperm chromatin integrity and stability prerequisites might help us improving the quality of various technologies used in assisted medical procreation.     

The Drosophila maternal gene sésame is required for sperm chromatin remodeling at fertilization

The spermatozoon features an extremely condensed and inactive nucleus. The unique sperm chromatin organization is acquired during the late stages of spermatid differentiation by the replacement of somatic histones with sperm-specific chromosomal proteins. At fertilization, the inactive sperm nucleus must be rapidly transformed into a DNA replication competent male pronucleus before the formation of the zygote. The sequential events of this crucial process are well conserved among animals and are controlled by molecules present in the egg. We have previously identified a Drosophila maternal effect mutation called sésame, which specifically arrests male pronucleus formation at a late stage of chromatin decondensation. In this study, we show that sésame affects maternal histone incorporation in the male pronucleus, a situation that is expected to prevent nucleosomal organization of the paternal chromatin. As an apparent consequence, the male pronucleus is arrested before the first S-phase and does not condense mitotic chromosomes. However, centromeric heterochromatin is present on paternal centromeres, which occasionally interact with microtubules. The abnormal chromatin organization of the male pronucleus does not prevent the formation of a male pronuclear envelope, which breaks down and reassembles in synchrony with maternally derived nuclei present in the same cytoplasm.     

Sperm nuclei glutathione peroxidases and their occurrence in animal species with cysteine-containing protamines

The selenoenzyme sperm nuclei glutathione peroxidase (snGPx), also called the nuclear form of phospholipid hydroperoxide glutathione peroxidase (n-PHGPx), was found to be involved in the stabilization of condensed sperm chromatin, most likely by thiol to disulfide oxidation of the cysteine residues of the mammalian protamines, small nuclear basic proteins in the nuclei of sperm cells. By applying Acidic Urea-PAGE in combination with SDS-PAGE, snGPx with an apparent molecular mass of 34 kDa and a 24-kDa protein were purified from rat sperm nuclei. The 24-kDa protein was identified by means of mass spectrometry as a truncated form of snGPx produced by cleavage at the N-terminal end. After defined processing of spermatozoa and detergent treatment of the sperm nuclei fraction, snGPx and its truncated form were shown to be the only selenoproteins present in mature mammalian sperm nuclei. Both forms were found in mature rat and horse sperm nuclei but in man only snGPx was detected. In trout and chicken, species with sperm cells which likewise undergo chromatin condensation but do not contain cysteine in their protamines, the snGPx proteins were missing. This can be taken as an indirect proof of the function of snGPx to act as protamine cysteine thiol peroxidase in the mammalian species with cysteine-containing protamines.     

Processing of the precursor of protamine P2 in mouse. Identification of intermediates by their insolubility in the presence of sodium dodecyl sulfate

Two basic proteins, protamines P1 and P2, are present in chromatin of mouse spermatozoa. Protamine P1, the less abundant protein in mouse, has a homolog in most mammals, and its synthesis follows a conventional route. In contrast, protamine P2 has been found only in certain other mammals, including humans, and it is synthesized as a precursor nearly twice as long as the mature protein. Processing of this precursor is not yet understood, although it necessarily takes place in elongating spermatids and is likely to play a role in the chromatin condensation occurring in these haploid cells. We have fractionated basic proteins from mouse testis chromatin and have identified six proteins on electrophoretic gels which, like protamines, are insoluble in SDS. All six were also soluble at the same trichloroacetic acid concentration as protamine P2 and were present in chromatin of elongating spermatids. Radioactive labelling patterns acquired by these SDS-insoluble proteins during translation in vitro of testis RNA indicate that the largest represents the precursor of protamine P2, and suggest that the others represent intermediates generated by proteolytic cleavage of the precursor. Results from pulse 3H labelling in vivo were also consistent with the conclusion that a precursor/product relationship exists between these proteins and protamine P2. Conclusions concerning the kinetics of processing have, in addition, been drawn from this data. Hypotheses concerning possible functional roles played by the precursor are presented.     

Genomic relatedness of Staphylococcus aureus phages of the International Typing Set and detection of serogroup A, B, and F prophages in lysogenic strains

On the basis of HindIII-restriction digest analysis of genomic DNAs, the S. aureus bacteriophages of the International Typing Set were divided into five clusters designated as A, F, Ba, Bb, and Bc. The clusters A and F include all the phages of serogroups A and F and correspond to species 3A and 77 proposed by Ackermann and DuBow (1987). On the other hand, the phages of serogroup B were divided into three clusters designated as Ba, Bb, and Bc that differ significantly each from the other in their restriction patterns. The clusters Ba and Bb may represent two separate species, while the cluster Bc may include more than one phage species. For each of the phage serogroups A, B, and F, common HindIII-restriction fragments of phage 3A (1700 bp), of 53 (4060 bp), and of 77 (8300 bp) were used for the preparation of probes specific to the phages of serogroups A, B, and F. These probes were very effective, making it possible to detect up to three different prophages in a given lysogenic strain at the same time. Restriction enzyme maps of phages 3A, 53, and 77, each representing a different serogroup, were constructed. The restriction maps of phage 3A and that of phage 77 are linear, whereas that of phage 53 is circular and exhibits a circular permutation. DNAs of the phages of serogroups A and F have cohesive ends. On each restriction map, the sites corresponding to specific probes are indicated. The size of intact genomic DNA of all phages estimated by PFGE varies within the range of 41.5-46.2 kb.     

