The RCN1-encoded A subunit of protein phosphatase 2A increases phosphatase activity in vivo.

Protein phosphatase 2A (PP2A), a heterotrimeric serine/threonine-specific protein phosphatase, comprises a catalytic C subunit and two distinct regulatory subunits, A and B. The RCN1 gene encodes one of three A regulatory subunits in Arabidopsis thaliana. A T-DNA insertion mutation at this locus impairs root curling, seedling organ elongation and apical hypocotyl hook formation. We have used in vivo and in vitro assays to gauge the impact of the rcn1 mutation on PP2A activity in seedlings. PP2A activity is decreased in extracts from rcn1 mutant seedlings, and this decrease is not due to a reduction in catalytic subunit expression. Roots of mutant seedlings exhibit increased sensitivity to the phosphatase inhibitors okadaic acid and cantharidin in organ elongation assays. Shoots of dark-grown, but not light-grown seedlings also show increased inhibitor sensitivity. Furthermore, cantharidin treatment of wild-type seedlings mimics the rcn1 defect in root curling, root waving and hypocotyl hook formation assays. In roots of wild-type seedlings, RCN1 mRNA is expressed at high levels in root tips, and accumulates to lower levels in the pericycle and lateral root primordia. In shoots, RCN1 is expressed in the apical hook and the basal, rapidly elongating cells in etiolated hypocotyls, and in the shoot meristem and leaf primordia of light-grown seedlings. Our results show that the wild-type RCN1-encoded A subunit functions as a positive regulator of the PP2A holoenzyme, increasing activity towards substrates involved in organ elongation and differential cell elongation responses such as root curling.

A mutation in protein phosphatase 2A regulatory subunit A affects auxin transport in Arabidopsis.

The phytohormone auxin controls processes such as cell elongation, root hair development and root branching. Tropisms, growth curvatures triggered by gravity, light and touch, are also auxin-mediated responses. Auxin is synthesized in the shoot apex and transported through the stem, but the molecular mechanism of auxin transport is not well understood. Naphthylphthalamic acid (NPA) and other inhibitors of auxin transport block tropic curvature responses and inhibit root and shoot elongation. We have isolated a novel Arabidopsis thaliana mutant designated roots curl in NPA (rcn1). Mutant seedlings exhibit altered responses to NPA in root curling and hypocotyl elongation. Auxin efflux in mutant seedlings displays increased sensitivity to NPA. The rcn1 mutation was transferred-DNA (T-DNA) tagged and sequences flanking the T-DNA insert were cloned. Analysis of the RCN1 cDNA reveals that the T-DNA insertion disrupts a gene for the regulatory A subunit of protein phosphatase 2A (PP2A-A). The RCN1 gene rescues the rcn1 mutant phenotype and also complements the temperature-sensitive phenotype of the Saccharomyces cerevisiae PP2A-A mutation, tpd3-1. These data implicate protein phosphatase 2A in the regulation of auxin transport in Arabidopsis.

Approaches to understanding auxin action.

The effects of auxin on plant growth and development have been studied for decades, but the molecular mechanisms of auxin action remain unknown. These mechanisms have primarily been investigated by characterization of auxin physiology mutants and analysis of auxin-binding proteins and auxin-regulated genes. These efforts are now converging, since some mutants have recently been shown to have altered expression of specific auxin-binding proteins and auxin-regulated genes. The features of these proteins and genes are providing the first tantalizing clues to the organization of auxin signal transduction pathways.

Two members of the ERabp gene family are expressed differentially in reproductive organs but to similar levels in the coleoptile of maize.

A Zea mays cDNA clone, ZmERabp4, coding for a new member of the auxin-binding protein family was isolated. The primary amino acid sequence contains an N-terminal hydrophobic leader sequence, a potential glycosylation site (Asn136-Thr-Thr) and a C-terminal KDEL motif known to be responsible for retention of proteins within the lumen of the ER. The expression pattern of the ZmERabp4 gene in various organs of maize differs from the expression pattern previously observed for the ZmERabp1 gene. The ZmERabp4 gene is expressed highly in male flower organs, whereas the ZmERabp1 gene shows highest expression in female flower parts. In situ hybridization and analysis by laser scanning microscopy revealed enhanced levels of expression for both genes in the coleoptile when compared with the primary leaf of etiolated maize seedlings.

Molecular analysis of an auxin binding protein gene located on chromosome 4 of Arabidopsis.

