GTPase Activity and Biochemical Characterization of a Recombinant Cotton Fiber Annexin

doi:10.1104/pp.119.3.925

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GTPase Activity and Biochemical Characterization of a Recombinant Cotton Fiber Annexin¹

Heungsop Shin and R. Malcolm Brown Jr.^*

Department of Botany, University of Texas, Austin, Texas, 78713-7640

ABSTRACT

Top
Abstract
Introduction
Methods
Results
Discussion
References

A cDNA encoding annexin was isolated from a cotton (Gossypium hirsutum) fiber cDNA library. The cDNA was expressed in Escherichiacoli, and the resultant recombinant protein was purified. We theninvestigated some biochemical properties of the recombinant annexinbased on the current understanding of plant annexins. An "add-backexperiment" was performed to study the effect of the recombinantannexin on $beta$ -glucan synthase activity, but no effect was found.However, it was found that the recombinant annexin could displayATPase/GTPase activities. The recombinant annexin showed muchhigher GTPase than ATPase activity. Mg²⁺ was essential for these activities, whereas a high concentrationof Ca²⁺ was inhibitory. A photolabeling assay showed that this annexincould bind GTP more specifically than ATP. The GTP-binding siteon the annexin was mapped into the carboxyl-terminal fourth repeatof annexin from the photolabeling experiment using domain-deletionmutants of this annexin. Northern-blot analysis showed that theannexin gene was highly expressed in the elongation stages ofcotton fiber differentiation, suggesting a role of this annexinin cell elongation.

INTRODUCTION

Top
Abstract
Introduction
Methods
Results
Discussion
References

Annexins constitute a family of at least 13 structurally related proteins in mammals that interact with phospholipid membranesin a Ca²⁺-dependent manner. These proteins contain four or eight characteristicstructural repeats consisting of 70 to 75 amino acids each, includingthe 17-amino acid "endonexin motif" or "consensus sequence" (seeRaynal and Pollard, 1994). Annexins have diverse biological functionsrelated to their Ca²⁺- and phospholipid-binding properties. In plants the first annexin-likeproteins were identified from tomato (Boustead et al., 1989).Since then, relatively abundant annexins have been identifiedand isolated from a number of plants (Smallwood et al., 1990;Blackbourn et al., 1992; Clark et al., 1992; Andrawis et al.,1993). Although the general functions of plant annexins are stillin question (for review, see Clark and Roux, 1995; Delmer andPotikha, 1997), recent isolation of partial or complete annexincDNA clones from higher plants, including monocots (Battey etal., 1996) and dicots (Pirck et al., 1994; Gidrol et al., 1996;Proust et al., 1996; Potikha and Delmer, 1997), provides someinsight into the structural characteristics of plant annexins.The endonexin repeats found in animal annexins are also observedin plant annexins; however, it seems that plant annexins containfewer predicted Ca²⁺-binding sites than animal annexins (see Clark and Roux, 1995).

Progress has been made recently in understanding the biochemical properties of plant annexins. Most importantly, some plantannexins have been found to be associated with enzyme activities.Maize annexins were first found to be associated with ATPase activity(McClung et al., 1994). It was later found that tomato annexinscould display a similar ATPase activity that was inhibited byphospholipid binding (Calvert et al., 1996). These observationsindicate that annexins may be involved in the energy-dependentcellular processes in plant cells. Recently, an annexin from Arabidopsiswas found to possess a peroxidase-like activity (Gidrol et al.,1996). Because peroxidase is known to be involved in plant-defensemechanisms during the oxidative burst (see Lamb and Dixon, 1997),it would be interesting to determine whether the peroxidase-likeannexins really function in plant-defense mechanisms associatedwith the oxidative burst. Taken together, these discoveries suggestthat plant annexins are multifunctional and play a role in a varietyof cellular processes, as is the case for mammalian annexins (Raynaland Pollard, 1994).

In cotton (Gossypium hirsutum) fibers, annexins were first identified by Andrawis et al. (1993) during $beta$ -glucan synthase purification,and these authors suggested that these proteins might be responsiblefor inhibition of $beta$ -glucan synthase activity. We also isolatedannexins associated with $beta$ -glucan synthase activity from cottonfiber membranes (Shin et al., 1995). In this report we demonstratethat cotton fibers contain the so-called "annexin doublet" withapparent molecular masses of 35 and 35.5 kD that is similar toother plants (see Clark and Roux, 1995), whereas the cotton annexinsreported by Andrawis et al. (1993) were identified as a singleband at 34 kD on SDS-PAGE. We also report the cloning of a cDNAencoding the 35.5-kD annexin from a cotton fiber cDNA library,which allowed us to express the cotton annexin cDNA in Escherichiacoli. Here we show some biochemical properties of the resultantrecombinant annexin purified from E. coli in relation to the currentunderstanding of plant annexins. Our present study focused onthe GTPase activity displayed by the recombinant annexin.

