COLONY FORMATION AND SEXUAL MORPHOGENESIS IN THE COCCOLITHOPHORE PLEUROCHRYSIS SP. (HAPTOPHYTA)1

Pleurochrysis sp. formed two types of symmetrical, diploid colonies on solid media: (i) single‐cell lineage (SCL) colonies and (ii) aggregation (AG) colonies. The first division of a single mother cell was asymmetric in ～54% of SCL colonies. These colonies developed at a slower rate than AG colonies. Diffusible molecules released from the cells acted like morphogens enhancing formation of AG colonies; their influence on chemotaxis of aggregating cells was dependent on concentration of the inoculum. Nitrogen depletion of diploid colonies induced sexual morphogenesis and colony patterning into inner and outer regions. The smaller innermost cells were surrounded by outer larger cells. Developmental mechanisms of colony formation were examined in relation to the heteromorphic, haplo‐diploid life cycle.     

Specifying positional information in the embryo: looking beyond morphogens

Concentration gradients of small diffusible molecules called morphogens are key regulators of development, specifying position during pattern formation in the embryo. It is now becoming clear that additional or alternative mechanisms involving interactions among cells are also crucial for positional specification.     

Morphogens: experimental illusion or reality?

The main attention is paid to the critical analysis of experimental data on morphogenetically active substances, so called "morphogens". It is proposed to consider the morphogens as specific transmitters providing for definite phases of morphogenetic tissues interactions, rather than as vectors of "morphogenetic information". In the normal development, the most studied morphogenetic tissue interactions can be referred to as so called permissive inductions, since the cells of the vertebrate embryos (amphibians, avians) are early determined for development in the ectomeso--and endodermal directions. A slow progress in studying the morphogens can be due to the following causes. 1. Theoretical "inadequacy" of the former concepts on the essence and mechanisms of embryonic induction. The necessity to develop a new system of concepts in this area of developmental biology is stressed. 2. Incompleteness of knowledge about the properties of reacting tissues and the mechanisms of action of morphogens. The early gastrula ectoderm of amphibians, most frequently used for testing the morphogens, appears to be a heterogenous population of the cells with different properties and potencies. It is, therefore, impossible to standardize strictly the biotesting of morphogens. It is suggested that the use to this end of aggregates of cell "strains" from the gastrula ectoderm, rather than of the gastrula ectoderm itself, may be more adequate 3. Insufficiency of embryonic material for biochemical identification and isolation of natural morphogens. A study of so called heterogenous inductors might be of help; these latter can be considered as analogs of natural morphogens. But the similarity of natural and heterogenous inductors can be limited only by their final effect on target tissue. The data are provided on the chemical nature, properties and mechanisms of action for a number of natural and heterogenous inductors (vegetalizing, neuralizing, mesodermalizing, lens-inducing factors). A conclusion is drawn that specific antigens do exist normally but they should not be established as a special class of "informationally important" molecules. The information necessary for development is contained in target cells and the function of a morphogen consists in providing for a definite link in the chain of processes leading to the switching on or expression of one or another programme. Only syntheses of specific proteins can, apparently, be programmed, thus reflecting the "onset" of differentiation path for a cell.     

The Decapentaplegic morphogen gradient: a precise definition

Two key processes are in the basis of morphogenesis: the spatial allocation of cell types in fields of na?ve cells and the regulation of growth. Both are controlled by morphogens, which activate target genes in the growing tissue in a concentration-dependent manner. Thus the morphogen model is an intrinsically quantitative concept. However, quantitative studies were performed only in recent years on two morphogens: Bicoid and Decapentaplegic. This review covers quantitative aspects of the formation and precision of the Decapentaplegic morphogen gradient. The morphogen gradient concept is transitioning from a soft definition to a precise idea of what the gradient could really do.     

Morphogens and endocytosis

During development, secreted signaling proteins of the Wingless/Wnt, Hedgehog and Decapentaplegic (Dpp)/Bone Morphogenic Protein (BMP) families act as morphogens. Previous work had shown that these molecules act directly on distant cells, although until recently nothing was known about how they reach those distant cells. During the past two years, work carried out on Drosophila using genetic and cell biology approaches have revealed that endocytosis plays a central part in the mechanisms that control the spread of morphogens.     

