Control of gap junction formation in early mouse embryos

Overview of junctional complexes during mammalian early embryonic development

Cell-cell junctions form strong intercellular connections and mediate communication between blastomeres during preimplantation embryonic development and thus are crucial for cell integrity, polarity, cell fate specification and morphogenesis. Together with cell adhesion molecules and cytoskeletal elements, intercellular junctions orchestrate mechanotransduction, morphokinetics and signaling networks during the development of early embryos. This review focuses on the structure, organization, function and expressional pattern of the cell-cell junction complexes during early embryonic development. Understanding the importance of dynamic junction formation and maturation processes will shed light on the molecular mechanism behind developmental abnormalities of early embryos during the preimplantation period.

Connexins in the development and physiology of stem cells

Connexins (Cxs) form gap junction (GJ) channels linking vertebrate cells. During embryogenesis, Cxs are expressed as early as the 4-8 cell stage. As cells differentiate into pluripotent stem cells (PSCs) and during gastrulation, the Cx expression pattern is adapted. Knockdown of Cx43 and Cx45 does not interfere with embryogenic development until the blastula stage, questioning the role of Cxs in PSC physiology and development. Studies in cultivated and induced PSCs (iPSCs) showed that Cx43 is essential for the maintenance of self-renewal and the expression of pluripotency markers. It was found that the role of Cxs in PSCs is more related to regulation of transcription or cell-cell adherence than to formation of GJ channels. Furthermore, a crucial role of Cxs for the self-renewal and differentiation was shown in cultivated adult mesenchymal stem cells. This review aims to highlight aspects that link Cxs to the function and physiology of stem cell development.

Therapeutic strategies targeting connexins

The connexin family of channel-forming proteins is present in every tissue type in the human anatomy. Connexins are best known for forming clustered intercellular channels, structurally known as gap junctions, where they serve to exchange members of the metabolome between adjacent cells. In their single-membrane hemichannel form, connexins can act as conduits for the passage of small molecules in autocrine and paracrine signalling. Here, we review the roles of connexins in health and disease, focusing on the potential of connexins as therapeutic targets in acquired and inherited diseases as well as wound repair, while highlighting the associated clinical challenges.

Mouse Embryo Compaction

Compaction is a critical first morphological event in the preimplantation development of the mammalian embryo. Characterized by the transformation of the embryo from a loose cluster of spherical cells into a tightly packed mass, compaction is a key step in the establishment of the first tissue-like structures of the embryo. Although early investigation of the mechanisms driving compaction implicated changes in cell-cell adhesion, recent work has identified essential roles for cortical tension and a compaction-specific class of filopodia. During the transition from 8 to 16 cells, as the embryo is compacting, it must also make fundamental decisions regarding cell position, polarity, and fate. Understanding how these and other processes are integrated with compaction requires further investigation. Emerging imaging-based techniques that enable quantitative analysis from the level of cell-cell interactions down to the level of individual regulatory molecules will provide a greater understanding of how compaction shapes the early mammalian embryo.

The States of Pluripotency: Pluripotent Lineage Development in the Embryo and in the Dish

The pluripotent cell lineage of the embryo comprises a series of temporally and functionally distinct intermediary cell states, the epiblast precursor cell of the newly formed blastocyst, the epiblast population of the inner cell mass, and the early and late epiblast of the postimplantation embryo, referred to here as early and late primitive ectoderm. Pluripotent cell populations representative of the embryonic populations can be formed in culture. Although multiple pluripotent cell states are now recognised, little is known about the signals and pathways that progress cells from the epiblast precursor cell to the late primitive ectoderm in the embryo or in culture. The characterisation of cell states is most advanced in mouse where conditions for culturing distinct pluripotent cell states are well established and embryonic material is accessible. This review will focus on the pluripotent cell states present during embryonic development in the mouse and what is known of the mechanisms that regulate the progression of the lineage from the epiblast precursor cell and the ground state of pluripotency to the late primitive ectoderm present immediately prior to cell differentiation.

Number of blastomeres and distribution of microvilli in cloned mouse embryos during compaction

The events resulting in compaction have an important influence on the processes related to blastocyst formation. To analyse the quality of the embryos obtained by somatic cell nuclear transfer (SCNT) in aspects different from previous studies, not only the number of blastomeres of cloned embryos during the initiation of compaction, but also the distribution of microvilli in cloned, normal, parthenogenetic, and tetraploid embryos before and after compaction was preliminarily investigated in mouse. Our results showed that during compaction the number of blastomeres in SCNT embryos was fewer than that in intracytoplasmic sperm injection (ICSI) embryos and, before compaction, there was a uniform distribution of microvilli over the blastomere surface, but microvilli became restricted to an apical region after compaction in the four types of embryos. We also reported here that the time course of compaction in SCNT embryos was about 3 h delayed compared with that in ICSI embryos, while there was no significant difference between SCNT and ICSI embryos when developed to the 4-cell stage. We concluded that: (i) the cleavage of blastomeres in cloned embryos was slow at least before compaction; (ii) the distribution of microvilli in cloned, normal, parthenogenetic, and tetraploid embryos was coherent before and after compaction; and (iii) the initiation of compaction in SCNT embryos was delayed compared with that of ICSI embryos.

