Electron microscopic and biochemical analyses of the organization of human sperm chromatin decondensed with sarkosyl and dithiothreitol

Relationship between chromatin condensation, DNA integrity and quality of ejaculated spermatozoa from infertile men

Normal chromatin condensation is important for sperm fertilising ability. However, routine semen analysis does not identify defects in sperm chromatin structure. This study aimed to investigate the condensation of chromatin and DNA integrity in spermatozoa of infertile men and deduce the relationship with sperm quality, as measured by conventional semen parameters. Semen analysis was carried out to assess sperm quality according to World Health Organization criteria. The remaining aliquot of each sample was processed for transmission electron microscopy, chromomycin A3 (CMA3) and terminal deoxynucleotidyl transferase dUTP nick end labelling (TUNEL) assays. The ultrastructural analysis of spermatozoa from infertile men showed heterogeneity in sperm nuclear morphology. Some spermatozoa displayed a round nucleus with incomplete chromatin condensation. Immunoreactivity with antitransitional protein and antiprotamine antibodies indicated nuclear maturation defects in the spermatozoa of infertile men. Spearman's correlation analysis indicated a positive correlation between the percentages of CMA3- and TUNEL-positive spermatozoa. In addition, these two parameters were negatively correlated with sperm concentration, motility and normal morphology. This study demonstrated that men with morphologically normal spermatozoa of <30% have greater degree of protamine deficiency and DNA damage than men with morphologically normal spermatozoa of >30%. Evaluation of chromatin integrity appears to be a useful tool for assessing male fertility.

Analysis of DNA looped domains organization duringTriturus cristatusspermatogenesis

Chromatin from eukaryotes is organized in DNA loops with sequential attachments to a nucleoskeleton named nuclear matrix. This organization plays major roles in replication, transcription, recombination, DNA repair, chromosome condensation and segregation. During spermatogenesis, chromatin undergoes several dynamic transitions, which are often associated with important changes not only in its physical conformation but even in its compositions and structure. To understand the periodical change in the functional organization of chromatin during spermatogenesis, the higher order organization of chromatin in different testicular cell types (pachytene spermatocytes, round spermatids) and the epididymal sperm ofTriturus cristatushave been investigated. The expansion and the contraction of nucleoid DNA were measured with a fluorescence microscope following exposure of nucleoids to increasing concentrations of ethidium bromide (EtBr) (2.5–200 μg/ml) as an intercalating dye to induce DNA-positive supercoils. Nucleoids from all studied cell types exhibited a biphasic change (condensed–relaxed–condensed) in size as a consequence of exposure to increasing concentrations of EtBr, indicating that they contained negatively supercoiled DNA. At higher EtBr concentrations, maximum positive supercoiling occurred in pachytene DNA loops. Our data suggest that pachytene DNA is the most open chromatin conformation in terms of EtBr intercalation.

Histone acetylation-mediated chromatin compaction during mouse spermatogenesis

One of the most dramatic chromatin remodelling events takes place during mammalian spermatogenesis involving massive incorporation of somatic and testis-specific histone variants, as well as generalized histone modifications before their replacement by new DNA packaging proteins. Our data suggest that the induced histone acetylation occurring after meiosis may direct the first steps of genome compaction. Indeed, a double bromodomain-containing protein expressed in postmeiotic cells, Brdt, shows the extraordinary capacity to specifically condense acetylated chromatin in vivo and in vitro. In elongating spermatids, Brdt widely co-localizes with acetylated histones before accumulating in condensed chromatin domains. These domains preferentially maintain their acetylation status until late spermatogenesis. Based on these data, we propose that Brdt mediates a general histone acetylation-induced chromatin compaction and also maintains differential acetylation of specific regions, and is therefore involved in organizing the spermatozoon's genome.

