La réorganisation de la chromatine au cours de la spermatogénèse

Escoffier, Emmanuelle

15 October 2009

Au cours de la spermiogenèse, une réorganisation très importante de la chromatine se produit : la quasi-totalité des histones sont progressivement enlevées et remplacées par des protéines de transition puis par des protamines. Mon travail de thèse a alors consister à caractériser l'organisation finale de cette chromatine dans les spermatozoïdes ainsi que les mécanismes mis en jeu. Nos résultats montrent pour la première fois l'existence, dans les spermatides condensées de souris, de structures nucléoprotéiques contenant l'histone testiculaire TH2B ainsi que de nouveaux variants d'histones identifiés au laboratoire. De plus, ces structures organisent de manière préférentielle l'hétérochromatine péricentromérique de ces cellules. Cette réorganisation impliquerait la protéine chaperonne NAP1L4, qui pourrait être ciblée sur la chromatine en interagissant avec les queues N-terminales des histones H3. D'autres régions particulières du génome pourraient être la cible de la réorganisation différentielle de la chromatine par ces structures, permettant de les différencier du reste du génome et constituant ainsi le support d'une information épigénétique mâle transmise lors de la fécondation. L'analyse des protéines présentes dans les cellules germinales nous a également permis d'identifier deux autres protéines, HMGB4 et FYTTD1, qui ne semblent pas impliqués dans le processus de réorganisation de la chromatine dans les stades tardifs de la spermiogénèse. Néanmoins, le rôle potentiel de FYTTD1 dans le phénomène de maturation des ARN, ces derniers pouvant être un autre support de l'information épigénétique, pourrait s'avérer être un nouveau champ d'investigations très intéressant.

[SDV:BC] Life Sciences/Cellular Biology

spermatogenese

chromatine

histones

variants

Untersuchungen zur Expression von Connexin (Cx)43 und Connexin (Cx)45 in Sertoli-Zellen und Keimzellen in der normalen Spermatogenese, Sertoli-Zelltumoren und Seminomen des Hundes

Rüttinger, Christina.

January 2008

Zugl.: Giessen, Universiẗat, Diss., 2008.

Untersuchungen zur Expression von Connexin (Cx)43 und Connexin (Cx)45 in Sertoli-Zellen und Keimzellen in der normalen Spermatogenese, Sertoli-Zelltumoren und Seminomen des Hundes /

Rüttinger, Christina.

January 2008

Zugl.: Giessen, Universiẗat, Diss., 2008.

Expression des Activator of CREM in Testis (ACT) bei normaler und gestörter Spermatogenese verschiedener Spezies

Beßmann, Ingrid

January 2006

Univ., Diss., 2006--Giessen

Tudor domain containing protein 6 and its essential role in murine spermatogenesis.

Tiedau, Daniela

20 October 2009

Expression of the Tudor domain containing protein 6 (TDRD6), which is restricted to the male germ line, starts at day 16 of spermatogenesis, i.e. in pachytene spermatocytes. TDRD6 is a 250 kDa protein, which we recently found to be cleaved at the C-terminal end during germ cell development, resulting in a 230 kDa product. Neither is the process of cleavage itself nor are the functions of the two different forms known. The 230 kDa isoform is the most prominent form in round spermatids, where it localizes to the chromatoid body (CB), i.e. a single filamentous, perinuclear granule. One characteristic component of the CB is the RNA helicase MVH. CBs contain components of the microRNA (miRNA) pathway, including Piwi-interacting RNAs (piRNAs), as well as MIWI, MIWI2, and MILI, the mouse homologs of the Piwi proteins, which bind piRNAs and also act in transposon regulation. We showed that TDRD6 interacts with MIWI and MILI in vitro, and a direct interaction with MVH was shown before. To reveal the function of TDRD6, we generated Tdrd6-/- mice, which lack the protein. These mice are generally healthy but the males are sterile, due to the absence of mature spermatozoa. The most striking intracellular phenotype of Tdrd6-/- mice is the highly aberrant architecture of chromatoid bodies in round spermatids. Tdrd6-/- CBs appear as diffuse, disrupted, and less condensed structures. Their interior is largely missing, and only a “ghost”-like structure remains, expected to be significantly impaired in function. Other CB components like MVH, MIWI and MILI are expressed in Tdrd6-/- testes, but they cannot localize to the disrupted CBs. This suggests a role for TDRD6 in assembling the chromatoid body complex by recruiting other proteins. The CB is important for storage and translational regulation of mRNA, through interaction with miRNAs. In Tdrd6-deficient testes 10 % of all known murine miRNAs are differently expressed, whereas most of the mature miRNAs are up-regulated, indicating less turnover, and thus, accumulation of mature miRNAs. Since some precursor miRNAs are up-regulated as well, we assume, that TDRD6 affects miRNA transcription most likely by indirectly influencing transcriptional regulation of miRNA genes. In Tdrd6-/- mice an overall abnormal mRNA gene expression pattern was observed by microarray analyses. Of all mis-regulated genes 36 % are located to the centromer-proximal region of Chr 8, and 11 % are located to the distal end of Chr 1. This mis-regulation might be due to a common transcriptional regulation. The orthologous regions on the human chromosomes show altered chromosomal structures in many different carcinomas. If TDRD6 plays a role in carcinogenesis has to be investigated.

