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Vol. 18, Issue 9, 3620-3634, September 2007
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*Department of Molecular, Microbial, and Structural Biology, University of Connecticut Health Center, Farmington, CT 06030; and Kobe Advanced ICT Research Center, National Institute of Information and Communications Technology, 588-2 Iwaoka, Nishi-ku, Kobe 651-2492, Japan
Submitted October 13, 2006;
Revised July 3, 2007;
Accepted July 5, 2007
Monitoring Editor: Erika Holzbaur
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ABSTRACT |
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 TOP ABSTRACT INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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and 
heavy chains (HCs). The HC–associated LC4 light chain is a member of the calmodulin family and binds 1-2 Ca2+ with KCa = 3 x 10–5 M in vitro, suggesting it may act as a Ca2+ sensor for outer arm dynein. Here we investigate interactions between the LC4 light chain and HC. Two IQ consensus motifs for binding calmodulin-like proteins are located within the stem domain of the heavy chain. In vitro experiments indicate that LC4 undergoes a Ca2+-dependent interaction with the IQ motif domain while remaining tethered to the HC. LC4 also moves into close proximity of the intermediate chain IC1 in the presence of Ca2+. The sedimentation profile of the HC subunit changed subtly upon Ca2+ addition, suggesting that the entire complex had become more compact, and electron microscopy of the isolated subunit revealed a distinct alteration in conformation of the N-terminal stem in response to Ca2+ addition. We propose that Ca2+-dependent conformational change of LC4 has a direct effect on the stem domain of the HC, which eventually leads to alterations in mechanochemical interactions between microtubules and the motor domain(s) of the outer dynein arm. |
INTRODUCTION |
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TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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; King, 2000; Samso and Koonce, 2004). The ATP-sensitive microtubule-binding site is located at the tip of a coiled-coil stalk protruding from between the AAA4 and AAA5 subdomains. In general, the region N-terminal of AAA1 is poorly conserved between the various axonemal and cytoplasmic dyneins and is involved in HC-HC interactions as well as association with various intermediate (ICs), light intermediate chains, and light chains (LCs) that may confer chain-specific regulatory and cargo attachment functions (for review see King, 2002).
To generate coordinated flagellar beating, dynein motor activity must be tightly controlled. Ca2+-regulated waveform alterations have been observed in the flagella of various cells including Paramecium (Naitoh and Kaneko, 1972), and sea urchin (Brokaw et al., 1974) and mammalian (Lindemann and Goltz, 1988) sperm. In demembranated and reactivated Chlamydomonas cell models, the cis- and trans- flagellar axonemes respond differentially to variations in Ca2+ concentration in the range pCa 8 to pCa 61 (Kamiya and Witman, 1984). Modulation of intraflagellar Ca2+ in the submicromolar range allows the cell to undergo phototaxis (directed movement toward or away from a light source), and mutant studies indicate that this control system requires the inner, but not outer, row of dynein arms (Kamiya and Okamoto, 1985; Mitchell and Rosenbaum, 1985). In addition, reactivated Chlamydomonas axonemes display an asymmetric beat pattern at Ca2+ concentrations below pCa 6, become quiescent at pCa 5, and then resume beating, but with a symmetric waveform at pCa 4 (Bessen et al., 1980). This waveform conversion provides the physiological basis for the photophobic (avoidance) response and either does not occur or is aberrant in strains lacking outer arms (Kamiya and Okamoto, 1985; Mitchell and Rosenbaum, 1985), suggesting that this motor is essential for flagellar reversal.
The Chlamydomonas outer arm contains three HCs (
, , and ) that have distinct assembly and enzymatic properties (Pfister et al., 1982; Pfister and Witman, 1984; Sakakibara et al., 1991, 1993). These motor units are associated with two WD-repeat intermediate chains (IC1 and IC2), at least 10 light chains (LCs), and a trimeric docking complex (DC) necessary for attachment of the arm to the appropriate axonemal location (Takada and Kamiya, 1994). We demonstrated previously that ATP-sensitive microtubule binding by an outer arm dynein subparticle containing only the and HCs can be maximally activated above pCa 6 (Sakato and King, 2003). This observation suggested that outer arm dynein function is regulated by Ca2+ binding directly to a component of the motor complex in vitro.
The purified Chlamydomonas outer arm contains two potential candidates for this putative Ca2+ regulatory subunit. The docking complex protein DC3 has two consensus EF hands and binds one Ca2+ with Kd = 1 x 10–5 M in a redox-sensitive manner; it also binds Mg2+ but with a much lower affinity (Casey et al., 2003a,b). However, a DC3-null mutant (oda14) rescued with a defective form of DC3 that cannot bind Ca2+ displays apparently normal photobehavior, suggesting that Ca2+-binding by this protein is not required for these responses (Casey et al., 2003a). The LC4 light chain, which directly associates with the HC, is also related to calmodulin and contains four helix-loop-helix motifs, two of which conform to the EF hand consensus for Ca2+-binding loops (Pfister et al., 1982; King and Patel-King, 1995). This LC binds 1-2 Ca2+ with KCa = 3 x 10–5 M in vitro; it does not bind Mg2+ (King and Patel-King, 1995). The phenotypic consequences due to a lack of LC4 are unknown, because no mutants defective for this protein currently exist. However, the direct association of LC4 with a HC makes it a promising candidate for an outer arm Ca2+ sensor. Here we focus on the detailed interactions between LC4 and the HC and explore the molecular mechanism by which conformational alterations involving LC4 might regulate dynein motor activity in response to Ca2+ binding.