The use of antibodies to gap junction protein to explore the role of gap junctional communication during development

Antibodies raised against the major 27 kDa protein electrophoretically eluted from isolated gap junctions and affinity purified against the antigen have been used to explore the role of communication through gap junctions in the early amphibian and mouse embryos. In both species, injection of the antibodies into one cell completely blocks both dye transfer and electrical coupling between cells connected by gap junctions. In the amphibian embryo the generation of a communication-incompetent clone of cells leads to patterning defects in the region derived from the antibody-injected cell. In the mouse embryo, blocking cell-to-cell communication leads to decompaction of the communication-incompetent cells. The possible significance of these findings in relation to development in general and to the organization of the first transporting epithelia to appear during development is discussed.

In vitro tagging of embryos with nanoparticles

PURPOSE

To develop an in vitro method for tagging embryos and to compare the development of the embryos after nanoparticles injection versus externally-applied nanoparticles derived from either polystyrene or polyacrylonitrile.

METHODS

Each mouse 1-cell embryo (the selected test-model) was either: (a) injected by intracytoplasmic injection or (b) co-incubated with different nanoparticles at 37 degrees C, 5% CO2 in air. The embryos were assessed after 2 and 6 days of culture.

RESULTS

Embryo development was similar for externally-applied polystyrene nanoparticles and control (97.6 +/- 2.7 versus 100.0 +/- 0%) but different for polyacrylonitrile nanoparticles (90.0 +/- 2.8 %) on day 2. However, the results were similar on Day 6. Injected embryos were linked to lower percent development on Day 2. Few injected embryos reached blastocyst stage on Day 6 after a brief UV-fluorescence exposure.

CONCLUSIONS

Tagging embryos by external polystyrene-based nanoparticles was the better method when compared with injected nanoparticles. Larger nanoparticles in microsphere range were easier to qualitate. Inhibited hatching limited their use beyond the blastocyst stage.

Gap Junction Formation and Connexin Distribution in Pig Trophoblast before Implantation

This study describes the gap junctions in extraembryonic cell layers of the preimplantation pig embryo (trophectoderm and endoderm constituting the trophoblast). Using specific antibodies against connexins 31, 32 and 43, we found these connexins in embryos by immunodetection using Western blot and immunofluorescence analysis. By immunofluorescence, the first foci of connexin 31 were detected in the four-cell stage blastomeres, and the first diffuse gap junctions appeared at the eight-cell stage. Intercellular communication was observed with Lucifer yellow transfer to start also at the eight-cell stage around the onset of compaction. Typical gap junctions developed in the trophectoderm of blastocysts, as observed by transmission electron microscopy of thin sections and freeze-fracture replicas. Connexin proteins were differently expressed in time and space: connexin 31 was continuously present in trophectoderm, connexin 32 was essentially found in endoderm during elongation; connexin 43 was distributed in both trophectoderm and endoderm during blastulation and expansion. Connexin 43 was also found in two isoforms, phosphorylated or not, at day 14. Such developmentally regulated connexin expression may be essentially useful to control the exponential growth of trophoblast in preimplantation pig blastocysts.

Induction of Oct-3/4 expression in somatic cells by gap junction-mediated cAMP signaling from blastomeres

We report the induction of embryonic gene expression in epithelial HC-11 cells upon communication with blastomeres in compacting mouse embryos. In contrast to NIH3T3 fibroblasts, HC-11 epithelial cells form gap junctions with blastomeres after injection into cleavage-stage embryos, as shown by targeting of phosphorylated connexin43 (pCx43) to areas of cell-to-blastomere contact and dye coupling. This was accompanied by expression of the embrvo-specific transcription factor, Oct-3/4, in the HC-11 cells. Dye coupling and Oct-3/4 expression were abolished with heptanol and 18beta- glycyrrhetinic acid, two gap junction blockers. Oleamide, which blocks gap junction-mediated communication but not electrical conductance, also inhibited Oct-3/4 expression in HC-11 cells, suggesting that Oct-3/4 induction results from transfer of molecules of < 1 kDa through gap junctions. Inhibition of cAMP signaling in blastomeres abolishes Oct-3/4 expression in somatic cells despite gap junction formation. In addition, reprogramming of NIH3T3 fibroblasts in an extract of HC-11 cells enabled assembly of pCx43 and Oct-3/4 expression after contact of the reprogrammed cells with blastomeres. We propose that gap junction-mediated cAMP signaling between blastomeres and somatic cells results in changes in somatic cell gene expression.

Increase of intracellular Ca2+ and relocation of E-cadherin during experimental decompaction of mouse embryos

To determine the role of intracellular Ca2+ in compaction, the first morphogenetic event in embryogenesis, we analyzed preimplantation mouse embryos under several decompacting conditions, including depletion of extracellular Ca2+, blocking of Ca2+ channels, and inhibition of microfilaments, calmodulin, and intracellular Ca2+ release. Those treatments induced decompaction of mouse morulae and simultaneously induced changes in cytosolic free Ca2+ concentration and deregionalization of E-cadherin and fodrin. When morulae were allowed to recompact, the location of both proteins recovered. In contrast, actin did not change its cortical location with compaction nor with decompaction-recompaction. Calmodulin localized in areas opposite to cell-cell contacts in eight-cell stage embryos before and after compaction. Inhibition of calmodulin with trifluoperazine induced its delocalization while morulae decompacted. A nonspecific rise of intracellular free Ca2+ provoked by ionomycin did not affect the compacted shape. Moreover, the same decompacting treatments when applied to uncompacted embryos did not produce any change in intracellular Ca2+. Our results demonstrate that in preimplantation mouse embryos experimentally induced stage-specific changes of cell shape are accompanied by changes of intracellular free Ca2+ and redistribution of the cytoskeleton-related proteins E-cadherin, fodrin, and calmodulin. We conclude that intracellular Ca2+ specifically is involved in compaction and probably regulates the function and localization of cytoskeleton elements.