Tdrd6

spermatogenesis

Chromatoid body

miRNA

Tdrd6

Spermatogenese

Chromatoid body

miRNA

ddc:570

rvk:WD 5100

Exploring the role of STAG3 in mammalian meiosis

Suresh, Laya

06 August 2024

In the intricate realm of biology, meiosis stands as the remarkable process responsible for generating genetically diverse haploid gametes from diploid cells. In 2000, Pezzi et al., identified STAG3 as a novel meiotic-specific synaptonemal-complex associated protein belonging to the highly conserved family of stromalin nuclear proteins. Later, over the years, research groups characterised the depletion phenotype of STAG3 in mice, where deficiency of STAG3 causes severe chromosomal defects and early meiotic arrest. These studies together collectively highlighted STAG3 as the most important meiotic cohesin. Traditionally, the role of the cohesin complex was understood as maintaining cohesion between chromatids during cell division. However, over the years, this perception has evolved significantly, expanding to include the regulation of dynamic chromosomal configurations during meiosis. With the realisation of STAG3's importance in meiotic progression, the next pressing question becomes: how does STAG3 coordinate this intricate process? This study sought to address that question by examining the STAG3 interactome in male germ cells, aiming to uncover novel pathways through which STAG3 contributes to maintaining meiotic progression. Through successful purification of the STAG3-REC8 complex, its ability to form functional complexes in-vitro was demonstrated. During my PhD thesis, I discovered links between STAG3 and DNA repair mechanisms beyond the well-known homologous recombination /non-homologous end joining pathway in meiotic recombination. By looking at the meiotic-specific protein interactome bound to the STAG3-REC8 complex through Mass Spectroscopic analysis, we identified STAG3 involvement in PARP-1-mediated repair of DNA double-strand breaks occurring outside of the programmed DSB repair during the zygotene stage of prophase I. PARP-1 is an ADP-ribose polymerase which acts as a first responder that detects DNA damage and facilitates the activation of the DNA repair pathway. STAG3 shows a preferential interaction with PARP-1 when spermatocytes are challenged with extensive DNA damage. Furthermore, the interaction of SMC3, another component of the cohesin complex, with PARP-1 during DNA damage suggests that STAG3, as part of the cohesin complex, contributes to DNA damage repair in spermatocytes. To gain deeper insights into the distinctive characteristics of STAG3, an extensive analysis of spermatogenesis in mice expressing a C-terminus truncated form of STAG3 was performed. The C-terminal region of STAG3 is not conserved among the stromalin family members, and hence it was speculated that this region might have unique functions to meiosis. Removal of the C-terminal end comprising 47 amino acids led to an early meiotic arrest, mirroring the phenotype in most cohesin subunit deletion mutants. The phenotype observed mimics the complete STAG3 depletion phenotype to some extent. The truncated STAG3 resulted in an arrest at a late zygotene/early pachytene-like stage during meiotic prophase I. One of the most notable observations was the significant reduction in the length of the axial elements (AE) in this mutant. Despite stable expression of and localisation of STAG3 to the axis, the axis length decreased by over 60%. This mutation compromised synaptonemal complex formation, leading to the early meiotic arrest. Although SYCP1 loads onto the axis and initiate synapsis, the shortened axial elements could not synapse, marked by HORMAD-1, a well-known asynapsis marker. The average number of SYCP3-marked stretches was 35 in this mutant. The increased number of AE and shortened axis length did not result from chromosome fragmentation because most chromosomes/axes had intact telomere and centromeric signals, validated by RAP1 and ACA foci, respectively. Centromeric and telomeric cohesion may be partially affected as some chromosome showed aberrant telomeric and centromeric defects. C terminal truncated STAG3 impairs synapsis between homologous chromosomes, but the sister chromatid cohesion remains largely unaffected. Also, this deletion did not affect the loading of the cohesin complex subunits onto the chromosome axis. The early meiotic arrest resulted in underdeveloped gonads, leading to infertility in otherwise healthy mice. Taken together, these results suggest novel roles for STAG3 in meiosis, and the meiotic-specific C terminal region of STAG3 is critical for proper meiotic progression in mice.

