Cleavage and gastrulation in the shrimp Penaeus (Litopenaeus) vannamei (Malacostraca, Decapoda, Dendrobranchiata)

While most malacostracan crustaceans develop through superficial cleavage, in the Amphipoda, Euphausiacea, and Dendrobranchiata (Decapoda) cleavage is complete. Euphausiaceans and dendrobranchiate shrimp share a similar early cleavage pattern, early cleavage arrest and ingression of mesendoderm progenitor cells, a ring of crown cells (prospective naupliar mesoderm) around the blastopore, and hatching as a nauplius larva. Yet recent phylogenies do not support a close relationship between Euphausiacea and Decapoda. In addition, some variation is reported in the timing of mesendoderm cell arrest and number of crown cells for a number of dendrobranchiates. To determine the representative pattern of development in the Dendrobranchiata, embryos of the Pacific white shrimp Penaeus (Litopenaeus) vannamei were stained with Sytox Green to label chromosomes and nuclei and examined with confocal microscopy. The early cleavage pattern, mesendoblast arrest and subsequent ingression at the 32-cell stage, presence of 8 initial crown cells, and fates of the mesendoblasts are the same for P. vannamei (family Peneaeidae) and Sicyonia ingentis (family Sicyoniidae). The lineage of the primordial endoderm cells differs from that reported for P. kerathurus. These characters were discussed in the context of the evolution of development in the Dendrobranchiata and in comparison to the Euphausiacea.     

Cell differentiation during early development of Nassarius reticulatus L. (Gastropoda,prosobranchia)

Summary In Nassarius reticulatus the nuclei and nucleoli undergo important morphological changes from the zygote to the 16-cell stage. In the zygote and in the trefoil (2-cell) and 4-cell stage, several agranular, fibrillar nucleolus-like bodies 1 m diameter are present in the interphase nucleus. Granular nucleoli first appear at the 8-cell stage. These nucleoli have fibrillar and granular regions. The granular regions are made up predominantly of ribosome-like osmiophilic granules. From the 16 and 32-cell stage onwards, the one or two spherical nucleoli of each nucleus measure 2.5 m in diameter and show a concentric organization with a very dense central region surrounded by a broad peripheral zone containing numerous granules, possibly of ribonucleoprotein. At the same time the number of ribosome-like particles increase in the karyoplasm and that of ribosomes in the cytoplasm. These findings are surprising because in eggs with radial cleavage, which have been subjected to more detailed analysis, the first granular nucleoli appear after the end of the cleavage, at the blastula or gastrula stage. The early appearance of granular nucleoli which seem to be characteristic of several eggs with spiral cleavage is discussed in connection with biochemical data on RNA-synthesis.This investigation was supported by the Deutsche Forschungsgemeinschaft and the Stiftung VolkswagenwerkWe wish to thank Mrs. C. Mehlis for valuable technical assistance and Prof. J. Bergerard for the excellent working conditions at the Station biologique at Roscoff (France)     

Cleavage pattern,gastrulation, and neurulation in the appendicularian, <Emphasis Type="Italic">Oikopleura dioica</Emphasis>

The appendicularian, Oikopleura dioica is a chordate. Its life cycle is extremely short—approximately 5 days—and its tadpole shape with a beating tail is retained throughout entire life. The tadpole hatches after 3 h of development at 20°C. Here, we describe the cleavage pattern and morphogenetic cell movements during gastrulation and neurulation. Cleavage showed an invariant pattern. It is basically bilateral but also shows various minor left–right asymmetries starting from the four-cell stage. We observed two rounds of unequal cleavage of the posterior-vegetal B-line cells at the posterior pole. The nature of the unequal cleavages is reminiscent of those in ascidian embryos and suggests the presence of a centrosome-attracting body, a special subcellular structure at the posterior pole. The representation of the cell division pattern in this report will aid the identification of each cell, a prerequisite for clarifying the gene expression patterns in early embryos. Gastrulation started as early as the 32-cell stage and progressed in three phases. By the end of the second phase at the 64-cell stage, every vegetal cell had ingressed into the embryo, and animal cells had covered the entire embryo by epiboly. There was no archenteron formation. In the anterior region, eight A-line cells were aligned as a 2 × 4 array along the anterior–posterior axis and become internalized during the 64-cell stage. This process was considered to correspond to neurulation. The simple and accelerated development of Oikopleura, nevertheless giving rise to a conserved chordate body plan, is advantageous for studying developmental mechanisms using molecular and genetic approaches and makes this animal the simplest model organism in the phylum Chordata. Electronic supplementary material The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Inner cell allocation in the mouse morula: the role of oriented division during fourth cleavage

