Flow cytometric characterization of viable meiotic and postmeiotic cells by Hoechst 33342 in mouse spermatogenesis
Background Spermatogenesis in adult is a complex stepwise process leading to terminally differentiated spermatozoa. The cellular heterogeneity of testis renders complex the studies on molecular aspects of this differentiation process. Analysis of the regulation of adult spermatogenesis would undoubtedly benefit from the development of techniques to characterize each germinal differentiation step. Methods Hoechst 33342 staining of mouse testicular cells allows characterization of an enriched population in germinal stem cell and spermatogonia, called side population. In this study, we examined the definition of the various germinal populations stained by Hoechst 33342, notably meiotic and postmeiotic cells. Results Preleptotene spermatocytes, spermatocyte I, spermatocyte II, and round and elongated spermatids were discriminated by Hoechst 33342 staining. In addition, we associated differentiation of spermatocyte I through leptotene to diplotene with changes in Hoechst 33342 red fluorescence pattern. Conclusions Hoechst 33342 staining of viable germinal cells constitutes a valuable tool to study normal and impaired mouse adult spermatogenesis or to isolate viable cells from various differentiation stages for studies of molecular mechanisms regulating spermatogenesis. © 2005 Wiley‐Liss, Inc.
Stem cells in various somatic tissues (bone marrow, skeletal muscle) can be identified by the `Side Population' marker based on Hoechst 33342 efflux. We show that mouse testicular cells also display a `Side Population' that express Bcrp1 mRNA, the ABC transporter responsible for Hoechst efflux in hematopoietic cells. Inhibition of Hoechst efflux by specific BCRP1 inhibitor Ko143 show that germinal `Side Population' phenotype is dependent on BCRP1 activity. Analysis of two well-defined models of altered spermatogenesis(W/Wv mutants and cryptorchid male mice) and RNA expression studies of differentiation markers demonstrate that germinal `Side Population' contains spermatogonial cells. In addition,α 6-integrin and Stra8 germinal stem cell markers, are expressed in the `Side Population'. In vivo repopulation assay clearly establishes that testis `Side Population' in adult mice is highly enriched in male germ stem cells.
In adults, stem cells are responsible for the maintenance of many actively renewing tissues, such as haematopoietic, skin, gut and germinal tissues. These stem cells can self-renew or be committed to becoming progenitors. Stem-cell commitment is thought to be irreversible but in male and female Drosophila melanogaster, it was shown recently that differentiating germ cells can revert to functional stem cells that can restore germinal lineage. Whether progenitors are also able to generate stem cells in mammals remains unknown. Here we show that purified mouse spermatogonial progenitors committed to differentiation can generate functional germinal stem cells that can repopulate germ-cell-depleted testes when transplanted into adult mice. We found that GDNF, a key regulator of the stem-cell niche, and FGF2 are able to reprogram in vitro spermatogonial progenitors for reverse differentiation. This study supports the emerging concept that the stem-cell identity is not restricted in adults to a definite pool of cells that self-renew, but that stemness could be acquired by differentiating progenitors after tissue injury and throughout life.
IntroductionOne of the aims of regenerative medicine is to repair or restore functional organs by engrafting adult or fetal somatic stem cells into a damaged tissue. These cells, present in most self-renewing tissues, such as skin, intestine, and the hematopoietic system, can be purified, expanded ex vivo, and then used for reconstitution of damaged tissues. 1,2 Many major advances have been achieved in purification and ex vivo amplification of somatic stem cells, 1,3 but few data are available on the prerequisites that will enhance their in vivo biologic activities. New methods to improve the efficiency of bone marrow transplantation and, more generally, reconstitution of damaged tissues by somatic stem cells, depend on tracking of stem cells injected into the animal and thus on the development of imaging strategies that reveal the recruitment, homing, and initial proliferation of these injected somatic stem cells in the context of a living body.The best-characterized mammalian adult somatic stem cells are the hematopoietic stem cells (HSCs) 4,5 whose maintenance and development in the bone marrow are dependent on the HSC niche through niche-regulating pathways. 6 HSCs can be purified close to homogeneity, 7 and a single HSC can produce lifelong complete hematopoietic reconstitution of a lethally irradiated recipient mouse. 4 Many adhesion molecules, signaling pathways, and transcription factors that regulate hematopoietic reconstitution have been characterized, and the roles of these regulatory factors have been shown in vivo using overexpression or genetic inactivation.Yet, the critical early events of recruitment to the bone marrow, homing in the bone marrow microenvironment, and initial proliferation of HSCs after transplantation into lethally irradiated mice are poorly characterized because few methods are available to study these dynamics processes at the cellular level.The early cellular events that precede hematopoietic reconstitution from a small number of HSCs cannot be studied in vitro on hematopoietic cells recovered from recipient animals and presents a demanding challenge for imaging studies as the initial signals that can be detected are very weak. Among imaging techniques, 4 can presently be used to follow the reconstitution of the hematopoietic system at the cellular level. The first technique combines local surgery for placement of a bone window that is used for fluorescent microscopy, but this technique is invasive and limited by the size of the window. 8 The second technique combines high-resolution confocal microscopy and 2-photon video imaging and has greatly improved detection of multiple fluorescent signals in a living animal. This intravital microscopy permits high-resolution imaging of small tissue volume but, in the case of hematopoietic reconstitution, is limited by the thickness of the bone. [9][10][11][12] It cannot be used to study hematopoietic reconstitution in long bones and has been used to image hematopoietic reconstitution in mouse calvarium bone marrow. The third technique ...
