42 CONVERSION OF THE CHROMATIN OF SOMATIC CELLS INTO SPERMATID-LIKE STRUCTURES

Abstract

The post-meiotic phase of spermatogenesis is characterised by a radical reorganization of the chromatin, leading to its nucleosomal to toroid transition. The replacement of histones with protamine is a gradual process regulated to the hierarchical translation of repressed mRNAs leading to the following events: incorporation of testis-specific histone variants and general histone hyperacetylation, bromodomain proteins, transition proteins, concluded by protamine incorporation on DNA. In this work, we tested whether the induced expression of human protamine 1 (PR1) in sheep somatic cells could induce a protamine/toroid conformation of interphase nuclei. Sheep adult fibroblasts (SAF) were cultured in DMEM with 10% fetal bovine serum from second to eighth passage. Then, SAF at 80% confluence were transfected with 3 μg of pPR1-red fluorescent protein (RFP) and pRFP (CTR) with lipofectamine. At 4 h post-transfection, cells were treated with 5 nM trichostatin A (TSA; histone deacethylase inhibitor) for an additional 16 h. Transfected cells (visualised through the RFP tag) were analysed for nuclear morphology (transmission electron microscopy), PR1-RFP expression (confocal microscope, RT-PCR, Western blot), cytofluorimeter, DNA damage (comet assay, pH2A.X immune-detection), and chromatin immune-precipitation assays (ChIP). Moreover, to visualise the histone/protamine exchange, we transfected with PR1 mouse GFP-H2B fibroblasts. Protaminized cells were used as donors for nuclear transfer (NT) and TH2B (testis/oocyte-specific histone normally present in male pronucleus, a marker of reprogramming) was detected in pronuclear stage of NT zygotes. The χ² test was used for statistical analyses. We demonstrated that PR1 translocates into the nuclei and gradually compacts them into elongating spermatid-like structures in 48 h; TSA treatment facilitates the process [TSA 83.3% (50/60); without TSA 55.2%; 58/105; P < 0.0003]. A complete histone-to-protamine exchange was also visualised in GFP-H2B nuclei (mouse fibroblasts) 40h after PR1 transfection. Cytofluorimetric analysis demonstrated that protamine incorporation occurs in any cell cycle stage and without DNA breaks. Next, protamine-protamine binding was excluded by ChIP analysis, which confirmed protamine-DNA binding. Finally, protaminized nuclei transplanted into enucleated oocytes incorporated maternal histone TH2B (3/8), whereas no signal was detected in control cells (0/9), suggesting that protaminized nuclei are better remodelled. We conclude that the induced expression of PR1 forces the somatic chromatin to acquire a structure overlapping elongated spermatid/spermatozoa, a conformation that perfectly matches the nuclear reprogramming machinery of the oocyte. Further work will determine whether protaminized cells are better reprogrammed upon nuclear transfer.