Implication of actin in the uptake of sucrose and valine in the tap root and leaf of sugar beet

Actin microfilaments (F-actin) are major components of the cytoskeleton essential for many cellular dynamic processes (vesicle trafficking, cytoplasmic streaming, organelle movements). The aim of this study was to examine whether cortical actin microfilaments might be implicated in the regulation of nutrient uptake in root and leaf cells of Beta vulgaris. Using antibodies raised against actin and the AtSUC1 sucrose transporter, immunochemical assays demonstrated that the expression of actin and a sucrose transporter showed different characteristics, when detected on plasma membrane vesicles (PMVs) purified from roots and from leaves. The in situ immunolabeling of actin and AtSUC1 sites in PMVs and tissues showed their close proximity to the plasma membrane. Using co-labeling in protoplasts, actin and sucrose transporters were localized along the internal border and in the outermost part of the plasma membrane, respectively. This respective membrane co-localization was confirmed on PMVs and in tissues using transmission electronic microscopy. The possible functional role of actin in sucrose uptake (and valine uptake, comparatively) by PMVs and tissues from roots and leaves was examined using the pharmacological inhibitors, cytochalasin B (CB), cytochalasin D (CD), and phalloidin (PH). CB and CD inhibited the sucrose and valine uptake by root tissues in a concentration-dependent manner above 1 μM, whereas PH had no such effect. Comparatively, the toxins inhibited the sucrose and valine uptake in leaf discs to a lesser extent. The inhibition was not due to a hindering of the proton pumping and H⁺ -ATPase catalytic activity determined in PMVs incubated in presence of these toxins.

Structural features and phylogeny of the actin gene of Chondrus crispus (Gigartinales, Rhodophyta)

We have characterized the cDNA and genomic sequences that encode actin from the multicellular red alga Chondrus crispus. Southern-blot analysis indicates that the C. crispus actin gene (ChAc) is present as a single copy. Northern analysis shows that, like the GapA gene, the actin gene is well expressed in gametophytes but weakly in protoplasts. Compared to actin genes of animals, fungi, green plants and oomycetes, that of C. crispus displays a higher evolutionary rate and does not show any of the amino-acid signatures characteristic of the other lineages. As previously described for GapA, ChAc is interrupted by a single intron at the beginning of the coding region. The site of initiation of transcription was characterized by RNAse protection. The promoter region displays a CAAT box but lacks a canonical TATA motif. Other noticeable features, such as a high content of pyrimidines as well as a 14-nt motif found in both the 5'-untranslated region and the intron, were observed.

Actin dynamics during the cell cycle in Chlamydomonas reinhardtii

We have used two monoclonal antibodies to demonstrate the presence and localization of actin in interphase and mitotic vegetative cells of the green alga Chlamydomonas reinhardtii. Commercially available monoclonal antibodies raised against smooth muscle actin (Lessard: Cell Motil. Cytoskeleton 10:349-362, 1988; Lin: Proc. Natl. Acad. Sci. USA 78:2335-2339, 1981) identify Chlamydomonas actin as a approximately 43,000-M(r) protein by Western immunoblot procedures. In an earlier study, Detmers and coworkers (Cell Motil. 5:415-430, 1985) first identified Chlamydomonas actin using NBD-phallacidin and an antibody raised against Dictyostelium actin; they demonstrated that F-actin is localized in the fertilization tubule of mating gametes. Here, we show by immunofluorescence that vegetative Chlamydomonas cells have an array of actin that surrounds the nucleus in interphase cells and undergoes dramatic reorganization during mitosis and cytokinesis. This includes the following: reorganization of actin to the anterior of the cell during preprophase; the formation of a cruciate actin band in prophase; reorganization to a single anterior actin band in metaphase; rearrangement forming a focus of actin anterior to the metaphase plate; reextension of the actin band in anaphase; presence of actin in the forming cleavage furrow during telophase and cytokinesis; and finally reestablishment of the interphase actin array. The studies presented here do not allow us to discriminate between G and F-actin. None the less, our observations, demonstrating dynamic reorganization of actin during the cell cycle, suggest a role for actin that may include the movement of basal bodies toward the spindle poles in mitosis and the formation of the cleavage furrow during cytokinesis.