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MATERIALS AND METHODS |
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TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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). Intact outer arm dynein ( HCs) and an - HC subparticle that lacks the HC motor unit were extracted from ida1 and oda4-s7 mutant strains, respectively. Dyneins were purified by sucrose density gradient centrifugation in the presence of Mg2+ and at low hydrostatic pressure as previously described (Takada et al., 1992; Sakato and King, 2003). To obtain and HC subparticles, sucrose was removed from purified intact outer arm dynein by ultrafiltration, and the sample was subjected to a second sucrose gradient centrifugation in the absence of Mg2+. Peak fractions containing each subparticle were pooled and kept at –75°C until use.
Coimmunoprecipitation of Preassembled Dynein Subunits from Cytoplasm
Cytoplasmic extract preparation and coimmunoprecipitation were performed by following the method of Fowkes and Mitchell (1998) with minor modifications including autolysin treatment (Qin et al., 2004). Chlamydomonas cells were grown to a density of 
1.0 x 106 cells/ml in 500 ml liquid medium, harvested, treated with autolysin, and resuspended in immunoprecipitation (IP) buffer (30 mM HEPES, pH 7.4, 5 mM MgSO4, 0.5 mM EDTA, 25 mM KCl, 1 mM dithiothreitol [DTT]) plus a 1/100x volume of protease inhibitor cocktail (P8849, Sigma, St. Louis, MO) to a total volume of 0.5 ml. The cell suspension was homogenized with an equal volume of acid-washed glass beads (diameter 1 mm) by vortexing for 1 min. The homogenate was clarified in a TLA100.2 rotor (Beckman, Fullerton, CA) at 33,000 rpm for 2 h at 4°C. The clarified cytoplasmic extract was supplemented with 75 mM NaCl and 0.05% Triton X-100 and incubated with CT240 antibody (generated in this study) or preimmune serum for 1 h at 4°C and for 1 more hour after the addition of 10 µl settled volume of ImmunoPure Immobilized protein G Plus beads (Pierce Biotechnology, Rockford, IL). The beads were washed three times with IP buffer containing 75 mM NaCl and 0.05% Triton X-100 and once with IP buffer only. The immunoprecipitates were eluted by adding 2x gel loading buffer (0.1 M Tris-Cl, pH 6.8, 0.2 M DTT, 4% SDS, 0.2% bromophenol blue, and 20% glycerol) and boiling. Twenty micrograms of cytoplasmic extracts and equal volumes of immunoprecipitates were analyzed by electrophoresis and immunoblotting.
Ca2+ Effects on HC Subparticle Sedimentation
The purified HC subparticle was fractionated in a 5–20% sucrose gradient in HME buffer (30 mM HEPES, pH 7.4, 5 mM MgSO4, 1 mM EGTA) containing 1 mM DTT and 1 mM phenylmethylsulfonyl fluoride either in the absence of Ca2+, or at pCa 5 or pCa 3, in a SW55 rotor (Beckman) at 30,000 rpm for 12 h at 4°C. Appropriate amounts of a CaCl2 stock solution were added to yield the desired Ca2+ concentration. Fifteen fractions of 350 µl were collected from each gradient. Recombinant LC4 protein (see below) was sedimented in parallel with the HC subparticle to confirm that this LC does not migrate at 12S in the absence of the HC. As additional controls, bovine brain tubulin (Cytoskeleton, Denver, CO), and the outer arm subunits were also sedimented in additional gradients. Equal volumes of each fraction were electrophoresed in 10% tricine SDS gels, 8% SDS gels, and 4% acrylamide 4 M urea gels and transferred to nitrocellulose for immunoblotting. Densitometric analysis was performed using ImageJ.