The microenvironment created by non-blocking embryos in aggregates may rescue blocking embryos via cell-embryo adherent contacts

Under our culture conditions, mouse embryos from the BALB/c inbred mouse strain develop successfully in culture only from the late 2-cell stage onwards (so-called 2-cell block), whether or not EDTA is added to the culture medium. (CBA x C57BL) F2 embryos do not exhibit a 2-cell block. Medium conditioned by culture of non-blocking embryos from the 2-cell to the 8-cell stage did not improve the development of blocking embryos, nor did co-culture of blocking and non-blocking embryos, with or without conditioned medium. On the other hand phytohaemagglutinin (PHA)-assisted aggregation of an early 2-cell BALB/c embryo with five surrounding non-blocking F2 embryos (2-cell or 8-cell) or five BALB/c 8-cell embryos allowed the early 2-cell BALB/c embryos to develop into blastocysts within 72 h. Aggregation of blocking BALB/c 2-cell embryos with each other had no 'rescue' effect. When blocking and non-blocking 2-cell embryos were aggregated together, an integrated blastocyst was formed; but when the early 2-cell BALB/c embryos were aggregated with non-blocking 8-cell embryos, the blocking embryos formed a separate small blastocyst, which nonetheless retained adherent contact with the non-blocking embryos throughout the culture period. Ultrastructural analysis showed that 2-cell embryos aggregated with the aid of PHA form close adherent cell contacts up to several micrometres in length.

Temporal control of gap junction assembly in preimplantation mouse embryos

The de novo assembly of gap junctions during compaction in the 8-cell stage of mouse development is a temporally regulated event. We have performed experiments designed to explore the relationship between this event and DNA replication in the second, third, and fourth cell cycles after fertilization. Inhibition of DNA synthesis by continuous treatment with the DNA synthesis inhibitor, aphidicolin, during the third and fourth cell cycles had no effect on the establishment of gap junctional coupling during compaction. However, a delay of 10 hours in DNA synthesis during the second cell cycle caused by a transient aphidicolin treatment resulted in the failure of gap junctional coupling at the time of compaction. Thus the timing of establishment of gap junctional coupling, like the timing of compaction itself, is linked to DNA replication in the 2-cell stage. Immunofluorescence analysis showed that the failure of gap junctional coupling after aphidicolin treatment in the 2-cell stage is correlated with the failure of nascent connexin43 to be inserted into plasma membranes. We propose that the developmental ‘clock’ that controls gap junction assembly is set in motion by events surrounding the second cycle of DNA replication, and that this ‘clock’ ultimately controls the post-translational processing of connexin43.

Functional analysis of amino acid sequences in connexin43 involved in intercellular communication through gap junctions

Gap junctions allow direct communication between cells without recourse to the extracellular space and have been widely implicated as important mediators of cell-cell signalling. They are constructed from the connexin proteins, which form a large family, and individual connexins show complex spatial and temporal variations in their expression patterns. Understanding how this variation contributes to the control of intercellular signalling, both in the adult and during embryonic development, is an important problem that would be aided by reagents that interfere with gap junctional communication through specific connexins. We have begun to address this issue by raising antibodies to peptides derived from connexin43 and connexin32. Connexin43 peptides were located in the amino terminus, cytoplasmic loop and carboxytail. Connexin32 peptides came from the cytoplasmic loop and the first extracellular loop. Immunoblotting and immunostaining properties of purified IgGs were characterized on mouse heart, liver and the 8- to 16-cell mouse embryo. Effects on transfer through gap junctions were assessed in the fully compacted 8-cell mouse embryo by co-injection with Lucifer Yellow or Cascade Blue. Embryos were maintained in culture to assess the developmental consequences of injection. Peptide competition was used to confirm the specificity of immunostaining and inhibition of dye transfer. All connexin specific antibodies recognized their parent connexin on immunoblots and showed no 43/32 cross-reactivity. The connexin32 extracellular loop antibody recognized both connexin 32 and 43 on immunoblots, as predicted by the amino acid sequence homology in this region, but did not immunostain intact gap junctions. Connexin specific antibodies that immuno-stained showed the predicted connexin specificity. Antibodies to either connexin43 amino acids (AA) 1–16 (amino terminus) or AA 101–112 (cytoplasmic loop) neither immunostained nor prevented functional communication through 8-cell embryo gap junctions. Antibodies to AA 123–136 and AA 131–142 in the cytoplasmic loop immunostained heart and 8-cell embryo gap junctions and blocked transfer through them with high efficiency. Fab' fragments were equally effective. Peptide competition showed that both antibodies contained epitopes within AA 131–136 of connexin43. Antibodies against AA 313–324 in the carboxytail immunostained heart and the 8-cell embryo and, as IgGs, prevented dye transfer. Fab' fragments were ineffective. All connexin43 antibodies that blocked gap junctional communication between cells of the 8-cell mouse embryo induced non-communicating cells subsequently to withdraw from compaction.(ABSTRACT TRUNCATED AT 400 WORDS)

Cell adhesion and gap junction formation in the early mouse embryo are induced prematurely by 6-DMAP in the absence of E-cadherin phosphorylation

