GTPase activity and biochemical characterization of a recombinant cotton fiber annexin

A cDNA encoding annexin was isolated from a cotton (Gossypium hirsutum) fiber cDNA library. The cDNA was expressed in Escherichia coli, and the resultant recombinant protein was purified. We then investigated some biochemical properties of the recombinant annexin based on the current understanding of plant annexins. An "add-back experiment" was performed to study the effect of the recombinant annexin on beta-glucan synthase activity, but no effect was found. However, it was found that the recombinant annexin could display ATPase/GTPase activities. The recombinant annexin showed much higher GTPase than ATPase activity. Mg2+ was essential for these activities, whereas a high concentration of Ca2+ was inhibitory. A photolabeling assay showed that this annexin could bind GTP more specifically than ATP. The GTP-binding site on the annexin was mapped into the carboxyl-terminal fourth repeat of annexin from the photolabeling experiment using domain-deletion mutants of this annexin. Northern-blot analysis showed that the annexin gene was highly expressed in the elongation stages of cotton fiber differentiation, suggesting a role of this annexin in cell elongation.     

Isolation and characterization of a <Emphasis Type="Italic">GAI/RGA</Emphasis>-like gene from <Emphasis Type="Italic">Gossypium hirsutum</Emphasis>

The aim of the investigation reported here was to assess the role of gibberellin in cotton fiber development. The results of experiments in which the gibberellin (GA) biosynthesis inhibitor paclobutrazol (PAC) was tested on in vitro cultured cotton ovules revealed that GA is critical in promoting cotton fiber development. Plant responses to GA are mediated by DELLA proteins. A cotton nucleotide with high sequence homology to Arabidopsis thaliana GAI (AtGAI) was identified from the GenBank database and analyzed with the BLAST program. The full-length cDNA was cloned from upland cotton (Gossypium hirsutum, Gh) and sequenced. A comparison of the putative protein sequence of this cDNA with all Arabidopsis DELLA proteins indicated that GhRGL is a putative ortholog of AtRGL. Over-expression of this cDNA in Arabidopsis plants resulted in the dwarfed phenotype, and the degrees of dwarfism were related to the expression levels of GhRGL. The deletion of 17 amino acids, including the DELLA domain, resulted in the dominant dwarf phenotype, demonstrating that GhRGL is a functional protein that affects plant growth. Real-time quantitative PCR results showed that GhRGL mRNA is highly expressed in the cotton ovule at the elongation stage, suggesting that GhRGL may play a regulatory role in cotton fiber elongation.     

Cotton annexin proteins participate in the establishment of fiber cell elongation scaffold

Cotton plant is one of the most important economic crops in the world which supplies natural fiber for textile industry. The crucial traits of cotton fiber quality are fiber length and strength, which are mostly determined by the fiber elongation stage. Annexins are assumed to be involved in regulating fiber elongation, but direct evidences remain elusive. Recently, we have investigated the activities of fiber-specific expressed annexins AnGb5/6 and their interacted proteins in cotton. AnGb5 and 6 can interact reciprocally to generate a protein macro-raft in cell membrane. This macro-raft is probably a stabilized scaffold for Actin1 organization. The actin assembling direction and density are correlated with AnGb6 gene expression and fiber expanding rate among three fiber length genotypes. These results suggest that annexins may act as the adaptor that linked fiber cell membrane to actin assembling. Due to the strong Ca²⁺ and lipid binding ability of annexins, these results also indicate that annexins complex may function as an intermediate to receive Ca²⁺ or lipid signals during fiber elongation.     

