Charles A. Peto

Phenotypic and genetic analysis of det2, a new mutant that affects light-regulated seedling development in Arabidopsis

The greening phenotypes produced by recessive mutations in a gene designated de-etiolated-2 (DET2) are described. Recessive mutations in the DET2 gene uncouple light signals from a number of light-dependent processes. det2 mutations result in dark-grown Arabidopsis thaliana seedlings with many characteristics of light-grown plants, including hypocotyl growth inhibition, cotyledon expansion, primary leaf initiation, anthocyanin accumulation, and derepression of light-regulated gene expression. In contrast to these morphological and gene expression changes, however, the chloroplast development program is not initiated in the dark in det2 mutants, suggesting that light-regulated gene expression precedes the differentiation of etioplasts to chloroplasts. det2 mutations thus reveal at least two classes of downstream light-regulated responses that differ in their timing and control mechanisms. Homozygous det2 mutations also affect photoperiodic responses in light-grown plants, including timing of flowering, dark adaptation of gene expression, and onset of leaf senescence. The phenotype of det1 det2 double mutants is additive, implying that DET1 and DET2 function in distinct pathways that affect downstream light-regulated genes. Furthermore, these pathways are not utilized solely during early seedling development but must also be required to regulate different aspects of the light developmental program during later stages of vegetative growth.

Arabidopsis thaliana mutant that develops as a light-grown plant in the absence of light.

The signal transduction pathways that lead to chloroplast biogenesis in plants are largely unknown. We describe here the identification and initial characterization of a novel genetic locus which fits the criteria of a regulatory gene located in a central pathway controlling light-mediated development. In the absence of light, these Arabidopsis thaliana mutants, designated det1 (de-etiolated 1), constitutively display many characteristics that are light-dependent in wild-type plants, including leaf and chloroplast development, anthocyanin accumulation, and accumulation of mRNAs for several light-regulated nuclear and chloroplast genes. The switch between dark and light growth modes thus appears to be a programmed step in a developmental pathway that is defined by det1. We suggest a model where the primary role of light on gene expression is mediated by the activation of leaf development. Further, the recessive nature of the det1 mutation implies that there is negative growth control on leaf development in dicotyledonous plants in the absence of light.

The epidermis both drives and restricts plant shoot growth

The size of an organism is genetically determined, yet how a plant or animal achieves its final size is largely unknown. The shoot of higher plants has a simple conserved body plan based on three major tissue systems: the epidermal (L1), sub-epidermal (L2) and inner ground and vascular (L3) tissues. Which tissue system drives or restricts growth has been a subject of debate for over a century. Here, we use dwarf, brassinosteroid biosynthesis and brassinosteroid response mutants in conjunction with tissue-specific expression of these components as tools to examine the role of the epidermis in shoot growth. We show that expression of the brassinosteroid receptor or a brassinosteroid biosynthetic enzyme in the epidermis, but not in the vasculature, of null mutants is sufficient to rescue their dwarf phenotypes. Brassinosteroid signalling from the epidermis is not sufficient to establish normal vascular organization. Moreover, shoot growth is restricted when brassinosteroids are depleted from the epidermis and brassinosteroids act locally within a leaf. We conclude that the epidermis both promotes and restricts shoot growth by providing a non-autonomous signal to the ground tissues.

Different Roles for Phytochrome in Etiolated and Green Plants Deduced from Characterization of Arabidopsis thaliana Mutants.

We have isolated a new complementation group of Arabidopsis thaliana long hypocotyl mutant (hy6) and have characterized a variety of light-regulated phenomena in hy6 and other previously isolated A. thaliana hy mutants. Among six complementation groups that define the HY phenotype in A. thaliana, three (hy1, hy2, and hy6) had significantly lowered levels of photoreversibly detectable phytochrome, although near wild-type levels of the phytochrome apoprotein were present in all three mutants. When photoregulation of chlorophyll a/b binding protein (cab) gene expression was examined, results obtained depended dramatically on the light regime employed. Using the red/far-red photoreversibility assay on etiolated plants, the accumulation of cab mRNAs was considerably less in the phytochrome-deficient mutants than in wild-type A. thaliana seedlings. When grown in high-fluence rate white light, however, the mutants accumulated wild-type levels of cab mRNAs and other mRNAs thought to be regulated by phytochrome. An examination of the light-grown phenotypes of the phytochrome-deficient mutants, using biochemical, molecular, and morphological techniques, revealed that the mutants displayed incomplete chloroplast and leaf development under conditions where wild-type chloroplasts developed normally. Thus, although phytochrome may play a role in gene expression in etiolated plants, a primary role for phytochrome in green plants is likely to be in modulating the amount of chloroplast development, rather than triggering the initiation of events (e.g., gene expression) associated with chloroplast development.