Compaction of the mouse embryo, which takes place at the 8-cell stage, is dependent upon the adhesion molecule E-cadherin (uvomurulin), but does not require protein synthesis, suggesting that post-translational modification(s) is (are) implicated in the setting up of this phenomenon. The demonstration recently that E-cadherin is phosphorylated at the 8-cell stage just before compaction supports this theory. In this work we used 6-dimethylaminopurine, a serine-threonine kinase inhibitor, to investigate the role of protein phosphorylation in compaction of mouse embryos. 6-dimethylaminopurine is able to induce cell flattening and gap junction formation prematurely at the 4-cell stage; however, it does not induce cell surface polarization, as occurs during normal compaction. 6-dimethylaminopurine-induced premature flattening is inhibited when the embryos are cultured in the presence of an anti-E-cadherin antibody or without extra-cellular Ca2+, demonstrating that this process requires functional E-cadherin; whereas cell flattening and gap junction formation take place in the absence of E-cadherin phosphorylation, suggesting that its phosphorylation is not required normally for these events. The relationship between E-cadherin-mediated cell flattening and gap junction formation during compaction is discussed.

A maternal factor affecting mouse blastocyst formation

Normal development of the mouse embryo requires the presence of both paternal and maternal genomes. This is due to functional differences having their origin in a differential imprinting of parental genomes. Furthermore, several lines of evidence show that the very early interactions between egg cytoplasm and pronuclei may influence the programming of the embryonic genome and modulate the functional inequality of the parental contribution even during preimplantation stages. In this paper, we show that a factor present in ovulated oocytes of the mouse mutant strain DDK and therefore of maternal origin prevents the formation of the blastocyst. This factor, which acts via an interaction with the paternal genome, is present in oocytes as an RNA and is still active in preimplantation embryos. This is the first direct evidence of such a maternal control in the mouse.

Morulae at compaction and the pattern of protein synthesis in mouse embryos

Compaction of mouse embryos at the 8-cell stage causes a drastic change in cell form and in cell-to-cell contacts in 3-4 h. We have studied the effect of inhibitors of transcription (alpha-amanitin), DNA replication (aphidicolin) and compaction (cytochalasin D, EGTA, alpha-lactalbumin and Con A) on the pattern of protein synthesis using gel electrophoresis. Our results show that the pattern of protein synthesis is regulated principally by passage through S phase during each early cell cycle rather than by de novo transcription, while changes induced in cell form or contacts do not alter the pattern significantly.

Connexin trafficking and the control of gap junction assembly in mouse preimplantation embryos

Gap junction assembly in the preimplantation mouse embryo is a temporally regulated event, beginning a few hours after the third cleavage during the morphogenetic event known as compaction. Recently, we demonstrated that both mRNA and protein corresponding to connexin43, a gap junction protein, accumulate through preimplantation development beginning at least as early as the 4-cell stage. Using an antibody raised against a synthetic C-terminal peptide of connexin43, this protein was shown to assemble into gap junction-like plaques beginning at compaction (G. Valdimarsson, P. A. De Sousa, E. C. Beyer, D. L. Paul and G. M. Kidder (1991). Molec. Reprod. Dev. 30, 18–26). The purpose of the present study was to follow the fate of nascent connexin43 during preimplantation development, from synthesis to plaque insertion, and to learn more about the control of gap junction assembly during compaction. Cell fractionation and reverse transcription-polymerase chain reaction were employed to show that connexin43 mRNA is in polyribosomes at the 4-cell stage, suggesting that synthesis of connexin43 begins at least one cell cycle in advance of when gap junctions first form. The fate of nascent connexin43 was then followed throughout preimplantation development by means of laser confocal microscopy, using two other peptide (C-terminal)-specific antibodies. As was reported previously, connexin43 could first be detected in gap junction-like plaques beginning in the 8-cell stage, at which time considerable intracellular immunoreactivity could be seen as well. Later, connexin43 becomes differentially distributed in the apposed plasma membranes of morulae and blastocysts: a zonular distribution predominates between outside blastomeres and trophectoderm cells whereas plaque-like localizations predominate between inside blastomeres and cells of the inner cell mass. The cytoplasmic immunoreactivity in morulae was deemed to be nascent connexin en route to the plasma membrane since it could be abolished by treatment with cycloheximide, and redistributed by treatment with monensin or brefeldin-A, known inhibitors of protein trafficking. Treatment of uncompacted 8-cell embryos with either monensin or brefeldin-A inhibited the appearance of gap junction-like structures and the onset of gap junctional coupling in a reversible manner. These data demonstrate that the regulated step in the onset of gap junction assembly during compaction is downstream of transcription and translation and involves mobilization of connexin43 through trafficking organelles to plasma membranes.

Cell-to-cell coupling in early-stage bovine embryos: A preliminary report

Gap junction communication has been implicated in providing positional information within an embryo. This positional information is then used to direct the differentiation of the early embryo. To begin to gain an assessment of the cell-to-cell communication observed in the early bovine embryo, fluorescein (5%) was microinjected into single blastomeres of freshly collected embryos. Dye communication was not observed in any of the 8-to 16-cell stage embryos. Very limited dye coupling was observed in compact morula (18%) and expanded blastocysts (25%). Interestingly, none of the expanded blastocysts resulting from in vitro maturation and in vitro fertilization showed any dye coupling. The degree of coupling observed in the bovine embryo was less than that observed in compact morula mouse embryos, where almost all (95%) embryos showed dye coupling. This experimental data is discussed in context with previous electron microscopy data.

