Isolation of placental cadherin cDNA: identification of a novel gene family of cell-cell adhesion molecules

Ca2+-dependent cell--cell adhesion molecules, termed cadherins, are classified into subclasses with different tissue distributions and distinct cell--cell binding specificities. We report the cloning of cDNA encoding a cadherin present in the placenta which is called P-cadherin. The deduced sequence encodes a polypeptide of 822 amino acids with the characteristic features of integral membrane proteins. A computer search of the amino acid sequence homology of P-cadherin against itself showed that this molecule contains internal repeats in the extracellular domain. Comparison of the primary structure of P-cadherin with that of the epithelial cadherin (E-cadherin) showed that there is 58% homology in their amino acid sequences. These results provide evidence for our hypothesis that cadherins constitute a gene family.     

Role of N-cadherin cell adhesion molecules in the histogenesis of neural retina

We investigated the role of N-cadherin cell adhesion molecules in the histogenesis of the chicken neural retina. In the undifferentiated retina of early embryos, N-cadherin is almost evenly distributed. With differentiation, N-cadherin was gradually localized in particular cell layers. In the 8.5 to 10.5 day embryos, N-cadherin was most abundant in the optic nerve fiber layer, the plexiform layers and the outer limiting membrane. Thereafter, this molecule gradually diminished from most parts of the retina, except in the outer limiting membrane. When incubated with Fab fragments of a polyclonal antibody to N-cadherin, retinas of early embryos tended to dissociate and could not be maintained as a tissue mass. Retinas from older embryos were not dissociated by the Fab, but their morphogenesis was severely affected. We conclude that N-cadherin is essential for maintaining the overall structure of the undifferentiated retina, but during development, its role becomes restricted to maintaining more specific regions of the tissue. We also suggest that there might be additional, unidentified cadherin-like molecules in the retina.     

Cloning and expression of cDNA encoding a neural calcium-dependent cell adhesion molecule: its identity in the cadherin gene family

The neural cadherin (N-cadherin) is a Ca2+-dependent cell-cell adhesion molecule detected in neural tissues as well as in non-neural tissues. We report here the nucleotide sequence of the chicken N-cadherin cDNA and the deduced amino acid sequence. The sequence data suggest that N-cadherin has one transmembrane domain which divides the molecule into an extracellular and a cytoplasmic domain; the extracellular domain contains internal repeats of characteristic sequences. When the N-cadherin cDNA connected with virus promoters was transfected into L cells which have no endogenous N-cadherin, the transformants acquired the N-cadherin-mediated aggregating property, indicating that the cloned cDNA contained all information necessary for the cell-cell binding action of this molecule. We then compared the primary structure of N-cadherin with that of other molecules defined as cadherin subclasses. The results showed that these molecules contain common amino acid sequences throughout their entire length, which confirms our hypothesis that cadherins make a gene family.     

Cadherins in neuronal morphogenesis and function

Classic cadherins represent a family of calcium-dependent homophilic cell–cell adhesion molecules. They confer strong adhesiveness to animal cells when they are anchored to the actin cytoskeleton via their cytoplasmic binding partners, catenins. The cadherin/catenin adhesion system plays key roles in the morphogenesis and function of the vertebrate and invertebrate nervous systems. In early vertebrate development, cadherins are involved in multiple events of brain morphogenesis including the formation and maintenance of the neuroepithelium, neurite extension and migration of neuronal cells. In the invertebrate nervous system, classic cadherin-mediated cell–cell interaction plays important roles in wiring among neurons. For synaptogenesis, the cadherin/catenin system not only stabilizes cell–cell contacts at excitatory synapses but also assembles synaptic molecules at synaptic sites. Furthermore, this system is involved in synaptic plasticity. Recent studies on the role of individual cadherin subtypes at synapses indicate that individual cadherin subtypes play their own unique role to regulate synaptic activities.     

Olfactory epithelium consisting of supporting cells and horizontal basal cells in the posterior nasal cavity of mice

The olfactory epithelium of mice generally consists of olfactory cells, progenitors of olfactory cells (globose basal cells), supporting cells, and horizontal basal cells. However, in the dorsal fossa (the roof) of the posterior nasal cavity of mice, we found seven epithelial patches consisting of only non-neuronal cell types, i.e., supporting cells and horizontal basal cells, among the normal olfactory epithelium. The supporting cells occupied three or four layers in the apical to middle regions; in the basal region, horizontal basal cells were localized in a single row adjacent to the basement membrane. Bowman's gland ducts were also present in the epithelium. Neuronal cells (olfactory cells and globose basal cells) were totally absent. The ultrastructure of the supporting cells, horizontal basal cells, and Bowman's glands was essentially similar to that in the normal olfactory epithelium. In the early postnatal period (P1-P7), cell types in the epithelium were the same as those in the normal olfactory epithelium. From P10 to P21, olfactory cells and globose basal cells had disappeared from the olfactory epithelium. At this period, the number of TUNEL-positive cells was significantly higher than that in the surrounding olfactory epithelium; ultrastructurally, many apoptotic figures were observed. This suggests that the epithelium consisting of supporting cells and horizontal basal cells is generated by the apoptotic death of olfactory cells and globose basal cells during postnatal development.     

Purification of two forms of starch branching enzyme (Q-enzyme) from developing rice endosperm

Two isoforms of starch branching enzyme (Q-enzyme), QEI and QEII, have been purified to honlogeneity from developing rice endosperm. QEI and QEII, with molecular weights of about 80 and 85 kDa, respectively, could be fully separated by anion-exchange or hydrophobic chromatography. The peptide maps obtained after V₈ proteinase digestion were quite different between the two enzymes. Antibodies prepared against QEI showed no immunological cross-reaction with the QEII protein in Western blot experiments, and anti-QEII serum did not react with the QEI protein. The data indicate that QEI and QEII are distinct proteins encoded by different genes in rice plants.     