The genetic origin of mouse annexin VIII

Mouse annexin VIII cDNA was characterized by DNA sequencing of expressed sequence tag clones, molecular systematic analysis, and genetic linkage mapping to investigate its evolutionary origin. Its subfamily identity, divergence pattern, and nucleotide substitution rate were established by comparison with other annexin cDNA and deduced protein sequences. The known phylogenetic association of annexin VIII in an evolutionary clade with annexins XI, IV, V, and VIa identified these close homologs as potential progenitors or duplication products. Cladistic analysis confirmed the base position of annexin XI and its relationship to annexin IV as a direct duplication product. Although annexin VIII also derived from annexin XI, the evolutionary branching order, gene separation times, and mapping results indicated that it was probably a subsequent duplication product of annexin IV about 300 million years ago. Dates were calibrated against the assumed separation time of 75 Mya for rodents from other mammals, divergence rates were based on comparisons of all available annexin species, and relative rate tests implied individually stable gene clocks for most annexins. Linkage mapping of mouse Anx8 to the centromeric region of Chromosome (Chr) 14 placed it in a more distal homology group from previously mapped Anx7 and Anx11. Despite their synteny, the combined proximity and segregation of these three annexins diminished the likelihood that they were mutual gene duplication products. Received: 25 May 1997 / Accepted: 13 September 1997     

Identification of a novel annexin in Hydra vulgaris. Characterization, cDNA cloning, and protein kinase C phosphorylation of annexin XII.

As a first step toward the elucidation of a simple animal model in which to investigate annexin function, we identified, isolated, and characterized a novel annexin from Hydra vulgaris, annexin XII. A hydra cDNA library was screened using a probe generated by polymerase chain reaction from primers based on the partial amino acid sequence of annexin XII. Annexin XII cDNA was cloned and the functional protein was expressed in high yields in Escherichia coli. The annexin XII cDNA sequence predicted a 316-amino acid protein that had between 44 and 54% sequence identity with the Ca2+-binding core domains of previously characterized vertebrate and Drosophila annexins. The amino-terminal domain of annexin XII did not have sequence similarity with other known annexins except at and around a site that resembled known protein kinase C (PKC) phosphorylation sites in other annexins. As anticipated from its sequence, annexin XII was a high affinity substrate for purified rat brain PKC; half-maximal phosphorylation occurred below 0.1 microM annexin XII, and incorporation of up to 0.8 mol of phosphate/mol of annexin XII was observed. A PKC-like activity in hydra extracts also phosphorylated annexin XII. In summary, hydra promises to be a valuable model system for investigating the biological function of annexins and for determining how this function is modulated by PKC phosphorylation.     

Distinct Annexin Subfamilies in Plants and Protists Diverged Prior to Animal Annexins and from a Common Ancestor

Annexin homologues in the kingdoms of Planta and Protista were characterized by molecular sequence analysis to determine their phylogenetic and structural relationship with annexins of Animalia. Sequence fragments from 19 plant annexins were identified in sequence databases and composite sequences were also assembled from expressed sequence tags for Arabidopsis thaliana. Length differences in protein amino-termini and evidence for unique exon splice sites indicated that plant annexins were distinct from those of animals. A third annexin gene of Giardia lamblia (Anx21-Gla) was identified as a distant relative to other protist annexins and to those of higher eukaryotes, thus providing a suitable outgroup for evolutionary reconstruction of the family tree. Rooted evolutionary trees portrayed protist, plant, and Dictyostelium annexins as early, monophyletic ramifications prior to the appearance of closely related animal annexin XIII. Molecular phylogenetic analyses of DNA and protein sequence alignments revealed at least seven separate plant subfamilies, represented by Anx18 (alfalfa, previously classified), Anx22 (thale cress), Anx23 (thale cress, cotton, rape and cabbage), Anx24 (bell pepper and tomato p34), Anx25 (strawberry, horseradish, pea, soybean, and castor bean), Anx26-Zma, and Anx27-Zma (maize). Other unique subfamilies may exist for rice, tomato p35, apple, and celery annexins. Consensus sequences compiled for each eukaryotic kingdom showed some breakdown of the ``annexin-fold' motif in repeats 2 and 3 of protist and plant annexins and a conserved codon deletion in repeat 3 of plants. The characterization of distinct annexin genes in plants and protists reflects their comparable diversity among animal species and offers alternative models for the comparative study of structure–function relationships within this important gene family. Received: 30 May 1996 / Accepted: 20 August 1996     

A Cotton Annexin Protein AnxGb6 Regulates Fiber Elongation through Its Interaction with Actin 1

