Modulation of endocytosis in pollen tube growth by phosphoinositides and phospholipids

Summary. In plants, tip-growing cells represent an ideal system to investigate signal transduction mechanisms, and among those, pollen tubes are one of the favourite models. Many signalling pathways have been identified during germination and tip growth, namely, Ca²⁺, calmodulin, phosphoinositides, cyclic AMP, and GTPases. Not surprisingly, the apical secretory machinery, essential for tip growth, seems to be an intersection point for all these pathways. Recently, the phospholipid phosphatidic acid was also suggested to actively participate in the control of endo- and exocytosis and to interfere with the correct positioning of the actin cytoskeleton. Phosphatidic acid seems to act concertedly with the phosphoinositides phosphatidylinositol 4,5-bisphosphate and D-myo-inositol 1,4,5-trisphosphate. Here we review previous data and discuss additional evidence that these three molecules have a combined action modulating both the actin cytoskeleton and the apical secretory machinery. We further discuss how these findings can be integrated into a working model for pollen tube apical secretion that contemplates the existence of a rapid endocytosis mechanism. Correspondence and reprints: Instituto de Ciência Aplicada e Tecnologia, Faculdade de Ciências, Universidade de Lisboa, Campo Grande, 1749-016 Lisboa, Portugal.     

Calcium ions as second messengers in guard cell signal transduction

Ca²⁺ is a ubiquitous second messenger in plant cell signalling. In this review we consider the role of Ca²⁺-based signal transduction in stomatal guard cells focusing on three important areas: (1) the regulation of guard cell turgor relations and the control of gene expression in guard cells, (2) the control of specificity in Ca²⁺ signalling, (3) emerging technologies and new approaches for studying intracellular signalling. Stomatal apertures alter in response to a wide array of environmental stimuli as a result of changes in guard cell turgor. For example, the plant hormone abscisic acid (ABA) stimulates a reduction in stomatal aperture through a decrease in guard cell turgor. Furthermore, guard cells have been shown to be competent to relay an ABA signal from its site of perception to the nucleus. An increase in the concentration of cytosolic free Ca²⁺ ([Ca²⁺]₁) is central to the mechanisms underlying ABA-induced changes in guard cell turgor. We describe a possible model of Ca²⁺-based ABA signal transduction during stomatal closure and discuss recent evidence which suggests that Ca²⁺ is also involved in ABA nuclear signal transduction. Many other environmental stimuli which affect stomatal apertures, in addition to ABA, induce an increase in guard cell [Ca²⁺]₁) This raises questions regarding how increases in [Ca²⁺]₁) can be a common component in the signal transduction pathways by which stimuli cause both stomatal opening and closure. We discuss several mechanisms of increasing the amount of information contained within the Ca²⁺ signal, including encoding information in a stimulus-specific Ca²⁺ signal or Ca²⁺ signature', the concept of the ‘physiological address’ of the cell, and the use of other second messengers. We conclude by addressing the emerging technologies and new approaches which can be used in conjunction with guard cells to dissect further the molecular mechanisms of Ca²⁺-mediated signalling in plants.     

The control of specificity in guard cell signal transduction

Stomatal guard cells have proven to be an attractive system for dissecting the mechanisms of stimulus-response coupling in plants. In this review we focus on the intracellular signal transduction pathways by which extracellular signals bring about closure and opening of the stomatal pore. It is proposed that guard cell signal transduction pathways may be organized into functional arrays or signalling cassettes that contain elements common to a number of converging signalling pathways. The purpose of these signalling cassettes may be to funnel extracellular signals down onto the ion transporters that control the fluxes of ions that underlie stomatal movements. Evidence is emerging that specificity in guard cell signalling may be, in part, encoded in complex spatio-temporal patterns of increases in the concentration of cytosolic-free calcium ([Ca²⁺]_cyt). It is suggested that oscillations in [Ca²⁺]_cyt may generate calcium signatures that encode information concerning the stimulus type and strength. New evidence is presented that suggests that these calcium signatures may integrate information when many stimuli are present.     