	MATERIALS AND METHODS

Top Abstract Introduction Methods Results Discussion References

Materials

Cotton (Gossypium hirsutum cv Texas marker 1) fibers at different stages of development after anthesis were removed from thelocules and immersed in liquid nitrogen as described previously(Okuda et al., 1993

). Unless indicated otherwise, all chemicalsfor the preparation and assay of $beta$ -glucan synthases were purchasedfrom the sources described previously (Okuda et al., 1993

; Kudlickaet al., 1995

). A PCR kit with Taq polymerase was purchased fromGIBCO-BRL. A TA cloning kit was from Invitrogen (San Diego, CA).The expression vector pET21a(+), Escherichia coli BL21 (DE3),and His-bind resin/buffer kit for His-tag chromatography werefrom Novagen (Madison, WI).

$beta$ -Glucan Synthase Preparations

The PME fraction from cotton fibers was prepared as described previously (Okuda et al., 1993

; Kudlicka et al., 1995

). Cottonfibers ground to a fine powder in liquid nitrogen were extractedwith cold buffer consisting of 50 mM Mops, pH 7.5, 5 mM EDTA,0.25 M Suc, and a combination of protease inhibitors (0.5 mM PMSF,10 µM leupeptin, 0.1 mM N- $alpha$ -p-tosyl-L-Lys chloromethyl ketone,and 0.1 mM L-1-tosylamide-2-phenyl-ethyl chloromethyl ketone).The extract was filtered through a 210-µm Spectra mesh screen(Spectrum Medical Industries, Houston, TX) to remove cell wallsand then was centrifuged at 8,000g for 10 min over a 60% Suc cushion.The PME fraction was collected at the buffer-Suc interface, resuspendedin a 1:5 dilution of extraction buffer, and recentrifuged at 100,000gfor 30 min. The membrane pellet was resuspended in a small volumeof resuspension buffer consisting of 50 mM Mops, pH 7.5, and 0.25M Suc.

The fractions of digitonin-solubilized enzymes (SE1 and SE2) were obtained from the PME fraction as described previously (Kudlickaet al., 1995). The PME fraction was mixed with an equal volumeof the first solubilization buffer containing 50 mM Mops, pH 7.5,0.25 M Suc, and 0.1% digitonin. The mixture was centrifuged overa 30% (w/v) glycerol cushion at 100,000g for 1 h at 4°C. The supernatantwas collected and denoted as SE1. The pellet was resuspended withthe second solubilization buffer containing 50 mM Mops, pH 7.5,0.25 M Suc, and 1% digitonin. The suspension was centrifuged at100,000g for 1 h at 4°C over 30% (w/v) glycerol, and the supernatantwas denoted as SE2. SE1 and SE2 were concentrated using Centriprep-10(Amicon, Beverly, MA) before use.

The membrane fraction precipitated in the second solubilization step was resuspended in 50 mM Mops, pH 7.5, and 0.25 M Sucand denoted as the pellet (P) fraction.

Protein assay for the different enzyme fractions was performed using a modification of the Lowry procedure (Markwell et al.,1978).

$beta$ -Glucan Synthase Assay

The assay mixture was composed of 8 mM MgCl₂, 1 mM CaCl₂, 20 mM cellobiose, 100 µM cylic 3 $'$ -5 $'$ -GMP, 0.5 mM UDP-[U-¹⁴C]Glc (specific activity, 12.5 mCi/mmol), 10 mM bis-Tris-propane-Hepesbuffer (pH 7.6), and approximately 40 µg of protein in a finalvolume of 200 µL. The reaction was conducted for 30 min at 25°Cand terminated by placing the reaction mixture in a boiling-waterbath for 1 min. The radioactive product was collected by filtrationon a GF/C glass filter (Whatman) and washed three times with distilledwater and once with methanol. The radioactivity on the filterwas dissolved in Ready Organic cocktail and counted with a liquidscintillation system (model LS 6800, Beckman).

Isolation of Annexins by Product Entrapment from Cotton Fibers

Annexins were isolated from the SE1 fraction by a modification of the product-entrapment procedure according to the methodof Kudlicka et al. (1995)

. The SE1 fraction was incubated in the $beta$ -glucan synthase assay mixture as described above, except that1 mM UDP-Glc was used as the substrate. After incubation at 25°Cfor 2 h, the reaction product was pelleted by centrifugation at6000g for 10 min. The pellet was resuspended in a small volumeof buffer (10 mM Mops, pH 7.5, and 0.25 M Suc) by vigorous vortexingand centrifuged again at 6000g for 10 min. Annexins of 35 and35.5 kD were highly enriched in the supernatant. The supernatantwas subjected to SDS-PAGE and the proteins were visualized withCoomassie blue R-250 staining.

Protein Sequencing

The Coomassie blue-stained 35- and 35.5-kD bands were excised from SDS-polyacrylamide gels and pooled. The gel slices wereincubated in neutralization buffer and subjected to enzyme digestionwith V-8 protease (P2922, Sigma) as described by Cleveland (1983)

.The resulting peptides were separated by electrophoresis on a16% SDS-polyacrylamide gel and blotted onto PVDF membranes accordingto the method of Matsudaira (1987)

. Automated N-terminal sequencingof the PVDF-blotted peptides was performed on a sequencer (model477A, Applied Biosystems) at the Protein Sequencing Laboratoryat the University of Texas, Austin.