Preparation of Recombinant Proteins and Antibodies
Using the full-length HC cDNA2 (constructed by Dr. C. G. Wilkerson, Michigan State University.) as template, the following fragments of the HC stem domain were amplified with Pfu DNA polymerase (Stratagene, La Jolla, CA) and cloned into the pMAL-c2 vector (New England Biolabs, Ipswich, MA); residues 1-442, 1-754, 1-1089, 1-1486, 1432-1848, 338-754, 691-1089, 691-1486, 875-893, 875-1167, 875-1182, 890-1167, 890-1182, 1014-1486, and 1164-1182. This resulted in fusion of these regions to the C-terminus of maltose-binding protein (MBP) via a hydrophilic linker containing a Factor Xa cleavage site. Fragments 338-754, 691-1089, 1014-1486, and 691-1486 were either expressed very poorly or showed very limited solubility and could not be used further. The control MBP-LacZ protein derived from the original pMAL-c2 vector; the MBP-LC4 construct was described previously (King and Patel-King, 1995). To generate an N-terminal 10x His-tagged LC4 construct, full-length LC4 was amplified with Pfu DNA polymerase using the original LC4 cDNA (King and Patel-King, 1995) as template and cloned into the pET16b vector (Novagen, Madison, WI).
Recombinant proteins were overexpressed in Escherichia coli strains XL1-Blue (Stratagene) or BL21(DE3)pLysS (Novagen). MBP fusion proteins were purified by amylose affinity chromatography (New England Biolabs). His-tagged LC4 was purified using His-Bind Resin (Novagen). Recombinant LC4 was obtained by digesting MBP-LC4 with Factor Xa and separating the products by anion exchange chromatography using a HiTrap ANX FF column (Amersham Biosciences, Piscataway, NJ) on a Biologic chromatography workstation (Bio-Rad Laboratories, Hercules, CA).
The MBP-LC4 and MBP- HC stem domain N1 (residues 1-442) proteins were used as the immunogens to obtain rabbit polyclonal antibodies CT61 and CT240, respectively. Sera were blot-purified against the appropriate recombinant proteins lacking the MBP moiety before use; for some preparations of CT61 His-tagged LC4 was used. Other antibodies used include rabbit polyclonals against LC1 (R5932; Benashski et al., 1999), LC3 (R4930; Patel-King et al., 1996; Harrison et al., 2002), LC5 (R4929; Patel-King et al., 1996), and DC1 (Wakabayashi et al., 2001) and murine monoclonals DM1A (Sigma), 1878A, 18A, 18C, and 12B versus -tubulin, IC1, and the , , and HCs, respectively (King et al., 1985, 1986; King and Witman, 1988a; Wilkerson et al., 1994). Immunoblotting was performed as described previously (Harrison et al., 1998).
In Vitro Expression of 35S-labeled Proteins
To generate a LC4 construct for the binding assay, a PstI-XhoI fragment of the original LC4 cDNA was subcloned into pBluescript II KS+ (Stratagene) downstream of the T7 promoter and the SmaI and blunted BstBI sites were ligated to remove a part of the 5'-untranslated region (UTR) that contained additional out-of-frame ATG codons. For the chemical crosslinking experiment, a Kozak sequence was incorporated into the full-length and N-terminal–truncated versions of the LC4 construct to enhance translation initiation at the first AUG.
Radiolabeled LC4 proteins were synthesized using the TnT T7-coupled reticulocyte lysate system (Promega, Madison, WI). Each 50 µl reaction contained the amino acid mixture minus methionine and 20 µCi of EasyTag L-[35S]methionine (PerkinElmer Life Sciences, Boston, MA). Reactions were incubated for 1.5 h at 30°C, chilled on ice, and clarified by centrifugation. Supernatants were pooled and subsequently used for binding assays or chemical crosslinking experiments. In addition to full-length LC4, the translation products from the 
5'UTR LC4 construct included a series of N-terminal–truncated forms that derived from translation initiation at internal downstream Met residues.
In Vitro LC4- HC Binding Assay
MBP fusion proteins containing segments of the HC IQ motif region or LacZ were bound to a 100-µl settled volume of amylose beads in 100 µl of HMET (HME buffer plus 0.1% Tween 20) or HMECT (HMEC [HME buffer containing 1 mM Ca2+] and 0.1% Tween 20). The latter buffer was used to ensure that LC4 was fully saturated with Ca2+. Additional control samples containing no MBP fusion protein were processed in parallel. Beads were mixed with 2 µl of the 5'UTR LC4 in vitro translation reaction and incubated for 4 h at 4°C. Samples were washed five times with HMET or HMECT buffer, once with HME or HMEC buffer, and resuspended in 20 µl of 4x gel loading buffer. Samples were denatured for 30 min at 56°C, separated in 10–20% acrylamide tricine SDS gels, and stained with Coomassie blue. The 35S-labeled proteins were detected by autoradiography using Fuji super RX film (Tokyo, Japan).
LC4- HC Chemical Crosslinking
Five micrograms of MBP protein fused to the HC stem fragments, the LacZ control, or no protein, in 40 µl of HME or HMEC buffer containing 1 mM DTT and 10 mM maltose were preincubated with 5 µl of the full-length or N-terminal–truncated form of 35S-LC4 protein for 1 h on ice. Maltose was necessary for the solubility of the MBP- HC stem fragment fusion proteins. Crosslinking was initiated by the addition of 2 µl of 200 mM DMP in methanol (final concentration 10 mM), and samples were incubated for 1 h at room temperature; methanol without DMP was used as a control. After incubation, 20 µl of each sample was mixed with 5 µl of 5x gel loading buffer and denatured for 30 min at 56°C. Equal amounts of denatured samples were separated in 8% acrylamide SDS gels and stained with Coomassie blue, and 35S-labeled protein was detected by autoradiography.