Endogenous and exogenous modulation of gap junctional intercellular communication: toxicological and pharmacological implications

During the evolution of single-celled organisms to multicellular metazoans, a family of highly conserved genes coding for proteins (connexins), which as hexameric units (connexins), has evolved to form intercellular channels (gap junctions). These gap junctions allow ions and small molecular weight molecules to flow between coupled cells, thereby facilitating synchronization of electrotonic or metabolic cooperation. Control of cell proliferation, cell differentiation and adaptive responses of differentiated cells have been speculated to be biological roles of gap junctions. The regulation of these gap junctions can occur at the transcriptional, translational and posttranslational levels. Transient downregulation by endogenous or exogenous chemicals can bring about adaptive or maladaptive consequences depending on circumstances. Stable abnormal regulation of gap junction function has been associated with the activation of several oncogenes. Several tumor suppressor genes have also been associated with the up-regulation of gap junction function. Since gap junctions exist in all organs of the multi-cellular organisms, the dysfunction of these gap junctions by various toxic chemicals which have cell type/tissue/organ specificity could bring about very distinct clinical consequences, such as embryo lethality or teratogenesis, reproductive dysfunction in the gonads, neurotoxicity of the CNS system, hyperplasia of the skin, and tumor promotion of initiated tissue. Understanding how many non-mutagenic chemicals might alter normal gap junction function should form the basis of "epigenetic" toxicology. On the other hand, restoring normal gap junction function to cells which have dysfunctional intercellular communication could be the basis for a new approach for therapeutic pharmaceuticals.

The genetic program for preimplantation development

This review summarizes information on accumulation profiles of individual gene transcripts in preimplantation development. Most of the information is from the mouse, but some data from other species are reviewed as well. The principal finding is that the transcription of most genes is not temporally linked with any of the three morphogenetic transitions (compaction, cavitation, and blastocoel expansion) that characterize this period. Most genes that are expressed during preimplantation development of the mouse are already being transcribed in the 4-cell stage, and some clearly begin as early as the 2-cell stage. Once activated, a gene continues to be transcribed at least into the blastocyst stage, resulting in continuous mRNA accumulation. Thus the pattern of gene transcription established at the time of genomic activation in the 2-cell stage is perpetuated into the blastocyst, with a few additions along the way. This information is interpreted in light of previous findings concerning the sensitivity of morphogenetic transitions to inhibition of gene expression. The lack of a clear relationship between the timing of expression of most genes and the schedule of morphogenesis leads one to conclude that temporal regulation is imposed downstream of transcription and translation. This conclusion is substantiated by a consideration of factors controlling the events of compaction.

Zygotic expression of the connexin43 gene supplies subunits for gap junction assembly during mouse preimplantation development

De novo assembly of gap junctions begins during compaction in the eight-cell stage of mouse development, and intercellular coupling mediated by gap junctions appears to be required for maintenance of the compacted state. We have begun to explore the expression of the family of genes encoding the connexins, the proteins that form the gap junction channels. We recently reported that a protein with antigenic and size similarity with connexin32, the rat liver gap junction protein, is inherited as an oogenetic product by the mouse zygote, but its gene appears not to be transcribed prior to implantation (Barron et al., Dev Genet 10:318-323, 1989). Here we report that another member of this gene family, connexin43, is transcribed by the embryonic genome from shortly after the time of genomic activation. As revealed by Northern blotting, connexin43 mRNA is absent from ovulated oocytes, becomes detectable in the 4-cell stage, and accumulates steadily thereafter to reach a maximum in blastocysts. In contrast, no transcripts of connexin26 could be detected in any preimplantation stage. A protein with antigenic and size similarity with connexin43 from rat heart was found by Western blotting to accumulate from the four-cell stage onward. Immunofluorescence analysis with embryo whole mounts was used to demonstrate that this protein is incorporated into punctate interblastomeric foci during compaction, consistent with its assembly into gap junction plaques. We conclude that connexin43 is one member of the connexin gene family whose zygotic expression is critical for preimplantation morphogenesis.

Developmental regulation of gap junction gene expression during mouse embryonic development

The expression of products from three different gap junction genes (alpha 1, beta 1 and beta 2) was studied in pre- and postimplantation mouse embryos, during organogenesis, during differentiation of F9 teratocarcinoma cells, and in cultured embryonic stem (ES) cells. In this analysis, the following results were obtained. 1) Pre- and postimplantation mouse embryos. The alpha 1 transcript was the earliest gap junction RNA detected (in the 4 cell stage embryo) and its abundance increased significantly throughout subsequent development. 2) Organogenesis. Evidence was obtained for developmental expression of these three different gap junction genes during early embryogenesis and throughout the late stages of organogenesis. The expression patterns for these genes may be related to differences in gap junctional communication requirements for fetal organ development versus neonatal and adult organ function, or the utilization of different genes by different cell types during organogenesis. 3) During the differentiation of F9 cells in culture, expression of these three genes was modulated. Thus, this is the first evidence for modulation of gap junction gene expression during the differentiation of a single cell type in culture. 4) In an ES cell culture line, alpha 1 was the only gap junction gene product detected. This is consistent with the findings of alpha 1 expression in the embryonic inner cell mass region and in undifferentiated teratocarcinoma cells.