Cloning of an Annexin cDNA

The complete cDNA was obtained in two steps using the peptide-sequence information obtained by protein sequencing. In thefirst step, a partial cDNA fragment encoding the C terminus ofthe 35.5-kD annexin was synthesized by PCR using a cotton fibercDNA library constructed in the Uni-ZAP XR vector (Stratagene).This library (provided by Xiaojiang Cui, University of Texas atAustin) was constructed using mRNAs obtained from cotton fibers14 d after anthesis. For PCR a 24-mer degenerate oligonucleotidedesigned from the partial amino acid sequence KAYSDDDV of the35.5-kD annexin was used as a 5 $'$ upstream primer, and a poly(dT)_12-18oligonucleotide was used as a 3 $'$ downstream primer. The PCR productwas subcloned into the pCRII vector using a TA-cloning system,and the nucleotide sequence was determined by DNA sequencing.A second PCR was then performed with a new set of primers on thesame cDNA library to obtain a full-length cDNA. An SK sequenceflanking the 5 $'$ ends of cDNA inserts in the Uni-ZAP cDNA libraryvector was synthesized as a 5 $'$ upstream primer, and a 21-mer antisenseoligonucleotide from the 3 $'$ untranslated region of annexin cDNAwas synthesized as a 3 $'$ downstream primer. The amplified productwas ligated into the pCRII vector using a TA-cloning system, andit was used to transform E. coli XL1 Blue. The identity of theannexin clone (pCRII-Ann) was verified by DNA sequencing.

Amplification of Annexin cDNAs for Expression Cloning

The plasmid (pCRII-Ann) containing the full-length annexin cDNA was used as a template for PCR to amplify cDNAs encoding afull-length and seven domain-deletion mutants of cotton annexin.Eight primers (1F, 2F, 3F, 4F, 1R, 2R, 3R, and 4R) were synthesizedfor PCR, where the numbers indicate the identity of annexin domainsand the letters F and R indicate the site and the orientationof primers on each annexin domain, respectively (see Fig. 5).For example, 1F is a forward 5 $'$ primer corresponding to the N-terminalsite of annexin domain 1, and 1R is a reverse 3 $'$ primer correspondingto the C-terminal site of annexin domain 1. All forward primersincorporated an NdeI restriction site at the 5 $'$ ends of the DNAs,and all reverse primers incorporated an XhoI restriction siteat the 3 $'$ ends of the DNAs. A total of eight amplified productswere obtained from PCR performed with eight combinations of forwardand reverse primers. These products were designated 1F4R, 1F3R,1F2R, 1F1R, 2F4R, 2F3R, 3F4R, and 4F4R by the combination of primersused in the PCR.

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Figure 5. Strategy for the construction of domain-deletion mutants of cotton annexin. The four annexin repeat domains are designated inside of the boxes. The numbers below the boxes indicate the first and last numbers of amino acid residues of the cotton annexin expressed by the constructs. The hatched boxes represent the 6xHis tags at the C-terminal ends of recombinant proteins. The eight PCR primers synthesized for mutant construction are designated 1F, 2F, 3F, 4F, 1R, 2R, 3R, and 4R above the arrows that show the sites and orientations of these primers.

Expression and Purification of Recombinant Annexin Proteins

The eight amplified products (1F4R, 1F3R, 1F2R, 1F1R, 2F4R, 2F3R, 3F4R, and 4F4R) were subcloned into the NdeI and XhoI sitesof pET21a(+), which were used to transform E. coli XL1 Blue. Ampicillin-resistantcolonies were used to isolate plasmids, the identities of whichwere verified by DNA sequencing. The sequence-verified plasmidswere used to transform E. coli BL21 (DE3), and the positive transformantswere cultured overnight at 37°C in 4 mL of Luria-Bertani mediumincluding 100 µg/mL ampicillin. These precultures were used toinoculate 200 mL of Luria-Bertani-ampicillin medium, and cellswere grown for approximately 2 h at 37°C until the A₆₀₀ of culturesreached approximately 0.6. Protein expression was then inducedby the addition of isopropyl 1-thiol- $beta$ -D-galactopyranoside toa final concentration of 1 mM and incubation was continued for3 h. The cells were collected by centrifugation at 5000g for 5min.

Because all of the recombinant constructs were designed to express proteins with a fusion of six His residues at their C termini,the purification of expressed proteins from the collected cellswas performed by the protocol provided with His-bind resin anda buffer kit for His-tag chromatography from Novagen. The His-taggedrecombinant proteins eluted from the His-tag column were dialyzedfor 24 h at 4°C against 25 mM Mops buffer, pH 7.0, using Slide-A-Lyzerdialysis kits (Pierce). Protein concentrations were determinedby the Lowry assay with BSA as a standard and confirmed by SDS-PAGEwith Coomassie blue staining. All eight recombinant annexin proteinswere purified and designated Ann1F4R(1-316), Ann1F3R(1-241), Ann1F2R(1-163),Ann1F1R(1-82), Ann2F4R(76-316), Ann2F3R(76-241), Ann3F4R(157-316),and Ann4F4R(235-316), where the numbering system indicates theamino acid residues of cotton annexin that are included in therecombinant protein (see Fig. 5).

$beta$ -Glucan Synthase Assay with Recombinant Annexin

Various amounts of the affinity-purified recombinant annexin were added to the $beta$ -glucan synthase assays performed with differentenzyme fractions. The assay for $beta$ -glucan synthase was performedas described above.

