Structure of nucleosomes and organization of internucleosomal DNA in chromatin

We have compared the mononucleosomal pattern produced by micrococcal nuclease digestion of condensed and unfolded chromatin and chromatin in nuclei from various sources with the repeat length varying from 165 to 240 base-pairs (bp). Upon digestion of isolated H1-containing chromatin of every tested type in a low ionic strength solution (unfolded chromatin), a standard series of mononucleosomes (MN) was formed: the core particle, MN145, and H1-containing, MN165, MN175, MN185, MN195, MN205 and MN215 (the indexes give an approximate length of the nucleosomal DNA that differs in these particles by an integral number of 10 bp). In addition to the pattern of unfolded chromatin, digestion of whole nuclei or condensed chromatin (high ionic strength of Ca2+) gave rise to nuclei-specific, H1-lacking MN155. Digestion of H1-lacking chromatin produced only MN145, MN155 and MN165 particles, indicating that the histone octamer can organize up to 165 bp of nucleosomal DNA. Although digestion of isolated sea urchin sperm chromatin (repeat length of about 240 bp) at a low ionic strength gave a typical "unfolded chromatin pattern", digests of spermal nuclei contained primarily MN145, MN155, MN235 and MN245 particles. A linear arrangement of histones along DNA (primary organization) of the core particle was found to be preserved in the mononucleosomes, with the spacer DNA length from 10 to 90 bp on one (in MN155) or both sides of core DNA being a multiple of about 10 bp. In MN235, the core particle occupies preferentially a central position with the length of the spacer DNA on both sides of the core DNA being usually about 30 + 60 or 40 + 50 bp. Histone H1 is localized at the ends of these particles, i.e. close to the centre of the spacer DNA. The finding that globular part of histones H3 and sea urchin sperm H2B can covalently bind to spacer DNA suggests their involvement in the organization of chromatin superstructure. Our data indicate that decondensation of chromatin is accompanied by rearrangement of histone H1 on the spacer DNA sites adjacent to the core particle and thus support a solenoid model for the chromatin superstructure in nuclei in which the core DNA together with the spacer DNA form a continuous superhelix.     

Lectin binding sites on head structures of the spermatid and spermatozoon of the mosquito Culex quinquefasciatus (Diptera,Culicidae)

The presence of intranuclear and acrosomal lectin binding sites in spermatids and spermatozoa of the mosquito Culex quinquefasciatus was analysed. Direct and indirect lectin-gold techniques were used on LR White-embedded cells. The nuclear compartment was the structure most intensely labelled. Early spermatid nucleus showed moderate labelling for peanut agglutinin (PNA), Griffonia simplicifolia IB4 (GS-IB4) and Ricinus communis agglutinin (RCA), and light labelling for the other lectins tested. The sperm nucleus was intensely labelled by all lectins. The acrosome, an enzyme-containing structure, was labelled by some lectins. The anterior acrosomal region was labelled by PNA, while the proximal acrosomal region was labelled by PNA and G. simplicifolia II (GS II) lectins, and showed the presence of fucose residues with the use of Ulex europaeus I (UEA-I) lectin. The spermatozoa stored in the spermatheca showed the same pattern of labelling as that observed in spermatozoa localized in testis and seminal vesicles for all lectins tested. Carbohydrate residues in the nuclear compartment may be involved with the process of chromatin condensation. In the acrosomal region these residues may play a role in the process of spermoocyte interaction.     

Chromatin on a membrane: accessibility of histone H5 for antibodies in the supernucleosomal structure

Histone H5 accessibility for the antibodies in chromatin was studied. Chromatin was immobilised on the nitrocellulose membrane in conditions which provide different levels of its compactization. Antiserum specific to the globular domain of histone H5 was used. It was shown, that for establishing real protection of histone H5 in the supernucleosomal structure it is necessary to use long fibers of chromatin. Their linking to the membrane must occur by a minimum quantity of points. It was established, that histone H5 is 5 times more accessive in the preparations of dispersed chromatin (low ionic strength) then in chromatin with the supernucleosomal organization (physiological ionic strength). We suppose that the small level of accessibility of histone H5 for the antibodies in the compact chromatin can be explained by some disruptions in the supernucleosomal organization. On the contrary, the long equable solenoid of nucleosomes provides complete protection of histone H5. In accordance with the results obtained, the model of ordered packaging of nucleosomes in the solenoid is discussed. In this model the point of entrance and exit of DNA on the nucleosomes, fixed by globular region of histone H5, is localized inside the solenoid.     

