Subcellular localization of DNA polymerase gamma and changes in its activity in sea urchin embryos

1. Subcellular localization and changes in the activity of DNA polymerase gamma were examined in sea urchin eggs and embryos. 2. The enzyme was shown to be localized predominantly in mitochondria by differential and isopycnic centrifugation. 3. During embryogenesis, the enzyme activity per embryo remained constant until blastula stage, and thereafter increased. 4. Similarly mitochondrial DNA per embryo increased, indicating that mitochondrial DNA replication starts during embryogenesis. 5. The gamma-activity per mitochondrial DNA remained constant during embryogenesis. 6. These results suggest that mitochondria contain a constant amount of replicative enzyme (DNA polymerase gamma) regardless of mitochondrial DNA replication, which differs from the case of nuclear DNA replication.     

Mitochondria, redox signaling and axis specification in metazoan embryos

Mitochondria are not only the major energy generators of the eukaryotic cell but they are also sources of signals that control gene expression and cell fate. While mitochondria are often asymmetrically distributed in early embryos, little is known about how they contribute to axial patterning. Here we review studies of mitochondrial distribution in metazoan eggs and embryos and the mechanisms of redox signaling, and speculate on the role that mitochondrial anisotropies might play in the developmental specification of cell fate during embryogenesis of sea urchins and other animals.     

Selective and continuous elimination of mitochondria microinjected into mouse eggs from spermatids, but not from liver cells, occurs throughout embryogenesis

Exclusion of paternal mitochondria in fertilized mammalian eggs is very stringent and ensures strictly maternal mtDNA inheritance. In this study, to examine whether elimination was specific to sperm mitochondria, we microinjected spermatid or liver mitochondria into mouse embryos. Congenic B6-mt(spr) strain mice, which are different from C57BL/6J (B6) strain mice (Mus musculus domesticus) only in possessing M. spretus mtDNA, were used as mitochondrial donors. B6-mt(spr) mice and a quantitative PCR method enabled selective estimation of the amount of M. spretus mtDNA introduced even in the presence of host M. m. domesticus mtDNA and monitoring subsequent changes of its amount during embryogenesis. Results showed that M. spretus mtDNA in spermatid mitochondria was not eliminated by the blastocyst stage, probably due to the introduction of a larger amount of spermatid mtDNA than of sperm mtDNA into embryos on fertilization. However, spermatid-derived M. spretus mtDNA was eliminated by the time of birth, whereas liver-derived M. spretus mtDNA was still present in most newborn mice, even though its amount introduced was significantly less than that of spermatid mtDNA. These observations suggest that mitochondria from spermatids but not from liver have specific factors that ensure their selective elimination and resultant elimination of mtDNA in them, and that the occurrence of elimination is not limited to early stage embryos, but continues throughout embryogenesis.     

Mouse zygotes injected with mitochondria develop normally but the exogenous mitochondria are not detectable in the progeny

A microinjection procedure to introduce "paternal" mitochondria from a source other than spermatozoa into fertilized mouse eggs is described. When a mitochondrial suspension isolated from the testes or liver of Mus molossinus mice was microinjected into fertilized eggs of CD1 mice, the microinjected zygotes survived, developed normally, and offspring were produced. Mus molossinus mitochondrial DNA can be distinguished from CD1 mitochondrial DNA by Southern blot analyses using restriction enzymes such as Eco R1, Xba 1, or Spe 1. Although up to 120 viable mitochondria were injected, no exogenous mitochondrial DNA was detected in fetal samples or in the brain, liver, heart, testis, or ovary of the mature progeny. Under the experimental conditions used, similar results were obtained when mitochondria from the testes of New Zealand black mice or from testes of Syrian hamsters were microinjected into fertilized CD1 mouse eggs. Failure to detect the exogenous mitochondrial DNA under our assay conditions suggests that microinjected mitochondria from testis or liver did not selectively replicate during embryonic development. The "foreign" mitochondria appear to have the same fate during early embryogenesis as the mitochondria of the spermatozoon.     

