Evans blue treatment promotes blastomere separation and twinning in Lytechinus pictus embryos

Demembraned Lytechinus pictus embryos briefly treated with the dye Evans Blue during the first cleavage division subsequently showed frequent blastomere disengagement leading to development of twinned embryos. Further development of twinned embryos was observed in hanging drops and in batch cultures. The timing of micromere production was disturbed in some twinned embryos, but this disturbance was not correlated with subsequent developmental problems. Many twinned embryos resulting from blastomere separation following Evans Blue treatment developed into small but normal-appearing plutei.     

Water relations parameters and tissue development in somatic and zygotic embryos of three pinaceous conifers

There is increasing interest in using somatic embryogenesis to meet the demand for high quality seedlings. However, in vitro production of propagules on a large scale depends on the optimization of the maturation and germination steps promoted by desiccation and subsequent imbibition of the embryo, respectively. It is therefore important to characterize zygotic and somatic embryos in terms of their water relations. Bound water, elastic modulus, osmotic potential at full turgor, and relative water content at turgor loss point were determined for somatic and zygotic embryos of western larch and loblolly pine and somatic embryos of white spruce at two developmental stages. These water relations parameters were derived from water-release curves obtained by suspending tissue samples in sealed vials over unsaturated NaCl solutions of known water potential. There was little difference in water relations parameters among species but marked stage dependency for bound water and elastic modulus. The amount of bound water was lowest in western larch somatic embryos (0.02-0.07) and highest in zygotic loblolly pine embryos (0.10-0.18). Elastic modulus ranged from 2.5 to 6.2 MPa in somatic embryos but varied between 1.4 and 1.8 MPa in zygotic embryos. The osmotic potential was lower in somatic embryos than in their zygotic counterparts. Our results show that water relations parameters are remarkably conservative across species but that, within a given species, these parameters are stage specific. It would seem, therefore, that desiccation protocols might be developed for a given developmental stage and applied across a range of species without the confounding effects of differences in water relations parameters.     

Non-zygotic embryos of Brassica napus L. contain embryo-specific storage proteins

The storage-protein content of non-zygotic and zygotic embryos of B. napus was compared, using antibodies to guantitate 12S storage protein in extracts by rocket immunoelectrophoresis. Non-zygotic embryos were induced from microspores in anther culture and on the hypocotyls of zygotic embryos in culture. All embryo-like structures were found to contain 12S storage protein, whereas preculture anthers, anthers from which embryos had been removed, and regenerated shoots did not have detectable 12S storage protein. In zygotic embryos, 12S storage protein was first detected at the cotyledon stage, but microsporic embryos contained storage protein at the globular and heart stages. Storage protein levels in microsporic and hypocotyl embryos were low relative to those in zygotic embryos. The largest microsporic embryo had a storage protein concentration of 13 g mg^-1 fresh weight, almost 10 times lower than a mature zygotic embryo. Thus, although storage proteins are present in both zygotic and non-zygotic embryos, the timing and extent of accumulation differ.     

Comparative protein accumulation patterns in soybean somatic and zygotic embryos

Summary The relative maturity and competence of somatic embryos is often estimated on the basis of their morphologic similarity to various stages of immature zygotic embryo development. Morphologic abnormalities noted in soybean [Glycine max (L.) Merr.] somatic embryos are similar to those observed in zygotic embryos maturing in vitro and may reflect common interruptions of normal developmental processes. We provide here a more objective means of assessing the point(s) at which cultured embryos deviate from the normal embryogenical pathway by comparing the accumulation of the embryo-specific marker proteins (11S and 7S storage globulins, soybean agglutinin, and seed lipoxygenase) between somatic and immature zygotic embryos maturing in culture to zygotic embryos maturingin planta. Immature (heart-stage) soybean (cv. ‘McCall’) zygotic embryos were removed from the testa and cultured for 5, 15, or 45 days in nien modified Linsmaer-Skoog salts, 5% sucrose liquid medium. Somatic embryos were induced from immature cotyledon explants on a medium containing either naphthalene acetic acid or 2,4 dichlorophenoxyacetic acid (10 mg·liter⁻¹). The measured level of the marker proteins present in cultured embryos never exceeded those observed in mature soybean seeds. During the culture period, immature zygotic embryos accumulated significant levels of all marker proteins except a 29 kDa soybean agglutinin associated with the final stages of seed maturationin planta. Somatic embryos of all morphologic classes exhibited similar levels of the marker proteins suggesting that morphology may not accurately represent the developmental state of the culture-derived embryos. Somatic embryos induced on naphthalene acetic acid-containing medium accumulated detectable levels of all maturation-specific marker proteins except the 7S β and 29-kD soybean agglutinin antigen and seemed similar in most respects to the cultured zygotic embryos. Embryos induced on 2,4-dichlorophenoxyacetic acid accumulated none of the mature 7S or 11S storage globulin subunits nor any soybean agglutinin antigen, and yet the synthesis of 7S and 11S precursor polypeptides was similar in both naphthalene acetic acid-and 2,4-dichlorophenoxyacetic acid-induced somatic embryos. These observations are consistent with the view that embryos induced on high 2,4-dichlorophenoxyacetic are arrested at a relatively earlier developmental stage than naphthalene acetic acid-induced embryos of similar morphology and may indicate that some external signal (e.g., abscisic acid or desiccation or both) is necessary for the transition to the late maturation stage of seed ontogeny.     