Sperm ultrastructure of the spider crab Maja brachydactyla (Decapoda: Brachyura)

This study describes the morphology of the sperm cell of Maja brachydactyla, with emphasis on localizing actin and tubulin. The spermatozoon of M. brachydactyla is similar in appearance and organization to other brachyuran spermatozoa. The spermatozoon is a globular cell composed of a central acrosome, which is surrounded by a thin layer of cytoplasm and a cup‐shaped nucleus with four radiating lateral arms. The acrosome is a subspheroidal vesicle composed of three concentric zones surrounded by a capsule. The acrosome is apically covered by an operculum. The perforatorium penetrates the center of the acrosome and has granular material partially composed of actin. The cytoplasm contains one centriole in the subacrosomal region. A cytoplasmic ring encircles the acrosome in the subapical region of the cell and contains the structures‐organelles complex (SO‐complex), which is composed of a membrane system, mitochondria with few cristae, and microtubules. In the nucleus, slightly condensed chromatin extends along the lateral arms, in which no microtubules have been observed. Chromatin fibers aggregate in certain areas and are often associated with the SO‐complex. During the acrosomal reaction, the acrosome could provide support for the penetration of the sperm nucleus, the SO‐complex could serve as an anchor point for chromatin, and the lateral arms could play an important role triggering the acrosomal reaction, while slightly decondensed chromatin may be necessary for the deformation of the nucleus. J. Morphol., 2010. © 2009 Wiley‐Liss, Inc.     

Atomic force microscopy and cytochemistry of chromatin from marsupial spermatozoa with special reference to Sminthopsis crassicaudata

Atomic force microscopy (AFM) of the nuclear topology of spermatozoa from two marsupial species, Sminthopsis crassicaudata and Trichosurus vulpecula was investigated to determine the structural organisation of the chromatin subunits. That of the former species is of special interest as it has a peripheral nucleohistone region (C2) as well as a nuclease-resistant, nucleoprotamine core region (C1). Atomic force microscopy showed that the C2 region contained clusters of 120–160 nm nodules, whereas the C1 region exhibited smaller 50–80 nm nodules. The spermatozoa nuclei of Trichosurus, which has mainly nucleoprotamines, contained higher order chromatin structures of similar size to those from the C1 region of Sminthopsis. This study shows that nucleohistones and nucleoprotamines of marsupial sperm form distinct higher order conformations. For the second part of this work, the chromatin density and affinity for cationic stains of Sminthopsis spermatozoa were determined. Spermatozoa were observed with the transmission electron microscopy (TEM) either unstained or stained with metal salts. In the unstained specimens, the C2 nucleohistone region appeared more electron-lucent than the C1 region. When large cations such as uranyl were used, the reverse situation was observed. Therefore, the electron-dense appearance of the C2 chromatin in conventionally stained material may be due to the presence of net negative DNA charges that attract the cations used for EM staining, whereas the C1 chromatin may lack excess DNA negative charges that attract these stains and thus appears less electron-dense. Mol. Reprod. Dev. 48:367–374, 1997. © 1997 Wiley-Liss, Inc.     