Fate of amplified nucleoli in Xenopus laevis embryos

We have followed the fate of two components of extrachromosomal nucleoli, amplified ribosomal DNA (rDNA) and 7.5 kb precursor rRNA, during early embryogenesis of Xenopus laevis. Other workers have shown that the amount of amplified rDNA accumulated during oogenesis remains unchanged through the 16-cell stage of embryogenesis. Here we show that as embryonic cleavage continues, the amount of amplified rDNA decreases until it is no longer detectable in the early gastrula embryo. In contrast, the amount of 7.5 kb precursor rRNA in eggs, early cleavage stage embryos, or blastula stage embryos is the same as in oocyte nuclei. Since no rRNA synthesis occurs during these early stages, we conclude that the precursor rRNA sequences synthesized in the oocyte are neither processed nor degraded during early development. The amplified rDNA is not replicated in the early embryo even though the chromosomal DNA of the embryo replicates every 30 min during the first 7.5 hr of embryogenesis. When amplified rDNA is purified and then injected into cleaving embryos, however, we find that it is replicated. This finding suggests that some factor(s) prevents the endogenous amplified rDNA from responding to the cellular replication signals. We show that methylation of cytosine in the rDNA is not related to the DNA's capacity for replication in this system since amplified (unmethylated) and chromosomal (methylated) rDNA are both replicated when injected into embryos. The methylation pattern of these rDNAs appears to be maintained after replication in the embryo.     

Replication of mitochondrial DNA in the early development of Misgurnus fossilis

Mitochondria isolated from Misgurnus fossilis embryos at various developmental stages were incubated with ³H-dTTP in vitro and the incorporation into mtDNA was determined. It has been found that the rate of mtDNA labeling increases exponentially with a doubling time of 7 hr from 0.01 pmole of ³H-dTMP/mg protein/hr in mitochondria from unfertilized eggs to 0.4 pmoles of ³H-dTMP/mg protein/hr in mitochondria of 35 hr embryos. The pool of intramitochondrial dTTP decreases 2.5 times during the first 10 hr after fertilization, then remains practically constant up to 35 hr of development. The rate of exogenous ³H-dTTP incorporation into the acid soluble pool of isolated mitochondria at two stages is approximately proportional to the pool size. Thus identical specific activities of ³H-dTTP inside mitochondria would be obtained even with pools of different sizes. We conclude that the increase of ³H-dTMP incorporation into mtDNA in development reflects genuine activation of mtDNA synthesis. As early as 6 hr after fertilization the bulk of the label incorporated into mtDNA is found in the fraction associated with covalently closed molecules. This pattern of labeling characteristic for replicating mtDNA is maintained throughout early development. In contrast such preferential label incorporation into the closed circular fraction was not found with mitochondria of unfertilized eggs. Closed mtDNA from unfertilized eggs contains not more than 1% of molecules with D-loops. In 35 hr embryos the corresponding value is equal to about 4%. Activation of mtDNA replication in embryogenesis is probably due to the activation of mechanisms responsible for the generation of primers for replication. DNA polymerase activity solubilized from mitochondria remains unchanged in the course of embryogenesis.     

Injection of mitochondria into oocytes and fertilized eggs]

The suspension of mitochondria isolated from the loach embryos or the frog heart were injected in the oocytes or fertilized eggs of the loach, newt, toad and frog in the amount roughly equivalent to the content of mitochondria in the egg. After the injection the oocytes did not differ during several days from the normal ones and the fertilized eggs of the loach, newt and South Afican clawed toad developed normally. The activity of cytochrome oxidase in the injected oocytes was kept at a somewhat higher level (1.4 to 1.9 vs 1.0 in the control) during several days. In the developing eggs the activity of cytochrome oxidase began to decrease from the blastula stage and attained rapidly the control level. The decrease of the enzyme activity is due to non-specific degradation of excessive mitochondria or to compensatory inactivation of the enzyme ensuring the maintenance of its normal activity during the development.     

