The origin of skeleton forming cells in the sea urchin embryoUrben, Susan; Nislow, Corey; Spiegel, Melvin
doi: 10.1007/bf00385678pmid: 28305470
SummaryIn embryos of the “modern” sea urchin species, subclass Euechinoidea, primary mesenchyme cells are derived from the progeny of micromeres formed at the sixteen cell stage of embryogenesis. The micromeres reside within the vegetal plate epithelium and later ingress into the blastocoel as primary mesenchyme cells which form the larval skeleton. Embryos of Eucidaris tribuloides, a member of the “primitive” subclass Perischoechinoidea, exhibit several noteworthy differences from euechinoid primary mesenchyme cell lineage including variable numbers and sizes of micromeres, the absence of mesenchyme ingression, and the lack of any detectable primary mesenchyme although a larval skeleton forms. In the present study, the cell lineage of the spiculogenic mesenchyme has been studied in Eucidaris tribuloides and in the euechinoid Lytechinus pictus by microinjecting the fluorescent tracer, Lucifer Yellow, into individual blastomeres of the embryo. In addition, wheat germ agglutinin, a lectin which binds only to primary mesenchyme cells of the early euechinoid embryo, was injected into the blastocoel of embryos of both species in order to examine the distribution of cells which possess primary mesenchyme-specific cell surface markers. The results of these experiments demonstrate that the spiculogenic mesenchyme of both Lytechinus and Eucidaris arise from descendants of micromeres formed at the sixteen cell stage, although the temporal and spatial distribution of these mesenchyme cells varies considerably between species. Furthermore, the evidence obtained suggests that the information necessary for spicule formation is already segregated to the vegetal pole by the eight cell stage. The results also suggest that there are no gap junctions present between the blastomeres of the early sea urchin embryo.
Two groups of interrelated genes regulate early neurogenesis in Drosophila melanogasterBrand, Michael; Campos-Ortega, José A.
doi: 10.1007/bf00385679pmid: 28305471
SummaryIn Drosophila melanogaster the neuroblasts separate from epidermoblasts to give rise to the neural primordium. This process is under the control of several genes. The group of the so-called neurogenic genes is required for epidermal development; other genes, comprising those of the achaete-scute complex and daughterless, are required for neural development. We have studied the relationships between both groups of genes in two different ways. We have analyzed the phenotype of double-mutant embryos and our results show that the neural hyperplasia caused by neurogenic mutations can be partially prevented if a mutation in one of the other genes is present in the same genome. Only the neural cells that do not require the function of a particular gene of the achaete-scute complex in the wild-type seem to develop to a neural fate in the double mutant embryos. At least some of the genetic interactions affect the transcriptional level, as shown by in situ hybridization, since the territories of transcription of the achaetescute genes are expanded in neurogenic mutants. All cells of the neurogenic region of the double mutants apparently initiate neural development. However, during later development some of these cells switch their fate either to epidermogenesis or to cell death and this leads to the final phenotype of the double mutants. We discuss these results with respect to the events of early neurogenesis.
Nerve cell and nematocyte production in Hydra is deregulated by lithium ionsHassel, Monika; Berking, Stefan
doi: 10.1007/bf00385680pmid: 28305472
SummaryLiCl, a well-known vegetalising agent, interferes with the commitment of stem cells to nerve cells and nematocytes in Hydra attenuata. Treatment with 20 mM LiCl inhibits commitment to nerve cells, treatment with 1 mM LiCl inhibits commitment to nematocytes. However, LiCl does not prevent stem cells committed to the nematocyte pathway from dividing and differentiating into nests of nematocytes. Following LiCl treatment, determination to nerve cells and nematocytes is triggered again. Commitment to nerve cells is strongly stimulated within the first 3 h following pulse treatment with LiCl if the animals have been fed immediately prior to treatment. In Hydra exposed to LiCl for 10 days the stem cell density is reduced by at least 90% of the initial value, and nematocytes are almost completely missing, whereas the density of nerve cells is within the normal range in animals with normal morphology. Animals which developed a transverse constriction in the middle of the body axis contain a 1.7-fold higher nerve cell density in the lower part than is observed in control animals.
Interactions between janus and bcd cortical pattern mutants in Tetrahymena thermophilaCole, Eric Stephen; Frankel, Joseph; Jenkins, Leslie Meek
doi: 10.1007/bf00385681pmid: 28305473
SummaryAn analysis of bcd, janA; bcd, janB; and bcd, janC double-mutant phenotypes in Tetrahymena thermophila has allowed us to examine patterning processes affected by two different classes of mutations. bcd brings about a broadening of the oral and contractile vacuole pore domains in the ciliate cortex, while the janus mutations generate a mirror-image duplication of the ventral cortical pattern. We observed both bcd and janus characteristics expressed in the double mutants, as well as features unique to the double-mutant. Temperature-shift experiments employing the temperature-sensitive janB mutation in a double-mutant (bcd, janB) combination allowed us to observe the changes in pattern as a mirror-image geometry was brought into expression and subsequently removed within the bcd, janB double homozygote. These experiments suggest that there are multiple pattern-mechanisms at work with differing kinetics of expression in the ciliate cortex. We discuss how the bcd mutation could influance expression of the janus mutations in light of a model previously proposed to account for the janus phenotype.