Establishment of male-specific epigenetic information

The setting of male-specific epigenetic information is a complex process, which involves a major global re-organisation, as well as localized changes of the nucleus structure during the pre-meiotic, meiotic and post-meiotic stages of the male germ cell differentiation. Although it has long been known that DNA methylation in targeted regions of the genome is associated with male-specific genomic imprinting, or that most core histones are hyperacetylated and then replaced by sperm-specific proteins during the post-meiotic condensation of the nucleus, many questions remain unanswered. How these changes interact, how they affect the epigenetic information and how the paternal epigenetic marks contribute to the future genome are indeed major issues remaining to be explored.

Protamines in the internally fertilizing neobatrachian frogEleutherodactylus coqui

The internally fertilizing primitive frog Ascaphus truei (family Ascaphidae) from the Pacific Northwest is the only frog with an intromittent organ. The more advanced neobatrachian frog Eleutherodactylus coqui (family Leptodactylidae) from Puerto Rico has secondarily acquired internal fertilization but mates by cloacal apposition. Nonetheless, both frogs have introsperm with an elongated head containing highly condensed chromatin. Characterization of sperm nuclear basic proteins (SNBPs) in E. coqui by acid-urea polyacrylamide gel electrophoresis indicates that, as in A. truei, testes from a single animal contain several protamines. Amino acid analysis indicates a composition for the most rapidly moving protamine of each species as follows: in E. coqui, ARG (35.6 mol %) + LYS (3.8 mol %) + HIS (7.6 mol %) = 47 mol % total basic residues and in A. truei, ARG (42.1 mol %) + LYS (11.1 mol %) = 53.2 mol % total basic residues. Transmission electron microscopy shows that E. coqui introsperm, like those in A. truei, are elongate with highly condensed chromatin. However, E. coqui introsperm lacks an axial perforatorium that extends into an endonuclear canal. These morphological features are plesiomorphic (primitive) and shared by A. truei with urodeles and basal amniotes (Jamieson et al. (1993) Herpetologica 49:52-65). In E. coqui introsperm, the nucleoprotein complex has a cross-sectional axis of 420 + 20 angstroms and shows a knobby chromatin structural organization in TEM. The presence of arginine-enriched protamines in both a basal anuran like the ascaphid A. truei and a more advanced neobatrachian like the leptodactylid E. coqui supports the hypothesis that internal fertilization acts as a constraint on the range of SNBP diversity in animals.

The nuclear status of human sperm cells

In the last decade, and in particular since the development of in vitro fertilization techniques, the nuclear status of human sperm cells has shown to be a key parameter in the assessment of male fertility. The shape and condensed state of the mature sperm nucleus are determined by structural and functional events that occur during spermiogenesis. This paper reviews essential findings on re-organization of the nucleus during sperm differentiation and maturation, and reports recent data on the architecture, biochemical composition and stability of the nucleus in human ejaculated spermatozoa. Different methods used to evaluate nuclear maturity in relation to male fertility are critically appraised.

Fluorescence in situ hybridization to Y chromosomes in decondensed human sperm nuclei

Human sperm nuclei were isolated with mixed alkyltrimethylammonium bromide and dithiothreitol (MATAB/DTT) and decondensed by treatments with lithium diiodosalicylate (LIS), sodium chloride, or Tris salts. Concentrations as low as 1 mM LIS induced measurable nuclear swelling compared to 600 mM required for the other two salts. As measured by image analyses, the projected nuclear area increased linearly up to approximately fivefold with LIS concentrations up to 10 mM. Swollen nuclei also maintained the elliptical shapes characteristic of the human sperm head. Expanded sperm nuclei of three men were hybridized with a fluorescently labeled 3.4 kb Y chromosome-specific repetitive DNA probe; 50.1% of the nuclei of each semen sample showed fluorescent labeling over a part of the nucleus indicating presence of the Y chromosome. In comparison, unswollen sperm did not yield reliable hybridization signals. This procedure is suitable for determining the proportion of human sperm with Y chromosomes and can be used to evaluate sperm separation techniques. The availability of probes specific for most human chromosomes suggests that this procedure may find general application in studies of sperm chromosomal constitution.