Effect of cell contact on regionalization of mouse embryos

Cytochemical demonstrations of 5'-nucleotidase and alkaline phosphatase reveal the activity of these enzymes on regions of cell apposition from the late four-cell stage onward. These enzyme activities also appear on regions of artificial cell contact between aggregated embryos having more than four cells. Cytochemistry of single two-cell embryos does not reveal 5'-nucleotidase nor alkaline phosphatase activity, however, these enzyme activities appear at both the artificial and natural contacts in chimaeras of two two-cell embryos. We interpret these results as meaning: (1) that cell contact causes the regionalization of 5'-nucleotidase and alkaline phosphatase activity on the cell surface, (2) that these enzyme activities can be induced or enhanced by contact between two two-cell embryos, (3) that a signal is transmitted from the artificial to the natural contact.

Activation of protein kinase C triggers premature compaction in the four-cell stage mouse embryo

During mouse preimplantation development, the cells of the mouse embryo undergo a progressive subcellular reorganization at compaction, which eventually results in the formation of two distinct cell types. We have investigated the effect that activators of the Ca2(+)-phospholipid-dependent protein kinase (PKC) have on mouse compaction. Phorbol ester activation of PKC caused premature compaction of four-cell embryos within a few minutes of addition followed by a prolonged decompaction phase after 1 hr. This response was dose-dependent to concentrations as low as 250 pg/ml. Diacylglycerides also caused compaction; however, it was more sustained than with phorbol esters and was not followed by a phase of decompaction. Inhibition of PKC with sphingosine blocks induced compaction in a dose-dependent manner and also blocks normal compaction of eight-cell embryos. A monoclonal antibody to the cell adhesion molecule, E-cadherin, which mediates mouse embryo compaction, completely blocks compaction induced by these activators of PKC. Indirect immunofluorescence with a monoclonal antibody to E-cadherin indicates that PKC activation causes a rapid shift in the localization of this cell adhesion molecule, which coincides with the observed compaction. These results suggest that PKC plays a role in the initiation of compaction through its effect either directly or indirectly on E-cadherin.

Development of cytoskeletal connections between cells of preimplantation mouse embryos

Observations by scanning electron microscopy of mouse cleaving embryos reveal the presence of long microvilli around cell contact regions that often bridge the gap between blastomeres. These microvilli correspond, in detergent-extracted morulae, to strings connecting the cortical cytoskeletons of adjoining cells. They appear about 4 h after compaction in synchronized cultures. Transmission electron microscopy, heavy meromyosin decoration and DNase I digestion show that cytoskeletal connections contain bundles of actin microfilaments. The establishment of cytoskeletal connections does not require immediate protein synthesis, as shown by incubation with cycloheximide. Diverse treatments that interfere with compaction were tested for the development of cytoskeletal connections: culture media with low Ca²⁺ and/or Mg²⁺, or EGTA, or α-lactalbumin, do not prevent the establishment of connections, while colchicine delays their appearance and cytochalasin D suppresses it. The relation between cytoskeletal connections, compaction and blastulation is discussed.

Octaploid mouse embryos produced by electrofusion polarize and cavitate at the same time as normal embryos

We created enlarged octaploid mouse blastomeres by subjecting four-cell embryos to a large (greater than 2,000 V/cm) dc field of brief duration (10 microseconds). This electrofusion pulse caused three to four of the blastomeres to fuse in 60% of the embryos tested. Modifications of fusion chamber and medium enabled fusion of up to 20 embryos per pulse, greatly increasing the yield for this fusion method. The effectiveness of the electrofusion pulse depended upon such parameters as embryonic cell cycle time and the pH and temperature of the electrofusion medium. There was no discernable lag in the onset of the third cleavage division or the time of cavitation in fused blastomeres. These fused blastomeres also underwent polarization of their apical surfaces at the same time as controls in spite of their increased cell size. These results suggest that octaploid mouse blastomeres created via electrofusion divide normally through the blastocyst stage and polarize at the same time and in the same sequence as smaller control blastomeres. This suggests that the mechanisms underlying cell division, cavitation, and cortical polarization are not affected by changes in cellular size or ploidy.

Abnormal development and dye coupling produced by antisense RNA to gap junction protein in mouse preimplantation embryos

Antisense RNA to the 27/32-kDa rat liver gap junction (GJ) protein was used to explore the role of GJs in preimplantation embryos. When all blastomeres of two- and four-cell embryos were injected with GJ antisense RNA, the percentage of embryos compacted at 60 hr of development was reduced to less than 20%, while 90% of uninjected embryos and 75% of embryos injected with an unrelated RNA were compacted. When most cells of compacted eight-cell embryos were injected with the GJ antisense RNA, 20% of the embryos were decompacted and only 5% had developed to the blastocyst stage at 90 hr, when blastulation had occurred in 90% of the control embryos. When antisense RNA was injected in one blastomere of four-cell embryos, 40% of the embryos presented a large cell that was not included in the compacted embryo at the time of compaction, and an additional 30% of the embryos had two smaller, excluded blastomeres. These excluded cells were identified as the injected cell with a rhodamine-conjugated dextran marker. To assess effects on junctional communication, one blastomere of some embryos was injected with Lucifer yellow, a GJ-penetrating dye, at various times after a blastomere was injected with antisense RNA. The dye was visible in the whole cell mass of control embryos, but it was excluded from a portion of experimental embryos when the delay between the RNA and the Lucifer yellow injections was 1 hr or longer.