Amitotic division of the macronucleus in Tetrahymena thermophila: DNA distribution by genomic unit

The macronucleus of the ciliate Tetrahymena cell contains euchromatin and numerous heterochromatins called chromatin bodies. During cell division, a chromatin aggregate larger than chromatin body appears in the macronucleus. We observed chromatin aggregates in the dividing macronucleus in a living T. thermophila cell, and found that these were globular in morphology and homogeneous in size. To observe globular chromatin clearly, optimal conditions for making it compact were studied. Addition of Mg ion, benomyl and oryzalin, microtubule inhibitors, to cell suspension was effective. Globular chromatin appeared when the micronuclear anaphase began at the cell cortex, and disappeared long after cell separation. Using living cells with a small macronucleus at early log phase, we counted the number of globular chromatin per nucleus and measured the DNA content of globular chromatin in the macronucleus which was stained with Hoechst 33342 by using ImageJ. The number of globular chromatin per nucleus was reduced by half after division, indicating the globular chromatin is a distribution unit of DNA. A globular chromatin contained similar DNA content as that of the macronuclear genome. We developed methods for inducing and isolating a cell with an extremely small macronucleus with a DNA amount of one globular chromatin. These cells grew, divided, and give clones, suggesting that the macronuclear genome is not dispersed within the macronucleus and the globular chromatin may be a macronuclear genome. We named this globular chromatin "macronuclear genome unit" (MGU).     

Ultrastructure of the Spermatozoa and Spermatophores of the Zuwai Crab,Chionoecetes opilio (Majidae,Brachyura)

The fine structure of the spermatozoa and spermatophores of the zuwai crab, Chionoecetes opilio, was examined electron microscopically. The spermatophores embedded in the secretory droplets within the vasa deferentia showed a spherical structure with an extremely wrinkled envelope and contained numerous spermatozoa. The mature spermatozoa of this crab, similar to those of other brachyurans, were stellate in shape and had a globular acrosome surrounded by a cup-like nucleus with several radiating processes. The acrosome was ultrastructurally complex and its apical part was characterized by an electron-dense discoid structure, whereas its innermost part was occupied by an electron-lucent cylindrical structure containing assemblies of thin tubules and a reticular formation of electron-dense material. The cytoplasm interposed between the nucleus and acrosome was remarkably reduced in volume and displayed a membranous lamellar complex, few mitochondria, and a centriole. The nuclear chromatin was not condensed but represented by finely flocculent material. The morphological aspects of the zuwai crab spermatozoa are discussed in comparison with those of other decapod crustaceans.     

Ultrastructure of nuclear condensation and localization of DNA and proteins in spermatozoa of a dasyurid marsupial,Sminthopsis crassicaudata

In the dasyurid marsupial, Sminthopsis crassicaudata, the mature spermatozoon has an inner homogeneous (C1) and a peripheral indented (C2) region. Using DNase-gold conjugates, and biotinylated genomic DNA probes, DNA was found to occur in both C1 and C2 regions. The morphogenesis of the spermatozoon nucleus was investigated using ultrastructural and cytochemical studies. Spermiogenesis was divided into 15 steps. By step 10, condensation of the C1 region was complete, and at the caudal extremity of the spermatid nucleus, the nuclear envelope enclosed an electron-lucent space. This space and the surrounding nuclear envelope became very enlarged at step 11. At this stage, a plate of approximately 70 nm in thickness was present along the caudal segment of the C1 region; this “nuclear mantle” did not bind DNase-gold conjugates but stained for lysine-rich proteins using alcoholic phosphotungstic acid. Chromatin condensation resumed at step 12 with the appearance of spherical chromatin structures peripheral to the C1 chromatin. These structures then partially coalesced and the indentations of the C2 region were observed. The expanded nuclear envelope at the caudal extremity persisted in caput epididymal spermatozoa. Spherical inclusions within it did not bind to DNase-gold conjugates but stained for lysine-rich proteins. As the sperm traveled down the epididymis, these inclusions amassed near the nuclear pores and were then removed from the nucleus. In addition, the nuclear mantle was found to have disappeared by the time the spermatozoa reached the corpus epididymidis. © 1996 Wiley-Liss, Inc.     