We have isolated a cDNA clone from Arabidopsis, At-ERabp1, for the Arabidopsis auxin binding protein located in the lumen of the endoplasmic reticulum (ER). This cDNA clone codes for a protein related to the major auxin binding protein from maize, Zm-ERabp1. A single open reading frame, 594 bases in length, predicts a protein of 198 amino acid residues and a molecular mass of 22,044 D. The primary amino acid sequence contains an N-terminal hydrophobic signal sequence of 33 amino acids. We demonstrated by in vitro studies that the At-ERabp1 protein is translocated into ER-derived microsomes. The protein was processed, and the cleavage site for the N-terminal signal peptide was determined by radiosequencing. The mature protein is composed of 165 amino acid residues, with a molecular mass of 18,641 D. The At-ERabp1 protein contains potential N-glycosylation sites (Asn46-Ile-Ser and Asn130-Ser-Thr). In vitro transport studies demonstrated cotranslational glycosylation. Retention within the lumen of the ER correlates with an additional signal located at the C terminus and represented by the amino acids Lys196-Asp-Glu-Leu, well known to be essential for active retrieval of proteins into the lumen of the ER. DNA gel blot analysis of genomic DNA revealed single hybridizing bands, suggesting that only a single At-ERabp1 gene is present in the Arabidopsis genome. Restriction fragment length polymorphism mapping indeed revealed a single locus mapping to chromosome 4.

Hormonal modulation of plant growth: the role of auxin perception.

The organisation of growth and development in vascular plants appears to be highly adapted to meet the specific demands of a sessile, autotrophic habit. Many of the characteristic features of plant development are associated with the activities of five groups of phytohormones. Each of the phytohormones has the ability to influence fundamentally a remarkable variety of developmental and physiological processes. This ability has been widely documented but remains to be explained. Here we describe how recent breakthroughs in the analysis and understanding of eucaryotic signal transduction are being applied, in conjunction with technical advances in molecular genetics, to elucidate the molecular basis of the phytohormonal properties of auxin. Both auxin concentration, and the sensitivity of plant cells to this phytohormone have been implicated as important parameters in auxin action. We describe recent molecular biological approaches to assess the contribution made by each of these parameters. Emphasis is given to a description of recent genetic and biochemical progress towards identification of the molecular targets of the auxin signal and the molecular components involved in its subsequent transduction.

Peribacteroid membrane nodulin gene induction by Bradyrhizobium japonicum mutants.

Seventeen translation products from Glycine max root mRNA precipitated with antiserum prepared against a peribacteroid membrane preparation from effective root nodules. Messenger RNA from fix (+) nodules coded for these 17 products plus 7 other nodule-specific polypeptides which bound to the antiserum. Of these 7 nodulins only 4 were present when nodules were infected with Bradyrhizobium japonicum 110 rif 15 2960, which induces the plant to produce 'empty' peribacteroid membranes. In nodules infected with B. japonicum strains inducing either very short-lived or defective peribacteroid membrane, only 5 or 6, respectively, of these nodulins could be detected.From these results we hypothesize that the microsymbiont is responsible for the production of at least 4 different signals leading to peribacteriod membrane formation by the plant.

Particle density and protein composition of the peribacteroid membrane from soybean root nodules is affected by mutation in the microsymbiont Bradyrhizobium japonicum.

Particle frequency of the peribacteroid membrane (PBM) from nodules of Glycine max (L.) Merr. cv. Maple Arrow infected with Bradyrhizobium japonicum 61-A-101 (wild-type strain) was determined by freeze-fracturing to be about 2200·µm(-2) in the protoplasmic fracture face and 700·µm(-2) in the exoplasmic fracture face. In membranes isolated from nodules infected with the mutant RH 31-Marburg of B. japonicum, the particle frequency was similar in both fracture faces with 1200-1300 particles·µm(-2). Analysis of particlesize distribution on peribacteroid membranes showed a loss, especially of particle sizes larger than 11 nm, in the mutant-infected nodules. Two-dimensional gel electrophoresis (isoelectric focussing and sodium dodecyl sulfate-polyacrylamide) showed 27 different polypeptides in the PBM from nodules infected with the wild-type strain, four of which were absent from the PBM of nodules infected with the mutant RH 31-Marburg, which also exhibited one extra small-molecular-weight polypeptide. At least 14 of the 27 polypeptides in the PBM from the wild-type-infected nodule were glycoproteins. In three of these glycoproteins, post-translational modifications were either lacking or different when the membrane was derived from mutant-infected nodules.

Further compounds from the pedal gland of the bontebok (Damaliscus dorcas dorcas).

The identification of four further major constituents of the pedal gland exudate of the bontebok, Damaliscus dorcas dorcas, viz. alpha-terpineol, 2-n-heptylpyridine, m-cresol and (A)-6-dodecen-4-olide and the investigation of the stereochemistry of the double bond in (Z)-6-dodecen-4-olide by means of iterative computer analysis are described. An improved synthesis of this compound is outlined.