Tryptamine Induces Phosphoinositide Turnover and Modulates Adrenergic and Muscarinic Cholinergic Receptor Function in Cultured Cerebellar Granule Cells

Abstract: Tryptamine dose-dependently increased phosphoinositide (PI) hydrolysis by approximately fourfold in primary cultures of rat cerebellar granule cells (EC₅₀ = 56 µ M ). The PI response stimulated by tryptamine was dependent on the presence of extracellular Ca²⁺ and Na⁺. Tryptamine-induced PI breakdown could be partially inhibited by pretreatment with 4β-phorbol 12-myristate 13-acetate but not pertussis toxin. The presence of tryptamine markedly attenuated PI responses induced by norepinephrine (NE) and carbachol, with no apparent effect on the responses to 5-hydroxytryptamine and glutamate. The inhibition of NE- and carbachol-induced PI turnover by tryptamine was dose dependent with IC₅₀ values of ∼0.4 and ∼2.5 m M , respectively. Pretreatment of cells with tryptamine (0.5 m M ) also attenuated NE- and carbachol-induced PI turnover, but failed to affect 5-hydroxytryptamine- and glutamate-induced responses. Furthermore, ketanserin, atropine, and prazosin did not have any effect on inositol phosphate formation induced by tryptamine. These observations indicate that tryptamine markedly increased Ca²⁺- and Na⁺-dependent PI turnover in cerebellar neurons and selectively inhibited NE- and carbachol-induced PI hydrolysis.     

The Effects of Inflorescence Size and Flower Position on Biomass and Temporal Sex Allocation in <Emphasis Type="Italic">Lobelia sessiliflora</Emphasis>

To test the prediction of sex allocation theory that plants or flowers high in resource status emphasize the female function, we explored the variation in both biomass (the number of pollen grains and ovules) and temporal (male and female durations) sex allocation among and within plants of protandrous Lobelia sessilifolia in relation to plant size and flower position within plants. Among plants, the mean number of pollen grains and ovules per flower of a plant increased with plant size, whereas the mean P/O ratio (number of pollen grains/number of ovules ratio) decreased with plant size. The mean male duration, the mean female duration, and the mean ratio of male duration/flower longevity per flower of a plant were not correlated with plant size. Thus, large plants emphasized female function in terms of biomass sex allocation, which is consistent with the prediction of size-dependent sex allocation theory. The results for temporal sex allocation, however were inconsistent with the theory. Within plants, the mean number of pollen grains and ovules per flower at each position decreased from lower to upper flowers (early to late blooming flowers) and that of the P/O ratio increased from lower to upper flowers. The mean male duration and the mean female duration per flower decreased from lower to upper flowers, whereas the mean ratio of male duration/flower longevity increased from lower to upper flowers. The population sex ratio changed from male-biased to female-biased. Thus, later blooming flowers emphasized the male function in terms of both biomass and temporal sex allocation, consistent with the sex allocation theory, regarding the change in the population sex ratio.     

Cell binding function of E-cadherin is regulated by the cytoplasmic domain.

Cadherins are a family of transmembrane glycoproteins responsible for Ca2+-dependent cell-cell adhesion. Their amino acid sequences are highly conserved in the cytoplasmic domain. To study the role of the cytoplasmic domain in the function of cadherins, we constructed expression vectors with cDNAs encoding the deletion mutants of E-cadherin polypeptides, in which the carboxy terminus was truncated at various lengths. These vectors were introduced into L cells by transfection, and cell lines expressing the mutant E-cadherin molecules were isolated. In all transfectants obtained, the extracellular domain of the mutant E-cadherins was exposed on the cell surface, and had normal Ca2+-sensitivity and molecular size. However, these cells did not show any Ca2+-dependent aggregation, indicating that the mutant molecules cannot mediate cell-cell binding. The mutant E-cadherin molecules could be released from cells by nonionic detergents, whereas a fraction of normal E-cadherin molecules could not be extracted with the detergent and appeared to be anchored to the cytoskeleton at cell-cell junctions. These results suggest that the cytoplasmic domain regulates the cell-cell binding function of the extracellular domain of E-cadherin, possibly through interaction with some cytoskeletal components.     

EVOLUTIONARILY STABLE SELFING RATES OF HERMAPHRODITIC PLANTS IN COMPETING AND DELAYED SELFING MODES WITH ALLOCATION TO ATTRACTIVE STRUCTURES

I present a resource-allocation model to analyze how patterns of allocation to reproductive structures influence the evolution of selfing rates in hermaphrodites subject to competing and delayed forms of self-fertilization. The evolutionarily stable state does not depend on the mode of pollination. In contrast to previous models in which the number and the size of flowers were not considered, intermediate selfing is not evolutionarily stable with linear constraints on flower number and size. In contrast, intermediate selfing can be evolutionarily stable with nonlinear constraints on flower number and size. Optimal allocations to attractive structures increase and selfing rates decrease in the presence of inbreeding depression. In particular, stable intermediate levels of selfing may be favored when flower number is strongly constrained. Thus, nonlinear constraints on flower number and size could favor the evolution of intermediate selfing in either the delayed or the competing modes of selfing. Outcrossing is not favored in the absence of inbreeding depression, a result inconsistent with Holsinger's results in which allocation to attractive structures was not considered.