A close relationship between microvilli and metabolic cooperation deficiency in embryonal carcinoma cells

A revertant clone has been isolated from the metabolic cooperation-deficient embryonal carcinoma clone PT2md1. In PT2md1, its cooperation-competent parent, and its cooperation-competent revertant an inverse correlation has been demonstrated between cooperation competence and the incidence of microvilli. This demonstration, together with a similar correlation previously reported in an independently isolated series of cell lines, establishes a close causal relationship between the incidence of microvilli and communication deficiency.

Preimplantation mammalian aggregation and injection chimeras

The preimplantation embryo is highly resilient to experimental manipulations. A specific manipulation that has revealed many clues to the developmental process is chimera production. Chimeras have been used to describe the importance of developmental characteristics of embryonic cells and how these characteristics are involved with developmental fate. These characteristics have been monopolized in the production of interspecific chimeras and the production of transgenic animals. This review attempts to discuss the major factors affecting preimplantation mammalian embryo chimera production.

Connexin32, a gap junction protein, is a persistent oogenetic product through preimplantation development of the mouse

Gap junctions appear de novo during compaction in the eight-cell stage of mouse development. This is a critical event in the life of the embryo, because gap junctional intercellular communication is an essential requirement for maintaining compaction and, hence, for development of the blastocyst. Recently, a family of genes encoding gap junction proteins (connexins) has been identified and cloned, and we have taken advantage of the availability of antibodies and cDNA probes to investigate the expression of these genes in early development. We found that a protein with antigenic and size similarity to the "liver" gap junction protein, connexin32, is present throughout preimplantation development from the zygote through the late morula. Connexin32 mRNA, however, could not be detected in any preimplantation stage. This, and the presence of connexin32 in zygotes before activation of embryonic transcription, leads us to conclude that this protein is inherited as an oogenetic product that persists well beyond the transition from the oogenetic to embryonic program of gene expression. Furthermore, we found that mRNA for another gap junction protein, connexin43, is fairly abundant in preimplantation embryos. We conclude that it is more likely connexin43, and not connexin32, that is used to assemble new connexons as the level of intercellular coupling increases after compaction.

Chimerization of highly asynchronous murine blastomeres: developmental alteration?

Previous studies have shown that early embryos contain information that can alter the developmental fate of adjacent cells and transferred nuclei. In this report we show that a specific combination of cells from early murine embryos, a single blastomere from an eight-cell embryo placed under the zona pellucida with a two-cell embryo, results in a difference in incorporation of 3H-uridine and expression of two protein bands between the chimeric treatment group and the nonchimeric controls, a single blastomere from an eight-cell embryo in a separate zona pellucida and a two-cell embryo. The incorporation of 3H-uridine in the chimeric group and nonchimeric control group was significantly different at 45 hours after chimerization (P less than .02). A stage-specific protein band (52k) on a polyacrylamide gel detected with fluorography was found to be qualitatively different (present more often; P less than .01) and another stage-specific protein band (48k) was found to be quantitatively different (more protein; P = .07) in the chimeric treatment vs. the nonchimeric controls at 45 hours after chimerization. These results suggest communication between the cells resulting in a change in their incorporation of uridine and protein synthetic profiles.

Roles of cell junctions in gametogenesis and in early embryonic development

Recent reviews of the role of cell junctions in development have focused primarily upon functions related to the relatively subtle physiological modulation of their subunits in relation to fundamental developmental processes in a wide variety of organisms. There is, however, considerable support from numerous laboratories that the more radical modulation of the presence and number of junctional subunits in many diverse tissues may play a pivotal role in a wide spectrum of developmental phenomena ranging from gametogenesis to organogenesis. Since a great deal of recent interest in this latter subject has concentrated upon vertebrate systems including mammals, this review will examine the functional significance of the modulation of gap junctions, tight junctions and desmosomes in a developing idealized mammalian system from gamete formation to tissue and organ differentiation during embryo-genesis.

Gap junctional communication and compaction during preimplantation stages of mouse development

The ability of gap junction antibodies to block dye transfer and electrical coupling was examined in the compacted 8-cell mouse zygote. In control zygotes, Lucifer yellow injected into 1 cell transferred to the rest of the embryo. When antibodies raised against the major protein extracted from gap junctions were co-injected with Lucifer yellow, dye transfer failed in 86% of the zygotes tested and electrical coupling was almost completely inhibited. Subsequently, the antibody-containing cells were extruded. When the antibodies were injected into 1 cell at the 2-cell stage, 82% of the zygotes divided normally to the 8-cell stage. Cells containing gap junction antibodies were uncompacted, but continued to divide. We conclude that these antibodies inhibit gap junctional communication in the early mouse zygote and that communication through gap junctions may be involved in the maintenance of compaction.

Disruption of embryonic and fetal development due to preimplantation chemical insults: a critical review

Descriptive teratology has developed several fundamental precepts, two of which can now be challenged on the basis of experimental evidence. The first is that prior to implantation the developing embryo is not susceptible to survivable defects from chemical injury. The second is that developmental defects cannot be due to mutational events since rare events seem unlikely to explain alterations in large populations of cells. This review presents current experimental evidence demonstrating that the effects of chemical exposure on blastocyst stage embryos may be manifest long after the time of insult and that subtle nonlethal mutations may have a role in poor fetal performance after early chemical exposures.