Asymmetry in histone H3 variants and lysine methylation between paternal and maternal chromatin of the early mouse zygote

In mammalian fertilization, the paternal genome is delivered to the secondary oocyte by sperm with protamine compacted DNA, while the maternal genome is arrested in meiotic metaphase II. Thus, at the beginning of fertilization, the two gametic chromatin sets are strikingly different. We elaborate on this contrast by reporting asymmetry for histone H3 type in the pre-S-phase zygote when male chromatin is virtually devoid of histone H3.1/3.2. Localization of the histone H3.3/H4 assembly factor Hira with the paternal chromatin indicates the presence of histone H3.3. In conjunction with this, we performed a systematic immunofluorescence analysis of histone N-tail methylations at position H3K4, H3K9, H3K27 and H4K20 up to the young pronucleus stage and show that asymmetries reported earlier are systematic for virtually all di- and tri-methylations but not for mono-methylation of H3K4 and H4K20, the only marks studied present in the early male pronucleus. For H4K20 the expanding male chromatin is rapidly mono-methylated. This coincides with the formation of maternally derived nucleosomes, a process which is observed as early as sperm chromatin decondensation occurs. Absence of tri-methylated H3K9, tri-methylated H4K20 and presence of loosely anchored HP1-beta combined with the homogenous presence of mono-methylated H4K20 suggests the absence of a division of the paternal chromatin in eu- and heterochromatin. In summary the male, in contrast to female G1 chromatin, is uniform and contains predominantly histone H3.3 as histone H3 variant.     

Recent origins of sperm genes in Drosophila

Newly created genes often acquire testis-specific or enhanced expression but neither the mechanisms responsible for this specificity nor the functional consequences of these evolutionary processes are well understood. Genomic analyses of the Drosophila melanogaster sperm proteome has identified 2 recently evolved gene families on the melanogaster lineage and 4 genes created by retrotransposition during the evolution of the melanogaster group that encode novel sperm components. The expanded Mst35B (protamine) and tektin gene families are the result of tandem duplication events with all family members displaying testis-specific expression. The Mst35B family encodes rapidly evolving protamines that display a robust signature of positive selection within the DNA-binding high-mobility group box consistent with functional diversification in genome repackaging during sperm nuclear remodeling. The Mst35B paralogs also reside in a significant regional cluster of testis-overexpressed genes. Tektins, known components of the axoneme, are encoded by 3 nearly identical X-linked genes, a finding consistent with very recent gene family expansion. In addition to localized duplication events, the evolution of the sperm proteome has also been driven by recent retrotransposition events resulting in Cdlc2, CG13340, Vha36, and CG4706. Cdlc2, CG13340, and Vha36 all display high levels of overexpression in the testis, and Cdlc2 and CG13340 reside within testis-overexpressed gene clusters. Thus, gene creation is a dynamic force in the evolution of sperm composition and possibly function, which further suggests that acquisition of molecular functionality in sperm may be an influential pathway in the fixation of new genes.     

Nucleotide sequences and expression of cDNA clones for boar and bull transition protein 1 and its evolutionary conservation in mammals

During spermatogenesis, the nucleoproteins undergo several dramatic changes as the germinal cells differentiate to produce the mature sperm. With nuclear elongation and condensation, the histones are replaced by basic spermatidal transition proteins, which are themselves subsequently replaced by protamines. We have isolated cDNA clones for one of the transition proteins, namely for TP1, of bull and boar. It turned out that TP1 is a small, but very basic protein with 54 amino acids (21% arginine, 19% lysine) and is highly conserved during mammalian evolution at the nucleotide as well as at the amino-acid level. Gene expression is restricted to the mammalian testis, and the message first appears in round spermatids. Thus production of TP1 is an example of haploid gene expression in mammals. The size of the mRNA for TP1 was found to be identical in 11 different mammalian species at around 600 bp. Hybridization experiments were done with cDNAs from boar and bull, respectively. The positive results in all mammalian species give further evidence for the conservation of the TP1 gene during mammalian evolution and its functional importance in spermatid differentiation.     

H2A.Bbd: an X-chromosome-encoded histone involved in mammalian spermiogenesis

Despite the identification of H2A.Bbd as a new vertebrate-specific replacement histone variant several years ago, and despite the many in vitro structural characterizations using reconstituted chromatin complexes consisting of this variant, the existence of H2A.Bbd in the cell and its location has remained elusive. Here, we report that the native form of this variant is present in highly advanced spermiogenic fractions of mammalian testis at the time when histones are highly acetylated and being replaced by protamines. It is also present in the nucleosomal chromatin fraction of mature human sperm. The ectopically expressed non-tagged version of the protein is associated with micrococcal nuclease-refractory insoluble fractions of chromatin and in mouse (20T1/2) cell line, H2A.Bbd is enriched at the periphery of chromocenters. The exceedingly rapid evolution of this unique X-chromosome-linked histone variant is shared with other reproductive proteins including those associated with chromatin in the mature sperm (protamines) of many vertebrates. This common rate of evolution provides further support for the functional and structural involvement of this protein in male gametogenesis in mammals.