Two populations of blastomeres become positionally distinct during fourth cleavage in the mouse embryo; the inner cells become enclosed within the embryo and the outer cells form the enclosing layer. The segregation of these two cell populations is important for later development, because it represents the initial step in the divergence of placental and fetal lineages. The mechanism by which the inner cells become allocated has been thought to involve the oriented division of polarized 8-cell blastomeres, but this has never been examined in the intact embryo. By using the technique of time-lapse cinemicrography, we have been able for the first time to directly examine the division planes of 8-cell blastomeres during fourth cleavage, and find that there are three, rather than two, major division plane orientations; anticlinal (perpendicular to the outer surface of the blastomere), periclinal (parallel to the outer surface of the blastomere), and oblique (at an angle between the other two). The observed frequencies of each type of division plane orientation provide evidence that the inner cells of the morula must derive from oriented division of 8-cell blastomeres, in accordance with the polarization hypothesis. Analysis of fourth cleavage division plane orientation with respect to either lineage or division order reveals that it is not associated with lineage from either the 2- or the 4-cell stage, but has a slight statistical association with fourth cleavage division order. The lack of association between division plane orientation and lineage supports the prediction that packing patterns and intercellular interactions within the 8-cell embryo during compaction play a role in determining fourth cleavage division plane orientation and thus, the positional fate of the daughter 16-cell blastomeres.     

Cell lineage,axis formation,and the origin of germ layers in the amphipod crustacean Orchestia cavimana

Embryos of the amphipod crustacean Orchestia cavimana are examined during cleavage, gastrulation, and segmentation by using in vivo labelling. Single blastomeres of the 8- and 16-cell stages were labelled with DiI to trace cell lineages. Early cleavage follows a distinct pattern and the a/p and d/v body axes are already determined at the 4- and 8-cell stages, respectively. In these stages, the germinal rudiment and the naupliar mesoderm can be traced back to a single blastomere each. In addition, the ectoderm and the postnaupliar mesoderm are separated into right and left components. At the16-cell stage, naupliar ectoderm is divided from the postnaupliar ectoderm, and extraembryonic lineages are separated from postnaupliar mesoderm and endoderm. From our investigation, it is evident that the cleavage pattern and cell lineage of Orchestia cavimana are not of the spiral type. Furthermore, the results of the labelling show many differences to cleavage patterns and cell lineages in other crustaceans, in particular, other Malacostraca. The cleavage and cell lineage patterns of the amphipod Orchestia are certainly derived within Malacostraca, whose ancestral cleavage mode was most likely of the superficial type. On the other hand, Orchestia exhibits a stereotyped cell division pattern during formation and differentiation of the germ band that is typical for malacostracans. Hence, a derived (apomorphic) early cleavage pattern is the ontogenetic basis for an evolutionarily older cell division pattern of advanced developmental stages. O. cavimana offers the possibility to trace the lineages and the fates of cells from early developmental stages up to the formation of segmental structures, including neurogenesis at a level of resolution that is not matched by any other arthropod system.     