Antibody Production and Western-Blot Analysis

The full length of a recombinant annexin (Ann1F4R) purified as described above was sent to HTI Bio-Products, Inc. (Ramona,CA) to raise polyclonal antisera in rabbits.

For western-blot analysis, 30 µg of total protein per lane was separated on a 10% SDS-polyacrylamide gel, and the proteinswere transferred to nitrocellulose membranes (Schleicher & Schuell)by semidry electroblotting. After blocking overnight in PBS buffer(80 mM Na₂HPO₄, 20 mM NaH₂PO₄, 100 mM NaCl, pH 7.5, and 0.02%Tween 20) with 5% nonfat, dried milk (Carnation, Glendale, CA)at 4°C, the membrane was incubated with antiserum in PBS bufferat 1:250 dilution for 2 h. After the blot was washed in PBS bufferfour times, it was incubated with a horseradish peroxidase-conjugatedsecondary antibody at 1:1000 dilution for 1 h at room temperature.The protein complexes were detected by chemiluminescence (ECL,Amersham) according to the manufacturer's instructions.

GTPase and ATPase Assays

GTPase and ATPase activities were determined by the method of Ames (1996) with some modifications. The 200-µL reaction mixturescontaining 10 µg of purified recombinant annexin, 5 mM Mops buffer,pH 6.5, 50 mM KCl, 3 mM MgCl₂, and 3 mM GTP (or ATP) were incubatedat 37°C for 30 to 60 min. The reactions were terminated by theaddition of 0.6 mL of Ames reagent and allowed to stand for 30min at room temperature for the color development. A₈₂₀ was measuredagainst the blank buffer control containing no annexin protein.

Photoaffinity Labeling with [ $alpha$ -³²P]GTP

Purified annexin proteins were incubated with 5 µCi of [ $alpha$ -³²P]GTP in 20 mM Hepes, pH 7.6, 2 mM MgCl₂, and 0.1 mg/mL BSA, ina final volume of 100 µL, for 5 min at room temperature, thenplaced in an ice bath, and irradiated with UV light (254 nm) for20 min. For competition assays varying concentrations of ATP andGTP were added into this reaction mixture, which was incubatedand irradiated under the same conditions. After irradiation, proteinswere concentrated with methanol/chloroform extraction and mixedwith SDS-sample buffer for polyacrylamide gel analysis. Autoradiographsof gels were exposed for 2 to 5 d.

Northern Blotting

Total RNAs from different cotton tissues were isolated and quantitated by general protocol. For northern-blot analysis, totalRNAs (20 µg) from each tissue were electrophoresed in alkalineagarose gels and transferred to nylon membranes (Hybond-N, Amersham)according to the manufacturer's protocol. The probe was synthesizedby the Prime-a-Gene labeling kit (Promega) with [ $alpha$ -³²P]dCTP using full-length annexin cDNA (1149 bp) as the template.

	RESULTS

Top Abstract Introduction Methods Results Discussion References

Copurification of Annexins with $beta$ -Glucan Synthase

During the process of $beta$ -glucan synthase purification from cotton fibers 18 to 20 d after anthesis, we noticed that two polypeptideswith apparent molecular masses of 35 and 35.5 kD were highly enrichedby product-entrapment reaction from the low SE1 fraction. It isinteresting that increasing the Ca²⁺ concentration in the entrapment reactions increased the yieldof these two proteins along with that of $beta$ -glucan synthase activity(Fig. 1), indicating a Ca²⁺-dependent interaction of $beta$ -glucan synthase with these proteins.The identity of these two bands was investigated by sequencingthe 18- and 16-kD peptides generated from V-8 protease digestionof the 35- and 35.5-kD peptides, respectively. The partial aminoacid sequences obtained from the two peptides showed significanthomology with annexins (Fig. 1) from Arabidopsis (Gidrol et al.,1996

), maize (Battey et al., 1996

), and cotton fibers (Delmerand Potikha, 1997

). Our experiments demonstrate for the firsttime, to our knowledge, the presence of the so-called "annexindoublet" in the cotton fibers similar to those observed in otherplants (see Clark and Roux, 1995

). The cotton annexins reportedby Andrawis et al. (1993)

were observed as a single band at 34kD on SDS-PAGE.

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Figure 1. Copurification of annexins with $beta$ -glucan synthase from cotton fibers. A, Protein profiles of different enzyme fractions on an SDS-PAGE gel stained with Coomassie blue. Lane 1, SE1, 15 µg/lane. Lanes 2, 3, 4, and 5, Proteins released from product entrapment of the SE1 fraction that was performed with different Ca²⁺ concentrations of 0, 1, 2, and 4 mM, respectively. B, $beta$ -Glucan synthase assay for the fractions in A. $beta$ -Glucan synthase activity is represented as units, where 1 unit = 1 nmol Glc incorporated min¹. C, Partial amino acid sequences obtained from the 35- and 35.5-kD bands are aligned with homologous regions in annexins from maize (35 kD; Battey et al., 1996