Crosslinking of native dynein samples with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC), 1,5-difluoro-2,4-dinitrobenzene (DFDNB), dimethylpimelimidate (DMP), and disuccinimidyl suberate (DSS) and vanadate-mediated photolysis of native dynein HCs was performed as described previously (Benashski and King, 2000). All chemical crosslinking reagents used in this study were obtained from Pierce Biotechnology.
Immunoprecipitation of Crosslinked Products and Mass Spectrometry
Crosslinking of purified outer arm dynein was performed by the addition of 10 mM DMP or solvent only in the presence of 1 mM Ca2+ as described above. The reaction was quenched by 0.1 M Tris-Cl, pH7.4, denatured in 2% SDS, and diluted with more than 20x volume of Tris-buffered saline (TBS; 50 mM Tris-Cl, pH 7.4, 150 mM NaCl) containing 1% Triton X-100 (to reduce the SDS level to below 0.1%). Twenty microliters of settled volume of CT61 antibody-bound protein G Plus beads was added to the diluted sample, incubated with gentle agitation overnight at 4°C, and washed five times with TBS. The immunoprecipitates were eluted by the addition of 40 µl of 2x gel loading buffer and boiling and analyzed by electrophoresis and immunoblotting. Twenty-five microliters of the eluate from the crosslinked sample was separately electrophoresed in an 8% acrylamide SDS gel and stained with Coomassie blue. The crosslinked product band was excised for mass spectrometry. This method is modified from King et al. (1991).
After trypsin digestion, peptides were identified by mass spectrometry at the University of Massachusetts Medical School Proteomic Mass Spectrometry Facility (Worcester, MA).
Negative Stain Electron Microscopy and Single Particle Analysis
For negative-stain electron microscopy, the HC subparticle was isolated by anion-exchange chromatography (Sakakibara and Nakayama, 1998) to avoid the use of sucrose, which adversely affects staining. Before electron microscopic observation, samples were examined by SDS-PAGE and staining with a fluorescent dye (SYPRO Ruby stain, Bio-Rad) to ensure that LC4 had not dissociated from the HC during purification. Purified HC subparticles were diluted to 20 nM with MMEK buffer (30 mM MOPS-K, 5 mM MgCl2, 1 mM EGTA, 100 mM KCl, pH7.4) with or without 1.1 mM CaCl2 (final concentration), fixed briefly with 2% glutaraldehyde, and applied to carbon-coated copper grids that had been treated with ozone to make the carbon film hydrophilic. Samples on grids were stained with 1.0% (wt/vol) uranyl acetate. Micrographs were taken with a JEM2000EX electron microscope (JEOL, Tokyo, Japan) operated at an accelerating voltage of 80 kV with a nominal magnification of 50,000x. Electron micrographs were digitized on an EPSON GTX-700 scanner (Seiko Epson, Nagano, Japan) at 1000 dpi, corresponding to a pixel size of 0.54 nm on the grid. Digital micrographs were imported into the SPIDER suite of programs (Frank et al., 1996) for all subsequent image processing (Burgess et al., 2003, 2004a,b). For the analysis, we used 703 particles imaged in plus Ca2+ conditions and 582 particles prepared in the absence of Ca2+. The particles were aligned using a reference-free alignment procedure and classified using K-means clustering (Burgess et al., 2004a). We often observed that there is a kink or inflection in the tail of the HC subparticle, and we set the kink point to the center of the alignment. Image classification was performed based on images of the N-terminal tail region.
Other Computational Methods
The HC IQ motifs were identified using the calmodulin target database (http://calcium.uhnres.utoronto.ca/; Yap et al., 2000).
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RESULTS |
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TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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HC HC (oda11), the HC motor domain (oda4-s7), and an uncharacterized alteration in the HC that results in suppression of paralysis due to lack of the radial spokes or central pair microtubule complex (sup2 previously termed sup-pf2). Fractionation of outer arm dynein into two subparticles revealed that all LC4 is directly associated with the HC (Figure 1C) as suggested previously (Pfister et al., 1982), unlike the LC3 thioredoxin that binds to both the and HCs (Harrison et al., 2002).