Uptake and release of63Ni2+ byXenopus embryos during early cleavage stages

Summary Uptake and release of⁶³Ni was studied in dejelliedXenopus laevis embryos exposed to⁶³Ni²⁺ (0.3–30 mol/1) for 0.5-h intervals during the period 1–4.5 h post-fertilization (i.e. from first cleavage to early blastula stage). At first cleavage, the mean uptake of⁶³Ni by embryos was 12-17 times that by non-fertilized eggs, suggesting that conversion of the vitelline envelope to the fertilization envelope enhanced integumental permeability to⁶³Ni²⁺. 63 Ni uptake by embryos at the 1-2-cell stage averaged 1.8–2.5 times that at the early blastula stage. An average of 5% of total⁶³Ni in washed embryos was recovered in isolated fertilization envelopes, indicating that⁶³Ni²⁺ passed through the envelope into internal compartments. Progressive increases of⁶³Ni uptake were seen with increasing exposure levels; after exposure during 1–1.5 h post-fertilization to the highest concentration of⁶³Ni²⁺ (30 mol/1),⁶³Ni uptake averaged 11.4 (SD±5.1) pmol/embryo. Rapid efflux of⁶³Ni was noted after⁶³Ni²⁺-exposed embryos were transferred to nickel-free medium; mean⁶³Ni contents at 0.25 h and 2 h post-exposure diminished to 50% and 15% of the initial values, regardless of the exposure level. The finding thatXenopus embryos are permeable to⁶³Ni²⁺ during early cleavage stages provides a convenient experimental system to investigate the embryotoxicity and teratogenicity of nickel.     

Electron microscopical investigations of the intercellular contacts during the early cleavage stages ofLymnaea stagnalis (Mollusca,Gastropoda)

Summary In early cleavage stages ofLymnaea stagnalis, three kinds of intercellular junctions could be distinguished up to the sixth cleavage: intermediate, septate and gap junctions. The first two form junctional belts located on the cell border at the periphery of the embryo. For the purpose of our study we were most interested in gap junctions as they are alleged to be structures that allow cell-to-cell communication. Gap junctions first appear at the four cell stage. Up to the sixth cleavage no difference in the distribution pattern could be found between and within each of the four quadrants of the embryo. Some of the cell tiers along the animal-vegetal axis lack gap junctions either between the blastomeres within the tier or between the blastomeres from adjacent tiers. All gap junctions observed in freeze fracture replicas show plaques with an irregular IMP pattern. The average IMP diameter measures 12 nm (SD±2 nm). In stages fixed after the fifth cleavage, gap junctions are found between micromeres at the animal pole and the central 3D macromere. This is in agreement with the presumed interaction between these cells at this stage. The possibility of a transition of non-functional into functional gap junctions after the fifth cleavage is discussed.     

The cleavage pattern of the axolotl egg studied by cinematography and cell counting

Summary The temporal pattern of cleavage in the egg of the axolotl,Ambystoma mexicanum, was studied 1. by time-lapse microcinematography, and 2. by counting the total number of blastomeres dissociated at successive stages.Eggs were filmed from the one-cell stage till the early gastrula either (A) simultaneously from above and below with a double-camera assembly, or (B) from the side with a single camera.The animal blastomeres divide synchronously from the 2nd up to and including the 10th cleavage. The cycle length is roughly constant from the 3rd till the 10th cleavage. The cycle from the 2nd to the 3rd cleavage is slightly longer, while that from the 1st to the 2nd cleavage is about 20% longer. After the 10th cleavage the synchrony of divisions is lost owing to variable lengthening of cell cycles in individual blastomeres. Gastrulation starts around the onset of the 15th cleavage in the animal blastomeres.The analysis of films taken in side view reveals seven recurring cleavage waves, from the 5th till the 11th cleavage. Cells in the animal, equatorial and vegetative regions in sequence repeatedly pass through the three successive phases of the cleavage cycle—rounding-up, division, and relaxation—but with a shift in phase. The start of the 10th cleavage division of the slowest vegetative cells more or less coincides with that of the 11th division of the animal cells; from then on the cleavage waves become increasingly obscured.Morulae and blastulae were dissociated by placing them in 1/15 M phosphate buffer (pH 7.8) for the duration of 2–3 cleavage cycles and then removing the vitelline membrane. In this solution cell divisions continued without disturbance of the temporal cleavage pattern. The dissociated cells were fixed either just prior to the onset of the next cleavage (up to the 10th cleavage) or at those times when cleavageswould have been expected, had there been no lenthening of cleavage cycles (beyond the 10th cleavage). The total cell number was counted, dividing cells being scored as two.Prior to the 11th cleavage the total cell number increased exponentially. Beyond the 10th cleavage the rate of increase was considerably lower. At the time when gastrulation would have started if the egg had not been dissociated, the total cell counts were 13,000–15,000, whereas the number anticipated without lengthening of cleavage cycles would be of the order of 130,000 (2¹⁷).The application of Balfour's rule to amphibian eggs is criticized.     