Meiose, Cohesine, STAG3, Spermatogenese

info:eu-repo/classification/ddc/610

ddc:610

Organ and primary culture of medaka (Oryzias latipes) testis: Test systems for the analysis of cell proliferation and differentiation / Organ und Primärzellkultur von Medaka Testis: Test Systeme zur Untersuchung des Zellproliferation und Zelldifferenzierung

Song, Miyeoun

22 June 2003

In cultured medaka testis fragments, cells remained viable for the entire culture period (17h), and spermatids that developed from spermatocytes were viable and motile. Primary cultures were characterized over a period of two days with respect to cell viability and the distribution of adherent and suspended cells. These two cell populations were maintained in dynamic equilibrium in vitro for several days. Proliferating cells were predominant among clusters of suspended cells, as determined by BrdU labeling, and CFSE and propidium iodide PI labeling. Based on cytological criteria, the proliferating cells were mostly spermatogonia and possibly also preleptotene spermatocytes. Differentiation of spermatocytes into spermatids or spermatozoa was also observed, mainly among the suspended cells. These results suggest that the organ and primary culture systems are suitable systems for studying the effects of substances that interfere with spermatogenesis in the medaka, a model vertebrate. The organ and primary culture systems were used to analyze the effects of a synthetic estrogen, EE2, on cell proliferation in medaka testis. Both organ and primary culture were suitable for this purpose consistently small concentrations (0.01 and 1 nM) of EE2 stimulated cell proliferation slightly, while higher concentrations (100 nM) had an inhibitory effect. To investigate the effect of phytoestrogens on cell proliferation in spermatogenesis, selected flavonoids [genistein (1, 10, 100 µg/ml), quercetin (0.01, 1, 100 µM), and 8-prenylnarigenin (0.001, 0.1, 1, 10 µM)] were added to medaka testis primary cultures. Genistein and quercetin inhibited cell proliferation in the cultures while 8-prenylnarigenin had no effect. In a second series of experiments the addition of genistein (10 µg/ml) to primary cultures significantly inhibited both cell proliferation and cell differentiation as determined by flow cytometry using CFSE/PI labeling.

Durchflusszytometrie

EE2

Genistein

Medaka

Spermatogenese

Spermatogonien

Zelldifferenzierung

Zellproliferation

EE2

cell proliferation

flow cytometry

genistein

primary culture

spermatogenesis

spermatogonia

ddc:32

rvk:WX 5500

Diole

Durchflusscytometrie

Endokrin wirksamer Stoff

Genistein

Japankärpfling

Proliferation

Spermatogenese

Spermatogonium

Zelldifferenzierung

Organ and primary culture of medaka (Oryzias latipes) testis: Test systems for the analysis of cell proliferation and differentiation

Song, Miyeoun

18 July 2003

In cultured medaka testis fragments, cells remained viable for the entire culture period (17h), and spermatids that developed from spermatocytes were viable and motile. Primary cultures were characterized over a period of two days with respect to cell viability and the distribution of adherent and suspended cells. These two cell populations were maintained in dynamic equilibrium in vitro for several days. Proliferating cells were predominant among clusters of suspended cells, as determined by BrdU labeling, and CFSE and propidium iodide PI labeling. Based on cytological criteria, the proliferating cells were mostly spermatogonia and possibly also preleptotene spermatocytes. Differentiation of spermatocytes into spermatids or spermatozoa was also observed, mainly among the suspended cells. These results suggest that the organ and primary culture systems are suitable systems for studying the effects of substances that interfere with spermatogenesis in the medaka, a model vertebrate. The organ and primary culture systems were used to analyze the effects of a synthetic estrogen, EE2, on cell proliferation in medaka testis. Both organ and primary culture were suitable for this purpose consistently small concentrations (0.01 and 1 nM) of EE2 stimulated cell proliferation slightly, while higher concentrations (100 nM) had an inhibitory effect. To investigate the effect of phytoestrogens on cell proliferation in spermatogenesis, selected flavonoids [genistein (1, 10, 100 µg/ml), quercetin (0.01, 1, 100 µM), and 8-prenylnarigenin (0.001, 0.1, 1, 10 µM)] were added to medaka testis primary cultures. Genistein and quercetin inhibited cell proliferation in the cultures while 8-prenylnarigenin had no effect. In a second series of experiments the addition of genistein (10 µg/ml) to primary cultures significantly inhibited both cell proliferation and cell differentiation as determined by flow cytometry using CFSE/PI labeling.

info:eu-repo/classification/ddc/32

ddc:32

Identification et caractérisation de la protéine Atad2, un facteur du remodelage de la chromatine acétylée au cours de la spermatogenèse.

