Potential role for phosphorylation in differential regulation of the assembly of dynein light chains

The homodimeric light chains LC8 and Tctex-1 are integral parts of the microtubule motor cytoplasmic dynein, as they directly associate with dynein intermediate chain IC and various cellular cargoes. These light chains appear to regulate assembly of the dynein complex by binding to and promoting dimerization of IC. In addition, both LC8 and Tctex-1 play roles in signaling, apoptosis, and neuronal development that are independent of their function in dynein, but it is unclear how these various activities are modulated. Both light chains undergo specific phosphorylation, and here we present biochemical and NMR analyses of phosphomimetic mutants that indicate how phosphorylation may regulate light chain function. For both LC8 and Tctex-1, phosphorylation promotes dissociation from IC while retaining their binding activity with other non-dynein proteins. Although LC8 and Tctex-1 are homologs having a common fold, their reduced affinity for IC upon phosphorylation arises by different mechanisms. In the case of Tctex-1, phosphorylation directly masks the IC binding site at the dimer interface, whereas for LC8, phosphorylation dissociates the dimer and indirectly eliminates the binding site. This modulation of the monomer-dimer equilibrium by phosphorylation provides a novel mechanism for discrimination among LC8 binding partners.     

Solution structure of isoform 1 of Roadblock/LC7, a light chain in the dynein complex

Roadblock/LC7 is a member of a class of dynein light chains involved in regulating the function of the dynein complex. We have determined the three-dimensional structure of isoform 1 of the mouse Roadblock/LC7 cytoplasmic dynein light chain (robl1_mouse) by NMR spectroscopy. In contrast to a previously reported NMR structure of the human homolog with 96% sequence identity (PDB 1TGQ), which showed the protein as a monomer, our results indicate clearly that robl1 exists as a symmetric homodimer. The two beta3-strands pair with each other and form a continuous ten-stranded beta-sheet. The 25-residue alpha2-helix from one subunit packs antiparallel to that of the other subunit on the face of the beta-sheet. Zipper-like hydrophobic contacts between the two helices serve to stabilize the dimer. Through an NMR titration experiment, we localized the site on robl1_mouse that interacts with the 40 residue peptide spanning residues 243 through 282 of IC74-1_rat. These results provide physical evidence for a symmetrical interaction between dimeric robl1 and the two molecules of IC74-1 in the dynein complex.     

Structure and dynamics of LC8 complexes with KXTQT-motif peptides: swallow and dynein intermediate chain compete for a common site

The dynein light chain LC8 is an integral subunit of the cytoplasmic dynein motor complex that binds directly to and promotes assembly of the dynein intermediate chain (IC). LC8 interacts also with a variety of putative dynein cargo molecules such as Bim, a proapoptotic Bcl2 family protein, which have the KXTQT recognition sequence and neuronal nitric oxide synthase (nNOS), which has the GIQVD fingerprint but shares the same binding grooves at the LC8 dimer interface. The work reported here investigates the interaction of LC8 with IC and a putative cargo, Swallow, which share the KXTQT recognition sequence, and addresses the apparent paradox of how LC8, as part of dynein, mediates binding to cargo. The structures of Drosophila LC8 bound to peptides from IC and Swallow solved by X-ray diffraction show that the IC and Swallow peptides bind in the same grooves at the dimer interface. Differences in flexibility between bound and free LC8 were evaluated from hydrogen isotope exchange experiments using heteronuclear NMR spectroscopy. Peptide binding causes an increase in protection from exchange primarily in residues that interact directly with the peptide, such as the beta-strand intertwined at the interface and the N-terminal end of helix alpha2. There is considerably more protection upon Swallow binding, consistent with tighter binding relative to IC. Comparison with the LC8/nNOS complex shows how both the GIQVD and KXTQT fingerprints are recognized in the same groove. The similar structures of LC8/IC and LC8/Swa and the tighter binding of Swallow call into question the role for LC8 as a cargo adaptor protein, and suggest that binding of LC8 to Swallow serves another function, possibly that of a dimerization engine, which is independent of its role in dynein.     

The intermediate chain of cytoplasmic dynein is partially disordered and gains structure upon binding to light-chain LC8

The N-terminal domain of dynein intermediate chain, IC(1-289), is highly disordered, but upon binding to dynein light-chain LC8, it undergoes a significant conformational change to a more ordered structure. Using circular dichroism and fluorescence spectroscopy, we demonstrate that the change in conformation is due to an increase in the helical structure and to enhanced compactness in the environment of tryptophan 161. An increase in helical structure and compactness is also observed with trimethylamine-N-oxide (TMAO), a naturally occurring osmolyte used here as a probe to identify regions with a propensity for induced folding. Global protection of IC(1-289) from protease digestion upon LC8 binding was localized to a segment that includes residues downstream of the LC8-binding site. Several smaller constructs of IC(1-289) containing the LC8-binding site and one of the predicted helix or coiled-coil segments were made. IC(1-143) shows no increase in helical structure upon binding, while IC(114-260) shows an increase in helical structure similar to what is observed with IC(1-289). Binding of IC(114-260) to LC8 was monitored by fluorescence and native gel electrophoresis and shows saturation of binding, a stoichiometry of 1:1, and moderate binding affinity. The induced folding of IC(1-289) upon LC8 binding suggests that LC8 could act through the intermediate chain to facilitate dynein assembly or regulate cargo-binding interactions.     

