Project description:One of the key events during spermiogenesis is the hypercondensation of chromatin by substitution of the majority of histones by protamines. In humans and mice, protamine 1 (PRM1/Prm1) and protamine 2 (PRM2/Prm2), are expressed in a species-specific ratio. Using CRISPR-Cas9-mediated gene editing we generated Prm1-deficient mice and demonstrate, that Prm1+/- mice are subfertile while Prm1-/- are infertile. Prm1-/- and Prm2-/- sperm show high levels of reactive oxygen species (ROS)-mediated DNA damages and increased histone retention. In contrast, Prm1+/- sperm display only moderate DNA damages. The majority of Prm1+/- sperm were CMA3 positive indicating protamine-free DNA. This is not due to increased histone retention in Prm1+/- sperm. Additionally, we found that sperm from Prm1+/- and Prm1-/- mice contain high levels of incompletely processed PRM2. Further, the PRM1:PRM2 ratio is skewed from 1:2 in WT to 1:5 in Prm1+/- animals. Our results reveal that PRM1 is required for proper PRM2 processing to produce the mature PRM2 which, together with PRM1 is able to hypercondense DNA. Hence, the species specific PRM1:PRM2 ratio has to be precisely controlled in order to retain full fertility.

Project description:MTD project_description Protamines are testis-specific proteins, which replace the majority of histones during spermiogenesis. This results in a hypercondensation of the sperm DNA, finally causing a conformational change from a nucleosomal chromatin structure into a mainly toroid like structure. This is assumed to protect the paternal genome and to contribute to the formation of a hydrodynamic sperm head shape. In mice and humans, two protamines, Protamine 1 (Prm1) and Protamine 2 (Prm2), are expressed. Impaired sperm protamination has been repeatedly correlated with male subfertility in mice and humans. Apart from defects in DNA condensation and impaired DNA integrity, protamine-deficient human and murine sperm show multiple secondary defects, which cannot be explained by the chromosomal function of protamines. These include impaired sperm motility, decreased viability as well as acrsosomal malformations. In this study, we utilized a Prm2-deficient mouse model to investigate the underlying molecular mechanisms of these defects. Since trancription is silenced upon incorporation of protamines, we used LC-MS in combination with label-free quantification to compare the sperm proteome of Prm2-deficient (Prm2-/-) males with the proteome of wildtype (Prm2+/+) and Prm2 heterozygous (Prm2+/-) males. We show that Prm2 deficient mice display a strongly altered proteomic profile compared to controls. Of note, a significant downregulation of proteins SOD1 and PRDX5, which have a well-known function for the detoxification of reactive oxygen species was observed. Thus, together with a series of additional experiments, we could for the first time show that Prm2-deficiency triggers a reactive oxygen species (ROS) mediated sperm destruction cascade during epididymal sperm maturation, finally causing described secondary sperm defects.

Project description:DNA methyltransferases (DNMT) and histone deacetylases (HDAC) inhibitors are used as cancer epigenome drugs. However, these epigenetic drugs lack targeting specificity and could risk inducing genome instability and the expression of oncogenes. Therefore, there is a need to develop new therapeutic strategies where specific cancer genes can be targeted for silencing or activation. The CRISPR-dCas9 system represents a promising powerful therapeutic tool because of its simplicity and specificity. Protamine 1  (PRM1) is exclusively expressed in sperm and has a vital role in the tight packaging of DNA, thus inducing transcriptional silencing in sperm cells. We hypothesized that the activation of the PRM1 gene in tumorigenic cells would lead to DNA condensation and reduce the proliferation of these cells. We transfected human embryonic kidney cells 293T with a dCas9-P300 plasmid that adds acetyl groups to the promoter region of PRM1. RNA-Seq analysis of transfected cells revealed high specificity of targeted gene activation. PRM1 expression resulted in a significant decrease in cell proliferation as measured by the BrdU ELISA assay.  To confirm that the activation of PRM1 was due to acetyl groups deposited to H3K27,  a ChIP-qPCR was performed. The acetylation of the PRM1 promoter region targetted by dCa9-p300 in transfected cells was higher than that of the control cells. Interestingly,  the targeted promoter region for acetylation showed reduced DNA methylation.  These findings demonstrate the efficacy of epigenome editing in activating PRM1 in non-expressing tumorigenic cells, which can be used as a promising therapeutic strategy in cancer treatment. 

Project description:Spermatogenesis is a complex process of sperm generation, including mitosis, meiosis, and spermiogenesis. During spermiogenesis, histones in post-meiotic spermatids are removed from chromatin and replaced by protamines. Although histone-to-protamine exchange is important for sperm nuclear condensation, the underlying regulatory mechanism is still poorly understood. Here, we identify PHD finger protein 7 (PHF7) as an E3 ubiquitin ligase for histone H3K14 in post-meiotic spermatids. Generation of Phf7-deficient mice and Phf7 C160A knockin mice with impaired E3 ubiquitin ligase activity reveals defects in histone-to-protamine exchange caused by dysregulation of histone removal factor Bromodomain, testis-specific (BRDT) in early condensing spermatids. Surprisingly, E3 ubiquitin ligase activity of PHF7 on histone ubiquitination leads to stabilization of BRDT by attenuating ubiquitination of BRDT. Collectively, our findings identify PHF7 as a critical factor for sperm chromatin condensation and contribute to mechanistic understanding of fundamental phenomenon of histone-to-protamine exchange and potential for drug development for the male reproduction system.