Melatonin receptors and signal transduction mechanisms

The ovine pars tuberalis (PT) still offers the best model for the study of signal transduction pathways regulated by the melatonin receptor. From the evidence accumulated so far, it seems likely that the cAMP signal transduction pathway will be a major effector of a stimulatory signal to the PT which can be regulated by melatonin. Thus a principal action of melatonin in the PT may be the repression of biochemical processes driven by cAMP. However, through the phenomenon of sensitization, melatonin may also act to amplify a stimulatory input to the cAMP signal transduction pathway in the PT. These events are mediated via the melatonin receptor, which is itself a target for regulation by the melatonin signal. Studies using the PT have identified several signalling pathways that may serve to positively or negatively regulate the expression of the melatonin receptor. These and other studies in the PT have alluded to cAMP-independent pathways regulated by the melatonin receptor.     

Regulatory proteins with a sense of direction: cell cycle signalling network in Caulobacter

Localization of kinases and other signalling molecules at discrete cellular locations is often an essential component of signal transduction in eukaryotes. Caulobacter crescentus is a small, single-celled bacterium that presumably lacks intracellular organelles. Yet in Caulobacter, the subcellular distribution of several two-component signal transduction proteins involved in the control of polar morphogenesis and cell cycle progression changes from a fairly dispersed distribution to a tight accumulation at one or both poles in a spatial and temporal pattern that is reproduced during each cell cycle. This cell cycle-dependent choreography suggests that similarly to what happens in eukaryotes, protein localization provides a means of modulating signal transduction in bacteria. Recent studies have provided important insights into the biological role and the mechanisms for the differential localization of these bacterial signalling proteins during the Caulobacter cell cycle.     

Nitric oxide and ABA in the control of plant function

Abscisic acid (ABA) and nitric oxide (NO) are both extremely important signalling molecules employed by plants to control many aspects of physiology. ABA has been extensively studied in the mechanisms which control stomatal movement as well as in seed dormancy and germination and plant development. The addition of either ABA or NO to plant cells is known to instigate the actions of many signal transduction components. Both may have an influence on the phosphorylation of proteins in cells mediated by effects on protein kinases and phosphatases, as well as recruiting a wide range of other signal transduction molecules to mediate the final effects. Both ABA and NO may also lead to the regulation of gene expression. However, it is becoming more apparent that NO may be acting downstream of ABA, with such action being mediated by reactive oxygen species such as hydrogen peroxide in some cases. However not all ABA responses require the action of NO. Here, examples of where ABA and NO have been put together into the same signal transduction pathways are discussed.     

The Rop GTPase: an emerging signaling switch in plants

G proteins are ubiquitous molecular switches in eukaryotic signal transduction, but their roles in plant signal transduction had not been clearly established until recent studies of the plant-specific Rop subfamily of RHO GTPases. Rop participates in signaling to an array of physiological processes including cell polarity establishment, cell growth, morphogenesis, actin dynamics, H₂O₂ generation, hormone responses, and probably many other cellular processes in plants. Evidence suggests that plants have developed unique molecular mechanisms to control this universal molecular switch through novel GTPase-activating proteins and potentially through a predominant class of plant receptor-like serine/threonine kinases. Furthermore, the mechanism by which Rop regulates specific processes may also be distinct from that for other GTPases. These advances have raised the exciting possibility that the elucidation of Rop GTPase signaling may lead to the establishment of a new paradigm for G protein-dependent signal transduction in plants.     