Ascidian Wnt-5 gene is involved in the morphogenetic movement of notochord cells

Wnt proteins play important roles in many developmental events. Wnts are divided into two groups according to biological function. The Wnt-5a class proteins function in morphogenetic movement during embryogenesis. Previously, a Wnt-5 homolog has been isolated from the ascidian, Halocynthia roretzi. HrWnt-5 is expressed in the notochord until the tail-bud stage, implying a role in the notochord. In this study, the function of HrWnt-5 was investigated. When HrWnt-5 mRNA was injected into fertilized eggs, the embryos showed morphologic defects at around the neurula stage. The anterior-posterior axis was shorter than in control embryos. These defects were caused by the abnormal movement of notochord cells. However, the overexpression of HrWnt-5 mRNA did not affect the differentiation of tissues, suggesting that HrWnt-5 solely regulates the morphogenetic movement. Although endogenous HrWnt-5 is expressed in the notochord, the overexpression of HrWnt-5 mRNA caused the defects, suggesting that the amount of HrWnt-5 mRNA in the notochord is strictly regulated. These results suggest that HrWnt-5 regulates the morphogenetic movement of notochord cells during ascidian embryogenesis.     

CARBOHYDRATE METABOLISM IN THE EGGS OF THE SILKWORM, BOMBYX MORI. I. ABSENCE OF PHOSPHOFRUCTOKINASE IN THE DIAPAUSING EGG

In the diapausing eggs of the silkworm, Bombyx mori , glycogen is rapidly converted to sorbitol and glycerol, and this conversion is reversed at termination of the diapause (C hino , 1958). To elucidate the pathway leading to this polyol formation and its regulatory mechanisms, enzymes concerning carbohydrate metabolism were surveyed in diapausing as well as in developing eggs of the silkworm.
Most of the enzyme activities concerning citric acid cycle are low at the beginning of the embryogenesis and during diapause, but increase at the later stages of the development. Making an exception, reduction rate of malate and fumarate was rather high from the onset of the embryonic development. Several glycolytic enzymes were also studied. Most remarkable fact is that phosphofructokinase activity could not be demonstrated in the diapausing and also in the early stages of the developing eggs. Other enzymes, viz. α-glycerophosphate dehydrogenase, aldolase, glyceraldehyde-3-phosphate dehydrogenase were detected from the beginning of the embryogenesis.
Absence of phosphofructokinase, together with the high activity in glucose-6-phosphate dehydrogenase, suggests that predominant pathway in carbohydrate metabolism in the early stages of embryogenesis and in the diapause period is by way of pentose phosphate pathway. This supposition is confirmed by the experiments using labeled glucose. Incorporation of the label into glycerol of the diapausing eggs was three to four fold when G-6-¹⁴C was injected into pupae as compared with the case of G-1-¹⁴C injection. The above experiments provide evidence supporting the theory that glycogen is converted into sorbitol and glycerol mostly by way of the pentose phosphate pathway in the diapausing eggs.     

Changes in ion content and transport during development of embryonic rainbow trout

Wet mass and water content of four lots of whole eggs did not change throughout embryonic development of rainbow trout Oncorhynchus mykiss. Eggs in all four lots accumulated Na⁺. Eggs in lots 2 and 4 also accumulated Ca²⁺ and Cl^-, whereas eggs in lot 1 showed no significant change in Ca²⁺ or Cl^- and eggs in lot 3 showed no change in Cl^-and a small loss of Ca²⁺. Although the Na⁺ content of embryonic tissues increases in the later stages of development, the yolk sac content remained constant, indicating uptake of Na⁺ from the environment. Na+ uptake by whole eggs was non-saturable, consistent with diffusion of Na⁺ across the chorion into the perivitelline fluid. Na⁺ uptake in dechorionated embryos was saturable, as was Ca²⁺ uptake by both whole eggs and dechorionated embryos, consistent with active uptake or facilitated diffusion mechanisms at the surface of embryos. Very low Ca²⁺ uptake rates in dechorionated embryos suggest that the Ca²⁺ uptake mechanism is not fully developed until after hatching.     

Activin receptor mRNA is expressed early in Xenopus embryogenesis and the level of the expression affects the body axis formation.

