Developmental regulation of gene expression in Tetrahymena

The onset of gene expression in Tetrahymena thermophila during macronuclear differentiation was investigated by assay of galactokinase in conjugating deoxygalactose-resistant heterokaryons. Our results distinguish three successive states of galactokinase gene expression for cells developing a new macronucleus: stage 0, refractory to induction; stage 1, inducible by refeeding; and stage 2, induced. The refractory period ends at 12 to 13 hr after the onset of conjugation; this corresponds to the time of pair separation, and occurs several hours after the new macronuclei have become morphologically distinguishable. Stage 1 cells behave indistinguishably from mature starved cells. Inhibitor studies suggest that galactokinase synthesis is induced coincidentally with the induction of bulk protein synthesis during conjugation: thus it behaves developmentally like a typical protein; and that galactokinase mRNA is probably transcribed within 1 hr prior to its translation. Thus, when conjugating cells are refed during the refractory period, some developmental condition prevents the swift induction of protein (and galactokinase) synthesis observed upon refeeding starved (nonmating) cells. The possible nature of this developmental phenomenon is discussed.     

STAGING OF NEWT BLASTULA EMBRYOS AND FIRST APPEARANCE OF PRIMARY MESODERMAL COMPETENCE

Using the swimbladder of the crusian carp ( Carrasius auratus ) as an inductor, the first appearance of mesodermal competence in the presumptive ectoderm of the newt ( Triturus pyrrhogaster ) blastula was investigated. The time course of embryonic development before the gastrula stage was determined by counting the number of surface cells on a 0.25 mm line at the animal pole. Pregastrula embryos with 2–3, 4–5, 6–7 and 7–8 cells roughly correspond to those at 14, 14–12, 8–6 and 4–0 hr before the beginning of gastrulation. Using presumptive ectoderm of the early gastrula stage, 15 min was found to be the minimum time of contact necessary for the realization of induction. The reactivity of the presumptive ectoderm from pregastrula embryos was tested by 30 min contact. Presumptive ectoderm up to the 4–5 cell stage did not react to the inductor. It may become competent within the next 4–8 hr, since the ectoderm from embryos in the 6–7 cell stage was reactive.     

THE EFFECTS OF ACTINOMYCIN D ON MUSCLE CELLS OF ASCIDIAN EMBRYO*

The effect of actinomycin D on muscle cells development of the ascidian, Herdmania momus was studied ultrastructurally. No myofilament was formed when the drug was given at any stage before early tail-bud stage (stage 3). Some aggregates of myofilaments in various size were formed when the treatment was started at stage 4 (4.5 hr after fertilization at about 28°C). Above 60% of myofibrils of fully differentiated muscle cells were formed when the treatment was initiated at stage 5 (5 hr after fertilization). Muscle cells of the tadpoles treated from stage 7 (6 hr after fertilization), at which myofilaments were first detectable in normal development, differentiated almost normally. It is therefore suggested that most mRNAs for muscle proteins are synthesized preceding the onset of myofilament formation and are relatively stable. It is also suggested that mRNAs for myosin, actin and Z band materials are almost simultaneously synthesized. One of the characteristic features of the muscle cell development of the ascidian embryo is almost synchronous differentiation of relatively small numbers of cells (about 54–60 cells). The significance of these results is discussed in relation to mosaic natures of the muscle development.     

Purification and characterization of actophorin, a new 15,000-dalton actin-binding protein from Acanthamoeba castellanii

Actophorin is a new actin-binding protein from Acanthamoeba castellanii that consists of a single polypeptide with a molecular weight of 15,000. The isoelectric point is 6.1, and amino acid analysis shows an excess of acidic residues over basic residues. The phosphate content is less than 0.2 mol/mol. There is 0.4 +/- 0.1 mg of actophorin/g of cells, so that the molar ratio of actin to actophorin is about 10:1 in the cell. Unique two-dimensional maps of tryptic and chymotryptic peptides and complete absence of antibody cross-reactivity show that Acanthamoeba actophorin, profilin, capping protein, and actin are separate gene products with minimal homology. Actophorin has features of both an actin monomer-binding protein and an actin filament-severing protein. Actophorin reduces the extent of actin polymerization at steady state in a concentration-dependent fashion and forms a complex with pyrene-labeled actin that has spectral properties of unpolymerized actin. During ultracentrifugation a complex of actophorin and actin sediments more rapidly than either actin monomers or actophorin. Although actophorin inhibits elongation at both ends of actin filaments, it accelerates the late stage of spontaneous polymerization like mechanical shearing and theoretical predictions of polymer fragmentation. Low concentrations of actophorin decrease the length and the low shear viscosity of actin filaments. High concentrations cause preformed filaments to shorten rapidly. Ca2+ is not required for any of these effects. Muscle and amoeba actin are equally sensitive to actophorin.     

