Sequence-dependent DNA replication in preimplantation mouse embryos

Lack of enhancer function in mammals is unique to oocytes and fertilized eggs

Previous studies have shown that the lack of novel coactivator activity in mouse oocytes and one-cell embryos (fertilized eggs) renders them incapable of utilizing Gal4:VP16-dependent enhancers (distal elements) but not promoters (proximal elements) in regulating transcription. This coactivator activity first appears in two- to four-cell embryos coincident with the major activation of zygotic gene expression. Here we show that whereas oocytes and fertilized eggs could utilize Sp1-dependent promoters, they could not utilize Sp1-dependent enhancers, although they showed promoter repression, which is a requirement for delineating enhancer function. In contrast, both Sp1-dependent promoters and enhancers were functional in two- to four-cell embryos. Furthermore, the same embryonic stem cell mRNA that provided the coactivator activity for Gal4:VP16-dependent enhancer function also provided Sp1-dependent enhancer function in oocytes. Therefore, the coactivator activity appears to be a requirement for general enhancer function. To determine whether the absence of enhancer function is a unique property of oocytes or a general property of other terminally differentiated cells, transcription was examined in terminally differentiated hNT neurons and their precursors, undifferentiated NT2 stem cells. The results showed that both cell types could utilize enhancers and promoters. Thus, in mammals, the lack of enhancer function appears to be unique to oocytes and fertilized eggs, suggesting that it provides a safeguard against premature activation of genes prior to zygotic gene expression during development.

Detection of microinjected genes in bovine preimplantation embryos with combined DNA digestion and polymerase chain reaction

We have developed a simple digestion-polymerase chain reaction (PCR) assay for a simultaneous transgene detection and sexing of pronucleus-injected bovine preimplantation embryos. Bovine embryos were microinjected with dam-methylated gene construct and cultured in vitro for 6-7 days after the injections. The developed blastocysts and compact morulae were bisected and the embryonic biopsies representing mainly trophoblasts were subjected to the digestion-PCR, while the biopsied embryos remained in culture. Embryonic DNA was released with proteinase K and the samples were digested with a Dpnl-Bal31 mixture before the PCR amplification of the transgene, bovine alpha S1-casein, and bovine Y-chromosome fragments in the same reaction. The whole assay from biopsy to electrophoresis took less than 6 hr. The digestion removed up to 50 fg of dam-methylated transgene copies (unintegrated or contaminants) and also a few hundred copies of contaminating PCR products from the embryonic samples. The digestion-PCR assay eliminated all transgene contaminations from noninjected blastocysts, which were exposed to the microinjection DNA during the stay in injection chambers, and reduced the amount of transgene-positive embryos among pronucleus-injected blastocysts as compared with unmodified PCR. Analysis of 486 microinjected bovine embryo biopsies in 13 separate experiments revealed that we were able to sex 398 (82%) of the biopsies and 77 (19%) of the biopsies were scored as transgene positive and 57 (14%) as transgene questionable. Upon reanalysis of 41 of the biopsied embryos, 38 (93%) of the embryos were observed to be transgene negative and 2 questionable in both assays and uneven distribution of transgene copies was observed in one embryo. The results from sexing were in accordance with biopsies and remaining embryos in 38 (93%) of the embryos.

A unique role for enhancers is revealed during early mouse development

Transcription and replication of genes in mammalian cells always requires a promoter or replication origin, respectively, but the ability of enhancers to stimulate these regulatory elements and the interactions that mediate this stimulation are developmentally acquired. The primary function of enhancers is to prevent repression, which appears to result from particular components of chromatin structure. Factors responsible for this repression are present in the maternal nucleus of oocytes and its descendant, the maternal pronucleus of mouse 1-cell embryos and in mouse 2-cell embryos, but are absent in the paternal pronucleus. Thus, enhancers are not needed to achieve efficient transcription and replication in paternal pronuclei. However, enhancers, even in the presence of their specific activation protein, are inactive prior to formation of a 2-cell embryo, suggesting that a coactivator essential for enhancer function is not available until zygotic gene expression begins. Furthermore, enhancer stimulation of transcription appears to be mediated through a promoter transcription factor, but this interaction can change as cells undergo differentiation, switching from a TATA-box independent to a TATA-box dependent mode.