Potential morphogens involved in pattern formation during Dictyostelium differentiation.

Upon starvation, Dictyostelium amoebae aggregate together and then differentiate into either the stalk or spore cells that, respectively, form the stalk and sorus of the fruiting body. During differentiation, the prestalk and prespore cells become spatially segregated in a clearly defined developmental pattern. Several low molecular weight molecules that influence cell type determination during in vitro differentiation have been identified. The possible role of these molecules as morphogens, responsible for the formation of the developmental pattern, is discussed.     

Developmental roles of heparan sulfate proteoglycans in Drosophila

The formation of complex patterns in multi-cellular organisms is regulated by a number of signaling pathways. In particular, the Wnt and Hedgehog (Hh) pathways have been identified as critical organizers of pattern in many tissues. Although extensive biochemical and genetic studies have elucidated the central components of the signal transduction pathways regulated by these secreted molecules, we still do not understand fully how they organize gradients of gene activities through field of cells. Studies in Drosophila have implicated a role for heparan sulfate proteoglycans (HSPGs) in regulating the signaling activities and distribution of both Wnt and Hh. Here we review these findings and discuss various models by which HSPGs regulate the distributions of Wnt and Hh morphogens. Published in 2003.     

BMP type I receptor complexes have distinct activities mediating cell fate and axon guidance decisions

The finding that morphogens, signalling molecules that specify cell identity, also act as axon guidance molecules has raised the possibility that the mechanisms that establish neural cell fate are also used to assemble neuronal circuits. It remains unresolved, however, how cells differentially transduce the cell fate specification and guidance activities of morphogens. To address this question, we have examined the mechanism by which the Bone morphogenetic proteins (BMPs) guide commissural axons in the developing spinal cord. In contrast to studies that have suggested that morphogens direct axon guidance decisions using non-canonical signal transduction factors, our results indicate that canonical components of the BMP signalling pathway, the type I BMP receptors (BMPRs), are both necessary and sufficient to specify the fate of commissural neurons and guide their axonal projections. However, whereas the induction of cell fate is a shared property of both type I BMPRs, axon guidance is chiefly mediated by only one of the type I BMPRs, BMPRIB. Taken together, these results indicate that the diverse activities of BMP morphogens can be accounted for by the differential use of distinct components of the canonical BMPR complex.     

Molecular genetics of cell death in the nematode Caenorhabditis elegans

In C. elegans, cell death can be readily studied at the cellular, genetic, and molecular levels. Two types of death have been characterized in this nematode: (1) programmed cell death, which occurs as a normal component in development; and (2) pathological cell death which occurs aberrantly as a consequence of mutation. Analysis of mutations that disrupt programmed cell death in various ways has defined a genetic pathway for programmed cell death which includes genes that perform such functions as the determination of which cells die, the execution of cell death, the engulfment of cell corpses, and the digestion of DNA from dead cells. Molecular analysis is providing insightinto the nature of the molecules that function in these aspects of programmed cell death. Characterization of some genes that mutate to induce abnormal cell death has defined a novel gene family called degenerins that encode putative membrane proteins. Dominant alleles of at least two degenerin genes, mec-4 and deg-1, can cause cellular swelling and late onset neurodegeneration of specific groups of cells. © 1992 John Wiley & Sons, Inc.     

From Biochemistry to Morphogenesis in Myxobacteria

Many aspects of metazoan morphogenesis find parallels in the communal behavior of microorganisms. The cellular slime mold D. discoideum has long provided a metaphor for multicellular embryogenesis. However, the spatial patterns in D.d. colonies are generated by an intercellular communication system based on diffusible morphogens, whereas the interactions between embryonic cells are more often mediated by direct cell contact. For this reason, the myxobacteria have emerged as a contending system in which to study spatial pattern formation, for their colony strutures rival those of D.d. in complexity, yet communication between cells in a colony is carried out by direct cell contacts. Here I sketch some of the progress my laboratory has made in modeling the life cycle of these organisms.     