MITOTIC ACTIVITY AND CELL PROLIFERATION IN PRIMARY INDUCTION OF NEWT EMBRYO

Mitotic activity and cell proliferation of newt ( Triturus pyrrhogaster ) embryo were examined with special reference to primary induction.
Mitotic activity of gastrula ectoderm gradually decreases during gastrulation. The ectoderm, which is isolated from mid-gastrula (stage 12b) and cultured in vitro , also shows gradual decrease in mitotic activity during cultivation and the mitotic activity steeply decreases after 48 hr.
The ectoderm cultured with heterologous inductor (GPL-extract) shows a temporal suppression in mitotic activity. The ectoderm of the whole gastrula also shows a regional suppression where it is in contact with the chorda-mesoderm.
The number of the ectodermal cells increases about 2 times after 24 hr culture and to more than 3 times after 48 hr culture. Accordingly it is certain that the majority of the ectodermal cells divides at least one time in the course of 48 hr.
Histological examination of the ectoderm cultured together with the inductor reveals that differentiation of undifferentiated ectoderm to neural tissues is accomplished at least within 48 hr after cultivation with the inductor.
The present examination shows the possibility that the mitotic activity of the ectoderm may be temporarily suppressed by the inductor and that it then decreases along with neural cell differentiation after recovery of the activity.
The results also suggest that the determination of undifferentiated ectoderm to neural tissues occurs before the second cell division after the contact with the inductor and the events occurring during the first cell cycle after activating by the inducing stimulus are critical for the primary induction.     

Induction of connective tissue growth factor by activation of heptahelical receptors. Modulation by Rho proteins and the actin cytoskeleton

Expression of connective tissue growth factor (CTGF) was induced in renal mesangial cells by activation of heptahelical receptors by serotonin (5-HT) and lysophosphatidic acid (LPA). Induction of CTGF mRNA was transient with maximal expression after 1 to 2 h, whereas induction of CTGF by transforming growth factor beta (TGF-beta) increased over time. In contrast to the induction of other early response genes (Egr-1 and cyclooxygenase-2), LPA-mediated induction of CTGF was pertussis toxin-insensitive and independent of p42/44 MAP kinase activation. 5-HT-mediated CTGF induction was due to activation of 5-HT(2A) receptors and likewise independent of p42/44 MAP kinase activation. Upon stimulation, enhanced levels of CTGF protein were detected in cellular homogenates, whereas no protein was detectable in cell culture supernatants. Inhibition of proteins of the Rho family by toxin B abrogated basal as well as CTGF expression stimulated by LPA, 5-HT, and TGF-beta. Inhibition of the downstream mediator of RhoA, the Rho kinase by Y-27632 partially reduced induction of CTGF by LPA and TGF-beta. Toxin B not only affected gene expression, but disrupted the actin cytoskeleton similarly as observed after treatment with cytochalasin D. Disassembly of actin stress fibers by cytochalasin D partially reduced basal and stimulated CTGF expression. These data indicate that an intact actin cytoskeleton is critical for the expression of CTGF. Elimination of the input of Rho proteins by toxin B, however, was significantly more effective and their effect on CTGF expression thus goes beyond disruption of the cytoskeleton. These findings thus establish activation of heptahelical receptors coupled to pertussis toxin-insensitive G proteins as a novel signaling pathway to induce CTGF. Proteins of the Rho family and an intact cytoskeleton were identified as critical determinants of CTGF expression induced by LPA and 5-HT, and also by TGF-beta.     