), Arabidopsis (A. thaliana; Gidrol et al., 1996

), and cotton fibers (AnnGh1 and AnnGh2; Delmer and Potikha, 1997

Cloning of an Annexin cDNA Encoding the Cotton 35.5-kD Polypeptide

Because the 35.5-kD polypeptide was always more abundant than the 35-kD polypeptide in our purification, an attempt was madeto isolate a cDNA clone encoding the 35.5-kD polypeptide. Fromtwo rounds of PCR, we obtained a full-length cDNA clone (1149bp) for the 35.5-kD annexin (accession no. U89609). The completeopen reading frame encodes a protein of 316 amino acids, and itsdeduced molecular mass and pI are 36 kD and 6.62, respectively.The deduced amino acid sequence showed good homology to annexins,and the sequence could be divided into four repeat domains basedon the alignment with other plant annexins (Fig. 2). All plantannexins have the type-II Ca²⁺-binding site in the first repeat (Clark and Roux, 1995

). The35.5-kD cotton annexin also has the predicted type-II Ca²⁺-binding site in the first repeat, which is defined as a Gly-X-Gly-Thrloop with an acidic Asp or Glu residue 42 amino acids downstreamof the first Gly (Chen et al., 1993

). There is another type-II-likeconserved sequence in repeat 4 of the cotton annexin, in whichthe first Gly is substituted with an Arg residue. A search ofthe PROSITE database (www.expasy.ch, Swiss Institute of Bioinformatics,Geneva, Switzerland) for motifs revealed that there are many potentialposttranslational modification sites in the deduced cotton annexinsequence (Fig. 2). It was found that there are a total of 16 potentialphosphorylation sites in the deduced annexin sequence, including4 protein kinase C phosphorylation sites, 8 casein kinase II phosphorylationsites, 1 Tyr kinase phosphorylation site, and 3 cAMP-dependentprotein kinase phosphorylation sites. The potential protein kinaseC sites are located in the repeat domains 2 and 3 of the cottonannexin, whereas no potential protein kinase C site is found atthe N- and C-terminal domains of the cotton annexin (Fig. 2).In maize the PROSITE search with p33 and p35 annexins revealeda potential protein kinase C phosphorylation site at the mostN-terminal Thr residue in p33 annexin (Battey et al., 1996

). Otherpotential modification sites include one N-glycosylation siteand three N-myristoylation sites.

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Figure 2. A, The deduced amino acid sequence of a 35.5-kD cotton annexin cDNA. Potential posttranslational modification sites on the deduced sequence are emphasized as follows: Uppercase, underlined letters, N-myristoylation sites; lowercase, underlined letters, N-glycosylation site; boldface, uppercase letters, cAMP-dependent kinase phosphorylation sites; and boldface, lowercase letters, protein kinase C phosphorylation sites. B, Alignment of annexin repeat domains from cotton (Cot), Arabidopsis (Ara) (Gidrol et al., 1996

), and maize (Zea) (Battey et al., 1996

). Annexin repeat domains 1 to 4 from Arabidopsis, cotton, and maize are designated Ara1-4, Cot1-4, and Zea1-4, respectively. Underlined are amino acid residues conserved in the type-II Ca²⁺-binding site. The 17-amino acid annexin "endonexin fold" or "consensus sequence" is shown above the alignment, in which h = hydrophobic residue, P = polar residue, and x = variable residue. The 12 domains were aligned by the ClustalW1.7 program, which is available as an Internet service provided by the Human Genome Center at Baylor College of Medicine (Houston, TX).

Recently, two cDNA sequences encoding cotton fiber annexins, designated AnnGh1 and AnnGh2, were reported (Potikha and Delmer,1997). Our annexin amino acid sequence deduced from cDNA showed95% identity with AnnGh1 protein and 65% identity with AnnGh2protein, indicating that AnnGh1 from cotton cv Acala SJ-2 correspondsto our annexin.

Recombinant Annexin and $beta$ -Glucan Synthase Activity

A purified recombinant annexin was prepared after expression of the cotton annexin cDNA in E. coli (Fig. 3), and it was usedin an "add-back experiment" to observe the effect of annexin on $beta$ -glucan synthase activity (Table I). As summarized in TableI, no effect on $beta$ -glucan synthase activity was noted after additionof the recombinant annexin. In this experiment different enzymefractions were used to avoid the possibility of endogenous annexinsinterfering with the assay.

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Figure 3. Purification of recombinant cotton annexin. The cotton annexin cDNA was expressed in E. coli BL21 (DE3) as His-tagged protein and purified by affinity chromatography as described previously. Proteins were separated by 10% SDS-PAGE and stained with Coomassie blue. Lane 1, Crude extract from uninduced cell; lane 2, crude extract from isopropyl 1-thiol- $beta$ -D-galactopyranoside-induced cell; lane 3, soluble fraction obtained from lane 2 fraction; lane 4, washed-out fraction from His-tag chromatography; and lane 5, eluted fraction from His-tag chromatography. Note the highly purified annexin band in lane 5 with an apparent molecular mass of 36 kD.

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Table I. Influence of recombinant cotton annexin on $beta$ -glucan synthase activity

In each experiment, three separate reactions were carried out with individual enzyme fractions by using 1, 5, and 10 µg of purified recombinant annexin. The same experiment was repeated three times to obtain SD values. 1 unit = 1 nmol Glc incorporated min¹. SE1, The first solubilized fraction with 0.05% digitonin; SE2, the second solubilized fraction with 1% digitonin; P, the pellet fraction that remained after solubilization.