Comparative ultrastructural studies of spermiogenesis and spermatozoa in some species of Polyplacophora (Mollusca)

Summary

Comparative data on the ultrastructure of spermiogenesis and spermatozoa of the Polyplacophora Acanthochitona crinita, Chaetopleura angulata and Callochiton septemvalvis are presented in this study. In contrast to what has been described for this and other classes of Mollusca, no acrosome is present in the spermatozoa of these Polyplacophora. The nucleus is extended by a long, thin apical point. In A. crinita and C. angulata the mitochondria are situated at the basal and lateral regions of the nucleus. They do not present a typical middle piece. These species present a pericentriolar process. In C. septemvalvis the mitochondria are situated at the base of the nucleus, surrounding the centrioles, which are orthogonally positioned in all species. The ultrastructural development during spermiogenesis is similar. In middle spermatids of A. crinita, the chromatin is arranged in fine filaments. In C. septemvalvis and C. angulata the chromatin filaments are thicker, forming coarse bands. In late spermatids elongation of the nucleus continues, it becomes rather electron-dense and the chromatin filaments are more condensed. Finally, the nucleus has a uniformly electron-dense appearance, with no signs of filamentous organization. Considering the ultrastructural modifications observed, the Polyplacophora spermatozoa could be included in a modified type.     

Accessibility of the globular domain of histones H1 and H5 to antibodies upon folding of chromatin

Antibodies to the globular domain of histones H1 and H5 were purified by affinity chromatography and used to study the accessibility of this region of H1 and H5 in folded and unfolded rat liver and hen erythrocyte chromatin respectively. The different conformations of the chromatin filament were induced by varying the ionic strength from 1 mM to 80 mM NaCl and maintained by fixation with glutaraldehyde. Treatment with glutaraldehyde at a given salt concentration affected neither the orientation of nucleosomes relative to the fiber axis nor the compactness of chromatin. Solid-phase immunoassay and inhibition experiments showed no binding of the antibody against the globular domain of H1 to chromatin at the entire range of salt concentrations, while the antibody to the whole H1 molecule reacted with chromatin at low salt. On the other hand, the antibody to the globular region of H5 reacted with hen erythrocyte chromatin independently of the extent of chromatin condensation. These results indicate that the antigenic determinants of the globular domain of H5 are accessible to the antibody both in folded and unfolded chromatin, while those of the same region of H1 are masked, probably by interaction with DNA or proteins.     

Recent knowledge concerning mammalian sperm chromatin organization and its potential weaknesses when facing oxidative challenge

Spermatozoa are the smallest and most cyto-differentiated mammalian cells. From a somatic cell-like appearance at the beginning of spermatogenesis, the male germ cell goes through a highly sophisticated process to reach its final organization entirely devoted to its mission which is to deliver the paternal genome to the oocyte. In order to fit the paternal DNA into the tiny spermatozoa head, complete chromatin remodeling is necessary. This review essentially focuses on present knowledge of this mammalian sperm nucleus compaction program. Particular attention is given to most recent advances that concern the specific organization of mammalian sperm chromatin and its potential weaknesses. Emphasis is placed on sperm DNA oxidative damage that may have dramatic consequences including infertility, abnormal embryonic development and the risk of transmission to descendants of an altered paternal genome.     

Nuclear matrix involvement in sperm head structural organization

Summary— In the sperm nuclei the DNA is packaged into a highly condensed form and is not organized into nucleosome and solenoid but is bound and stabilized mainly by the protamines that arrange the DNA in an almost crystalline state. As demonstrated for somatic cells, the sperm DNA has been reported to be organized in loop domains attached to the nuclear matrix structures. However, the possible role of the sperm head matrix in maintaining the loop organization in absence of a typical nucleosomal structures has not been fully elucidated. By using in situ nick translation at confocal and electron microscope level, we analyzed the organization of the DNAprotamine complex and its association with the sperm nuclear matrix. The data obtained indicate that the chromatin organization in sperm nuclei is maintained during the sperm condensation by means of interactions with the nuclear matrix at fixed sites. The fine stucture of sperm nucleus and of sperm nuclear matrix, investigated on sections and replicas of freeze-fractured specimens, suggests that the lamellar array, observed by freeze-fracturing in the sperm nuclei, could depend on the inner matrix which presents a regular organization of globular structures possibly involved in the maintenance of chromatin domains in highly condensed sperm nuclei also.     