Requirement of cell division for muscle actin expression in the primary muscle cell lineage of ascidian embryos

The role of cell division in the expression of muscle actin and its relationship to acetylcholinesterase (AChE) development was examined in cleavage-arrested embryos of the ascidian Styela. Muscle actin expression was detected by two-dimensional gel electrophoresis of radioactively labelled proteins and by in situ hybridization with a cDNA probe, whereas AChE activity was assayed by enzyme histochemistry. In the majority of cases, muscle actin expression was first detected in embryos arrested after the 16-cell stage. Some embryos showed muscle actin expression after arrest at the 8-cell stage, however, muscle actin mRNA did not accumulate in embryos arrested at earlier cleavages. The cells that expressed muscle actin in 8- to 64-cell cleavage-arrested embryos belonged to the primary muscle lineage; secondary muscle cell precursors did not express muscle actin. Zygotic muscle actin mRNA appeared to accumulate with myoplasmic pigment granules in the perinuclear region of cleavage-arrested embryos, suggesting that the myoplasm may have a role in the organization of muscle cells. In contrast to muscle actin, AChE was detected in a small proportion of embryos treated with cytochalasin as early as the 1- or 2-cell stage, and most embryos treated with cytochalasin at later cleavages expressed this enzyme in some of their cells. Most primary muscle lineage cells expressed both muscle actin mRNA and AChE, however, some cells expressed only muscle actin mRNA or AChE. The results suggest that at least three cleavages are required for muscle actin expression and that muscle actin and AChE expression can be uncoupled in cleavage-arrested embryos.     

T cell induction of membrane IL 1 on macrophages

We have studied the role of T cells in the induction of a membrane-associated form of interleukin 1 (mIL 1) in murine macrophages. T helper cell clones and a T cell hybridoma induced macrophages to express mIL 1 after an antigen-specific, Ia-restricted interaction. Induction of mIL 1 was proportional to antigen concentration and was increased in the early course of the response in macrophages pretreated in culture with interferon-gamma. mIL 1 activity was detectable 4 hr after interaction with T cells. mIL 1 induction was inhibited by antibodies to either class II molecules or the T cell receptor. Two pathways of T cell-mediated mIL 1 induction could be defined. In the first, T cells, whose protein synthesizing capacity was completely eliminated by pretreatment with the irreversible protein synthesis inhibitor emetine, induced levels of mIL 1 expression indistinguishable from controls. In the second, T cells stimulated by paraformaldehyde-fixed macrophages in the presence of concanavalin A or antigen secreted a soluble factor that induced macrophage mIL 1 expression. Thus, it appears that T cells may induce macrophages to express mIL 1 both by direct cell-cell contact mediated through binding of T cell receptor to the Ia/antigen complex, and through the release of a lymphokine after activation. This lymphokine does not appear to be IL 2, IFN-gamma, BSF-1, or CSF-1.     

Elevation of apoptotic potential by anoxia-hyperoxia shift in NIH3T3 cells

Apoptosis has been hypothesized to be mediated through the induction of free radicals via oxidative pathway. In this study, we demonstrated the induction of cellular apoptosis by anoxia-hyperoxia shift, but not by anoxia or hyperoxia alone in NIH3T3 cells. The decrement of ROS by anoxia thus appears to be an essential early event leading to apoptosis. G1 arrest was detected in anoxia-treated cells, and postanoxic oxygen recovery could reverse this effect, and induce apoptosis. On analysis of the binding activity of AP-1, we found biphasic induction of binding ability in cells undergoing anoxia-hyperoxia shift. In the early stage of anoxia, a transitional increase of AP-1 binding activity was detected, which was reduced to the minimal levels after 24 h of anoxia. During the period of postanoxic hyperoxia treatment, the binding activity of AP-1 was reinduced and increased remarkably with time up to 24 h. These results were in accordance with the expressions of c-jun and c-fos proteins. Enhancement of poly(ADP-ribosyl)ation activities, especially ADP-ribosylation of histone H1 was detected in post-anoxic hyperoxia-treated cells, and cleavage of PARP and activation of caspase 3 were also observed in post-anoxic hyperoxia (recovery) treated cells, but not in anoxia-treated cells. We propose that the differential induction of c-jun/c-fos (AP-1) gene expressions and sequential activation of PARP activity are essential in anoxia/hyperoxia-induced apoptosis     

Embryonic induction and muscle gene activation

Embryonic induction, a process in which the differentiation of a cell is determined by its proximity to other kinds of cells, is of major importance in animal development. We review here what is known of the steps by which a muscle-specific actin gene is first activated by embryonic induction in early amphibian embryos.     