Requirements for DNA transcription and replication at the beginning of mouse development

In mice, the first round of DNA replication occurs in fertilized eggs (1-cell embryos), while the onset of zygotic gene transcription begins approximately 20 hours after fertilization, a time that normally coincides with formation of a 2-cell embryo. One approach to investigating the mechanisms that control these developmentally regulated events has been to microinject plasmid DNA into the nuclei of mouse oocytes and embryos in order to determine the requirements for unique DNA sequences that regulate transcription and replication. The results from these and other studies have revealed two important mechanisms that regulate the beginning of animal development. The first is a time dependent "zygotic clock" of unknown detail that delays the onset of transcription, regardless of whether or not a 2-cell embryo is formed. The second is a mechanism that represses the activity of promoters and origins of replication specifically in maternal pronuclei of oocytes and 1-cell embryos, and in all nuclei of 2-cell embryos, regardless of their parental origin or ploidy. This repression is linked to chromatin, but the striking ability to relieve this repression with specific embryo-responsive enhancers first appears with formation of a 2-cell embryo. The need for a TATA-box to mediate enhancer stimulation of promoter activity appears even later when cell differentiation becomes evident. Thus, a biological clock delays transcription until both paternal and maternal genomes are replicated and remodeled from a post-meiotic state to one in which transcription is repressed by chromatin structure in a manner that can be relieved by cell-specific enhancers at appropriate times during development.

Fate of microinjected genes in preimplantation mouse embryos

The state of genes microinjected into mouse embryos was followed from the one-cell to the blastocyst stage using the polymerase chain reaction (PCR). Microinjected DNA was detected in all one-, two-, and four-cell injected embryos and in 44% of morula and 26% of blastocysts. Head-to-tail ligation of microinjected genes, a common feature of stably integrated transgene arrays, was detected in all embryos after injection of microinjected genes and occurred irrespective of the structure at the ends of the injected genes. Sensitivity of microinjected DNA to a methylation-dependent restriction endonuclease Dpn I was lost in all embryos by the two-cell stage (24 hr), indicating a change in DNA methylation, independent of transgene integration. Dissociation of blastomeres prior to compaction revealed a mosaic distribution of the microinjected DNA within the embryo and supports the notion that injected genes form a limited number of arrays, which segregate independently until they integrate into the genome or are degraded.

Plasmids bearing mammalian DNA-replication origin-enriched (ors) fragments initiate semiconservative replication in a cell-free system

Four plasmids containing monkey (CV-1) origin-enriched sequences (ors), which we have previously shown to replicate autonomously in CV-1, COS-7 and HeLa cells (Frappier and Zannis-Hadjopoulos (1987) Proc. Natl. Acad. Sci. USA 84, 6668-6672), were found to replicate in an in vitro replication system using HeLa cell extracts. De novo site-specific initiation of replication on plasmids required the presence of an ors sequence, soluble low-salt cytosolic extract, poly(ethylene glycol), a solution containing the four standard deoxyribonucleoside triphosphates and an ATP regenerating system. The major reaction products migrated as relaxed circular and linear plasmid DNAs, both in the presence and absence of high-salt nuclear extracts. Inclusion of high-salt nuclear extract was required to obtain closed circular supercoiled molecules. Replicative intermediates migrating slower than form II and topoisomers migrating between forms II and I were also included among the replication products. Replication of the ors plasmids was not inhibited by ddTTP, an inhibitor of DNA polymerase beta and gamma, and was sensitive to aphidicolin indicating that DNA polymerase alpha and/or delta was responsible for DNA synthesis. Origin mapping experiments showed that early in the in vitro replication reaction, incorporation of nucleotides occurs preferentially at ors-containing fragments, indicating ors specific initiation of replication. In contrast, the limited incorporation of nucleotides into pBR322, was not site specific. The observed synthesis was semiconservative and appeared to be bidirectional.

