Preparation of Actin and Fluorescent Actin Analogs from Plant Cells

The plant actin cytoskeleton provides a dynamic cytoplasmic framework for many fundamental cellular processes like cytoplasmic streaming,cytokinesis and morphogenesis.Understanding the actin organization and structure in plants requires the generation of new probes for measuring actin dynamics in living cells. Fluorescent analog cytochemistry presents an unrivaled opportunity to probe the actin cytoskeleton in living cells. Such method using in the study of plant actin cytoskeleton has not been reported. By using this method, based on the affinity chromatography of profilin with PLP-Sepharose (PLP: poly-L-proline) for actin purification, the author obtained 6 mg of > 98% in purity, polymerizable actin from 10 g of maize (Zea mays L. ) pollen, and this actin was successfully labeled with Oregon Green 488 carboxylic acid. From 10 g of maize pollen, 1.2 mg with 60 % dye/protein ratio, polymerizable, fluorescent actin analog was obtained. The study yields an effective method for purifying plant actin and preparing fluorescent analog, which may provide facilities for the study of actin dynamics in plant ceils.     

植物肌动蛋白的纯化及荧光标记

以植物花粉为材料,利用肌动蛋白可以与其单体结合蛋白———profilin特异性结合的特性及profilin的多聚脯氨酸亲和柱层析法,获得较大量、高纯度,具有活性的植物肌动蛋白,并用羧酸俄勒冈绿对所获纯化肌动蛋白进行了荧光标记。结果显示,从10g玉米(ZeamaysL.)花粉中可得到1.2mg具有绿色荧光的肌动蛋白,标记率为60%。体外实验结果表明,所得荧光肌动蛋白在适宜条件下可聚合成绿色荧光微丝。     

Calcium-induced outgrowth of astrocytic peripheral processes requires actin binding by Profilin-1

Peripheral astrocytic processes (PAPs) are highly motile structures that are strategically positioned in close proximity to synapses. Long-lasting PAP retraction in hypothalamus is known to alter synaptic transmission [1]. The PAP motility is likely to be actin-based because they are known to contain actin-related proteins such as Ezrin [2]. However, the link between dynamic activity-dependent changes in astrocytic morphology and the synaptic function has not been established experimentally, presumably due to lack of appropriate tools. To selectively suppress activity-dependent morphological plasticity of astrocytes, we developed a bicistronic construct that allows simultaneous tracing and manipulating the morphology of PAPs. The construct is designed for co-expression of (i) the mutant actin binding protein Profilin-1 (abdProf-1) with a single amino acid substitution (H119E) that prevents its binding to actin monomers [3] with (ii) the membrane-targeted morphological tracer LckGFP [4]. Cultured cortical astrocytes transfected with this construct showed abdProf-1 overexpression at a 5-fold level compared to the endogenous Profilin-1. The cells also expressed LckGFP at a level sufficient for precise morphological tracing. We found that photolysis of caged Ca²⁺ induced a pronounced outgrowth of PAPs, which was suppressed by abdProf-1 overexpression in terms of PAP number, growth rate and maximal length. In contrast, the morphological complexity of astrocytes, basal motility of their PAPs and major cytoskeletal structures were not affected by abdProf-1 overexpression. In summary, we identified the actin binding by Profilin-1 as a pivotal mechanism in activity-dependent morphological plasticity of PAPs in cultured astrocytes.     

Actin and actin-binding proteins in higher plants

Summary The actin cytoskeleton is a complex and dynamic structure that participates in diverse cellular events which contribute to plant morphogenesis and development. Plant actins and associated actin-binding proteins are encoded by large, differentially expressed gene families. The complexity of these gene families is thought to have been conserved to maintain a pool of protein isovariants with unique properties, thus providing a mechanistic basis for the observed diversity of plant actin functions. Plants contain actin-binding proteins which regulate the supramolecular organization and function of the actin cytoskeleton, including monomer-binding proteins (profilin), severing and dynamizing proteins (ADF/cofilin), and side-binding proteins (fimbrin, 135-ABP/villin, 115-ABP). Although significant progress in documenting the biochemical activities of many of these classes of proteins has been made, the precise roles of actin-binding proteins in vivo awaits clarification by detailed mutational analyses.Dedicated to Professor Brian E. S. Gunning on the occasion of his 65th birthday     

Profilin revealed in pollen nuclei: immuno-electron microscopy of high-pressure frozen Ledebouria socialis Roth (Hyacinthaceae)

 Cryoimmobilization by high-pressure freezing, combined with cryosubstitution and resin embedding, allowed accurate retention in situ of the small (12–15 kDa) water-soluble protein, profilin, in anthers of Ledebouria socialis Roth (Hyacinthaceae). The subcellular distribution of profilin was investigated by using post-embedding immunogold labelling with rabbit antisera raised against recombinant birch profilin (RP2) or birch COOH-terminal profilin peptide (RP3). The patterns observed in mature pollen grains are novel to eukaryotic organisms: profilin was consistently demonstrated within both the vegetative and generative nuclei, an addition to its well-known presence in the cytoplasm. Methodological and immunological aspects, as well as possible biological implications, of this finding are considered. Received: 17 March 1997 / Revision accepted: 10 July 1997     

Localization of profilin- and actin-like immunoreactivity in in vitro-germinated tobacco pollen tubes by electron microscopy after special water-free fixation techniques

Double immunogold labeling of profilin and actin was performed on ultrathin sections of in vitro germinated tobacco pollen using different anti-profilin and anti-actin antibodies. Since profilin, besides its role as an actin-binding protein, is known as an allergen, water-free fixation in p-formaldehyde vapor was used. Profilin labeling occurs throughout the cytoplasm of the pollen tube. There is no profilin in the pollen tube wall. Actin reactivity is found in the cytoplasm and extracellularly in the pollen tube wall where three out of four different anti-actin antibodies give a positive signal. This labeling of the pollen tube wall may result from a wall-bound actin, an isoform of actin not yet described or from the presence of a molecule immunologically indistinguishable from actin.     