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HC Complex). To determine whether LC4 is also present in this cytoplasmic complex, we immunoprecipitated the HC from cytoplasmic extracts. Because our anti- HC mAb (12 B; King et al., 1985) does not work well for this assay, we prepared a polyclonal antibody (CT240) against the most N-terminal region of this HC (residues 1-442) expressed as a fusion with MBP. This antibody reacts solely with the HC and specifically does not recognize other axonemal HCs (Figure 2A). Both the HC and LC4 were present in immunoprecipitates from wild-type cytoplasmic extracts obtained using CT240, but were absent from the preimmune control (Figure 2, B and C). These precipitates contained only small amounts of the outer arm proteins IC1 and the HC-associated LC5. Furthermore, the outer arm docking complex protein (DC1) was not detectable in these samples (Figure 2C), suggesting either that the docking complex is transported to the flagellum as part of a separate unit (Wakabayashi et al., 2001) or that antibody binding induces dissociation as we observed previously for the interaction between the IC/LC complex and the and HCs after binding of the mAb 1869A (King and Witman, 1990). As a further control, similar experiments were performed with oda2 (lacks the HC) and oda3 (lacks DC1) extracts (Figure 2C). No dynein proteins were obtained from oda2 extracts using the HC antibody as expected, whereas all dynein components tested, including considerably enhanced quantities of IC1, were associated in oda3 extracts. These data indicate that LC4 and the HC are preassembled within the cytoplasm and suggest that binding of IC1 to the cytoplasmic HC-containing complex may be enhanced in the absence of the outer arm docking complex protein DC1.
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HC HC region with which LC4 interacts, we combined vanadate-mediated photolysis and chemical crosslinking. UV irradiation of dynein HCs in the presence of vanadate and ATP results in cleavage at the V1 site within the P-loop of the first AAA+ domain (Lee-Eiford et al., 1986; King and Witman, 1987). For the HC, this generates two fragments: an N-terminal stem domain of 211 kDa (Mr180,000) and a C-terminal motor domain of 302 kDa (Mr240,000;King and Witman, 1988b; Figure 3, A and B). The epitope recognized by the 12B mAb is located near the site of V1 cleavage within the N-terminal fragment (Wilkerson et al., 1994). DMP treatment covalently links primary amines via a linker of 9.2 Å. Treatment of the native HC particle with DMP resulted in crosslinking of LC4 to the smaller N-terminal V1 photocleavage fragment (Figure 3, A and B). This crosslinked product was detected by the CT61 antibody, but was not readily observed with CT240 or with the 12B mAb, presumably due to epitope modification; the 12B epitope (Wilkerson et al., 1994) and the HC region used as immunogen for CT240 contain 6 and 38 Lys residues, respectively.
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HC within the Native Complex). To test whether Ca2+ addition affected LC4- HC association, we fractionated the native HC complex (containing the HC, LC1, and LC4) by sucrose density gradient centrifugation either in the absence of Ca2+ or at pCa 5 or pCa 3 (Figure 4); LC4 precisely cosedimented with the HC at 12S under all Ca2+ conditions. Recombinant LC4 was found at the top of the gradient, indicating that this protein does not migrate at 12 S in the absence of the HC. Thus, LC4 remains attached to the HC under conditions in which the LC is saturated with Ca2+ (King and Patel-King, 1995), and ATP-sensitive microtubule binding by the - HC subparticle is maximally activated (Sakato and King, 2003). Intriguingly, we did observe a small and reproducible shift in the sedimentation profile for the 12S HC complex as a result of Ca2+ addition; the LC4/ HC peak was in fractions 9–10 in the absence of Ca2+, fraction 9 at pCa 5, and fractions 8–9 at pCa 3. This shift suggests that the complex may undergo a Ca2+-dependent change to a more compact form in the presence of ligand. In contrast, neither LC4 nor tubulin dimer peaks shifted upon Ca2+ addition; the outer arm subunit peak did not shift at pCa5 but became spread out across one additional fraction at pCa3.
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HC N-terminal Region HC complex in sucrose gradients derived from an alteration in conformation, we examined the isolated HC subunit by negative-stain electron microscopy in the presence and absence of Ca2+, followed by single-particle image processing (Burgess et al., 2003, 2004a,b). A survey micrograph of a representative preparation is shown in Figure 5A. We then identified dynein particles that had adsorbed to the carbon film in one of two orientations (termed "left" and "right") such that the face of the AAA ring with central cavity is observed. A montage of class-averaged particles in both orientations prepared in either the presence or absence of Ca2+ is shown in Figure 5B. Image averaging of the HC head domain revealed no major differences in conformation in either orientation after Ca2+ addition (Figure 5C). However, the N-terminal stem domain was affected by Ca2+. In many averaged images, this region showed an inflection point at about two-thirds of the distance from the N-terminal tip to the motor unit. To quantify this inflection, we measured the angle (°) between a line drawn along the length of the N-terminal region starting at the tip and a second line that passed through the center of the AAA ring and the point where the N-terminal domain joined the ring (Figure 5D). For dynein particles prepared in the absence of Ca2+, a relatively constant angle of 120–160° (144 ± 12°; mean ± SD) was obtained (Figure 5E). However, in the presence of Ca2+ a much larger angular dispersion about the inflection point, ranging from 35 to 140° (89 ± 40°; mean ± SD), was observed (Figure 5E). These observations suggest that the HC N-terminal region is relatively flexible about this inflection point in the presence of Ca2+ but that it becomes locked in a more extended conformation in the absence of ligand.