Regulation of gene expression in preimplantation mouse embryos: effects of the zygotic clock and the first mitosis on promoter and enhancer activities

Previous studies have reported that promoters requiring enhancers for full activity in mammalian somatic cells also require enhancers when injected into mouse two-cell embryos, whereas the same promoters can be expressed just as efficiently in the absence of an enhancer when injected into arrested one-cell embryos. Experiments were designed to determine whether this phenomenon reflected normal developmental changes at the beginning of mammalian development, or simply differences in the physiological states of these cells under the experimental conditions employed. The activity of three different promoters that function in a wide variety of mammalian cells was measured both in embryos whose morphological development was arrested and in embryos that continued development in vitro. Expression of the injected gene was related to the onset of zygotic gene expression ("zygotic clock"), the phase of the cell proliferation cycle, the use of aphidicolin to arrest cell proliferation, and formation of two-cell embryos in vitro and in vivo. The results demonstrated that promoter activity was tightly linked to zygotic gene expression, while the need for enhancers to stimulate promoter activity depended only on formation of a two-cell embryo. These results further support the hypothesis that the first mitosis induces a general repression of promoters prior to initiation of zygotic gene expression that is relieved specifically by enhancers.

A dual-circular plasmid structure dependent on DNA replication generated in monkey COS7 cells and cell extracts

When monkey COS7 cells are transfected with plasmids pSVod or pSV2-neo, a DNA structure can be detected consisting of two circular forms linked by a duplex bridge. Generation of this structure is enhanced by camptothecin, an inhibitor of DNA topoisomerase I. Generation of dual-circles in vitro, using a DNA replication system with added T-antigen, requires template DNA with an SV40 origin. Heterogeneous dual-circles can be visualized involving two initially independent molecules of different size. Implications for in vitro studies of certain types of recombination are discussed.

Interactions between the termini of adeno-associated virus DNA

The adeno-associated virus (AAV) genome is a linear, single polynucleotide chain with inverted terminal repeats of 145 bases. In order to test whether the terminal repeats at opposite ends of the genome have to be able to completely base-pair during DNA replication, we have created chimeric genomes in which an 11 base symmetrical sequence has been deleted from the terminal repeat at one end of the genome and replaced by a different 12 base symmetrical sequence. We have used these chimeric constructs either as a duplex insert in pBR322 or as purified duplex virion DNA to transfect adenovirus-infected HeLa cells. When chimeric duplex virion DNA was used, all of the progeny virions obtained after two cell passages contained DNA with wild-type sequences in both terminal repeats. When plasmid clones were used, the structure of virion DNA depended on the original orientation. If the mutant terminal repeat was originally at the right end of the genome (terminus of genetic map), all progeny terminal repeat sequences were again wild-type. However, if the original construct contained the mutant sequence in the left terminal repeat, the majority of progeny molecules were parental in type (i.e. mutant left and wild-type right terminal repeat). We conclude (1) although the terminal repeats at opposite ends of the genome may interact during DNA replication, it is not necessary that they be perfectly complementary. (2) In direct competition, the wild-type sequence displays an advantage over the mutant allele. (3) In a plasmid clone, the terminal repeat on the left end of the genome is at an advantage in a competitive situation. We note that the left terminal repeat is adjacent to a transcriptional promoter.

["Artificial" chromosomes]

The structural elements required for chromosome replication, segregation, and stability are replication origins, centromeres, and telomeres. DNA sequences capable of organizing these three elements have been isolated from yeast chromosomal DNA by means of recombinant DNA techniques and yeast cell transformation. It is now possible to combine these sequences into "artificial" chromosomes for yeast cells to obtain more insight into chromosome structure and function. Evidence is presented that the construction of artificial chromosomes functional in higher eukaryotes will be possible in the near future.