Cleavage in<Emphasis Type="Italic"> Nemertoderma westbladi</Emphasis> (Nemertodermatida) and its phylogenetic significance

Recent phylogenetic analyses of ribosomal and protein coding nuclear genes place the marine worms within the Nemertodermatida as one of the oldest lineages among the bilaterian animals. We studied the early embryonic cleavage in Nemertoderma westbladi to provide the first account of nemertodermatid early development. Live embryos were studied with interference microscopy and fixed embryos were either sectioned or studied with confocal laser scanning microscopy. Initially the divisions in the embryo are radial, but then micromeres are shifted clockwise generating a spiral pattern. The four-cell stage is characterized by duets of macromeres and micromeres and thus resembles the duet cleavage reported from members of the Acoela. However, subsequent stages differ from the acoel duet pattern and also from quartet spiral cleavage. The optimization of the cleavage pattern on current phylogenetic hypotheses with Nemertodermatida and Acoela as early bilaterian branches is discussed.     

Early cleavage in Phoronis muelleri (Phoronida) displays spiral features

The view that early cleavage in Phoronida follows a radial pattern is widely accepted. However, data supporting this characterization are ambiguous. Studies have been repeatedly reporting variation between individual embryos, and the occurrence of embryos exhibiting oblique divisions or nonradial cell arrangements. Such embryos were often considered to represent variation within radial cleavage, or artificial appearances. Cleavage in Phoronis muelleri was previously characterized as “derived radial,” but also oblique spindles and cell elongations, and shifted cell arrangements were observed. We studied the early cleavage in P. muelleri applying 4D microscopy, fluorescent staining, and confocal laser scanning microscopy. To deal with the problem of variation we provide statistical evaluations of our data. These show that oblique divisions do not represent variational abnormalities. In fact, they reveal that most cells divide obliquely from the third cleavage onwards. What is more, in almost all cells the axis of the third cleavage is inclined dextrally. The fourth cleavage is even stronger sinistrally pronounced. Subsequently, the pattern of alternating cleavage orientation is largely restricted to animal and vegetal blastomeres. As a result of the obliqueness of divisions, four cells encircle the poles in most embryos. Cross furrows are occasionally present. We found no indications for radial cleavage in P. muelleri. In contrast, the observed cleavage displays several characters consistent with the pattern of spiral cleavage. A close relation of phoronid and spiralian cleavage is also suggested by molecular phylogenies, allying both groups in the Lophotrochozoa. We suggest our findings to represent morphological support for this lophotrochozoan/spiralian affinity of Phoronida.     

Cleavage and gastrulation in the Kuruma shrimp Penaeus (Marsupenaeus) japonicus (Bate): A revised cell lineage and identification of a presumptive germ cell marker

A previous study suggested that mesendoderm (ME) cell arrest occurred at the 64‐cell stage and a ring of eight presumptive naupliar mesoderm cells or crown cells surrounded the blastopore in the Kuruma shrimp Penaeus (Marsupenaeus) japonicus. Since this varied from the pattern observed in other penaeoidean shrimp, cleavage and gastrulation was re‐examined in P. japonicus using the nucleic acid stain Sytox Green and confocal microscopy. In contrast to the earlier study, cleavage and gastrulation followed the pattern observed in other penaeoidean shrimp. The ME cells arrested at the 32‐cell stage, ingressed into the blastocoel, and resumed division after a three cell cycle delay. Nine naupliar mesoderm or crown cells surrounded the blastopore and their descendants invaginated during gastrulation. An intracellular body (ICB) was detected by Sytox Green and SYTO RNASelect staining to be segregated to one ME cell in P. japonicus, as described previously in Penaeus monodon. Staining of the ICB was eliminated by pre‐treatment with RNase but not DNase. The ICB was also found in two other penaeoidean shrimp, Penaeus vannamei (Family Penaeidae) and Sicyonia ingentis (Family Sicyoniidae). The results support the hypothesis that the ICB is a germ granule found in the Dendrobranchiata.     