An Arabidopsis thaliana virescent mutant reveals a role for ClpR1 in plastid development

The ATP-dependent Clp protease has been well-characterized in Escherichia coli, but knowledge of its function in higher plants is limited. In bacteria, this two-component protease consists of a Ser-type endopeptidase ClpP, which relies on the ATP-dependent unfolding activity from an Hsp100 molecular chaperone to initiate protein degradation. In the chloroplasts of higher plants, multiple isoforms of the proteolytic subunit exist, with Arabidopsis having five ClpPs and four ClpP-like proteins termed ClpR predicted in its genome. In this work we characterized an Arabidopsis mutant impaired in one subunit of the chloroplast-localized Clp protease core, ClpR1. clpR1-1, a virescent mutant, carries a pre-mature stop codon in the clpR1 gene, resulting in no detectable ClpR1 protein. The accumulation of several chloroplast proteins, as well as most of the chloroplast-localized Clp protease subunits, is inhibited in clpR1-1. Unexpectedly, some plastid-encoded proteins do not accumulate, although their transcripts accumulate to wild-type levels. Maturation of 23S and 4.5S chloroplast ribosomal RNA (cp-rRNA) is delayed in clpR1-1, and both RNAs accumulate as higher molecular weight precursors. Also, chloroplasts in clpR1-1 are smaller than in wild type and have fewer thylakoid membranes with smaller grana stacks. We propose that a ClpR1-containing activity is required for chloroplast development and differentiation and in its absence both are delayed.

Inhibin/activin subunits are costored with FSH and LH in secretory granules of the rat anterior pituitary gland.

We recently reported that pituitary gonadotropes, major targets of circulating inhibins and activins, are also capable of synthesizing the inhibin (I) alpha- and inhibin/activin (I/A) beta B-subunits. In the present study, we examined the subcellular distribution of these subunits, with special attention given to determinating the extent to which they might be colocalized with the gonadotropins in secretory granules. Pituitaries from adult male rats were cryofixed, molecular distillation-dried, and resin-embedded. Immunogold staining methods were used to examine concurrently the distributions of an I/A subunit and FSH or LH. I/A subunits were detected only in cells that also labeled positively for a gonadotropin, and, in contrast to the gonadotropins, were sequestered almost exclusively within secretory granules. The I alpha-subunit colocalized with FSH in 31%, and with LH in 36%, of all positively stained granules. The I/A beta B-subunit was found with FSH or LH in about 25% of the granules. Approximately 52-69% of the granules contained FSH or LH alone; 7-18% were positive only for an I/A subunit, and this varied as a function of the particular gonadotropin with which costaining was carried out. Dual staining for the I alpha- and the I/A beta B-subunits indicated that at least 35% of all immunolabeled granules showed positive signals for both subunits. Coupled with methodological considerations to indicate that these estimates of the extent of colocalization are likely to be conservative, these data suggest that inhibin and activin are characteristically copackaged, and presumably coreleased, with the gonadotropins.

Fine structure and plasticity of barosensitive neurons in the nucleus of solitary tract

Intravenous phenylephrine (PE) activates neurons in the nucleus of the solitary tract (NTS) whose distribution conforms to those of central projections of the carotid sinus and aortic depressor nerves. This was exploited to permit fine structural characterization of cells presumed to compose the first station in the processing of arterial baroreceptor input, and their responses to stimulation. Rats were perfused at varying intervals after PE injection, and sections through the baroreceptor afferent zone of the NTS prepared for preembedding immunolocalization of Fos‐immunoreactivity. Labeled neurons composed a continuous strip extending from the dorsal part of the commissural NTS (NTScom) to the dorsal subnucleus at the level of the area postrema (NTSap). PE‐sensitive neurons in these regions were medium‐sized, round to ovoid in shape, with scant cytoplasm and an unremarkable complement of organelles. Distinctive features included extensively invaginated nuclei and well‐developed Golgi apparati; Fos‐ir cells in the NTSap were distinguished from those in NTScom by virtue of better‐developed rough endoplasmic reticulum and Golgi, and less convoluted nuclei. Proximal synaptic input to PE‐sensitive neurons was sparse and was provided by terminals containing predominantly small, clear synaptic vesicles that formed mainly symmetric junctions with somata and primary dendrites. Prolonged stimulation was accompanied by accentuation of nuclear invaginations, marked accumulation of heterochromatin at their apices, and evidence of enhanced Golgi activity (vesicular budding). These may represent adaptations to facilitate changes in gene expression, to maintain neurotransmitter availability, or both, in the face of a persistent hypertensive challenge. J. Comp. Neurol. 422:338–351, 2000.

Ultrastructural localization of the corticotropin-releasing factor-binding protein in rat brain and pituitary.