The effect of glucose-6-phosphate isomerase genotype onin vitro specific activity andin vivo flux inMytilus edulis

Four samples of the musselMytilus edulis were taken between 1984 and 1987 from Stony Brook, New York, and used to study the glucose-6-phosphate isomerase (GPI) polymorphism in this species.In vitro specific activity andin vivo flux measured in the same animals were found to be significantly correlated. A significant effect of GPI genotype on flux was observed in one of the samples; overall, significant evidence of effect of genotype on enzyme activity was also obtained. GPI activities of common genotypes tend to deviate less from the population mean than those of rare (frequency less than 5%) genotypes. This suggests the possibility that rare GPI genotypes are rare as a consequence of having biochemical properties that deviate from an optimum level and, therefore, having a lower fitness. In support of this hypothesis, we found in one of our samples that shell length is a concave function of GPI activity with an intermediate optimum activity level. The financial support provided to P.J.N.S. by the Luso-American Educational Commission (Fulbright Program), the Instituto Nacional de Investigacao Científica (Portugal), and the Faculdade de Ciências da Universidade de Lisboa during several stages of this research is gratefully acknowledged. Financial support from the Ministerio de Educatión y Ciencia (Spain) in the form of a postdoctoral Fulbright/MEC fellowship to M.S. is also gratefully acknowledged. Research was supported by National Science Foundation Grant BSR-8415060 to R.K.K. This is contribution No. 736 from the Program in Ecology and Evolution, State University of New York at Stony Brook. On leave from Departamento de Biologia Vegetal, Faculdade de Ciências, Universidade de Lisboa, Campo Grande C2, Lisboa, Portugal.     

Differential proteolysis of sigma regulators controls cell-surface signalling in Pseudomonas aeruginosa

Cell-surface signalling systems are widespread in Gram-negative bacteria. In these systems gene expression occurs following binding of a ligand, commonly a siderophore, to a receptor protein in the outer membrane. The receptor interacts with a sigma regulator protein that extends from the periplasm into the cytoplasm to control the activity of a cognate sigma factor. The mechanisms of signal transduction in cell-surface signalling systems have not been determined. Here we investigate signal transduction in the pyoverdine, ferrichrome and desferrioxamine siderophore systems of Pseudomonas aeruginosa. When pyoverdine is present the sigma regulator FpvR undergoes complete proteolysis resulting in activation of two sigma factors PvdS and FpvI and expression of genes for pyoverdine synthesis and uptake. When pyoverdine is absent subfragments of FpvR inhibit PvdS and FpvI. Similarly, subfragments of the sigma regulators FoxR and FiuR are formed in the absence of desferrioxamine and ferrichrome. These are much less abundant when the siderophores are present and downstream gene expression takes place. In all three systems RseP (MucP/YaeL) is required for complete proteolysis of the sigma regulator and sigma factor activity. These findings indicate that regulated proteolysis is a general mechanism for signal transduction in cell-surface signalling.     

Protein complexes mediate signalling in plant responses to hormones,light, sucrose and pathogens

Living organisms use complex pathways of signal perception and transduction to respond to stimuli in their environments. In plants, putative signal transduction components have been identified through mutant screens and comparative analysis of genome sequences of model eukaryotes. Several pieces in a large series of puzzles have now been identified and a current challenge is to determine how these pieces interconnect. Functional analysis of the encoded proteins has necessitated a change from genetic to biochemical approaches. In recent years, the application of techniques such as two-hybrid screening and epitope tagging has facilitated the study of protein-protein interactions and has increased our understanding of cellular signalling mechanisms. One focus of present research is the ubiquitin/proteasome-mediated degradation of proteins. Increasing evidence suggests this is a control common to many plant signalling pathways including development and responsiveness to hormones, light and sucrose. A central challenge in the study of plant disease resistance has been to identify protein complexes that contain host defence proteins and pathogenicity factors. In this review we summarize the latest developments in these areas where the existence of protein complexes has been demonstrated to be of fundamental importance in plant signalling.     