Evidence for the induction of two types of potentially lethal damage after exposure of plateau phase Chinese hamster V79 cells toγ-rays

Summary The fixation of-rays induced potentially damage (PLD) caused after treatment either with-araA or in medium made hypertonic by the addition of sodium chloride was studied in plateau phase chinese hamster V79 cells. Treatment with-araA was found to affect a sector of PLD, the fixation of which specifically reduced the shoulder width of the survival curve. The effect was maximized when cell survival reached levels corresponding to an exponential line, with a slope similar to the final slope of the survival curve of untreated cells. This effect was achieved by a four hour treatment with-araA at concentrations above 150µM. Longer treatment times or incubation at higher-araA concentrations did not significantly enhance the effect. Treatment in hypertonic medium, on the other hand, enhanced cell killing in a concentration dependent (NaCl-concentration) way and the survival reached values much lower than those corresponding to an exponential line. No indication for a plateau in the effect, indicating complete fixation of the sector of PLD that reacts sensitively to this treatment, was obtained. Both the slope and the shoulder width of the survival curve were affected, the slope first being increased after short treatment times (up to 10 min), followed by a decrease in the shoulder width after longer treatment times (longer than 10 min). Lesions fixed after treatment with-araA were repaired within four hours, whereas the repair of lesions fixed after treatment in hypertonic medium (460 mM NaCl, 30 min) appeared to be biphasic, with a fast component (completed in about one hour) correlated with a decrease in the slope and a slow component (completed in four hours) correlated with restoration of the shoulder width. Based on these results, we suggest that two types of PLD may be induced in plateau phase V79 cells after exposure to-rays. One, the repair of which is completed within about one hour and which affects the slope of the survival curve, and a second, the repair of which takes place in a few hours and which specifically affects the survival curve shoulder width. The terms-PLD and-PLD are suggested for the first and second component, respectively.Comparison of the repair rates of-PLD as measured with the help of-araA and of sublethal damage as measured in split-dose experiments indicated that these two cellular repair processes have very similar kinetics when measured under the same experimental conditions. Furthermore, the rate was identical at which the shoulder of the survival curve reappeared (shoulder width was the only parameter of the survival curve affected in this type of experiment) in the time interval between either a conditioning dose of-rays and subsequent graded doses or between irradiation and treatment with-araA. Based on these results it is suggested that-PLD and sublethal damage may have a common molecular base.This work was supported by PHS-grants number CA 33951 and CA 39938 awarded by NCI, DHHS     

Origin of the inner cell mass in mouse embryos: cell lineage analysis by microinjection

The mouse inner cell mass is established by cells that are allocated to internal positions after the 8-cell stage. We analyzed the timing of this allocation by microinjecting two cell lineage markers, horseradish peroxidase and rhodamine-conjugated dextran, into mouse blastomeres at the 8- to 32-cell stage. Prospective analysis was performed by coinjection of peroxidase and dextran, followed by 12-22 hr of culture and staining for peroxidase activity; retrospective analysis was performed by injection of peroxidase alone and localization of sister cells without further culture. Both approaches indicated that cells are allocated to internal positions during the fourth and fifth cleavage divisions, but not the sixth cleavage division, of the mouse embryo. Thus, outer cells can have inner descendants until the late morula/early blastocyst (32-cell) stage, but cells remaining outside after the fifth cleavage division are restricted to a trophectoderm fate. This information about cell lineage indicates that the previously observed totipotency of the cleaving mammalian embryo's cells is a regulative attribute that is used in normal development.     