Annexins are assumed to be involved in regulating cotton fiber elongation, but direct evidence remains to be presented. Here we cloned six Annexin genes (AnxGb) abundantly expressed in fiber from sea-island cotton (G. barbadense). qRT-PCR results indicated that all six G. barbadense annexin genes were expressed in elongating cotton fibers, while only the expression of AnxGb6 was cotton fiber-specific. Yeast two hybridization and BiFC analysis revealed that AnxGb6 homodimer interacted with a cotton fiber specific actin GbAct1. Ectopic-expressed AnxGb6 in Arabidopsis enhanced its root elongation without increasing the root cell number. Ectopic AnxGb6 expression resulted in more F-actin accumulation in the basal part of the root cell elongation zone. Analysis of AnxGb6 expression in three cotton genotypes with different fiber length confirmed that AnxGb6 expression was correlated to cotton fiber length, especially fiber elongation rate. Our results demonstrated that AnxGb6 was important for fiber elongation by potentially providing a domain for F-actin organization.     

Functional characterization of <Emphasis Type="Italic">Gossypium hirsutum</Emphasis> profilin 1 gene (<Emphasis Type="Italic">GhPFN1</Emphasis>) in tobacco suspension cells

Cotton fiber is an extremely long plant cell. Fiber elongation is a complex process and the genes that are crucial for elongation are largely unknown. We previously cloned a cDNA encoding an isoform of cotton profilin and found that the gene (designated GhPFN1) was preferentially expressed in cotton fibers. In the present study, we have further analyzed the expression pattern of GhPFN1 during fiber development and studied its cellular function using tobacco suspension cells as an experimental system. We report that expression of GhPFN1 is tightly associated with fast elongation of cotton fibers whose growth requires an intact actin cytoskeleton. Overexpression of GhPFN1 in the transgenic tobacco cells was correlated with the formation of elongated cells that contained thicker and longer microfilament cables. Quantitative analyses revealed a 2.5–3.6 fold increase in total profilin levels and a 1.6–2.6 fold increase in the F-actin levels in six independent transgenic lines. In addition to the effect on cell elongation, we also observed delayed cell cycle progression and a slightly lower mitotic index in the transgenic cells. Based on these data, we propose that GhPFN1 may play a critical role in the rapid elongation of cotton fibers by promoting actin polymerization. Hai-Yun Wang and Yi Yu contributed equally to this work.     

Sequence and Chromosomal Localization of Mouse Annexin XI

Mouse annexin XI (anx11)²was cloned from a macrophage cDNA library and characterized by genetic linkage mapping, DNA sequencing, and structural comparison with other annexins. TheAnx11gene localized to mouse chromosome 14 in close linkage with theRarb, Plau,andWnt5agenes near the centromere and 1.8 cM distal from theAnx7gene. The open reading frame was flanked by long, untranslated regions and encoded a 503-amino-acid protein with 93.1% identity to its human orthologue. Its 189-aa amino terminus corresponded to the widely expressed variant 1 of two possible, alternatively spliced forms. A previously described peptide fromAplysia brasilianawas identified as a closely related invertebrate homologue. Since annexin XI is known to be localized in the nucleus at certain stages of development, the identification of a region in tetrad repeats 3 and 4 resembling the “chromo box” domain may be relevant to a nuclear regulatory function of annexin XI. Knowledge of the mouse cDNA sequence and genetic map location will assist in the analysis of genomic organization and expression and provide a useful animal model to investigate gene function and hereditary phenotype for annexin XI.     