Western-Blot Analysis of $beta$ -Glucan Synthase Fractions

To investigate whether the endogenous annexins were depleted from the $beta$ -glucan synthase fractions used in the add-back experiment,we performed western-blot analysis with a polyclonal antibodyraised against the 35.5-kD recombinant annexin. As shown in Figure4, the 35.5-kD annexin was present in the PME and the SE1 fractions,but was almost completely depleted in the SE2 fraction and wascompletely absent in the solubilization-resistant P fraction.

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Figure 4. Immunoblot analysis of different $beta$ -glucan synthase fractions prepared from cotton fibers. The proteins of different enzyme fractions (PME, SE1, SE2, and P) were separated on a 10% SDS-PAGE gel and transferred to a nitrocellulose membrane. The proteins were probed with polyclonal annexin antiserum diluted in PBS buffer (1:250 dilution). Lanes 1 to 4, PME, SE1, SE2, and P, respectively.

We found that a 42-kD polypeptide in the SE1 fraction appeared to interact with the antibody against the 35.5-kD annexin (Fig.4). Although we lack biochemical evidence for the identity ofthis 42-kD band, it is possible that this 42-kD protein may bea new annexin in cotton fibers. So far, a vacuole-associated annexinfrom tobacco cells (Seals et al., 1994) has been identified asthe only 42-kD annexin from plants.

Recombinant Annexin Displays GTPase Activity

Recently, annexins prepared from maize (McClung et al., 1994

) and tomato (Calvert et al., 1996

) tissues were found to exhibitATP/GTPase activity. These discoveries prompted us to determinewhether our recombinant annexin possessed such activity. As summarizedin Table II, the full-length (Ann1F4R) recombinant cotton annexindisplayed an enzyme activity for the hydrolysis of ATP and GTP.Significantly, it was found that GTPase activity was much greaterthan ATPase activity, indicating that GTP is the preferred substrateover ATP for cotton annexin activity. The specific activity ofGTPase by cotton annexin was about 400 nmol Pi mg¹ h¹, which is almost 10 times greater than that of ATPase (42 nmolPi mg¹ h¹). For the controls, four domain-deletion mutants of annexin wereassayed for their ATPase/GTPase activity. We found no significantactivity from either N-terminal (Ann2F4R and Ann3F4R) or C-terminaldeletion mutants (Ann1F3R and Ann1F2R) (see also Fig. 5 ). Thisresult clearly disproves the possibility that the ATPase/GTPaseactivity displayed by a whole recombinant annexin may be fromE. coli contamination during purification. In addition, boilingabolished the ATPase/GTPase activity from the recombinant annexin,indicating that the annexin activity is conformation dependent.

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Table II. Recombinant annexin and ATPase/GTPase activity

ATPase and GTPase assays were performed at pH 6.5, with 10 µg of purified recombinant annexin proteins and 3 mM MgCl₂ in the presence of 3 mM ATP or GTP. At least three replicates were carried out for each assay to obtain SD values.

To determine whether Ca²⁺ and/or Mg²⁺ can affect the annexin GTPase activity, varying concentrations of both cations were addedduring the enzyme assays. It was shown that Mg²⁺ was essential for the annexin GTPase activity and that a highconcentration of Ca²⁺ was inhibitory to the activity (Fig. 6). Addition of less than1.5 mM Mg²⁺ increased the GTPase activity of annexin, but more than 1.5 mMMg²⁺ did not affect the activity. Addition of less than 3 mM Ca²⁺ decreased the GTPase activity in an inverse manner, but morethan 3 mM Ca²⁺ did not further inhibit the GTPase activity. The maximum inhibitionlevel of GTPase activity by Ca²⁺ was about 60% of the full activity.

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Figure 6. Effects of Ca²⁺ and Mg²⁺ ions on the annexin GTPase activity. The assay was performed according to the method of Ames as described previously. One-hundred percent GTPase activity represents 400 nmol Pi mg¹ h¹. A, Effect of Mg²⁺ concentrations in the absence of Ca²⁺. B, Effect of Ca²⁺ concentrations in the presence of Mg²⁺ at 3 mM.

A photoaffinity-labeling experiment was performed with [ $alpha$ -³²P]GTP to determine the substrate preference of cotton annexin GTPase/ATPaseactivity (Fig. 7). As shown in Figure 7, the photolabeling ofannexin with [ $alpha$ -³²P]GTP was more sensitive to the presence of unlabeled GTP thanto unlabeled ATP in the reaction mixture, indicating a greaterbinding specificity of annexin to GTP than to ATP. Quantitatively,at least 100 µM unlabeled ATP was required to completely inhibitthe labeling, whereas 50 µM unlabeled GTP could achieve completeinhibition.