Morphogens in motion: growth control of the neural tube

The entire vertebrate nervous system develops from a simple epithelial sheet, the neural plate which, along development, acquires the large number and wide variety of neuronal cell types required for the construction of a functional mature nervous system. These include processes of growth and pattern formation of the neural tube that are achieved through complicated and tightly regulated genetic interactions. Pattern formation, particularly in the vertebrate central nervous system, is one of the best examples of a morphogen-type of function. Cell cycle progression, however, is generally accepted to be dependent on cell-intrinsic factors. Recent studies have demonstrated that proliferation of neural precursors is also somehow controlled by secreted signaling molecules, well-known by their role as morphogens, such as fibroblast growth factor (FGF), vertebrate orthologs of the Drosophila wingless (Wnt), hedgehog (Hh), and transforming growth factor beta (TGF-beta) families, that in turn regulate the activity of factors controlling cell cycle progression. In this review we will summarize the experimental data that support the idea that classical morphogens can be reused to regulate proliferation of neural precursors.     

A new type of collagen produced by mouse cells derived from early embryonic sources

We have previously demonstrated that cell lines derived from a mouse teratocarcinoma source or a mouse blastocyst source produce procollagen and collagen, and suggested that this material may represent a new form of collagen specifically related to early embryonic development. We have now obtained further evidence using carboxymethyl cellulose chromatography, analytical isoelectric focusing, cyanogen bromide peptide analysis, amino acid analysis, and carbohydrate analysis that these two cell lines produce identical collagen molecular types which are distinctly different from types I, II, III, and IV collagen and thus probably represent a new type of collagen, called type V. All of these new data add support to the contention that these teratocarcinoma and blastocyst derived cells correspond to a cell present in the mouse embryo which may be a primitive or mesenchymal connective tissue cell type. Thus, these collagen and procollagen molecules may serve as a marker for cells of the early mouse embryo which are committed to the lineage of connective tissue.     

The fine structure of blood cells in the ascidian Perophora viridis

The fine structure of each of the blood cell types of Perophora viridis has been characterized and strong evidence for localization of vanadium in two of these types is given. There are eight cell types; phagocytes which may contain completely engulfed cells, lymphocytes with a prominant nucleolus and scanty cytoplasm packed with clustered ribosomes, and six other cell types each with distinctive granules. Morula cells contain a central nucleus and cytoplasm filled by wedged bodies, about five of which are seen in section. These bodies contain regularly spaced electron dense foci. Green cells have the same organization but contain bodies which are electron dense throughout. Granular amoebocytes contain many smaller lightly staining oval bodies and much glycogen. Another cell type (probably orange cells of light microscopy) contains numerous granular rounded bodies. Compartment cells have vacuoles containing electron dense particles and signet ring cells have usually one large vacuole which is electron dense lined and may contain electron dense particles. Developmental stages of these cell types show involvement of endoplasmic reticulum and Golgi bodies in granule formation. After glutaraldehyde fixation alone the only extremely electron dense components are particles in the compartment cells and signet ring cells implicating these as sites of vanadium localization, although not excluding other cell types.     

Cell cycle regulation in the course of nodule organogenesis in Medicago

The molecular mechanisms of de novo meristem formation, cell differentiation and the integration of the cell cycle machinery into appropriate stages of the developmental programmes are still largely unknown in plants. Legume root nodules, which house nitrogen-fixing rhizobia, are unique plant organs and their development may serve as a model for organogenetic processes in plants. Nodules form and are essential for the plant only under limitation of combined nitrogen in the soil. Moreover, their development is triggered by external mitogenic signals produced by their symbiotic partners, the rhizobia. These signals, the lipochitooligosaccharide Nod factors, act as host-specific morphogens and induce the re-entry of root cortical cells into mitotic cycles. Maintenance of cell division activity leads to the formation of a persistent nodule meristem from which cells exit continuously and enter the nodule differentiation programme, involving multiple cycles of endoreduplication and enlargement of nuclear and cell volumes. While the small diploid 2C cells remain uninfected, the large polyploid cells can be invaded and, after completing the differentiation programme, host the nitrogen-fixing bacteroids. This review summarizes the present knowledge on cell cycle reactivation and meristem formation in response to Nod factors and reports on a novel plant cell cycle regulator that can switch mitotic cycles to differentiation programmes.     