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HC N-terminal Domain HC within the native complex, we examined segments from the HC N-terminal region to assess where the interaction site might be located. Various portions of this HC region (see Figure 6A) were fused to MBP. Full-length and N-terminal–truncated (residues 22-159; see below) forms of 35S-labeled LC4 were synthesized in a reticulocyte lysate (Figure 6B) and incubated with the MBP- HC proteins. Because 10 mM maltose was necessary for the solubility of these constructs, we used DMP crosslinking to stabilize any interactions before electrophoresis. Only the MBP-N4 construct ( HC residues 1-1486) was crosslinked to the LC4 proteins (Figure 6C); no products were obtained with any other HC region. The interaction between MBP-N4 and LC4 was not Ca2+-dependent. Thus, it appears that the HC region bounded by residues 1089–1486 is essential for the Ca2+-independent association of this LC and that the N-terminal region of LC4 is not involved in the interaction.
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HC). Sequence analysis revealed two IQ motifs within the N-terminal domain (residues 875-1182) of the HC (Figure 7A); this motif is not present in either the or outer arm HCs. To test whether one or both IQ motifs might be involved in binding LC4, we used an in vitro binding assay using MBP fusion proteins containing various parts of this HC region (Figure 7B) and 35S-labeled LC4 synthesized in a reticulocyte lysate (Figure 7, C and D). Full-length LC4 (indicated as M1) did not bind to any of the fusion proteins in either the presence or absence of Ca2+ (Figure 7D). However, a truncated LC4 product containing both N-terminal EF-hands and derived from translation initiation at either M20 or M22, bound to this HC region in a Ca2+-dependent manner. Other truncated products that lack intact N-terminal EF-hands (derived from initiation at M29 and M59) did not bind. Thus, the 22-159 segment of LC4, allows for Ca2+-dependent interaction with the IQ region of the HC. This association requires that the first EF hand within LC4 (residues 25-48) be intact, and, at least in this minimal in vitro system, is abolished by a short sequence at the N-terminus of LC4. Furthermore, this observation implies that the Ca2+-independent association of truncated LC4 (see Figure 6) involves a region of the HC that is C-terminal of residue 1182.
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HC HC N-terminal domain interact with other components within the isolated dynein particle, we used a combination of chemical crosslinking and vanadate-mediated photocleavage to probe intradynein associations (Figure 8, A and B). To help avoid confusion between the various HCs, this experimental series was performed using intact outer arm dynein purified from oda4-s7 mutant axonemes that contain a truncated 160 kDa form of the HC (indicated as * in Figure 8) that completely lacks the motor domain (Sakakibara et al., 1993). In the absence of DMP and UV irradiation, only intact and HCs and the truncated * were detected on immunoblots (Figure 8B, left panels). DMP treatment resulted in multiple crosslinked products containing various combinations of HCs and LCs. A single high molecular weight product containing the HC and LC5 thioredoxin (/5) was obtained; photocleavage revealed that this interaction involved the HC N-terminal domain (N-/5), confirming our previous observation (Harrison et al., 2002). In contrast, multiple products were generated containing the LC3 thioredoxin that is known to interact with both the and HCs (Pfister and Witman, 1984; Harrison et al., 2002). The * HC region became crosslinked to LC3 (*/3), and this complex was insensitive to UV irradiation as expected. In DMP-treated samples, we also observed several high molecular weight species containing LC3, including one consisting of the HC and LC3 (/3) and the quaternary complex of LC1, LC3, LC4, and the HC (/4/3/1). Photocleavage of this latter product at the V1 site yielded one product containing LC3, LC4, and the N-terminal domain of the HC (N-/4/3) and a pair of bands consisting of the HC C-terminal region and either one or two copies of LC1 (C-/1). In addition two other crosslinked products with Mr greater than that of N-/4/3 were generated; however, their origin remains uncertain. In the crosslinked quaternary complex, LC3 could associate either directly with the HC or via interaction with LC4. However, we did not observe a LC3/LC4 DMP crosslinked product (predicted molecular weight of 34 kDa) as would be expected in the latter case (not shown). Therefore, LC3 is most likely crosslinked to, and presumably interacts directly with, the N-terminal region of the HC.