Induction of proopiomelanocortin mRNA expression in animal caps of Xenopus laevis embryos

To convert animal pole cells of a frog embryo from an ectodermal fate into a neural one, inductive signals are necessary. The alkalizing agent NH4Cl induces the expression of several anterior brain markers and the early pituitary marker XANF-2 in Xenopus animal caps. Here it is demonstrated that NH4Cl also induced proopiomelanocortin (POMC)-expressing cells (the first fully differentiated pituitary cell type) in stage 9 and 10 Xenopus animal caps, and that all-trans retinoic acid, a posteriorizing agent, was able to block this induction when it was administered within 2 h after the start of NH4Cl incubation. Thus, after 2 h, the fate of Xenopus animal cap cells was determined. Microinjection of ribonucleic acid (RNA) encoding noggin, an endogenous neural inducer, led to the induction of POMC gene expression in animal caps of stage 10 embryos, suggesting that noggin represents a candidate mesodermal signal leading to the POMC messenger (m) RNA producing cell type in uncommitted ectoderm. Hence, an alkalizing agent and a neural inducer can generate a fully differentiated POMC cell lineage from Xenopus animal caps.     

Induction of neural cell adhesion molecule (NCAM) in Xenopus embryos

Using a classical neural induction protocol (H. Spemann and H. Mangold (1924). Roux' Arch. Entwicklungsmech. Org. 123, 389-517), it has been demonstrated that the sustained presence of NCAM in Xenopus embryos, as detected by immunohistochemistry, was confined to the experimentally induced nervous system and the primary host nervous system. Furthermore, in vitro NCAM expression by dorsal blastopore lip and animal pole tissue was detected only when the two tissues were cultured in contact. These and other results show that readily detected and sustained levels of NCAM expression in Xenopus can be used as a marker for neural tissue and an early positive indicator that neural induction has occurred. They suggest that the observed levels of NCAM are a consequence of and not a prerequisite for induction. Using NCAM expression in vitro to determine the minimum time necessary for this induction to occur in vivo, it was found that NCAM was first detected in cultured animal pole that had been removed at stage 10.75 or later. Thus, an inductive step necessary and sufficient for stimulation of NCAM expression in animal pole tissues had not occurred or was reversible prior to the first 2 to 2.5 hr of gastrulation.     

Delayed transition to new cell fates during cellular reprogramming

In many embryos specification toward one cell fate can be diverted to a different cell fate through a reprogramming process. Understanding how that process works will reveal insights into the developmental regulatory logic that emerged from evolution. In the sea urchin embryo, cells at gastrulation were found to reprogram and replace missing cell types after surgical dissections of the embryo. Non-skeletogenic mesoderm (NSM) cells reprogrammed to replace missing skeletogenic mesoderm cells and animal caps reprogrammed to replace all endomesoderm. In both cases evidence of reprogramming onset was first observed at the early gastrula stage, even if the cells to be replaced were removed earlier in development. Once started however, the reprogramming occurred with compressed gene expression dynamics. The NSM did not require early contact with the skeletogenic cells to reprogram, but the animal cap cells gained the ability to reprogram early in gastrulation only after extended contact with the vegetal halves prior to that time. If the entire vegetal half was removed at early gastrula, the animal caps reprogrammed and replaced the vegetal half endomesoderm. If the animal caps carried morpholinos to either hox11/13b or foxA (endomesoderm specification genes), the isolated animal caps failed to reprogram. Together these data reveal that the emergence of a reprogramming capability occurs at early gastrulation in the sea urchin embryo and requires activation of early specification components of the target tissues.     