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Figure 7. Competition analysis of photoaffinity labeling. The whole recombinant cotton annexin was incubated with [ $alpha$ -³²P]GTP for 10 min under UV irradiation in the presence of unlabeled GTP or ATP at variable concentrations. The protein was extracted and subjected to 10% SDS-PAGE. Top, Autoradiograph of a photolabeled SDS gel. Lanes 1 to 4, Competition of photolabeling by adding unlabeled GTP to a final concentration of 10, 20, 50, and 100 µM, respectively; lanes 5 to 8, competition of photolabeling by adding unlabeled ATP to a final concentration of 10, 20, 50, and 100 µM, respectively. Bottom, Coomassie blue staining of the same gel.

Mapping of the GTP-Binding Site on Annexin

Because the predicted amino acid sequence of the 35.5-kD cotton annexin lacked a common motif for nucleotide binding suchas a Walker-type nucleotide-binding site (Walker et al., 1982

),we decided to determine the GTP-binding site on cotton annexin.Domain-deletion mutants of annexin were constructed, expressed,and purified from E. coli as described in "Materials and Methods,"and the mutant proteins were designated Ann1F1R, Ann1F2R, Ann1F3R,Ann1F4R, Ann2F3R, Ann2F4R, Ann3F4R, and Ann4F4R (Fig. 5). Allmutant proteins migrated at their predicted molecular mass onSDS-PAGE (Fig. 8). Photoaffinity labeling with [ $alpha$ -³²P]GTP was performed to determine the GTP-binding ability of eachof the deletion mutants. BSA was included in all of the reactionsas the internal control. As shown in Figure 8, three annexin mutants,Ann2F4R, Ann3F4R, and Ann4F4R, all including the C-terminal fourthdomain of annexin, were labeled with [ $alpha$ -³²P]GTP, whereas any mutant missing the C-terminal domain was notlabeled. Therefore, the result of this experiment clearly suggeststhat the GTP-binding site on annexin is located in the C-terminalregion of the protein.

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Figure 8. Mapping of the GTP-binding site on annexin by photolabeling experiment. Recombinant annexin proteins were incubated with [ $alpha$ -³²P]GTP for 10 min under UV irradiation, and the proteins were extracted and subjected to 10% SDS-PAGE. A, SDS-polyacrylamide gel stained with Coomassie blue. Lanes 1 to 8, Purified recombinant annexin proteins of Ann1F1R, Ann1F2R, Ann1F3R, Ann1F4R, Ann2F4R, Ann3F4R, Ann4F4R, and Ann2F3R, respectively. BSA was added to the reactions as the internal control. B, Autoradiograph of the same gel. Note that any annexin mutant missing the C-terminal domain 4 was not labeled.

Cotton Annexin Gene Expression

To understand the physiological significance of our data, we performed a northern-blot analysis using a probe generated fromthe full-length cotton annexin cDNA. High levels of annexin transcriptat 1.2 kb were detected in roots, flowers, and fibers, whereasalmost none was detected in leaves (Fig. 9). In cotton fibersthe expression of the annexin gene was high during the early primarystage of development, and it gradually decreased as fibers enteredthe secondary stage. The expression was very low during the secondarystage beyond 24 d after anthesis. These results suggest that theexpression of the annexin gene is regulated temporally and spatiallyin cotton tissues.

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Figure 9. Northern-blot analysis of the annexin gene expression in cotton. Radioactive probe was generated from the full length of cotton annexin cDNA. Note that the expression of annexin gradually decreases as cotton fibers develop into the secondary stage. Annexin is highly expressed in flower and root tissues, but not in leaves (Leaf). Total RNA was quantitated by spectrophotometry, and equal loading (20 µg/lane) was confirmed by ethidium bromide staining.

	DISCUSSION

Top Abstract Introduction Methods Results Discussion References

Annexins and $beta$ -Glucan Synthase Activity

In cotton fibers annexins were first identified by Andrawis et al. (1993)

as the proteins that may be responsible for inhibitionof $beta$ -glucan synthase activity. Andrawis et al. (1993)

also suggestedthat the interaction between annexins and $beta$ -glucan synthase isCa²⁺ dependent. Our data in Figure 1 show an essential role of Ca²⁺ in the successful entrapment of $beta$ -glucan synthase with annexins,in accordance with the results of Andrawis et al. (1993)

. Thedata in Figure 1 appear to show a positive correlation betweenthe amount of entrapped annexins and the activity of $beta$ -glucansynthase.

In our experiment for the $beta$ -glucan synthase assay with a recombinant annexin (Table I), we provide clear evidence that the35.5-kD recombinant annexin has no effect on the $beta$ -glucan synthaseactivity. In addition, the endogenous 35.5-kD annexins are notthought to have interfered with our assay, because they were virtuallynot present in the SE2 and P fractions as shown by western-blotanalysis (Fig. 4). However, it may be premature to conclude thatannexins are not responsible for inhibition of $beta$ -glucan synthaseactivity because (a) we lack the data with all of the differentannexins (Potikha and Delmer, 1997) and (b) posttranslationalmodifications may be required for the functions of endogenousannexins.

Recombinant Annexin and GTPase Activity

The PROSITE analysis shows that the deduced amino acid sequence of the 35.5-kD cotton annexin cDNA contains a variety of potentialphosphorylation sites (Fig. 2), suggesting that phosphorylationmay determine the specific function of this annexin in cottonfibers. However, it remains to be determined whether these potentialsites are actually phosphorylated and whether phosphorylationaffects the biochemical properties of this annexin in vitro.