Down-regulating annexin gene GhAnn2 inhibits cotton fiber elongation and decreases Ca2+ influx at the cell apex

Cotton fiber is a single cell that differentiates from the ovule epidermis and undergoes synchronous elongation with high secretion and growth rate. Apart from economic importance, cotton fiber provides an excellent single-celled model for studying mechanisms of cell-growth. Annexins are Ca²⁺- and phospholipid-binding proteins that have been reported to be localized in multiple cellular compartments and involved in control of vesicle secretions. Although several annexins have been found to be highly expressed in elongating cotton fibers, their functional roles in fiber development remain unknown. Here, 14 annexin family members were identified from the fully sequenced diploid G. raimondii (D₅ genome), half of which were expressed in fibers of the cultivated tetraploid species G. hirsutum (cv. YZ1). Among them, GhAnn2 from the D genome of the tetraploid species displayed high expression level in elongating fiber. The expression of GhAnn2 could be induced by some phytohormones that play important roles in fiber elongation, such as IAA and GA₃. RNAi-mediated down-regulation of GhAnn2 inhibited fiber elongation and secondary cell wall synthesis, resulting in shorter and thinner mature fibers in the transgenic plants. Measurement with non-invasive scanning ion-selective electrode revealed that the rate of Ca²⁺ influx from extracellular to intracellular was decreased at the fiber cell apex of GhAnn2 silencing lines, in comparison to that in the wild type. These results indicate that GhAnn2 may regulate fiber development through modulating Ca²⁺ fluxes and signaling.     

Cotton LIM domain‐containing protein GhPLIM1 is specifically expressed in anthers and participates in modulating F‐actin

As one form of actin binding protein (ABP), LIM domain protein can trigger the formation of actin bundles during plant growth and development. In this study, a cDNA (designated GhPLIM1) encoding a LIM domain protein with 216 amino acid residues was identified from a cotton flower cDNA library. Quantitative RT‐PCR indicated that GhPLIM1 is specifically expressed in cotton anthers, and its expression levels are regulated during anther development of cotton. GhPLIM1:eGFP transformed cotton cells display a distributed network of eGFP fluorescence, suggesting that GhPLIM1 protein is mainly localised to the cell cytoskeleton. In vitro high‐speed co‐sedimentation and low co‐sedimentation assays indicate that GhPLIM1 protein not only directly binds actin filaments but also bundles F‐actin. Further biochemical experiments verified that GhPLIM1 protein can protect F‐actin against depolymerisation by Lat B. Thus, our data demonstrate that GhPLIM1 functions as an actin binding protein (ABP) in modulating actin filaments in vitro, suggesting that GhPLIM1 may be involved in regulating the actin cytoskeleton required for pollen development in cotton.     

Molecular characterization and expression analysis of nine cotton GhEF1A genes encoding translation elongation factor 1A

The translation elongation factor 1A, eEF1A, plays an important role in protein synthesis, catalyzing the binding of aminoacyl-tRNA to the A-site of the ribosome by a GTP-dependent mechanism. To investigate the role of eEF1A for protein synthesis in cotton fiber development, nine different cDNA clones encoding eukaryotic translation elongation factor 1A were isolated from cotton (Gossypium hirsutum) fiber cDNA libraries. The isolated genes (cDNAs) were designated cotton elongation factor 1A gene GhEF1A1, GhEF1A2, GhEF1A3, GhEF1A4, GhEF1A5, GhEF1A6, GhEF1A7, GhEF1A8, GhEF1A9, respectively. They share high sequence homology at nucleotide level (71-99% identity) in the coding region and at amino acid level (96-99% identity) among each other. Phylogenetic analysis demonstrated that the nine GhEF1A genes can be divided into 5-6 subfamilies, indicating the divergence occurred in structures of the genes as well as the deduced proteins during evolution. Real-time quantitative RT-PCR analysis revealed that GhEF1A genes are differentially expressed in different tissues/organs. Of the nine GhEF1A genes, five are expressed at relatively high levels in young fibers. Further analysis indicated that expressions of the GhEF1As in fiber are highly developmental-regulated, suggesting that protein biosynthesis is very active at the early fiber elongation.     