MLC-kinase/phosphatase control of Ca2+ signal transduction in airway smooth muscles

In airway smooth muscles, kinase/phosphatase-dependent phosphorylation and dephosphorylation of the myosin light chain (MLC) have been revealed by many authors as important steps in calcium (Ca²⁺) signalling pathway from the variation of Ca²⁺ concentration in cytosol to the force development. Here, a theoretical analysis of the control action of MLC-kinase (MLCK) and MLC-phosphatase (MLCP) in Ca²⁺ signalling is presented and related to the general control principles of these enzymes, which were previously studied by Reinhart Heinrich and his co-workers. The kinetic scheme of the mathematical model considers interactions among Ca²⁺, calmodulin (CaM) and MLCK and the well-known 4-state actomyosin latch bridge model, whereby a link between them is accomplished by the conservation relation of all species of MLCK. The mathematical model predicts the magnitude and velocity of isometric force in smooth muscles upon transient biphasic Ca²⁺ signal. The properties of signal transduction in the system such as the signalling time, signal duration and signal amplitude, which are reflected in the properties of force developed, are studied by the principles of the metabolic control theory. The analysis of our model predictions confirms as shown by Reinhart Heinrich and his co-workers that MLCK controls the amplitude of signal more than its duration, whereas MLCP controls both. Finally, the simulations of elevated total content of MLCK, a typical feature of bronchial muscles of asthmatic subjects and spontaneously hypertensive rats as well as potentiation of MLCP catalytic activity, are carried out and are discussed in view of an increase in the force magnitude.     

Role of cytokines and extracellular matrix in the regulation of haemopoietic stem cells

The understanding of molecular mechanisms regulating the formation, growth and differentiation of haemopoietic stem cells has advanced considerably recently. Particular progress has been made in defining the cytokines, chemokines and extracellular matrix components which retain and maintain primitive haemopoietic cell populations in bone marrow. Furthermore, signal transduction pathways that are critical for haemopoiesis, both in vivo and in vitro, and that are activated by cytokines have also been identified and further characterised. The importance of these processes has, this year, been exemplified by the phenotypes of mice deficient in key signal transduction proteins and the discovery that mutations in the component proteins of some signalling pathways are linked to human diseases. Significant advances in understanding the molecular mechanisms for mobilisation of stem cells from bone marrow have also been made this year; this has potential importance for bone marrow transplantation.     

Cytokine receptors and signal transduction

Cytokines are important regulators of hemopoiesis which exert their actions by binding to specific, high affinity, cell surface receptors. In the past several years, molecular cloning of these receptors has revealed a new superfamily referred to as the hemopoietic growth factor receptors. Members of this family are defined by a 200 amino acid conserved domain; however, it has become increasingly apparent that another characteristic of these receptors is the shared usage of a common signalling subunit among subgroups in this family. The shared signalling component explains the functional redundancy of many cytokines; however, the mechanism by which these receptors transduce a signal across the membrane is not yet clear. Studies into cytokine action have shown that many of the events that occur in response to ligand stimulation are similar to those observed for the better characterized intrinsic tyrosine kinase receptors. Thus, although the cytokine receptors do not possess intrinsic tyrosine kinase activity, these observations have led to a model of cytokine signal transduction adapted from the signalling mechanisms described for the tyrosine kinase receptors.     

Synthetic biology: lessons from engineering yeast MAPK signalling pathways

All living cells respond to external stimuli and execute specific physiological responses through signal transduction pathways. Understanding the mechanisms controlling signalling pathways is important for diagnosing and treating diseases and for reprogramming cells with desired functions. Although many of the signalling components in the budding yeast Saccharomyces cerevisiae have been identified by genetic studies, many features concerning the dynamic control of pathway activity, cross‐talk, cell‐to‐cell variability or robustness against perturbation are still incompletely understood. Comparing the behaviour of engineered and natural signalling pathways offers insight complementary to that achievable with standard genetic and molecular studies. Here, we review studies that aim at a deeper understanding of signalling design principles and generation of novel signalling properties by engineering the yeast mitogen‐activated protein kinase (MAPK) pathways. The underlying approaches can be applied to other organisms including mammalian cells and offer opportunities for building synthetic pathways and functionalities useful in medicine and biotechnology.