Expression of simian virus 40 early and late genes in mouse oocytes and embryos

Simian virus 40 (SV40) large- and small-tumor antigens (T-Ag, t-Ag) are normally synthesized early after infection of either permissive (monkey) or nonpermissive (mouse) fibroblasts, whereas an equivalent amount of viral coat protein (V-Ag) is observed late after infection of permissive cells and only after viral DNA replication has occurred. To determine whether or not expression of these genes is regulated in the same manner during early mammalian development, SV40 DNA was injected into the nuclei of mouse oocytes and one- and two-cell embryos. In oocytes, about three times more V-Ag was produced than T-Ag, and both were synthesized concomitantly in the same cells. Viral mRNA and proteins synthesized in oocytes comigrated during gel electrophoresis with the same products synthesized in SV40-infected monkey cells. Viral gene expression required circular DNA molecules injected into the nuclei of transcriptionally and translationally active cells. Injected DNA was stable and underwent conformational changes consistent with chromatin assembly. Oocytes did not replicate either polyomavirus or SV40 DNA. Thus, the temporal order of viral gene expression is circumvented in mouse germ cells, allowing these proteins to be expressed concurrently and in equivalent amounts with no requirement for DNA replication. However, in preimplantation embryos, neither T-Ag nor V-Ag was detected by immunoprecipitation although T-Ag synthesis was demonstrated as a specific requirement for SV40 DNA replication. Thus, viral gene expression in mouse embryos as early as the one-cell stage was reduced at least 500-fold relative to that in oocytes. Similarities between SV40 gene expression in mouse oocytes and that in Xenopus oocytes suggest that germ cells in higher animals share common regulatory mechanisms.

Germ line transmission of autonomous genetic elements in transgenic mouse strains

Upon microinjection into fertilized mouse eggs of circular molecules of plasmid pPyLT1 carrying the gene encoding the large T protein of polyoma virus within bacterial vector sequences, autonomous circular plasmids were stably maintained in low copy numbers in transgenic strains. These plasmids could be rescued in E. coli by transfection. Integrated forms could be detected neither in somatic tissues, nor in spermatozoa. Efficiency of paternal or maternal transmission was close to 100%. The plasmids had lost or had extensively rearranged the polyoma sequences. In addition, they had acquired defined segments of genomic mouse DNA, which might be responsible for correct segregation of daughter copies at both mitosis and meiosis (centromeric function).

Methylation analysis of a plasmid containing a mammalian cell cycle regulatory sequence after transient transfection into the host cell

A hamster genomic sequence containing a cell cycle regulatory sequence derived from a histone H3.2 gene was transfected into K12 hamster fibroblasts in the form of plasmid DNA prepared from dam+ E. coli. Analysis of the plasmid DNA recovered 72 hr after the transfection revealed that it was resistant to Mbol but was sensitive to Dpn 1 enzyme digestion, suggesting that this plasmid had retained its dam E. coli methylated sites and was therefore unable to undergo replication following transfection into homologous host cells. These results were discussed with relation to a previously described yeast cell cycle regulatory sequence which was functionally linked to an autonomous replicating sequence and was located near a yeast H2B gene.

Structure of transcriptionally active chromatin

Transcriptionally active or potentially active genes can be distinguished by several criteria from inactive sequences. Active genes show both an increased general sensitivity to endonucleases like DNase I or micrococcal nuclease and the presence of nuclease hypersensitive sites. Frequently, the nuclease hypersensitive sites are present just upstream of the transcription initiation site covering sequences that are crucial for the promoter function. Viral or cellular transcription enhancer elements are also associated with DNase I hypersensitive sites. At least for the SV40 enhancer, it was shown by electronmicroscopic studies that the DNase I hypersensitive DNA segment is excluded from nucleosomes. It is highly plausible that the binding of regulatory proteins to enhancer or promoter sequences is responsible for the exclusion of these DNA segments from nucleosomes and for the formation of nuclease hypersensitive sites. We speculate that the binding of such proteins may switch on a change in the conformation and/or the protein composition of a chromatin segment or domain containing one to several genes. Biochemical analysis of fractionated nucleosome particles or of active and inactive chromatin fractions have revealed differences in the composition as well as in the degree of modification of histones in these two subfractions of the chromosome. However, until present it is impossible to define unambiguously what are the crucial structural elements that distinguish between particles present on active and inactive chromatin.