We have demonstrated that a cotton annexin can display enzyme activities for the hydrolysis of ATP and GTP. This result isimportant because this is the first evidence, to our knowledge,of ATPase/GTPase activities obtained from a recombinant plantannexin. The tomato annexins (p34 and p35) that were recentlydemonstrated by Calvert et al. (1996) to have similar activitieswere directly purified from tomato tissues. Therefore, using ahighly purified recombinant protein, we provided evidence thatplant annexins can possess inherent ATPase/GTPase activities.Most important, we noted that several biochemical characteristicsof cotton annexin activities are different from those of tomatoannexins. First, most significantly, the substrate preferencefor GTP over ATP by cotton annexin was surprisingly high. Cottonannexin showed GTPase activity almost 10 times greater than ATPaseactivity (Table II). The substrate preference for GTP over ATPby cotton annexin was further demonstrated by competition photolabelingassay (Fig. 7). In tomato, annexins displayed ATPase activityalmost equal to GTPase activity. Second, whereas the tomato annexinsdid not require Mg²⁺ for the activity, it was essential for the cotton activity (Fig.6). Third, although it was not shown clearly in the tomato annexinswhether only Ca²⁺ can inhibit the tomato annexin activity, our results demonstratethat cotton annexin activity can be inhibited only by Ca²⁺ (Fig. 6). It was also shown that a correct conformation of theannexin protein is necessary for the activity, because boilingthe protein could destroy the activities.

Although a color assay modified from the Ames method (McClung et al., 1994) was used as the major GTPase assay, the GTPaseactivity of the recombinant cotton annexin was confirmed by usinga radioactive assay (de Boer et al., 1991) that resulted in theformation of ³²Pi from [ $gamma$ -³²P]GTP and that was determined by scintillation counting (datanot shown here).

We demonstrated that the GTP binding to cotton annexin occurs in a sequence-specific manner. From photoaffinity-labeling experimentsusing domain-deletion mutants of cotton annexin, it was evidentthat the GTP-binding site is present in the C-terminal domain4 of cotton annexin (Fig. 8). To our knowledge, this is the firstevidence showing the importance of the C-terminal domain in thefunctions of plant annexins.

Potential Functions of Annexin in Cotton Fibers

We demonstrated by northern-blot analysis that the expression of the cotton annexin gene is regulated temporally and spatially(Fig. 9). Notably, cotton annexin was highly expressed duringthe early primary stages of cotton fiber development. During theseearly stages in cotton fiber differentiation, cotton fibers growand elongate rapidly by forming the central vacuole, plasma membrane,and primary cell wall (Ramsey and Berlin, 1976

). According toRyser (1979)

, dictyosome-associated coated vesicles are especiallynumerous during the fiber-elongation stages, whereas they arenot conspicuous in the secondary stages of cotton fibers. Takentogether, it is tempting to suggest that annexins may be associatedwith dictyosome-derived coated vesicles participating in the elongationof cotton fibers.

Recently, Seals and Randall (1997) showed that a vacuole-associated annexin, VCaB42, was related to the expansion of tobaccocells. Other plant annexins that may have a similar role in cellexpansion are maize annexins that are strongly transcribed inthe cell-elongation region of root tips (Battey et al., 1996).Although the expansion of tobacco cells was suggested to occurby the vacuolation process in which annexins may play a certainrole (Seals and Randall, 1997), the exact role of annexins inthese cell-expansion processes is still unknown.

More recently, Carroll et al. (1998) provided evidence that annexins modulate exocytosis in maize root-cap cells. This isthe only direct evidence that suggests that plant annexins mayregulate exocytosis, because so far only circumstantial evidencehas been obtained from several studies with plant annexins (seeClark and Roux, 1995). Significantly, exocytosis from maize root-capcells was also shown to be modulated by Ca²⁺ and GTP (Carroll et al., 1998). In this context, our data thatcotton annexins possess GTPase activity inhibited by Ca²⁺ could provide some insights into the potential role of annexinsin the exocytotic process.

	FOOTNOTES

¹ This work was supported in part by grant no. DE-FG03-94ER20145 from the Division of Energy Biosciences, Department of Energy,and funds from the Johnson & Johnson Centennial Chair to R.M.B.
^* Corresponding author; e-mail rmbrown{at}mail.utexas.edu; fax 1-512-471-3573.

Received July 24, 1998; accepted November 25, 1998.

ABBREVIATIONS

Abbreviation: PME, plasma membrane-enriched.

	ACKNOWLEDGMENTS

We are grateful to Mr. Xiaojiang Cui, who kindly provided the cotton fiber RNAs and the cotton fiber cDNA library used inthis research. H.S. is especially grateful to the Department ofKorean Education for the award of a fellowship. We also thankDr. Stanley J. Roux, Dr. Inder Saxena, and Richard Santos forcritically reading the manuscript.

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GTPase Activity and Biochemical Characterization of a Recombinant Cotton Fiber Annexin1

Copyright Clearance Center: 0032-0889/99/119//10 © 1999 American Society of Plant Physiologists

GTPase Activity and Biochemical Characterization of a Recombinant Cotton Fiber Annexin¹

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© 1999 American Society of Plant Physiologists