Project description:Idiopathic fertility disorders are associated with mutations in various genes. Here, we report that coiled-coil glutamate-rich protein 1 (CCER1), a germline-specific and intrinsically disordered protein (IDP), mediates post-meiotic sperm differentiation, while CCER1 deficiency results in defective sperm chromatin compaction and infertility in mice. CCER1 increases transition protein (Tnp1/2) and protamine (Prm1/2) transcription and serves as a multifaceted mediator for multiple epigenetic modification events of histones during the histone to protamine transition (HTP). Immiscible with heterochromatin in the nucleus, CCER1 self-assembles into polymer droplet and acts as a liquid-liquid phase separated condensate in the nucleus. Notably, we identified the loss-of function variants of human CCER1 (hCCER1) in five patients with non-obstuctive azoospermia (NOA) while absent in 2,713 fertile controls. The mutants led to premature termination or frameshift of CCER1 translation and disrupted condensates in vitro. In conclusion, we propose that nuclear CCER1 is a novel phase-separated condensate that links histone epigenetic modifications, sperm HTP transitions, chromatin condensation, and male fertility.

Project description:Histone ubiquitination has been suggested to serve as a “tag” for nucleosome removal during histone-to-protamine exchange that is essential for chromatin packaging in round spermatids. Here, we screen for putative E3 ligase and identify that the PHF7, containing both RING finger and PHD domains, is critical for H2A ubiquitination and histone removal. Mechanistically, its PHD domain as a histone code reader can specifically bind H3K4me3/me2 and its RING domain as a histone writer can ubiquinate H2A. PHF7 deficiency results in male infertility in mice by generating Phf7 knockout mice using CRISPR-Cas9 technology. Futhermore, we find impaired histone-to-protamine exchange leads to reduced chromatin compaction in Phf7 knockout sperm. Immunostaining and western blot further confirme abnormal retention of core histones and reduced levels of protamine PRM1 and PRM2 in Phf7 knockout sperm. In order to exclude the possibility that Phf7 regulate the expession of protamine, we sorte the round spermatids from WT and Phf7 knockout females for RNA-seq. The transcriptomes in round spermatids are very similar between WT and Phf7 knockout mice. There are few differentially expressed genes in the two groups and the expression of protamine is also unchanged even if PHF7 deficiency. Therefore we find PHF7 has no effects on gene regulation in histone-to-protamine exchange.

Project description:Protamines are the safeguards of the paternal sperm genome. They replace most of the histones during spermiogenesis, resulting in DNA hypercondensation, thereby protecting its genome from environmental noxa. Impaired protamination has been linked to male infertility in mice and humans in many studies. Apart from impaired DNA integrity, protamine-deficient human and murine sperm show multiple secondary effects, including decreased motility and aberrant head morphology. In this study, we use a Prm2-deficient mouse model in combination with label-free quantitative proteomics to decipher the underlying molecular processes of these effects. We show that loss of the sperm`s antioxidant capacity, indicated by downregulation of key proteins like SOD1 and PRDX5, ultimately initiates an oxidative stress-mediated destruction cascade during epididymal sperm maturation. This is confirmed by an increased level of 8-OHdG in epididymal sperm, a biomarker for oxidative stress-mediated DNA damage. Prm2-deficient testicular sperm are not affected and initiate the proper development of blastocyst stage preimplantation embryos in vitro upon intracytoplasmic sperm injection (ICSI) into oocytes. Our results provide new insight into the role of Prm2 and its downstream molecular effects on sperm function and present an important contribution to the investigation of new treatment regimens for infertile men with impaired protamination.

Project description:Loss of Prm1 leads to defective chromatin protamination, impaired PRM2 processing, reduced sperm motility and subfertility in male mice [PRM1]

Project description:Conventional dogma presumes that protamine-mediated DNA compaction in sperm is achieved by passive electrostatics between DNA and the arginine-rich core of protamines. However, phylogenetic analysis reveals several non-arginine residues that are conserved within, but not across, species. The functional significance of these residues or post-translational modifications are poorly understood. In this experiment, we investigated the presence of post-translational modifications on mouse protamine 1 to begin to dissect their function in vivo.

Project description:To achieve the extreme nuclear condensation necessary for sperm function, most histones are replaced with protamines during spermiogenesis in mammals. Mature sperm retain only a small fraction of nucleosomes, which are, in part, enriched on gene regulatory sequences, and recent findings suggest that these retained histones provide epigenetic information that regulates expression of a subset of genes involved in embryo development after fertilization. We addressed this tantalizing hypothesis by analyzing two mouse models exhibiting abnormal histone positioning in mature sperm due to impaired poly(ADP-ribose) (PAR) metabolism during spermiogenesis and identified altered sperm histone retention in specific gene loci genome-wide using MNase digestion-based enrichment of mononucleosomal DNA. We then set out to determine the extent to which expression of these genes was altered in embryos generated with these sperm. For control sperm, most genes showed some degree of histone association, unexpectedly suggesting that histone retention in sperm genes is not an all-or-none phenomenon and that a small number of histones may remain associated with genes throughout the genome. The amount of retained histones, however, was altered in many loci when PAR metabolism was impaired. To ascertain whether sperm histone association and embryonic gene expression are linked, the transcriptome of individual 2-cell embryos derived from such sperm was determined using microarrays and RNA sequencing. Strikingly, a moderate but statistically significant portion of the genes that were differentially expressed in these embryos also showed different histone retention in the corresponding gene loci in sperm of their fathers. These findings provide new evidence for the existence of a linkage between sperm histone retention and gene expression in the embryo. Mnase sensitivity of sperm DNA, indicating nucleosomal, not protamine, packaging was altered in mice by manipulating poly(ADP-ribose) metabolism in adult males using a specific PARP inhibitor for 6 weeks. Abnormal sperm nucleosomal organization of males analyzed by these tiling arrays was compared with differential gene expression in 2 cell embryos fathered by these males analyzed by separate gene expression arrays and RNA sequencing.