Independent gene evolution in the potato actin gene family demonstrated by phylogenetic procedures for resolving gene conversions and the phylogeny of angiosperm actin genes

Nine different actin DNA sequences were isolated from the common potato, Solanum tuberosum, and the nucleotide sequence of five actin loci and of two allelic variants are presented. Unlike the wide variation in intron position among animal actin genes, the potato actin genes have three introns situated in the same positions as reported for all other angiosperm actin genes. Using a novel combination of analytical procedures (G-test and compatibility analysis), we could not find evidence of frequent large or small nonreciprocal exchanges of genetic material between the sequenced loci, although there were a few candidates. Resolution of such gene conversion events and the quantification of independence of gene evolution in multigene families is critical to the inference of phylogenetic relationships. Comparison with actin genes in other angiosperm species suggests that the actin multigene family can be divided into a number of subfamilies, evolved by descent rather than gene conversion, which are of possible functional origin, with one major subfamily diversification occurring before the divergence of monocots and dicots. The silent rate of nucleotide substitution was estimated to be similar to that suggested for a number of other plant nuclear genes, whereas the replacement rate was extremely slow, suggestive of selective constraints.

Plants contain highly divergent actin isovariants

Actin protein isovariants have been identified in animals with distinct cytoplasmic or muscle specific patterns of expression. Analysis of vascular plant actin gene sequences suggests that an even greater diversity should exist within the plant actin protein families, but previous studies on plant proteins have not demonstrated the presence of multiple actin isovariants. Antibodies recognizing a conserved amino-terminal plant actin peptide, a family of plant actin peptides from a variable region, and two monoclonal antibodies to conserved epitopes within animal actins were used to identify isovariants of soybean actin resolved by two-dimensional isoelectric focusing (IEF) sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Approximately six to eight actin isovariants with pI values ranging from 5.1 to 5.8 have been identified from soybean hypocotyls, stems, leaves, and roots with varying amounts of most isovariants present in all four organs. Acidic isovariants were present in much higher levels in leaves and stems. Antisera with lambda-class actin specificity detected a subset of three isovariants in all organs examined. One monoclonal and one antipeptide antisera are shown to react well with a wide variety of plant actin isovariants. Similar patterns of actin isovariants were detected in the distant angiosperms, Arabidopsis, petunia, and maize. It is likely that many of these diverse classes of isovariants have been preserved throughout vascular plant evolution and reflect the ancient diversity within plant actin gene families. The extreme difference among isovariants implies the presence of a complex actin-based cytoskeletal system in plants.

Nucleotide sequence of an actin gene from Arabidopsis thaliana

An 1830-bp genomic DNA segment containing an Arabidopsis thaliana actin gene, AAc1, has been cloned and sequenced. The AAc1 gene is present as a single-copy gene, but at least two other actin-like genes have been detected. Comparison of the nucleotide sequence of AAc1 with other cloned plant actin genes reveals four exons separated by three introns conservatively located in all plant actin genes. The deduced amino acid sequence has also been compared with actin protein sequences from other plants.

Cytodifferentiation of polar plant cells: formation and turnover of endoplasmic reticulum in root statocytes

By application of cytochalasin D (10 micrograms/ml) the distribution and turnover of endoplasmic reticulum (ER) in root statocytes of cress (Lepidium sativum L.) was studied. After 7 min of incubation, the distal ER complex, in 20-h-old control statocytes consisting of stacked cisternae, was disintegrated and redistributed. The amyloplasts sedimented into the most distal part of the cell. When the incubation time was increased up to 4 h, ER was formed near the nucleus and accumulated at the proximal cell pole. Thus microfilaments are suggested to be involved in (i) stabilization of the distal ER complex and (ii) the ER translocation from the forming site into the distal cell pole. By morphometric measurements the volume of story II (story III) statocytes was calculated to be 2400 microns3 (3000 microns3), containing an ER area of 1824 microns2 (2400 microns2). From the net ER formation rate of 5.2 microns2/min (story II) and 4.6 microns2/min (story III) and the net decrease rate of 23 microns2/min (story II) and 39.2 microns2/min (story III), a total ER formation rate of about 27 microns2/min (story II) and 43 microns2/min (story III) was estimated.

Effects of microfilament disrupters on microfilament distribution and morphology in maize root cells

Maize root tip cells were examined for the distribution of actin microfilaments in various cell types and to determine the effects of microfilament disrupters. Fluorescence microscopy on fixed, stabilized, squashed cells using the F-actin specific probe, rhodamine-labelled phalloidin, allowed for a three-dimensional visualization of actin microfilaments. Microfilaments were observed as long, meandering structures in root cap cells and meristematic cells, while those in immature vascular parenchyma were abundant in the thin band of cytoplasm and were long and less curved. By modifying standard electron microscopic fixation procedures, microfilaments in plant cells could be easily detected in all cell types. Treatment with cytochalasin B, cytochalasin D and lead acetate, compounds that interfere with microfilament related processes, re-organized the microfilaments into abnormal crossed and highly condensed masses. All the treatments affected not only the microfilaments but also the accumulation of secretory vesicles. The vivid demonstration of the effects of all of these microfilament disrupters on the number and size of Golgi vesicles indicates that these vesicles may depend on microfilaments for intracellular movement.