An embryo-specific protein of barley (Hordeum vulgare).

An immunological approach has been used to identify embryo-specific products that can be used as molecular markers of embryogenesis. Immunoadsorption of antisera to remove antigens common to embryos, meristematic cells and callus, revealed one major embryo-specific antigen, a polypeptide of 17 kDa. The antigen appeared at mid-stages of zygotic embryo formation and remained at similar levels up to six days post-germination of the seedling. The polypeptide could not be detected by protein staining, suggesting it is a non-abundant product. Appearance of the antigen could be induced by culture of zygotic embryos in vitro on abscisic acid (1 microM) or mannitol (9% mass/vol.). Cross-reactive products of near-identical molecular mass were observed in embryos of wheat, rye and oats but not distantly related cereals, nor embryos from dicotyledonous species. The timing of the appearance of the antigen was different in embryos formed from microspores during anther culture in vitro. In the cultured material, the 17-kDa polypeptide preceded the appearance of morphologically distinct embryonic structure.     

Evolutionary change in the process of dorsoventral axis determination in the direct developing sea urchin, Heliocidaris erythrogramma

Embryos of the indirect developing sea urchin, Heliocidaris tuberculata, and of Heliocidaris erythrogramma which develops directly without the formation of a pluteus larva, were bisected at the two- and four-cell stages. Paired half-embryos resulting from the bisection of H. tuberculata embryos along either the first or the second cleavage plane develop identically into miniature prism stage larvae. As in other indirect developing sea urchins, no differential segregation of developmental potential takes place as a result of the first and second cleavage divisions. Although half-embryos resulting from bisection along the second cleavage plane differentiate all cell types and develop equivalently in H. erythrogramma, the isolated first cleavage blastomeres do not. One of these two cells always forms significantly more mesodermal and endodermal cells. These patterns of differentiation are consistent with fate-mapping studies indicating that most mesodermal and endodermal cells are derived from the prospective ventral blastomere. Therefore, a differential segregation of developmental potential takes place at the first cleavage division in H. erythrogramma. When embryos of H. erythrogramma were bisected during the eight-cell stage, isolated tiers of animal blastomeres typically formed only ectodermal structures including the vestibule, whereas vegetal embryo halves formed all differentiated cell types. We propose that animal-vegetal cell determination and differentiation takes place along an axis which has been shifted relative to the pattern of cell cleavages in the embryos of H. erythrogramma. Vegetal morphogenetic potential for the formation of mesodermal and endodermal structures has become more closely associated with the prospective ventral side of the embryo during the evolution of direct development in Heliocidaris.     

Regeneration of zygotic-like microspore-derived embryos suggests an important role for the suspensor in early embryo patterning

The inaccessibility of the zygote and proembryos of angiospermswithin the surrounding maternal and filial tissues has hamperedstudies on early plant embryogenesis. Somatic and gametophyticembryo cultures are often used as alternative systems for molecularand biochemical studies on early embryogenesis, but are notwidely used in developmental studies due to differences in theearly cell division patterns with seed embryos. A new Brassicanapus microspore embryo culture system, wherein embryogenesishighly mimics zygotic embryo development, is reported here.In this new system, the donor microspore first divides transverselyto form a filamentous structure, from which the distal cellforms the embryo proper, while the lower part resembles thesuspensor. In conventional microspore embryogenesis, the microsporedivides randomly to form an embryonic mass that after a whileestablishes a protoderm and subsequently shows delayed histodifferentiation.In contrast, the embryo proper of filament-bearing microspore-derivedembryos undergoes the same ordered pattern of cell divisionand early histodifferentiation as in the zygotic embryo. Thisobservation suggests an important role for the suspensor inearly zygotic embryo patterning and histodifferentiation. Thisis the first in vitro system wherein single differentiated cellsin culture can efficiently regenerate embryos that are morphologicallycomparable to zygotic embryos. The system provides a powerfulin vitro tool for studying the diverse developmental processesthat take place during the early stages of plant embryogenesis. Key words: Brassica napus, microspore embryogenesis, pattern formation, polarity, suspensor, zygotic embryogenesis     

A hormonal misunderstanding in Acca sellowiana embryogenesis: levels of zygotic embryogenesis do not match those of somatic embryogenesis