Immunolocalization and histochemical evidence for the association of two different<Emphasis Type="Italic"> Arabidopsis</Emphasis> annexins with secretion during early seedling growth and development

Annexins are a multigene, multifunctional family of calcium-dependent, membrane-binding proteins found in animal and plant cells. In plants, annexins have been localized in the cytoplasm and at the cell periphery of highly secretory cell types, and in the tip region of polarly growing cells. Consequently, one proposed function for annexins in plant cells is participation in the Golgi-mediated secretion of new wall materials. In Arabidopsis, there are eight different annexin cDNAs, which share between 30% and 81% deduced amino acid sequence identity. We have used two monospecific Arabidopsis anti-annexin antibodies, raised against divergent 31-mer peptides from AnnAt1 and AnnAt2 and a previously characterized pea anti-annexin p35 antibody, for Western blot and immunolocalization studies in Arabidopsis. Western blot analyses of various Arabidopsis protein fractions showed that the two Arabidopsis antibodies are able to specifically recognize annexins in both soluble and membrane fractions. Immunofluorescence results with the three annexin antibodies show staining of secretory cells, especially at the cell periphery in developing sieve tubes, outer root cap cells, and in root hairs, consistent with previous results. In developmentally different stages some staining was also seen near the apical meristem, in some leaf cells, and in phloem-associated cells. Autoradiography following ³H-galactose incorporation was used to more clearly correlate active secretion of wall materials with the localization patterns of a specific individual annexin protein in the same cells at the same developmental stage. The results obtained in this study provide further support for the hypothesis that these two Arabidopsis annexins function in Golgi-mediated secretion during early seedling growth and development.     

棉花纤维发育相关基因GhPRP10的克隆及其功能分析

利用电子序列拼接结合RT-PCR技术,从12DPA(开花后天数)棉纤维中克隆到1个编码富含脯氨酸蛋白(PRPs)基因,命名为GhPRP10(登录号KP036633)。GhPRP10基因开放阅读框为684bp,编码228个氨基酸,其中脯氨酸(Pro)含量为34.6%。序列分析发现GhPRP10蛋白具有N端信号肽和富含脯氨酸区域,属于第一类PRPs。实时荧光定量PCR(RT-PCR)结果显示,GhPRP10在棉纤维组织中优势表达,在纤维发育过程中的表达量呈现先升高后降低的趋势,在18DPA纤维中表达量最高。利用Gateway技术构建植物过量表达载体,转入烟草BY-2悬浮细胞,表型观察和细胞长度测量结果显示,转GhPRP10基因细胞比野生型细胞显著增长。根据该基因的组织表达特征和转基因细胞表型分析,推测GhPRP10基因在纤维伸长和次生壁合成过程中发挥作用。     

一个陆地棉bZIP蛋白cDNA的克隆及表达分析

利用PCR筛选方法从陆地棉纤维cDNA文库中筛选到一个全长cDNA序列,命名为GhbZIP。其编码产物长度为645个氨基酸残基,序列中含有两个未知功能的保守区域DUF630和DUF632,而DUF632区中有一个类似碱性亮氨酸拉链基元;此外氨基酸序列中还存在一个富脯氨酸区和一个富苯丙氨酸区,因此该蛋白具有植物碱性亮氨酸拉链蛋白的结构特征。亲水性分析表明,GhbZIP为一个典型的膜蛋白。GhbZIP基因主要是在开花3d之后在胚珠和纤维细胞中表达,这表明该基因可能与棉纤维伸长过程中的基因表达调控有关。     

A beta-tubulin-like cDNA expressed specifically in elongating cotton fibers induces longitudinal growth of fission yeast

Using cDNA Representational Difference Analysis (RDA) techniques, we isolated a cDNA that was expressed specifically in cotton fibers but not in the ovules of a fuzzless-lintless mutant (fl). We designated it as Gh-BTubL for it shares high sequence identity with known plant and yeast beta-tubulins. RT-PCR and robotic cDNA dot blot analyses indicated that the expression of Gh-BTubL was correlated with the elongation pattern of cotton fibers. In situ hybridization results verified that there was no Gh-BTubL mRNA in fl ovules while it was easily detected in the elongating wild type cotton fiber cells. Overexpression of Gh-BTubL in fission yeast induced longitudinal growth of the host cells by 1.74-fold, with no apparent effect on other aspects of the host cells. We suggest that Gh-BTubL plays an important role in cotton fiber elongation and we believe that elucidation of the control mechanisms for expression of tubulin-like proteins may help improve fiber quality and productivity.