Lestrat, Cecile

16 October 2008

Au cours de la maturation des gamètes mâles a lieu un événement unique : les structures classiques qui ordonnent l'ADN sont complètement bouleversées et remplacées par une nouvelle, de composition et d'agencement différents, qui permet au noyau du spermatozoïde final une compaction qui n'est retrouvée nulle part ailleurs. Les signaux épigénétiques ainsi que les événements qui se déroulent alors au niveau moléculaire ne sont pas encore bien élucidés. C'est dans l'optique d'une meilleure compréhension de ce phénomène que la protéine Atad2 a été identifiée et caractérisée. Ce facteur, qui possède un bromodomaine ainsi qu'un domaine AAA, est retrouvé sous deux formes chez la souris. La plus courte, strictement testiculaire, est capable de se lier à la chromatine acétylée. De plus, comme les autres membres de la famille des AAAATPases, Atad2 est capable de se multimériser. Cette multimérisation régule son affinité à la chromatine. Des études plus poussées ont montré un rôle dans l'activité transcriptionnelle ainsi que dans la stabilité des structures basales d'ordonnancement de l'information génétique, les nucléosomes. De plus, chez l'humain, Atad2 a été retrouvé exprimé de façon aberrante dans certaines tumeurs. L'élucidation du rôle de cette protéine dans les cellules germinales et somatiques apportera ainsi des informations sur le changement complet de la nature chromatinienne au cours de la spermatogenèse, et peut-être permettra peut-être une meilleure appréhension de l'activité génomique ayant lieux dans les cellules tumorales.

bromodomaine

épigénétique

AAA-ATPase

chromatine

histone

nucleosome

spermatogenese

spermiogenese

cancer/testis antigène

Tudor domain containing protein 6 and its essential role in murine spermatogenesis.

Tiedau, Daniela

13 October 2009

Expression of the Tudor domain containing protein 6 (TDRD6), which is restricted to the male germ line, starts at day 16 of spermatogenesis, i.e. in pachytene spermatocytes. TDRD6 is a 250 kDa protein, which we recently found to be cleaved at the C-terminal end during germ cell development, resulting in a 230 kDa product. Neither is the process of cleavage itself nor are the functions of the two different forms known. The 230 kDa isoform is the most prominent form in round spermatids, where it localizes to the chromatoid body (CB), i.e. a single filamentous, perinuclear granule. One characteristic component of the CB is the RNA helicase MVH. CBs contain components of the microRNA (miRNA) pathway, including Piwi-interacting RNAs (piRNAs), as well as MIWI, MIWI2, and MILI, the mouse homologs of the Piwi proteins, which bind piRNAs and also act in transposon regulation. We showed that TDRD6 interacts with MIWI and MILI in vitro, and a direct interaction with MVH was shown before. To reveal the function of TDRD6, we generated Tdrd6-/- mice, which lack the protein. These mice are generally healthy but the males are sterile, due to the absence of mature spermatozoa. The most striking intracellular phenotype of Tdrd6-/- mice is the highly aberrant architecture of chromatoid bodies in round spermatids. Tdrd6-/- CBs appear as diffuse, disrupted, and less condensed structures. Their interior is largely missing, and only a “ghost”-like structure remains, expected to be significantly impaired in function. Other CB components like MVH, MIWI and MILI are expressed in Tdrd6-/- testes, but they cannot localize to the disrupted CBs. This suggests a role for TDRD6 in assembling the chromatoid body complex by recruiting other proteins. The CB is important for storage and translational regulation of mRNA, through interaction with miRNAs. In Tdrd6-deficient testes 10 % of all known murine miRNAs are differently expressed, whereas most of the mature miRNAs are up-regulated, indicating less turnover, and thus, accumulation of mature miRNAs. Since some precursor miRNAs are up-regulated as well, we assume, that TDRD6 affects miRNA transcription most likely by indirectly influencing transcriptional regulation of miRNA genes. In Tdrd6-/- mice an overall abnormal mRNA gene expression pattern was observed by microarray analyses. Of all mis-regulated genes 36 % are located to the centromer-proximal region of Chr 8, and 11 % are located to the distal end of Chr 1. This mis-regulation might be due to a common transcriptional regulation. The orthologous regions on the human chromosomes show altered chromosomal structures in many different carcinomas. If TDRD6 plays a role in carcinogenesis has to be investigated.

info:eu-repo/classification/ddc/570

ddc:570