Cell Lineage of the Ilyanassa Embryo: Evolutionary Acceleration of Regional Differentiation during Early Development

Cell lineage studies in mollusk embryos have documented numerous variations on the lophotrochozoan theme of spiral cleavage. In the experimentally tractable embryo of the mud snail Ilyanassa, cell lineage has previously been described only up to the 29-cell stage. Here I provide a chronology of cell divisions in Ilyanassa to the stage of 84 cells (about 16 hours after first cleavage at 23°C), and show spatial arrangements of identified nuclei at stages ranging from 27 to 84 cells. During this period the spiral cleavage pattern gives way to a bilaterally symmetric, dorsoventrally polarized pattern of mitotic timing and geometry. At the same time, the mesentoblast cell 4d rapidly proliferates to form twelve cells lying deep to the dorsal ectoderm. The onset of epiboly coincides with a period of mitotic quiescence throughout the ectoderm. As in other gastropod embryos, cell cycle lengths vary widely and predictably according to cell identity, and many of the longest cell cycles occur in small daughters of highly asymmetric divisions. While Ilyanassa shares many features of embryonic cell lineage with two other caenogastropod genera, Crepidula and Bithynia, it is distinguished by a general tendency toward earlier and more pronounced diversification of cell division pattern along axes of later differential growth.     

A Stereometric Analysis of Karyokinesis, Cytokinesis and Cell Arrangements during and following Fourth Cleavage Period in the Sea Urchin, Lytechinus variegatus

Fourth cleavage of the sea urchin embryo produces 16 blastomeres that are the starting point for analyses of cell lineages and bilateral symmetry. We used optical sectioning, scanning electron microscopy and analytical 3-D reconstructions to obtain stereo images of patterns of karyokinesis and cell arrangements between 4th and 6th cleavage. At 4th cleavage, 8 mesomeres result from a variant, oblique cleavage of the animal quartet with the mesomeres arranged in a staggered, offset pattern and not a planar ring. This oblique, non-radial cleavage pattern and polygonal packing of cells persists in the animal hemisphere throughout the cleavage period. Contrarily, at 4th cleavage, the 4 vegetal quartet nuclei migrate toward the vegetal pole during interphase; mitosis and cytokinesis are latitudinal and subequatorial. The 4 macromeres and 4 micromeres form before the animal quartet divides to produce a 12-cell stage. Subsequently, macromeres and their derivatives divide synchronously and radially through 8th cleavage according to the Sachs-Hertwig rule. At 5th cleavage, mesomeres and macromeres divide first; then the micromeres divide latitudinally and unequally to form the small and large micromeres. This temporal sequence produces 28-and 32-cell stages. At 6th cleavage, macromere and mesomere descendants divide synchronously before the 4 large micromeres divide parasynchronously to produce 56- and 60-cell stages.     

Phosphopyruvate carboxylase activity and carbon dioxide fixation via C4 acids over the division cycle in synchronized Euglena cultures

Summary Phosphoryruvate carboxylase activity was determined in division synchronized Euglena gracilis strain Z cultures. The profile of enzyme activity was essentially that of a peak enzyme; activity increased over the light phase of the cycle, doubling by early dark phase followed by a substantial decline in activity near the end of the dark phase. Dark carbon dioxide fixation did not parallel changes in phosphoryruvate carboxylase activity. The rate of carbon dioxide fixation increased fourfold over the light phase but decreased in the dark phase until it was only double the rate at the beginning of the light phase.Although the specific activity of phosphopyruvate carboxylase was greater than that of ribulose 1–5 diphosphate carboxylase in Euglena cell extracts at all stages over the division cycle C₄ acids were not an early product of carbon dioxide fixation in the light, neither did they ever account for more than a small proportion of the total ¹⁴C present in the soluble fraction of the cells. Phosphopyruvate carboxylase was shown by the non-aqueous localization technique to be present in the cytoplasm in Euglena, and it is concluded that the main function of this enzyme in algal cells is to provide an anaplerotic sequence to the tricarboxylic acid cycle.     