The Polycomb group of proteins is required for the proper orchestration of gene expression due to its role in maintaining transcriptional silencing. It is composed of several chromatin modifying complexes, including Polycomb Repressive Complex 2 (PRC2), which deposits H3K27me2/3. Here, we report the identification of a cofactor of PRC2, EZHIP (EZH1/2 Inhibitory Protein), expressed predominantly in the gonads. EZHIP limits the enzymatic activity of PRC2 and lessens the interaction between the core complex and its accessory subunits, but does not interfere with PRC2 recruitment to chromatin. Deletion of Ezhip in mice leads to a global increase in H3K27me2/3 deposition both during spermatogenesis and at late stages of oocyte maturation. This does not affect the initial number of follicles but is associated with a reduction of follicles in aging. Our results suggest that mature oocytes Ezhip−/− might not be fully functional and indicate that fertility is strongly impaired in Ezhip−/− females. Altogether, our study uncovers EZHIP as a regulator of chromatin landscape in gametes.
During testis development, proliferation and death of gonocytes are highly regulated to establish a standard population of adult stem spermatogonia that maintain normal spermatogenesis. As Transforming Growth Factor beta (TGFbeta) can regulate proliferation and apoptosis, we investigated its expression and functions during testis development. We show that TGFbeta2 is only expressed in quiescent gonocytes and decreases gonocyte proliferation in vitro. To study the functions of TGFbeta2, we developed conditional mice that invalidate the TGFbeta receptor type II in germ cells. Most of the knock-out animals die during fetal life, but the surviving adults show a reduced pool of spermatogonial stem/progenitor cells and become sterile with time. Using an organ culture system mimicking in vivo development, we show higher proportions of proliferating and apoptotic gonocytes from 13.5 dpc until 1 dpp, suggesting a reduction of germinal quiescence in these animals. Conversely, a 24-hour TGFbeta2-treatment of explanted wild-type testes, isolated every day from 13.5 dpc until 1 dpp, increased the duration of quiescence. These data show that the TGFbeta signaling pathway plays a physiological role during testis development by acting directly as a negative regulator of the fetal and neonatal germ cell proliferation, and indicate that the TGFbeta signaling pathway might regulate the duration of germ cell quiescence and is necessary to maintain adult spermatogenesis.
Neural stem cells from mouse forebrain are contained in a population distinct from the ‘side population’
Developing and adult forebrains contain neural stem cells (NSCs) but no marker is available to highly purify them. When analysed by flow cytometry, stem cells from various tissues are enriched in a 'side population' (SP) characterized by the exclusion of the fluorescent dye Hoechst 33342. Here, we characterize the SP in embryonic, neonatal and adult forebrains, as well as in neurosphere cultures and we have determined whether this SP could be a source of enriched NSCs. By using specific inhibitors, we found that the SP from embryonic forebrain results from the activity of the ABCG2 transporter, a characteristic of other stem cells, whereas the SP from adult forebrain probably results from the ABCB1 transporter. SP cells from embryonic and adult forebrains, however, expressed a range of cell surface markers more consistent with a haematopoietic/endothelial origin than with a neural origin; NSC markers were mostly expressed on cells outside the SP (in the main population, MP). Moreover, assays for NSC growth in vitro showed that SP cells from embryonic and adult forebrains did not generate NSC-derived colonies, whereas the MP did. We thus conclude that NSCs from developing and adult forebrains are not contained in the SP contrary to stem cells from other tissues.
This review focuses on the recent applications of flow cytometry (FCM) in microbiological research (1987-mid 1992). It tries to give a scope of the important breakthroughs which occurred in this field during this period. The technical difficulties of microorganism analysis by flow cytometry is briefly appraised. The significance and the limits of the different microbial cell parameters attainable by flow analyses are systematically evaluated: light scatter for cell size and structure, fluorescence measurements for quantification of cellular components, microbial antigen detection and cell physiological activity estimation. Emphasis is given on the new technological advances which appeared in the last two years. The second part of the review is devoted to the analysis of the usefulness of flow cytometric approach in the different fields of microbiology: fundamental studies in microbial physiology, differentiation, microbial ecology and aquatic sciences, medical microbiology, parasitology, microbial pharmacology and biotechnology.
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