Gap junction assembly in the preimplantation mouse conceptus is independent of microtubules, microfilaments, cell flattening, and cytokinesis

Gap junctions first appear during compaction in the eight-cell stage of mouse development. Their assembly can be initiated in the near absence of transcription and protein synthesis from the four-cell stage, indicating the existence of preformed precursors. We have investigated the temporal control of this event, focusing on the possible involvement of the cytoskeleton, cell flattening, and cytokinesis. Embryos in various cleavage stages were treated with cytochalasins, to disrupt microfilaments and block cell flattening, cytokinesis, or both, or nocodazole, to promote microtubule depolymerization. To assess their capacity to initiate gap junction assembly after such treatments, the embryos were then aggregated with communication-competent, compacted embryos that had been labeled with carboxyfluorescein diacetate. Passage of the fluorescent dye, carboxyfluorescein, from labeled to unlabeled embryo was taken as evidence that interembryonic junction formation had occurred. The capacity to assemble gap junctions was acquired at the normal time by embryos prevented by cytochalasin treatment from undergoing cell flattening or any cytokinesis from fertilization onward. Likewise, treatment with nocodazole beginning in the four-cell or early eight-cell stage did not interfere with gap junction assembly. Neither drug affected the inability of four-cell embryos to assemble gap junctions prematurely. We conclude that intact microfilament or microtubule networks are not required for gap junction assembly in this system, nor do they restrain junctional precursors from assembling prematurely. Furthermore, the timing of gap junction assembly is not linked to cell flattening, cytokinesis, or cell number.

Cell junctions during the early development of the sea urchin embryo (Paracentrotus lividus)

Thin sections, lanthanum tracer and the freeze-fracture technique revealed the presence of different types of cell junctions in early sea urchin (Paracentrotus lividus) embryos. During the first four cleavage cycles, which are characterized by synchrony of cell division, sister blastomeres were connected only by intercellular bridges, formed as a result of incomplete cytokinesis; no trace of other junctions was found at these stages. From the 16-cell stage onwards, septate junctions and gap junctions began to appear between blastomeres. It is postulated that cell-cell interactions may provide a mechanism for the propagation of signals necessary for the coordination of cell proliferation and differentiation.

Intercellular junctional coupling in preimplantation mouse embryos: effect of blocking transcription or translation

Gap junction formation in cleavage stage mouse embryos was examined by testing for ionic coupling or by observing the intercellular movement of the fluorescent dye, Lucifer yellow CH. Our results confirm that embryo-wide cell coupling, mediated by cell-to-cell membrane channels (gap junctions), is acquired in the 8-cell stage after compaction has begun. However, not all partially compacted embryos were found to be ionically or dye coupled, suggesting that the initiation of gap junction assembly is not necessarily triggered by the onset of cell flattening. The rate of fluorescent dye movement throughout the embryo was found to increase as embryos proceed through compaction and beyond, indicating that the number of gap junctional channels between blastomeres increases as development progresses. The inhibitors alpha-amanitin and cycloheximide were used to assess the requirement of new transcription and protein synthesis, respectively, for the onset of intercellular coupling and its progressive increase during compaction. Treatment conditions were chosen to bring about suppression of mRNA and protein synthesis within 2 hr. Ionic coupling was detected in almost all compacted 8-cell embryos treated with either inhibitor from the 4-cell stage. On the other hand, dye coupling was weak or undetectable in such embryos. We propose that a limited supply of junctional components is present by the 4-cell stage to serve as a pool of precursors for the first gap junctions to be assembled in the 8-cell stage. However, it is apparent that continued embryonic gene expression is required for the full extent of junctional coupling to be established.

Immunofluorescent localization of a monoclonally defined carbohydrate cell surface antigen (IIC3) during mouse development

A monoclonal antibody (anti-IIC3), raised against F9 embryonal carcinoma cells, detects an antigen which is first expressed at the compacted morula stage and segregates with the trophectoderm of the mouse blastocyst. We have further examined the expression of this antigen during embryonic development. Immunofluorescence experiments on sectioned embryos demonstrate that IIC3 expression is associated with the differentiation of extra-embryonic cell types. It is expressed at the cell surface of the trophectoderm of the attaching blastocyst and differentially by the two derivatives of this layer. The primary and secondary trophoblastic giant cells label intracellularly, whereas the cells of the ectoplacental cone and labyrinth placenta label at the cell surface. IIC3 is also expressed by the primitive endoderm of the blastocyst and subsequently by the visceral endoderm. The parietal endoderm does not express IIC3. Partial characterization of the IIC3 antigen with sugar hapten inhibition and glycosidase digestion experiments, suggests that the antigen is a lactosaminoglycan-like molecule, with galactose and N-acetylgalactosamine residues representing part of the antigenic determinant. Neuraminidase and fucosidase treatment exposed additional anti-IIC3-antigenic sites on the extra-embryonic ectoderm and chorion. A possible role for IIC3 in normal embryonic-uterine interactions is discussed.

Turing structures in an enzyme-induction system with gap junction-mediated non-linear diffusion

Two cells, each containing a reaction system modeling genetic induction, are coupled by diffusion. The substrate is moving through gap junctions, the number of which is regulated by the adjacent cells. This leads to a non-linear substrate diffusion term in the rate equations. Stability analysis reveals the conditions for the emergence of stable asymmetric solutions (dissipative structures). Due to non-linear diffusion rigid restrictions on the ratio of the two diffusion constants no longer exist. We demonstrate that substances operating as regulators of intercellular communication and participating in cellular metabolism may exhibit morphogenetic functions.