Chromatin folding in human spermatozoa. I. Dynamics of chromatin remodelling in differentiating human spermatids

Changes in chromatin structure at different stages of differentiation of human spermatids were studied. It was shown that, in nuclei of early spermatids, chromatin is loosely packed and its structural element is an 8-nm fiber. This "elementary" fiber is predominant at the initial stages of differentiation; in the course of maturation, it is replaced by globular elements approximately 60 nm in diameter. In intermediate spermatids, these globules start to condense into fibrillar aggregates and reduce their diameter to 30-40 nm. At all stages of spermatid maturation, except the final stages, these globules are convergence centers for elementary fibers. This remodelling process is vectored and directed from the apical (acrosomal) to the basal pole of the nucleus. In mature spermatids, the elementary 8-nm fibers are almost absent and the major components are 40-nm fibrillar aggregates. The nuclei of mature spermatids are structurally identical with the nuclei of spermatozoa with the so-called "immature chromatin," which are commonly found in a low proportion in sperm samples from healthy donors and may prevail over the normal cells in spermiogenetic disorders. The cause of this differentiation blockade remains unknown. Possibly, the formation of intermolecular bonds between protamines, which are required for the final stages of chromatin condensation, is blocked in a part of spermatids. The results of this study are discussed in comparison with the known models of nucleoprotamine chromatin organization in human spermatozoa.     

Foreign DNA introduced into the vas deferens is gained by mammalian spermatozoa

The uptake of exogenous DNA by mouse and rat spermatozoa was analyzed using in vitro and in vivo methods. Two DNA constructs were used, one containing the Growth hormone (GH) gene and the other the c-myc oncogene linked to the αA-crystallin promoter (CPV-1 plasmid). For the in vitro approach, washed epididymal spermatozoa were incubated for 2 hr in the presence of linearized DNA. For in vivo experiments, DNA was injected into the proximal region of the vas deferens, and spermatozoa were recovered 6 hr later. In situ hybridization employing fluorescent markers and electron microscopy were used to localize the exogenous genes in spermatozoa. The precise localization of the foreign DNA in spermatozoa was visualized by tridimensional reconstructions using a confocal laser microscopy. Uptake of exogenous DNA occurred in 60–70% of the spermatozoa after in vitro or in vivo treatments. A positive signal was detected in the sperm nucleus and was not affected by DNase treatments. Incorporation of exogenous DNA was also evaluated by slot blot and PCR techniques using the DNA isolated from the sperm nuclei and the corresponding labelled probes. Comparison of a nucleotide sequence between the DNA isolated from in vivo treated spermatozoa and CPV-1 plasmid showed a 98.6% identity. These results show the in vivo capacity of spermatozoa to incorporate exogenous DNA, the ability of this DNA to reach the nucleus, and also demonstrate that epididymal and vas deferens secretions do not block these capacities. Mol. Reprod. Dev. 51:42–52, 1998. © 1998 Wiley-Liss, Inc.     

Chromatin folding in human spermatozoa. I. Dynamics of chromatin remodelling in differentiating human spermatids

Changes in chromatin structure at different stages of differentiation of human spermatids were studied. It was shown that, in nuclei of early spermatids, chromatin is loosely packed and its structural element is an 8-nm fiber. This “elementary” fiber is predominant at the initial stages of differentiation; in the course of maturation, it is replaced by globular elements approximately 60 nm in diameter. In intermediate spermatids, these globules start to condense into fibrillar aggregates and reduce their diameter to 30–40 nm. At all stages of spermatid maturation, except the final stages, these globules are convergence centers for elementary fibers. This remodelling process is vectored and directed from the apical (acrosomal) to the basal pole of the nucleus. In mature spermatids, the elementary 8-nm fibers are almost absent and the major components are 40-nm fibrillar aggregates. The nuclei of mature spermatids are structurally identical with the nuclei of spermatozoa with the so-called “immature chromatin,” which are commonly found in a low proportion in sperm samples from healthy donors and may prevail over the normal cells in spermiogenetic disorders. The cause of this differentiation blockade remains unknown. Possibly, the formation of intermolecular bonds between protamines, which are required for the final stages of chromatin condensation, is blocked in a part of spermatids. The results of this study are discussed in comparison with the known models of nucleoprotamine chromatin organization in human spermatozoa.     

