Differential effects of culture on imprinted H19 expression in the preimplantation mouse embryo

The H19 gene is imprinted with preferential expression from the maternal allele. The putative imprinting control region for this locus is hypermethylated on the repressed paternal allele. Although maternal-specific expression of H19 is observed in mouse blastocysts that develop in vivo, biallelic expression has been documented in embryos and embryonic stem cells experimentally manipulated by in vitro culture conditions. In this study the effect of culture on imprinted H19 expression and methylation was determined. After culture of 2-cell embryos to the blastocyst stage in Whitten's medium, the normally silent paternal H19 allele was aberrantly expressed, whereas little paternal expression was observed following culture in KSOM containing amino acids (KSOM+AA). Analysis of the methylation status of a CpG dinucleotide located in the upstream imprinting control region revealed a loss in methylation in embryos cultured in Whitten's medium but not in embryos cultured in KSOM+AA. Thus, H19 expression and methylation were adversely affected by culture in Whitten's medium, while the response of H19 to culture in KSOM+AA approximated more closely the in vivo situation. It is unlikely that biallelic expression of H19 following culture in Whitten's medium is a generalized effect of lower methylation levels, since the amount of DNA methyltransferase activity and the spatial distribution of Dnmt1 protein were similar in in vivo-derived and cultured embryos. Moreover, imprinted expression of Snrpn was maintained following culture in either medium, indicating that not all imprinted genes are under the same stringent imprinting controls. The finding that culture conditions can dramatically, but selectively, affect the expression of imprinted genes provides a model system for further study of the linkage between DNA methylation and gene expression.     

Possible role of H1 histone in the differentiation of mouse erythroleukemia cells

Serum-starved mouse erythroleukemia cells, stationary phase cells or cells cultured in dibutyryl cAMP (1 mM) can be induced to differentiate by addition of 20% fetal calf serum plus cycloheximide. Culturing unstarved log phase cells in 20% fetal calf serum plus low levels of cycloheximide and histone H1 also causes a significant level of differentiation. These same concentrations of cycloheximide and H1 histone employed separately with 20% fetal calf serum do not induce differentiation. The role these procedures may have in causing an accumulation of histone H1 and cell differentiation is discussed.     

Analysis of compaction in the preimplantation mouse embryo

An SEM analysis of the effects of tunicamycin, cytochalasin B, and colcemid has yielded insights into the process of compaction in the early mouse embryo. All three reagents block or reverse compaction and decrease the number of microvilli (MV), although some MV polarization is permitted. In addition, tunicamycin is shown to lessen cell adhesion even in compacted embryos. Cytochalasin B causes the formation of MV clumps some of which are preferentially localized to the apex or lateral ring region. Colcemid reverses compaction and, coupled with Pronase treatment, completely blocks compaction of uncompacted 8-cell embryos. Observations also suggest that MV polarization can occur only once but compaction (the close adherance and flattening of blastomeres) can be reversed and reinduced. Evidence is consistent with a three-step compaction process involving (1) cell surface recognition and attachment of a ring of lateral microvilli to adjacent blastomeres, (2) subsequent microfilament shortening in these lateral MV, and (3) maintenance of the compacted and polarized state by microtubules.     

Expression of a Forssman antigenic specificity in the preimplantation mouse embryo.

A monoclonal antibody recognizing a Forssman antigenic specificity has been shown to react with cells of the preimplantation mouse embryo. The antigen is believed to be carried on glycolipid molecules on teratocarcinoma stem cells. This antigen is first detected on the trophectoderm of the early blastocyst. The topography of the expression on the trophectoderm is striking and novel. The antigen is no longer found on these cells after the blastocyst has hatched from the zona pellucida in utero. Inner cell masses are antigen-positive at all times. This is the first study of the distribution of a single antigenic determinant in early mouse embryogenesis.     