Cell-specific endopolyploidy in developing ArtemiaFreeman, John A.; Chronister, Robert B.
doi: 10.1007/bf00385682pmid: 28305474
SummaryCells in developing Artemia franciscana SFB demonstrated tissue-specific differences in DNA content, as determined by fluorescence intensity of bisbenzimide-stained nuclei and by nuclear area. The general epidermis comprised proliferating diploid (2C) cells. The setal cells had 4C–8C DNA content and did not divide during the first two instars. Salt gland cells were polyploid (>8C) and also did not undergo mitosis. Neural cells in the brain were diploid and were replicating. Cells in the thorax region of the gut had a 4C–8C DNA content and were proliferating. The muscle cells in the cephalic appendages contained 2C non-replicating nuclei. Only diploid epidermal cells were involved in segment morphogenesis. There was no difference in number of chromosomes (n=42) in the epidermal cells and the gut cells, indicating that the tissue-specific endopolyploidy was due to endoreduplication.
Role of hormones in starvation-induced delay in larval hemolymph protein gene expression in Galleria mellonellaMemmel, Nancy Ann; Ray, Aparna; Kumaran, Alapati Krishna
doi: 10.1007/bf00385683pmid: 28305475
SummaryDevelopmental Northern analysis of larval hemolymph protein gene transcripts in Galleria mellonella showed that Lhp76 is expressed all through the larval life, while Lhp82 is expressed only during the last larval stadium. Neither transcript was detectable in pharate adults and adult moths. In addition, these transcripts were not detectable during the first 48 h of the last larval stadium. Experimental analyses of the effects of the nutritional state and the hormonal levels of the last instar larvae on LHP gene expression suggests that the nutritional state of the larva has no direct effect, but nutrition acts through its effect on the hormone titers. Larvae starved after the first 24 h of the stadium and those fed on a non-protein diet produced both the transcripts on schedule on day 3. However, starvation during the first 24 or 48 h or feeding them on agar caused a marked delay in activation of Lhp82. These starved larvae pupated 4 to 12 days later than controls. Furthermore, JH titers in the starved larvae remain high even 5 days after ecdysis into the last instar. Prothorax-ligation of the starved and the starved-refed larvae accelerated production of the transcripts, thereby suggesting that the nutritional state does not directly affect LHP gene expression. Application of JH 1 to the ligated preparations resulted in selective blocking of Lhp82, while 20-OH ecdysone affected both the genes, thereby supporting the view that the insect hormones play an important role in stage-specific expression of LHP genes.
Expression of a reporter gene resembles that of its neighbour: an insertion in the hairy gene of DrosophilaFasano, Laurent; Coré, Nathalie; Kerridge, Stephen
doi: 10.1007/bf00385685pmid: 28305477
SummaryRandom insertions of a promotor fused to a reporter gene, such as Lac-Z, reveal regulatory sequences that confer temporal and spatial patterns of gene expression in eukaryotes. These patterns may reflect the activity of a neighbouring gene and thus lead to the isolation of new genes essential for normal development. Here, we demonstrate that this hypothesis is true for an insertion into the well characterized segmentation gene, hairy, in Drosophila. The insertion is homozygous lethal and fails to complement other hairy alleles, giving the phenotype described for hairy mutations. The insertion is located at 66D on the polytene chromosome map, is within 300–600 bp 5′ to the first hairy exon, and is orientated in the same sense (5′-3′) as the hairy transcription unit. Expression of β-galactosidase (β-gal), deriving from the insertion, follows closely the spatio-temporal patterns of expression of hairy gene product during embryogenesis. In addition, other sites of β-galactosidase expression are shown in the third larval instar stage and in the adult ovary. The results show that some insertions, giving restricted patterns of reporter gene expression, will reflect the temporo-spatial activity of a nearby gene.
A traction-based mechanism for somitogenesis in the chickBard, Jonathan B. L.
doi: 10.1007/bf00385686pmid: 28305478
SummaryThis paper suggests that chick somites form because presomitic cells exert tractional forces on one another. These forces derive from the increase in cell adhesion and density that occurs as N-CAM and N-cadherin are laid down by the motile cells of the presomitic mesoderm, well before the somites form. Harris et al. (1984) have shown that adhesive and motile cells in an appropriate environment in vitro can spontaneously form aggregates under the influence of the tractional forces that they exert. Presomitic mesodermal cells may behave similarly: as CAM production increases local adhesivity, the tractional forces between the cells should become sufficiently strong for groups of cells to segment off the mesenchyme as somites. The successive expression of CAMs down the presomitic mesoderm will thus lead to the formation of an anterior-posterior sequence of somites. This mechanism can explain several aspects of somitogenesis that models generating a repetitive pre-pattern through gating cohorts of cells find hard to explain: first, mesodermal segregation occurs among highly adherent cells; second, that multiple rows of somites can form in embryos cultured on highly adherent substrata; third, that stirred mesoderm will still form normal somites; and, fourth, how somite size can be altered in heat-shocked embryos and elsewhere. Suggestions are given as to how the mechanism may be tested and where else in the embryo it could apply.