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.

Changes in DNA topology during spermatogenesis

DNA topology in histone- and protamine-depleted nuclei (nucleoids) from somatic cells, sperm, and spermatogenic cells was studied to determine if the superhelical configuration of DNA looped domains is altered during spermatogenesis. The expansion and contraction of nucleoid DNA was measured with a fluorescence microscope following exposure of nucleoids to different concentrations of ethidium bromide (EB). Nucleoids from Xenopus laevis erythrocytes, primary spermatocytes, and round spermatids, and from Rana catesbeiana sperm all exhibited a biphasic change (condensed-relaxed-condensed) in size as a function of exposure to increasing concentrations (0.5-100 micrograms/ml) of EB, indicating that they contain negatively supercoiled DNA. In contrast, DNA in sperm nucleoids from Xenopus laevis and Bufo fowleri was relaxed and expanded at low (0.5-6 micrograms/ml) EB concentrations, but became gradually condensed as the EB concentration was increased (6-100 micrograms/ml). Nucleoids prepared from all cell types retained the general shape of the nucleus regardless of the superhelical configuration of the nucleoid DNA. Sperm nucleoid DNA condensed by 100 micrograms/ml EB was relaxed by exposure to UV light, DNase I, proteinase K, or 4 M urea, but not by RNase A or 10 mM dithiothreitol. These results demonstrate that the DNA in sperm nucleoids is constrained in domains of supercoiling by nonbasic nuclear proteins. Negatively supercoiled DNA is present in nucleoids from cells with a full complement of histones, including Rana sperm, but not in nucleoids from Xenopus and Bufo sperm in which histones are replaced by "intermediate-type" protamines. Histone replacement in these species, therefore, is accompanied by unfolding of nucleosomal DNA and active removal of the negative supercoils. Results presented also suggest an important role for the nonbasic nuclear proteins of sperm in the morphogenesis of the nucleus and the arrangement of DNA.

Nuclear chromatin decondensation of human sperm: a review

The decondensation of the nucleus of human spermatozoa normally occurs in the oocyte and allows the formation of a male pronucleus. This phenomenon must occur rapidly at this stage but is excluded during all the preceding stages of maturation of the sperm and during travel through the female genital tract, as otherwise it would loose its genome. The compactness of the sperm nucleus has been studied in an attempt to understand the biochemical substratum involved in the condensation/decondensation processes. This review is limited to human sperm, as the decondensation process seems, up to a point, rather different from that described in animals because of different susceptibilities to decondensing reagents and different protein ratios.

Sperm nucleomalacia in men with inflammatory bowel disease

The extent and nature of seminal anomalies in colitic and ileitic patients were investigated using cytological, cytochemical, and electron microscopical methods. In addition to basic seminal variables, the gross and fine structure of spermatozoa were analyzed and the recorded data correlated with actual clinical conditions and therapeutic regimen of patients. Spermiograms revealed that the effect on the testicular function varied among patients, ranging from a subtle embarrassment of late spermiogenesis to a suppression of spermatogenesis as reflected in severe oligozoospermia. In several instances, excurrent ducts and accessory sex glands also were involved. The nuclear syndrome was an invariably observed phenomenon and consisted of increased pleomorphy, excessive vacuolation, postnuclear blebbing, malcondensation, and spontaneous decondensation of chromatin. The nuclear pleomorphy, malcondensation, and decondensation, apparently interrelated, constitute the characteristic condition, referred to as nucleomalacia. Other sperm defects seemed to be mere amplifications of deficiencies common in human semen. The correlation between the extent of intestinal lesions or severity of symptoms and the ratio of nuclear aberrations, demonstrated with acid-fast technique, was striking. No such relationship was found regarding the sulfasalazine treatment.