Spermiogenesis and spermatozoa ultrastructure in Salminus and Brycon, two primitive genera in Characidae (Teleostei: Ostariophysi: Characiformes)

In Salminus, spermiogenesis is cystic and gives origin to a type I aquasperm. Spermatid differentiation is characterized by chromatin condensed into thick fibres, nuclear rotation, nuclear fossa formation, cytoplasmic channel formation, mitochondrial fusion producing long and ramified mitochondria, and the presence of several membranous concentric rings around the plasma membrane that encircles the cytoplasmic channel. In Salminus and Brycon, spermatozoa are very similar. They exhibit a spherical nucleus and chromatin condensed into fibre clusters, and a deep nuclear fossa. They show a long midpiece with few elongate mitochondria at the initial region and a cytoplasmic channel completely encircled by one or two membranous concentric rings. The flagellar axis is perpendicular to the nucleus and exhibits the classic axoneme (9 + 2). The very strong similarity observed between Salminus and Brycon spermatozoa supports the hypothesis that these subfamilies are likely to have a monophyletic origin.     

优雅蝈螽精子形成过程中核的形态结构变化观察（英文）

【目的】螽斯精子结构复杂,具有特征性的箭头状顶体,是研究昆虫精子形成的理想材料。为了研究螽斯精子形成过程中的动态变化机制,特别是细胞核的凝集机制和箭头状顶体的发生机制,本研究对优雅蝈螽Gampsocleis gratiosa精细胞和精子的细胞核进行了观察。【方法】选择发育良好的优雅蝈螽成虫精巢为研究材料,利用透射电镜技术、普通光学显微镜和荧光显微镜技术,制作光镜切片和电镜切片进行观察。【结果】根据其形态结构变化特征,将优雅蝈螽精子形成过程中的细胞核分为4个阶段：圆形核、叶形核、柱状核和成熟阶段。我们还通过常规HE染色,结合DNA特异性荧光探针DAPI,证明了圆形核时期,精细胞内具有两个明显的球状结构,一个为细胞核,另一个是原顶体;精子成熟阶段,精子尾部排出的细胞质微滴中含有DNA。【结论】优雅蝈螽精子形成过程中,精细胞的细胞核经历了显著的形态变化,精细胞核的形态变化与细胞骨架微管相关,细胞核塑形伴随着染色质的重组。本研究为进一步阐明直翅目昆虫精子形成的分子机制奠定了基础。     

Fine structure of the germinating cells during the spermiogenesis of Arion rufus (Mollusca,Pulmonate Gastropoda)

Changes in spermatozoan ultrastructure have been studied during spermiogenesis of the slug Arion rufus (Gastropoda, Pulmonata, Stylommatophora). The ovotestis was investigated during the male stage, definite by the presence of spermatozoa. Some peculiar characteristics are shown by early spermatids: Around the nucleus, the nuclear envelope presents two thick layers located on opposite sides, the apical and basal plates, that will determine the antero-posterior axis of the spermatid. The chromatin, first dispersed throughout the nucleoplasm gives later on thick filaments which become attached over the inner surface of these plates. The chromatin filaments are then arranged parallel to the antero-posterior axis as the nucleus elongates. The position of the plates determines the antero-posterior axis of the spermatid. In the mature spermatozoa, the chromatin is more condensed and the nucleus presents an helical organization. The acrosome and flagellum are respectively attached externally to the center of the apical and basal plates. The acrosome consists of a membrane-bound vesicle and forms a column of homogeneous material. In the middle piece, the mitochondria have been transformed into a mitochondrial derivate by the way of a complicated metamorphosis. The axoneme is surrounded by three mitochondrial helices but only one of them contains glycogene granules. © 1996 Wiley-Liss, Inc.