Preembedding immunoperoxidase staining methods were used to permit ultrastructural analyses of the distribution in rat brain and pituitary of the corticotropin‐releasing factor–binding protein (CRF‐BP), a moiety distinct from CRF receptors, but which is nonetheless capable of binding the peptide and reversibly neutralizing its biological actions. In anterior pituitary, CRF‐BP immunoreactivity (ir) was detected in corticotropelike cells, with reaction product associated principally with secondary lysosomes and multivesicular bodies and not at all with secretory granules. In brain, marked regional differences in the subcellular pattern of CRF‐BP staining were evident. In isocortex, where BP/peptide colocalization is rare, BP‐ir was distributed in cells and processes in a manner similar to that of a prototypic neuropeptide, including in terminals commonly engaging in synaptic contacts with unlabeled dendritic profiles. In the bed nucleus of the stria terminalis, a site that contains overlapping accumulations of CRF‐BP‐ir projections and CRF‐ir perikarya, BP staining was restricted to vesicle‐laden varicosities that rarely engaged in synaptic contacts with somatic or dendritic elements but were frequently apposed to unlabeled axon varicosities and terminals. In the ventromedial medulla, a site of partial CRF/BP overlap, most cells displayed a subcellular localization CRF‐BP‐ir like that seen in cortex, whereas in others the distribution shared similarities with that observed in pituitary. The results suggest that the function of the CRF‐BP may differ in different cellular contexts. In cellular targets of CRF or in neurons in which peptide and BP coexist, the CRF‐BP may play a role in processing and degradation of CRF and/or ligand–receptor complexes. In other areas of the central nervous system, the BP seems positioned to serve as a transmitter/modulator at conventional synapses or as an autocrine or paracrine modulator of local CRF effects. J. Comp. Neurol. 413:241–254, 1999.

Morphologic and functional correlates of plasma membrane injury during oxidant exposure

Plasma membrane injury by exposure to hydrogen peroxide was examined in a renal epithelial cell line (LLC-PK1). Morphologic and functional parameters of plasma membrane integrity were studied in an attempt to eludicate the sequence of membrane alterations during the evolution of hydrogen peroxide-mediated injury. These parameters included plasma membrane potential and permeability, plasma membrane bleb formation, cellular size, and plating efficiency. Plasma membrane potential was the earliest parameter affected by hydrogen peroxide exposure. Half maximal depolarization occurred within 15-30 min of exposure to 1 mM, after 10-15 min exposure to 100 mM and after over 150 min exposure to 10 microM hydrogen peroxide. After exposure to 1 mM hydrogen peroxide, the following sequence of events was seen; increased plasma membrane blebbing (30 min), cell swelling (90-125 min) and increased plasma membrane permeability (150-240 min). After a 30 min exposure to 1 mM hydrogen peroxide, cellular plating efficiency, measured at 24 h, was reduced by 50% (P less than .001). These changes were accelerated, although their order of appearance was unchanged, at higher concentrations of hydrogen peroxide. We conclude that functional and morphologic expressions of cellular injury in this model occur in a defined sequence with plasma membrane depolarization representing the earliest marker of membrane injury during hydrogen peroxide exposure.

The effect of phenothiazines upon maintenance of membrane integrity in the cultured myocardial cell

The cultured myocardial cell provides a defined model for examining factors which are responsible for maintaining cellular viability and sarcolemmal integrity. Our data indicates that the spontaneous loss of myocyte membrane integrity is a calcium-dependent process and thus provides a method for examining the mechanism through which calcium exerts this effect. Antimyosin antibody staining and propidium iodide uptake were used to quantitate membrane integrity. The integrity of the cell membrane was inversely related to the calcium concentration in the culture medium. This loss of membrane integrity was calmodulin-dependent as demonstrated by the following: phenothiazines (trifluoperazine greater than chlorpromazine greater than promethazine) and structurally dissimilar calmodulin-inhibitors prevented the formation of sarcolemmal defects at concentrations similar to those known to inhibit calmodulin; phenothiazines and calcium demonstrated a competitive interaction with respect to this effect on membrane integrity. Electron microscopy confirmed the integrity of the sarcolemma of the cells exposed to high phenothiazine concentrations although metabolic alterations occurred in these cells as evidenced by an increased membrane permeability to the low molecular weight probe propidium iodide, degenerative changes in the fine structure of the mitochondria, the accumulation of autophagic vacuoles in the cytoplasm and the loss of contractile ability. These findings indicate that calmodulin inhibitory compounds are capable of preserving the membrane integrity of cardiac myocytes, interfering with a calcium-dependent process that is associated with the spontaneous attrition of these cells in culture. Significant intracellular alterations appear at high doses of these agents even while the sarcolemma is free of gross defects.