Activin is a member of the transforming growth factor beta (TGF-beta) and possesses various activities in cellular control phenomena. During Xenopus embryonic development, activin is thought to act as a natural mesoderm-inducing factor. We isolated here the Xenopus activin receptor cDNA from Xenopus tadpole cDNA library and examined the expression of the Xenopus activin receptor gene during the course of early embryonic development. The Xenopus activin receptor has an 87% homology at the level of deduced amino acid sequence with the mouse activin receptor, and using the cDNA obtained, three bands of mRNA with different lengths were detected in Xenopus embryos throughout early embryogenesis. We synthesized activin receptor mRNA in vitro and tested the effect of the injection of the mRNA into Xenopus fertilized eggs on subsequent development. When the synthetic mRNA was injected into uncleaved fertilized eggs, embryos with reduced trunk structure were formed. However, when the mRNA was injected into the ventral blastomeres at the 16-cell stage, embryos with a secondary body axis were formed. These results indicate the importance of the function of activin receptor in the regulatory mechanism for body axis formation.     

The functioning of mammalian mitochondria injected into fish embryos

The possibility of mammalian mitochondria functioning in fish embryos has been studied. Suspension of mitochondria isolated from the mouse fibroblast B-82/cap (chloramphenicol-resistant) and B-82 (chloramphenicol sensitive) cell cultures, were injected into the fertilized loach eggs. These embryos with an artificially increased number of mouse mitochondria developed and lived till the larval stages. Activity of cytochrome oxidase in these embryos was 1.5-2 times that in the control several hours after the injection, decreased during development and reached the control level by the gastrula stage. If these embryos with artificially increased number of mouse mitochondria were incubated in presence of chloramphenicol, only embryos that contained mitochondria from chloramphenicol-resistant cells survived, thus suggesting that the injected mitochondria do not degrade but are preserved and function in the cytoplasm of developing loach embryos.     

Regulation of carbon flux from amino acids into sugar phosphates in Xenopus embryos

Xenopus laevis oocytes and embryos are glycogenic cells, metabolizing sugar phosphates into glycogen. These cells have very low pyruvate kinase activity in vivo and, consequently, make little pyruvate and lactate through glycolysis. Nevertheless, oocytes and embryos do contain significant pyruvate and lactate levels. To determine the source of carbon for sugar phosphates and pyruvate, 14C-labeled intermediary metabolites were injected into fertilized eggs and their metabolism examined by thin-layer chromatography. Alanine, pyruvate, and lactate form a pool of carbon that fluxes into sugar phosphates. Cytosolic (nonmitochondrial) aspartate, oxaloacetate, and malate form a pool of carbon which is largely blocked in the short-term from entering the smaller alanine/pyruvate/lactate pool. The data indicate that the major source of carbon for sugar phosphates in fertilized eggs and rapidly cleaving embryos is the alanine/pyruvate/lactate pool. Pyruvate from this pool is converted in the mitochondria to phosphoenolpyruvate, which in turn is metabolized outside the mitochondria to sugar phosphates. A key enzyme in regulating flux from amino acid carbon to pyruvate is malic enzyme. Three malic enzyme isozymes, one soluble and two mitochondrial, were partially isolated and kinetically characterized from total ovarian tissue. Full-grown oocytes and eggs, however, have very low soluble malic enzyme activity, which results in the separation of the cytosolic aspartate/oxaloacetate/malate and alanine/pyruvate/lactate pools.     

Distribution of foreign mitochondrial DNA during the first splitting of transmitochondrial mouse embryos

The distribution of human mitochondrial DNA (mtDNA) among single murine blastomeres was analyzed during the splitting of embryos injected with a suspension of human mitochondria at the one- or two-cell stage. Human mtDNA was detected by PCR with species-specific primers. The total amount of the- and four-cell murine embryos analyzed in the study was 315. In all embryos examined together with murine mtDNA copies of human mitochondrial genome were revealed indicating the phenomenon of an artificially modeled heteroplasmy. Foreign mtDNA was not ubiquitous in blastomeres of transmitochondrial embryos. Mathematical treatment of the results showed that, in the period between the injection of human mitochondria and the subsequent embryo cleavage, an uneven distribution of human mtDNA occurred in the cytoplasm. These results also indicate the presence of more than two to three segregation units of mtDNA in the entire pool of mitochondria (about 500) introduced into an embryo by microinjection.     