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110,000 in urea gels (Mr >120,000 in SDS gels) was detected by the LC4 antibody (Figure 8B, black arrowheads) after DMP treatment of intact oda4-s7 dynein in the presence of ATP/vanadate; the yield of this product was significantly enhanced upon photolysis, which mimics the "no ATP-bound" state. This suggests that LC4 also interacts with a protein of 90–100 kDa; a similar crosslinked product was obtained with oda11 sup1-2 dynein, which contains a HC with abrogated microtubule binding activity (not shown). Analysis of wild-type dynein using reagents with varying linker lengths of 0–11.4 Å revealed that DMP and DSS gave the highest yields of LC4-p100 in the presence of Ca2+ (Figure 9A); use of the zero-length reagent EDC generated a small amount of product, indicating that the two proteins indeed interact directly. The short-length amine-reactive linker DFDNB generated a barely detectable amount of LC4-crosslinked product at concentrations of 0.05–0.5 mM, suggesting that the amines crosslinked by DMP and DSS are >3 Å apart. We also noticed that the presence of Ca2+ was necessary to obtain this LC4-p100 product in high yield as very little was generated in the presence of EGTA (Figure 9B). Indeed, with both DSS and DMP significant amounts of LC4-p100 were obtained only with Ca2+ levels at or above pCa 4 (Figure 9C). Furthermore, addition of ATP/vanadate reduced the amount of LC4-p100 even in the presence of the metal ligand, suggesting that a further change in conformation occurs upon nucleotide binding (Figure 9B).
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HC subparticle (Figure 3, open arrowheads), it presumably derived from interaction of LC4 with a component of the HC subparticle or the outer arm docking complex. Accordingly, we isolated the crosslinked product by immunoprecipitation with CT61 (Figure 9D), excised the band after electrophoresis, and analyzed its composition by mass spectrometry. Five peptides derived from IC1 of the outer dynein arm were obtained, unambiguously identifying p100 as IC1. |
DISCUSSION |
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TOPABSTRACTINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONREFERENCES |
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). Mutational studies suggest that the outer row of axonemal dynein arms may be the ultimate target of this Ca2+-mediated signaling pathway (Kamiya and Okamoto, 1985; Mitchell and Rosenbaum, 1985). Previously we found that Ca2+ concentrations above pCa 6 maximally activate ATP-sensitive microtubule binding by purified - HC subparticles (Sakato and King, 2003). This indicates that outer arm dynein contains an integral Ca2+ sensor. Two Ca2+-binding proteins of the EF-hand superfamily have been identified within this structure: the docking complex protein DC3 (Casey et al., 2003a) and the HC–associated LC4 light chain (King and Patel-King, 1995). DC3 seems not to be involved in Ca2+ sensing because a null mutant (oda14) rescued with a DC3 variant unable to bind Ca2+ exhibits normal photo-induced behavioral responses, including waveform conversion (Casey et al., 2003a). Here we have examined the detailed interaction of the other candidate Ca2+ sensor (LC4) with the HC and describe structural alterations in this complex that occur in response to Ca2+ binding.
Interaction of LC4 with the HC
Four LCs (LCs 1, 3, 4, and 5) within the Chlamydomonas outer arm interact directly with their target HCs. LC3 and LC5 are thioredoxins and we have previously observed that at least one of these (LC3) interacts with two HCs ( and ; Harrison et al., 2002). The crosslinking experiments reported here further confirm this observation. In contrast, within the outer arm, the motor domain–associated protein LC1 interacts only with the HC (Benashski et al., 1999). Subfractionation of purified dynein and immunoblotting revealed that LC4 is similarly associated exclusively with the HC, as suggested previously from fractionation studies (Pfister et al., 1982). Furthermore, we observed that this LC4-HC interaction occurs within the cytoplasm, implying the preassembly of this HC/LC complex before its transport and incorporation into the flagellum.
Preassembled Outer Arm Dynein Complexes in the Cytoplasm
Previous studies of outer arm complexes within Chlamydomonas cytoplasm have revealed that all three HCs and both ICs can be immunoprecipitated by an anti- HC antibody (Fowkes and Mitchell, 1998) and that the dynein motor unit and docking complex are independently preassembled in the cytoplasm (Wakabayashi et al., 2001). Using an antibody directed against the HC N-terminal domain, we observed that LC4 was immunoprecipitated from wild-type extracts, indicating that HC-LC assembly also occurs in the cytoplasm. Intriguingly, in the same samples we obtained only very small amounts of IC1 and no DC1. However, the amount of immunoprecipitated IC1 increased very significantly in the DC1 mutant oda3, suggesting that the presence of the docking complex influences retention of IC1 and potentially the cytoplasmic assembly state of the outer arm dynein particle. Alternatively, because the N-terminal region of the HC must be located close to where these proteins interact, one possible reason for the low level of IC1 is that, in the presence of the docking complex, the CT240 antibody disrupts an interaction between the HC (or an associated protein) and components of the subunit; for example, we previously found that binding of an antibody against IC2 can disrupt association of the IC/LC complex with the and HCs (King and Witman, 1990).
Why Does the HC Contain Two IQ Motifs?