Cell surface and cytoskeletal elements: Cavitation in the mouse preimplantation embryo

Cavitation is the process whereby the mouse preimplantation embryo develops a fluid-filled blastocoele. Prior to the appearance of the blastocoele fluid, when the embryo is a morula consisting of 16–32 closely apposed cells, cytoplasmic droplets and mitochondria become cortically localized to apposed cell surfaces. This study focused on the restriction of cortical localization of droplets to apposed cell surfaces. Morulae were preincubated 30 min in colcemid, cytochalasin B, or in calcium-free medium and then immunolabeled for “mouse species” cell surface antigens. Indirect immunofluorescence indicated that the apparent density of antigens differed greatly between free and apposed cell surfaces. All three types of preincubations inhibited cavitation and the cortical localization of droplets and mitochondria while none of them affected antigen distribution, as detected by indirect immunofluorescence. Control experiments showed that the apparent difference in antigen density between free and apposed cell surfaces was not due to antigen capping or to inaccessibility of apposed cell surfaces to antibodies. These results are discussed in terms of cell surface-cytoskeletal interactions in the restriction of cortical localization of droplets and mitochondria to apposed cell surfaces as it relates to cavitation.     

Characterization of a diverse secretome generated by the mouse preimplantation embryo in vitro

This study investigates the suitability of surface-enhanced laser desorption and ionization time-of-flight (SELDI-TOF) and electrospray ionization (ESI) mass spectrometry for analysis of the proteins released by the mouse preimplantation embryo in vitro. SELDI-TOF analysis with CM10 or IMAC30 (but not Q10) protein chips detected a protein peak at m/z ~8570 released by both C57BL6 and hybrid embryos. No other peaks unique to the presence of the embryo were identified with this method. ESI mass spectrometry of tryptic digests of embryo-conditioned media identified a total of 20 proteins released during development from the zygote to blastocyst stage. Four proteins were expressed in at least 7 out of 8 cultures tested, one of these (lactate dehydrogenase B) was in all cultures. A further five proteins were in at least half of the cultures and 11 more proteins were in at least one culture. The expression of two of these proteins is essential for preimplantation embryo development (NLR family, pyrin domain containing 5 and peptidyl arginine deiminase, type VI). A further four proteins detected have roles in redox regulation of cells, and three others are capable of inducing post-translational modifications of proteins. This study shows the feasibility of ESI mass spectrometry for identifying the proteins secreted by the preimplantation embryo in vitro. This analysis identifies a range of targets that now require detailed functional analysis to assess whether their release by the embryo is an important property of early embryo development.     

Virtues and limitations of the preimplantation mouse embryo as a model system

The mouse is the most widely used model of preimplantation embryo development, but is it a good model? Its small size, prolificacy and ease of handling make the mouse a relatively low cost, readily available and attractive alternative when embryos from other species are difficult or expensive to obtain. However, the real power of the mouse as a model lies in mouse genetics. The development of inbred mouse strains facilitated gene discovery as well as our understanding of gene function and regulation while the development of tools to introduce precise genetic modifications uniquely positioned the mouse as a powerful model system for uncovering gene function. However, all models have limitations; the small size of the mouse limits tissue availability and manipulations that can be performed and differences in physiology among species may make it inappropriate to extrapolate from the mouse to other species. Thus, rather than extrapolating directly from the mouse to other species, it may be more useful to use the mouse as a model system for developing and refining hypotheses to be tested directly in species of interest. In this brief review, the value of the preimplantation mouse embryo as a model is considered, both as a model for other species and as a model for the mouse, as understanding the virtues and limitations of the mouse as a model system is essential to its appropriate use.     

Disruption of the cytokeratin filament network in the preimplantation mouse embryo

The distribution of the cytokeratin network in the intact preimplantation mouse embryo and the role of cytokeratin filaments in trophectoderm differentiation were investigated by means of whole-mount indirect immunofluorescence microscopy and microinjection of anti-cytokeratin antibody. Assembled cytokeratin filaments were detected in some blastomeres as early as the compacted 8-cell stage. The incidence and organization of cytokeratin filaments increased during the morula stage, although individual blastomeres varied in their content of assembled filaments. At the blastocyst stage, each trophectoderm cell contained an intricate network of cytokeratin filaments, and examination of sectioned blastocysts confirmed that extensive arrays of cytokeratin filaments were restricted to cells of the trophectoderm. Microinjection of anticytokeratin antibody into individual mural trophectoderm cells of expanded blastocysts resulted in a dramatic rearrangement of the cytokeratin network in these cells. Moreover, antibody injection into 2-cell embryos inhibited assembly of the cytokeratin network during the next two days of development. Despite this disruption of cytokeratin assembly, the injected embryos compacted and developed into blastocysts with normal morphology and nuclear numbers. These results suggest that formation of an elaborate cytokeratin network in preimplantation mouse embryos is unnecessary for the initial stages of trophectoderm differentiation resulting in blastocyst formation.