Important roles for epithelial cell peptides in hydra development

It has been convincingly shown that peptides play important roles in the regulation and maintenance of a variety of tissues and organs in living animals. However, little is known concerning the potential role of peptides as signaling molecules in developmental processes. In Hydra, there is circumstantial evidence that small diffusible molecules act as morphogens in the regulation of patterning processes. In order to view the entire spectrum of peptide signaling molecules, we initiated a project aiming at the systematic identification of peptide signaling molecules in Hydra. In this review, we describe three peptide signaling molecules and one family of peptides that function as signaling molecules in the processes of axial pattern formation and neuron differentiation in Hydra. These peptides are produced by epithelial cells and are therefore termed “epitheliopeptides”. We discuss the importance of epitheliopeptides in developmental processes within a subset of hydrozoans.     

Spontaneous autoradiographic grain activation associated with mast cells in methacrylate plastic embedded tissue sections

Autoradiographic tracing using tritium labeled compounds or cells is a common laboratory technique for light and electron microscopy. This report describes a chemographic effect associated with certain cells in sections from tissues embedded in the new methacrylate plastic embedding compounds. When tissue sections from rats and rhesus monkeys that received no radioisotope were coated with nuclear track emulsion and subsequently developed, cells with morphologic characteristics of mast cells showed significant grain formation over the entire cell. Three different types of methacrylate plastics were tested using rat and monkey tissues and all three were found to promote grain formation over mast cells; however, this phenomenon was not seen in similar tissue sections from paraffin or epoxy embedded material. The properties of methacrylate plastics which promote positive chemography by mast cells may reflect the greater permeability of this class of plastics. Due to their wide tissue distribution, the presence of such chemographically active cells could cause false estimates of the distribution of either exogenous radiolabeled cells or radioisotopes within many tissues.     

Conjugation in the Ciliate Euplotes octocarinatus: Comparison of Ciliary and Cell Body-Associated Glycoconjugates of Non-mating-Competent, Mating-Competent, and Conjugating Cells

Pair formation in the hypotrichous ciliate Euplotes octocarinatus is a poorly understood phenomenon. In order to obtain information about the molecules involved in this process, we compared ciliary and cell body-associated glycoconjugates of non-mating-competent, mating-competent, and conjugating cells. Detection of glycoconjugates was carried out on Western blots by immunostaining of oxidized, digoxigenin-labeled carbohydrate moieties. Using this method, in both of two complementary mating types a 130-kDa glycoprotein was identified, which appeared on cilia during acquisition of mating competence and was reduced during cell pairing. This suggests an active role of this glycoprotein in ciliary adhesion during pair formation, Additionally, in both of the two mating types a cell body-associated 135-kDa glycoprotein was detected, which is present in non-mating-competent cells as well as in mating-competent cells, but is strongly reduced in conjugating cells. In contrast to the ciliary 130-kDa glycoprotein, the cell body-associated 135-kDa glycoprotein is not surface-exposed [8]. We therefore propose that the cell body-associated glycoprotein is either involved in the preparation for cell fusion or meiosis or that it serves as a cytoplasmic pool for the ciliary 130-kDa glycoprotein.     

Control of spatial patterning and cell-type proportioning in Dictyostelium

The spatial patterning of prestalk and prespore cells in the slug arises from the differential sorting of newly differentiated cell types as the mound forms. This pattern is highly organized along an anterior-posterior axis and is constant irrespective of the size of the organism. Cell-type differentiation is plastic until late in development. A change in the ratio of cell types resulting from removal of part of the slug leads to a rapid restoration of the original ratio of the cell types through a pathway involving dedifferentiation, redifferentiation, and sorting of the existing cells. This review provides insight into various molecules, morphogens, and pathways regulating spatial patterning and cell-type proportioning.