The IQ motif is an established binding consensus for calmodulin family proteins (Rhoads and Friedberg, 1997), although several distinct molecular mechanisms have been described for these interactions (Hoeflich and Ikura, 2002). The HC N-terminal domain contains two IQ motifs that promote interaction with LC4 and are thus functional. However, stoichiometry measurements based on both Coomassie blue dye binding and 35S-labeling have indicated that there is a single copy of LC4 per dynein particle (King and Witman, 1989). The question therefore arises as to why there are two IQ motifs but only one bound copy of LC4. First, two copies of LC4 might interact with the HC in vivo, only one of which is bound sufficiently tightly to copurify with dynein after high salt extraction. Second, although both motifs can interact with LC4 in vitro, one might be used in vivo to bind a related protein, e.g., calmodulin, centrin, or the docking complex protein DC3. Although there is no direct evidence in support of this possibility, it cannot be ruled out at the present time. Finally, recent studies of calmodulin binding to the neck domain of myosin V (Martin and Bayley, 2004) and the small conductance Ca2+-activated K+ channel (Schumacher et al., 2001) have revealed that the N- and C-terminal domains of a single calmodulin molecule can independently bind to two different IQ motifs aligned in parallel, thereby forming a bridge between them; in the case of the K+ channel, this involves both Ca2+-dependent and -independent interactions and leads to Ca2+-dependent dimerization. If LC4 bound the HC N-terminal domain in a similar manner, it would readily explain the interaction with both IQ motifs as well as the apparently critical role played by the 278-residue intervening region. Furthermore, as only the two N-terminal helix-loop-helix motifs of LC4 conform to the consensus for Ca2+ binding (King and Patel-King, 1995), this model could accommodate a Ca2+-dependent interaction with one IQ domain and a Ca2+-independent association with the other. The differential interactions of these LC4 regions with the HC might alter the conformation of the complex and provide the physical basis for the shift in sedimentation coefficient, enhanced flexibility of the N-terminal region and interaction with IC1 observed upon Ca2+ addition. A model depicting these interactions is shown in Figure 10.
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). However, we did not observe any interaction between DC2 and LC4, and these motifs more likely bind other calmodulin-family proteins, such as DC3.
The HC Is Regulated by Multiple Signaling Pathways
Previously, we found that motor activity of the HC is required for Ca2+-dependent activation of ATP-sensitive MT binding by the - HC subparticle (Sakato and King, 2003). Furthermore, we observed that crosslinking of - HC dynein from oda11 sup1-2 that contains a HC with a defective coiled coil stalk domain still generated the LC4-IC1 product. This indicates that LC4 can undergo a Ca2+-dependent conformational change in this mutant dynein, even though it does not result in the activation of ATP-dependent microtubule binding. This suggests that the configuration of these two HCs is important to exert full motor activity at high Ca2+ concentrations. Because LC4 comes into close proximity of IC1 at high Ca2+, Ca2+-dependent conformational change of LC4 likely has a direct effect on the HC stem rather than its motor domain. This would be consistent with our observation that the stem domain adopts a relatively constant orientation in the absence of Ca2+ but is much more variable in its presence. Furthermore, recent studies revealed that the stem domain of the dynein HC undergoes a dynamic structural change during the ATP hydrolytic cycle and that this motion contributes to formation of the power stroke (Burgess et al., 2003; Kon et al., 2005). In addition, we observed that the Ca2+ sensitivity of the - HC subparticle was altered by binding tubulin to the basal ATP-insensitive site (our unpublished observations), providing further evidence that dynein motor activity can be modulated through the stem domain.
Chlamydomonas flagellar motility is also controlled by redox poise (Wakabayashi and King, 2006). The LC3 thioredoxin interacts with the HC and ATPase activity of this motor unit, but not the and HCs or the inner arms, is activated by sulfhydryl modification (Harrison et al., 2002). These observations suggest that the redox control mechanism may involve or be mediated through the HC. Furthermore, the HC has two potential regulatory inputs directly to the motor domain. Two copies of the leucine-rich repeat protein LC1 are associated with the nucleotide binding sites of the HC motor domain and also interact with an additional axonemal component (Benashski et al., 1999; Wu et al., 2000; DiBella et al., 2005) We have proposed previously that Arg residues within the terminal helix of LC1 control ATPase activity in a manner similar to the "arginine fingers" that promote GTPase activity of Ras and Rho (Wu et al., 2000; King, 2002); recent work has shown that the RNA interference–mediated knock down of an LC1 orthologue in trypanosomes leads to defective motility (Baron et al., 2007). Furthermore, analysis of the Chlamydomonas phosphoproteome (Wagner et al., 2006) has revealed that the HC is phosphorylated on Ser2467, which is located within the third AAA+ domain. Mutational studies of cytoplasmic dynein indicate that this domain plays an important role in dynein motor function (Silvanovich et al., 2003), and single molecule analysis (Mallik et al., 2004) suggests that nucleotide binding at domains other than AAA1 regulates the power stroke mechanism.
In conclusion, we have defined specific structural alterations within the outer dynein arm that involve the HC, LC4, and IC1 and occur in response to an increase in Ca2+. These results provide further evidence for the regulation of outer dynein arm structure and activity by Ca2+ and impart ins