Quantitative and ultrastructural analysis of the chondriome in ovogenesis and embryogenesis of the sea urchin Paracentrotus lividus. 2. Growth and proliferation of mitochondria in embryogenesis.

The dynamics of structural changes of the chondriome in the early development of the sea urchin Paracentrotus lividus was studied. Mature eggs and embryos at various stages of cleavage were used for quantitative and ultrastructural analysis based on computerized 3D reconstruction from serial ultrathin sections. The following structural transformations of the chondriome were shown to occur in the course of embryogenesis: (i) 15 min after fertilization, mitochondrial clusters disintegrate, and mitochondrial division is induced. At the stage of two blastomeres the population of mitochondria increases twofold; (ii) the mitochondria divide by means of the contraction of both outer and inner membranes. The forming furrow divides the "parental" mitochondrion into two equal "daughter" parts; (iii) at the four-cell stage the division ceases, and mitochondria start to grow, so that the mitochondrial length increases; (iv) cell differentiation further stimulates elongation of rod-shaped mitochondria, and the ratio of rod-shaped to spherical mitochondria changes; (v) in an unfertilised egg, the mitochondria are in a condensed form; after fertilisation all the mitochondria acquire a conventional form. Modern concepts of chondriome proliferation in eukaryotic cells are discussed.     

Interaction of glucocorticoid hormones with mitochondrial membranes

The mechanism of 3H glucocorticoid binding with the rat liver mitochondria in vitro is investigated. The linear dependence of the amount of bound hormones on the concentration of the free ones is shown and no saturation in the region of the physiological concentrations is observed. A very low specific binding in the presence of a 100-fold excess of an unlabelled hormone is found. The outer mitochondrial membranes binds a considerably higher amount of steroids, than the inner one. The binding of steroids with the intact liver mitochondria is 2-3 times higher as compared to the binding with spheroplasts of Escherichia coli. Delipidization of mitochondria by diverse lipotropic agents differently influences the binding of steroids with the different functional groups. The interaction of steroids with mitochondria depends on the osmolarity of the incubation medium: the binding is 1.5-3 times higher in the isotonic sucrose solution, that in the hypo- or hypertonic ones. A conclusion is made about the nonspecific character of glucocorticoid binding with mitochondria caused by the interaction with hydrophobic compounds of the mitochondrial membranes. The possible chemical mechanisms for such an interaction are discussed.     

Oocyte mitochondria: Strategies to improve embryogenesis

Mitochondria play a central role to provide ATP for fertilization and preimplantation embryo development in the ooplasm. The mitochondrial dysfunction of oocyte has been proposed as one of the causes of high levels of developmental retardation and arrest that occur in preimplantation embryos generated using Assisted Reproductive Technology. Cytoplasmic transfer (CT) from a donor to a recipient oocyte has been applied to infertility due to dysfunctional ooplasm, with resulting pregnancies and births. However, neither the efficacy nor safety of this procedure has been appropriately investigated. In order to improve embryogenesis, we observed the mitochondrial distribution in ooplasma under the several conditions using mitochondrial GFP-transgenic mice (mtGFP-tg mice) in which the mitochondria are visualized by GFP. In this report, we will present our research about the mitochondrial distribution in ooplasm during early embryogenesis and the fate of injected donor mitochondria after CT using mtGFP-tg mice. The mitochondria in ooplasm from the germinal vesicle stage to the morula stage were accumulated in the perinuclear region. The mitochondria of the mtGFP-tg mouse oocyte transferred into the wild type mouse embryo could be observed until the blastocysts stage, suggesting that the mtGFP-tg mice oocyte is very useful for visual observation of the mitochondrial distribution in the oocyte, and that the aberrant early developmental competences due to the oocyte mitochondrial dysfunction may be overcome by transferring the "normal" mitochondria.