Slow Axonal Transport of Soluble Actin with Actin Depolymerizing Factor, Cofilin, and Profilin Suggests Actin Moves in an Unassembled Form

Abstract: We examined the axonal transport of actin and its monomer binding proteins, actin depolymerizing factor, cofilin, and profilin, in the chicken sciatic nerve following injection of [³⁵S]methionine into the lumbar spinal cord. At intervals up to 20 days after injection, nerves were cut into 1-cm segments and separated into Triton X-100-soluble and particulate fractions. Actin and its binding proteins were then isolated by affinity chromatography on DNase I-Sepharose and by one- and two-dimensional polyacrylamide gel electrophoresis. Fluorographic analysis showed that the specific activity of soluble actin was two to three times that of its particulate form and that soluble actin, cofilin, actin depolymerizing factor, and profilin were transported at similar rates in slow component b of axonal flow. Our data strongly support the view that the mobile form of actin in slow transport is soluble and that a substantial amount of this actin may travel as a complex with actin depolymerizing factor, cofilin, and profilin. Along labeled nerves the specific activity of the unphosphorylated form of actin depolymerizing factor, which binds actin, was not significantly different from that of its "inactive" phosphorylated form. This constancy in specific activity suggests that continuous inactivation and reactivation of actin depolymerizing factor occur during transport, which could contribute to the exchange of soluble actin with the filamentous actin pool.     

Profilin oligomerization and its effect on poly (l-proline) binding and phosphorylation

Profilin is a cytoskeletal protein that interacts specifically with actin, phosphoinositides and poly (l-proline). Experimental results and in silico studies revealed that profilin exists as dimer and tetramer. Profilin oligomers possess weak affinity to poly (l-proline) due to unavailability of binding sites in dimers and tetramers. Phosphorylation studies indicate that profilin dimers are not phosphorylated while teramers are preferentially phosphorylated over monomers. In silico studies revealed that PKC phosphorylation site, S137 is buried in dimer while it is accessible in tetramer.     

Molecular cloning and characterization of a profilin gene <Emphasis Type="Italic">BnPFN</Emphasis> from <Emphasis Type="Italic">Brassica</Emphasis><Emphasis Type="Italic">nigra</Emphasis> that expressing in a pollen-specific manner

Brassica nigra is a newly found invasive species in Zhejiang Province, China. It distributes alongside the roads, in vegetable fields and on riversides. When it blooms, some natives there will suffer from allergic rhinitis. We designed gene-specific primer pairs according to reported profilin genes and successfully isolated their homolog from flower bud cDNA of B. nigra. The gene, designated BnPFN, was submitted to GenBank under accession number EU004073. BnPFN was 405 bp in length encoding 134 amino acids. Expression analysis of BnPFN gene was carried out by means of RT-PCR. The results showed that BnPFN express only in anthers and pollens, and there was no detection in roots, leaves, stems, sepals, petals and pistils. We suggest that BnPFN is a pollen-specific gene and may be responsible for pollen anaphylactic reactions in those invading areas when B. nigra blooms.     

Profilin 1 obtained by proteomic analysis in all-trans retinoic acid-treated hepatocarcinoma cell lines is involved in inhibition of cell proliferation and migration

Previous studies have shown that all-trans retinoic acid (ATRA) suppresses growth of hepatocarcinoma cell in vitro. To understand the underlying mechanisms, we investigated the protein expression profiles by 2-DE in hepatocarcinoma cell line SMMC-7721 treated with ATRA. Our results reveal that six proteins were differently expressed in response to ATRA. Using MS and database searching, they were identified as profilin 1, phosphoglycerate kinase 1, RuvB-like 1, alpha-enolase, pyridoxal kinase and F-actin capping protein. We selected the up-regulated protein, profilin 1 (PFN1), for further studies. The PFN1 expression was increased in response to ATRA in a dose- and time-dependent manner. The PFN1 expression was reduced dramatically in four hepatoma cell lines compared to L02 cell line of non-tumor origin. The PFN1 expression was also examined in 4 cases of primary hepatocarcinoma tissues by Western blot and 30 cases by tissues microarray. It was found that the protein level of PFN1 was lower in hepatocarcinoma tissues compared to that in the adjacent tissues. Similar to ATRA, overexpression of PFN1 led to inhibition of cell proliferation and migration. Furthermore, RNAi-based PFN1 knockdown could rescue the inhibitory effect of ATRA on cell proliferation and migration. In conclusion, ATRA inhibited cell proliferation and migration through up-regulation of PFN1.