Novel kelch-like protein, KLEIP, is involved in actin assembly at cell-cell contact sites of Madin-Darby canine kidney cells

Dynamic rearrangements of cell-cell adhesion underlie a diverse range of physiological processes, but their precise molecular mechanisms are still obscure. Thus, identification of novel players that are involved in cell-cell adhesion would be important. We isolated a human kelch-related protein, Kelch-like ECT2 interacting protein (KLEIP), which contains the broad-complex, tramtrack, bric-a-brac (BTB)/poxvirus, zinc finger (POZ) motif and six-tandem kelch repeats. KLEIP interacted with F-actin and was concentrated at cell-cell contact sites of Madin-Darby canine kidney cells, where it colocalized with F-actin. Interestingly, this localization took place transiently during the induction of cell-cell contact and was not seen at mature junctions. KLEIP recruitment and actin assembly were induced around E-cadherin-coated beads placed on cell surfaces. The actin depolymerizing agent cytochalasin B inhibited this KLEIP recruitment around E-cadherin-coated beads. Moreover, constitutively active Rac1 enhanced the recruitment of KLEIP as well as F-actin to the adhesion sites. These observations strongly suggest that KLEIP is localized on actin filaments at the contact sites. We also found that N-terminal half of KLEIP, which lacks the actin-binding site and contains the sufficient sequence for the localization at the cell-cell contact sites, inhibited constitutively active Rac1-induced actin assembly at the contact sites. We propose that KLEIP is involved in Rac1-induced actin organization during cell-cell contact in Madin-Darby canine kidney cells.     

Growth state-regulated expression of p52(PAI-1) in normal rat kidney cells

In normal rat kidney (NRK) cells, synthesis of the 52-kDa substrate-associated type 1 inhibitor of plasminogen activator [p52(PAI-1)] is linked to alterations in cell shape and substrate adhesion. Subconfluent NRK cells accumulated significantly more ventral undersurface-associated p52(PAI-1) compared to newly confluent or 1 - to 2-day postconfluent cultures, suggesting that p52(PAI-1) expression was also growth state-modulated. Since cytoarchitectural constraints function in cell growth control, changes in p52(PAI-1) synthesis were assessed with respect to defined morphologic events that accompany growth activation of cultured NRK cells. Stimulation of low population density, quiescent NRK cells with 20% serum-containing medium resulted in a rapid increase in matrix p52(PAI-1) protein content (6- and 26-fold after 1 and 5 hr, respectively). Growth activation in response to serum reflected elevations in p52(PAI-1) cytoplasmic mRNA abundance, which peaked at 2 hr (125-fold increase) and subsequently declined (100-fold increase) at 5 hr poststimulation. Morphologic analysis indicated that quiescent NRK cells were devoid of transcytoplasmic actin filaments and focal contact-associated vinculin. A marked increase in the fraction of cells that eleborated transcytoplasmic microfilaments and vinculin-containing focal adhesions was evident within 5 min of serum addition. Such cytoarchitectural restructuring preceded p52(PAI-1) induction. Morphologic reorganization and p52(PAI-1) induction occurred prior to progression of cells through the S-phase, indicating they are early events associated with serum stimulation in the NRK cell system. The relevance of p52(PAI-1) induction during this growth state transition is not clear but may influence the established cytoarchitectural changes observed prior to p52(PAI-1) induction by regulating pericellular proteolysis and, thereby, cell-to-substrate adhesion. © 1993 Wiley-Liss, Inc.     

Myogenesis in primary cell cultures from Drosophila melanogaster: protein synthesis and actin heterogeneity during development.

Muscle cell cultures from Drosophila melanogaster were obtained by plating dissociated gastrula stage embryo cells on protamine-treated culture dishes. They myogenic cells in these cultures fuse to form multinucleated pulsating cells by 15 hr after plating. An analysis of protein synthesis during myogenesis in these cultures, as measured by the incorporation of 35S-methionine and analyzed by two-dimensional polyacrylamide gel electrophoresis, showed profound changes in the pattern of protein synthesis. This analysis enabled us to identify three distinct classes of proteins. Class A proteins, the most abundant, are synthesized continuously throughout myogenesis, class B proteins are those proteins whose synthesis is initiated during myogenesis and continued throughout development; class C proteins are those synthesized at specific times during development. In addition, three forms of actin have been identified in these cultures. Actin I, which shows increased synthesis concomitant with the myogenic development in these cultures, is apparently a muscle-specific form of actin. Actin II, the predominant "cytoplasmic" form of actin in the nonmuscle Schneider cell line 2, is also the major form in the gastrula cultures before differentiation begins. Synthesis of this actin continues in the myogenic cultures. Actin III is a rapidly turning over form of actin which does not accumulate in either the Schneider cells or the myogenic cultures.