Cytochalasin B affects the structural polarity of statocytes from cress roots (Lepidium sativum L.)

The effect of cytochalasin B (CB; 25 micrograms ml-1 in 1% dimethylsulfoxide, DMSO) upon the structural polarity of statocytes in cress roots is demonstrated. If normal, vertically grown roots are incubated in CB, the structural polarity of the statocytes is altered according to the developmental stage of the root. Statocytes from young roots (13 or 17 hours, additionally 7 hours CB) are characterized by proximal ER cisternae and a sparsely developed distal ER-complex. Statocytes from older roots (24 hours, additionally 7 hours CB) still accumulate distal ER, as in control roots, but at the proximal cell pole in the vicinity of the nucleus additional ER is found. These effects are reversed by washing out the drug in DMSO. Growth of the roots under a continuous supply of CB yields statocytes with sedimented nuclei, proximal ER and almost no distal ER. Together with quantitative data from morphometric studies, a dynamic model of the expression of inherent cell polarity in structural polarity is proposed.

The control of cellulose microfibril deposition in the cell wall of higher plants : II. Freeze-fracture microfibril patterns in maize seedling tissues following experimental alteration with colchicine and ethylene

Cells of maize (Zea mays L.) seedling that are not fixed or cryoprotected contain the impressions of cellulose microfibrils on freeze-fractured plasma membranes. Impressions of the most recently deposited microfibrils have terminal complexes associated with them (see preceding paper). The orientations of microtubules in cytoplasmic fractures are parallel to the newest microfibrils observed on adjacent plasma membrane fractures. Small groups of microfibrils, distinguished from the next older layer by their new orientation, are sometimes observed directly adjacent and parallel to individual microtubules. Whereas microtubules are parallel to microfibril orientations which vary from transverse to occasionally longitudinal, microfilaments are parallel to the longitudinal cell axis. After colchicine treatment, cytoplasmic microtubules are absent, as are the bands of microfibrils that are observed on the membrane of control cells. Parallel orientations of microfibrils and normal pitfield outlines are often still observed after colchicine treatment. However, on some membranes, multidirectionally-oriented microfibril tips occur, associated with perturbations of microfibril orientation and rounded pit-field outlines. In ethylene-treated cells, some membranes have microfibril tips oriented in only one direction in new layers of longitudinal microfibrils. On other membranes, longitudinal bands of microfibril tips are oriented in opposing directions. We propose that after colchicine treatment, the patterns of microfibrils reflect an orientation mechanism which has been uncoupled from the influence of microtubules but which is still under some other form of cellular control. We propose that membrane flow could orient the lateral movement of synthesizing complexes in the membrane and that microtubules modulate this movement, apparently organizing the microfibrils into parallel bands in newly-forming wall layers.

Multigene family of actin-related sequences isolated from a soybean genomic library

We have investigated the actin-related sequences in soybean using heterologous actin DNA probes from Dictyostelium, Drosophila, and yeast. Southern blot analysis of restriction digests of soybean DNA indicates that actin is encoded in a small multigene family. In order to isolate individual members of this gene family, we have constructed a soybean genomic library in the lambda vehicle Charon 4A. A partial characterization of this library shows it to be nearly complete. We have isolated from this library a number of recombinant clones that hybridize to actin-coding sequences from all three heterologous probes. We have identified the fragments containing the actin-related sequences on the physical maps of two of these clones lambda SAc1 and lambda SAc3. These fragments were subcloned in the plasmid vehicle pBR322. Using electron microscope heteroduplex mapping we show that the subclones, pSAc1 and pSAc3, share homology with the entire actin-coding sequence (1.1 kb) of Drosophila and Dictyostelium. Furthermore, pSAc1 and pSAc3 have additional homology of approximately 0.22 kb at the 5' ends of their coding sequences. No homology is detected in the 3' flanking regions of these clones. The actin sequence in pSAc1 contains an interruption of approximately 0.30 kb located 0.39 kb from the 5' end of the actin polypeptide coding region.