Endogenous levels of IAA, ABA and four types of CKs were analyzed in zygotic and indirect (ISE) and direct somatic embryogenesis of Acca sellowiana. Zygotic and somatic embryos at different developmental stages were sampled for morphological and hormonal analysis. Both embryo types showed substantial asymmetry in hormone levels. Zygotic embryos displayed a conspicuous peak of IAA in early developmental stages. The results outlined the hormonal variations occurring during zygotic and somatic embryogenesis regarding the timing, nature and hormonal status involved in both processes. The short transient pulse of IAA observed on the 3rd day in culture was suggested to be involved with the signaling for the induction of somatic embryogenesis. Fertilized ovule development was associated with increased IAA levels 21?C24?days after pollination, followed by a sharp decrease in the cotyledonary stage, both in zygotic and somatic embryos. There was a prominent increase in ABA levels in cultures which generated ISE 24?C30?days after pollination, a period that corresponds to the heart and torpedo stages. The levels of total CKs (Z, [9R]Z, iP and [9R]iP) were also always higher in zygotic than in somatic embryogenesis. While zygotic embryogenesis was dominated by the presence of zeatin, the somatic process, contrarily, was characterized by a large variation of the other cytokinin forms and amounts studied. The above results, when taken together, could be related to the previously observed high frequency formation of anomalous somatic embryos formed in A. sellowiana, as well as to their low germination ability.     

Contrasting pattern of somatic and zygotic embryo development in alfalfa (Medicago sativa L.) as revealed by scanning electron microscopy

Scanning electron microscopy has been used to investigate the morphological changes occurring during the development of alfalfa somatic embryos. Embryos were initiated from callus, transferred to suspension culture and matured on solid agar medium. This developmental pattern was compared to that of zygotic embryos developing in ovulo. Somatic embryos begin as distinct pro-embryos within the callus tissue pieces placed in suspension culture. They become globular and heart-shaped while on solid agar medium and then undergo cotyledon elongation and maturation. Somatic embryos develop comparatively slower at early stages of development and faster at the later stages than zygotic embryos. They lack a well-defined suspensor and have a very rough, poorly-differentiated epidermis, the first layer of which is lost after pro-embryo formation. The cotyledons of somatic embryos are multiple and poorlydeveloped; there appears to be a correlation between the amount of surface roughness of the developing embryo and the extent to which polycotyledony occurs.     

Relationship between timing of development,morula morphology,and cell allocation to inner cell mass and trophectoderm in in vitro-produced bovine embryos

Noninvasive measurements of bovine embryo quality, such as timing of cleavage, morula morphology, blastocyst formation, and hatching ability, were linked with the number of inner cell mass (ICM) cells and trophectoderm (TE) cells of the resulting embryos. First, it was confirmed that fast-cleaving embryos proved to have significantly higher chances to reach advanced developmental stages vs. intermediate and slow cleavers (P = 0.01). They also showed significantly less fragmentation at the morula stage, implying the presence of more excellent morulae among fast-cleaving embryos (P < 0.05). Second, the quality of hatched blastocysts, resulting from morulae of different morphological grades, was examined by differential staining. The total cell and ICM cell numbers were significantly lower for hatched blastocysts developed from poor morulae compared to hatched blastocysts developed from excellent, good, or fair morulae. However, hatched blastocysts with <10 ICM cells were seen in embryos belonging to all four morphological scores. Finally, it was found that timing of first cleavage was not significantly correlated with timing of blastocyst formation or with cell number of blastocysts. Timing of blastocyst formation, however, was significantly correlated with cell number: day 8 blastocysts had significantly lower total cell and ICM cell numbers than day 6 and day 7 blastocysts (P < 0.001). These results suggest that the quality of in vitro-produced bovine embryos is very variable and cannot be linked with a single criterion such as embryo morphology and/or hatching ability. Timing of blastocyst formation was the most valuable criterion with regard to embryonic differentiation. Mol. Reprod. Dev. 47:47–56, 1997. © 1997 Wiley-Liss, Inc.     

Selective elimination of chromosomally unbalanced zygotes at the two-cell stage in the Chinese hamster

The gametic and zygotic selection of genome imbalance was investigated in the Chinese hamster by direct chromosome analyses of spermatocytes and preimplantation embryos from crosses between chromosomally normal females and males heterozygous for a reciprocal translocation, T(2;10)3Idr, abbreviated here as T3. The karyotypes and the frequencies of embryos observed at the first cleavage in the cross +/+female X T3/+male were consistent with those expected from MII scoring in male T3 heterozygotes. Therefore, it was concluded that there was neither gametic selection against genome imbalance nor zygotic selection from fertilization until the first cleavage metaphase. However, 9.1-10.8% of embryos were arrested at the two-cell stage, and karyotypes of these embryos were confirmed as 22(2,10,10,10(2)), 21(2,10,10), and 21(2,10,10(2)). The common abnormality of these embryos was partial monosomy of chromosome 2. Among day 4 embryos, some chromosomally unbalanced embryos, mainly with a deficiency of other segments of chromosomes 2 and 10, had fewer blastomeres than chromosomally balanced embryos. This finding suggests that cleavage of these embryos had been retarded by day 4 of gestation.