EFFECTS OF THE SURFACTANTS ON THE CLEAVAGE AND FURTHER DEVELOPMENT OF THE SEA URCHIN EMBRYOS 1. THE INHIBITION OF MICROMERE FORMATION AT THE FOURTH CLEAVAGE*

Eggs of the sea urchins, Hemicentrotus pulcherrimus, Temnopleurus toreumaticus and Pseudocentrotus depressus were used as materials. Embryos were exposed to the surfactants such as SLS, CTAB, digitonin, Tween 80, sodium deoxycholate and Lubrol P. If embryos are kept in the solutions of SLS, CTAB and digitonin, 4 vegetal cells of the 8-cell stage divide equally at the fourth cleavage and consequently 16 equal-sized blastomeres are formed at the 16-cell stage. In this case, micromere formation is inhibited by the equal cleavage. The minimum effective concentration of the surfactants for the equal cleavage gradually increases as the time performing the treatment is postponed. The continuous exposure to the surfactant is unnecessary for the inhibition of micromere formation. In the egg temporarily exposed during the earlier stage, the equal cleavage occurs at the fourth division in natural seawater. Micromere formation is strongly affected by the surfactant (SLS) at the mid 4-cell stage.     

Truncated presequences of mitochondrial F1-ATPase β subunit from Nicotiana plumbaginifolia transport CAT and GUS proteins into mitochondria of transgenic tobacco

The mitochondrial F₁-ATPase subunit (ATPase-) of Nicotiana plumbaginifolia is nucleus-encoded as a precursor containing an NH₂-terminal extension. By sequencing the mature N. tabacum ATPase-, we determined the length of the presequence, viz. 54 residues. To define the essential regions of this presequence, we produced a series of 3 deletions in the sequence coding for the 90 NH₂-terminal residues of ATPase-. The truncated sequences were fused with the chloramphenicol acetyl transferase (cat) and -glucuronidase (gus) genes and introduced into tobacco plants. From the observed distribution of CAT and GUS activity in the plant cells, we conclude that the first 23 amino-acid residues of ATPase- remain capable of specifically targeting reporter proteins into mitochondria. Immunodetection in transgenic plants and in vitro import experiments with various CAT fusion proteins show that the precursors are processed at the expected cleavage site but also at a cryptic site located in the linker region between the presequence and the first methionine of native CAT.     

An ultrastructural study of the role of an extracellular matrix during normal cleavage in a marsupial,the brushtail possum

In marsupials, the mechanisms of lineage allocation into pluriblast and trophoblast are related to conceptus polarity and polarized discharge of extracellular matrix (ECM). The brushtail possum, Trichosurus vulpecula, a major pest species in New Zealand, is being intensively studied to develop an immunocontraceptive control method. Of 23 specimens examined, 11 were examined by electron microscopy to study the presence and role of the ECM in lineage allocation in the possum. A number of polarized features in the zygote identified the future embryonic and abembryonic poles. Pronuclei, in a broad band of mitochondrion-rich cortical cytoplasm, lay in the embryonic hemisphere, and numerous electron-lucent vesicles characterized the abembryonic cytoplasm. These vesicles seemed to contribute to the ECM. During cleavage, cells lay near the zona in the embryonic hemisphere, and ECM accumulated chiefly in the abembryonic hemisphere. Cell-zona adhesion facilitated by microvillous and club processes occurred at the early 4-cell stage, and cell-cell adhesion commenced at the late 4-cell stage. The first two cleavages were meridional, equal, and accompanied by elimination into the cleavage cavity of much of the electron-lucent vesicular material in the form of several membrane-bound yolk masses. The third cleavage was unequal, with both meridional and latitudinal planes. The first differences between trophoblast and pluriblast lineages appeared at the 8-cell stage. Later cleavage planes were latitudinal or oblique. Conceptus polarity, polarized discharge of ECM, and localized cell-zona adhesion were related to the first lineage allocation in the possum. Mol. Reprod. Dev. 50:420–433, 1998. © 1998 Wiley-Liss, Inc.