Interactions of cytoplasmic dynein light chains Tctex-1 and LC8 with the intermediate chain IC74

The interactions of three subunits of cytoplasmic dynein from Drosophila melanogaster, LC8, Tctex-1, and the N-terminal domain of IC74 (N-IC74, residues 1-289), were characterized in vitro by affinity methods, limited proteolysis, and circular dichroism spectroscopy. These subunits were chosen for study because they are presumed to promote the assembly of the complex and to be engaged in the controlled binding and release of cargo. Limited proteolysis and mass spectrometry of N-IC74 in the presence of LC8 and Tctex-1 localized binding of Tctex-1 to the vicinity of K104 and K105, and localized binding of LC8 to the region downstream of K130. Circular dichroism, fluorescence, sedimentation velocity, and proteolysis studies indicate that N-IC74 has limited secondary and tertiary structure at near physiological solution conditions. Upon addition of LC8, N-IC74 undergoes a significant conformational change from largely unfolded to a more ordered structure. This conformational change is reflected in increased global protection of N-IC74 from proteolytic digestion following the interaction, and in a significant change in the CD signal. A smaller but reproducible change in the CD spectra was observed upon Tctex-1 binding as well. The increased structure introduced into N-IC74 upon light chain binding suggests a mechanism by which LC8 and Tctex-1 may regulate the assembly of the dynein complex.     

Cytoplasmic dynein regulation by subunit heterogeneity and its role in apical transport.

Despite the existence of multiple subunit isoforms for the microtubule motor cytoplasmic dynein, it has not yet been directly shown that dynein complexes with different compositions exhibit different properties. The 14-kD dynein light chain Tctex-1, but not its homologue RP3, binds directly to rhodopsin's cytoplasmic COOH-terminal tail, which encodes an apical targeting determinant in polarized epithelial Madin-Darby canine kidney (MDCK) cells. We demonstrate that Tctex-1 and RP3 compete for binding to dynein intermediate chain and that overexpressed RP3 displaces endogenous Tctex-1 from dynein complexes in MDCK cells. Furthermore, replacement of Tctex-1 by RP3 selectively disrupts the translocation of rhodopsin to the MDCK apical surface. These results directly show that cytoplasmic dynein function can be regulated by its subunit composition and that cytoplasmic dynein is essential for at least one mode of apical transport in polarized epithelia.     

Molecular characterization of Ciona sperm outer arm dynein reveals multiple components related to outer arm docking complex protein 2

Using proteomic and immunochemical techniques, we have identified the light and intermediate chains (IC) of outer arm dynein from sperm axonemes of the ascidian Ciona intestinalis. Ciona outer arm dynein contains six light chains (LC) including a leucine-rich repeat protein, Tctex1- and Tctex2-related proteins, a protein similar to Drosophila roadblock and two components related to Chlamydomonas LC8. No LC with thioredoxin domains is included in Ciona outer arm dynein. Among the five ICs in Ciona, three are orthologs of those in sea urchin dynein: two are WD-repeat proteins and the third one, unique to metazoan sperm flagella, contains both thioredoxin and nucleoside diphosphate kinase modules. The remaining two Ciona ICs have extensive coiled coil structure and show sequence similarity to outer arm dynein docking complex protein 2 (DC2) that was first identified in Chlamydomonas flagella. We recently identified a third DC2-like protein with coiled coil structure, Ci-Axp66.0 that is also associated in substoichiometric amounts with Ciona outer arm dynein. In addition, Oda5p, a component of an additional complex required for assembly of outer arm dynein in Chlamydomonas flagella, also groups with this family of DC2-like proteins. Thus, the assembly of outer arm dynein onto doublet microtubules involves multiple coiled-coil proteins related to DC2.     

Structure of Tctex-1 and its interaction with cytoplasmic dynein intermediate chain

The minus-ended microtubule motor cytoplasmic dynein contains a number of low molecular weight light chains including the 14-kDa Tctex-1. The assembly of Tctex-1 in the dynein complex and its function are largely unknown. Using partially deuterated, (15)N,(13)C-labeled protein samples and transverse relaxation-optimized NMR spectroscopic techniques, the secondary structure and overall topology of Tctex-1 were determined based on the backbone nuclear Overhauser effect pattern and the chemical shift values of the protein. The data showed that Tctex-1 adopts a structure remarkably similar to that of the 8-kDa light chain of the motor complex (DLC8), although the two light chains share no amino acid sequence homology. We further demonstrated that Tctex-1 binds directly to the intermediate chain (DIC) of dynein. The Tctex-1 binding site on DIC was mapped to a 19-residue fragment immediately following the second alternative splicing site of DIC. Titration of Tctex-1 with a peptide derived from DIC, which contains a consensus sequence R/KR/KXXR/K found in various Tctex-1 target proteins, indicated that Tctex-1 binds to its targets in a manner similar to that of DLC8. The experimental results presented in this study suggest that Tctex-1 is likely to be a specific cargo adaptor for the dynein motor complex.     

Regulatory dissociation of Tctex-1 light chain from dynein complex is essential for the apical delivery of rhodopsin

Post-Golgi to apical surface delivery in polarized epithelial cells requires the cytoplasmic dynein motor complex. However, the nature of dynein-cargo interactions and their underlying regulation are largely unknown. Previous studies have shown that the apical surface targeting of rhodopsin requires the dynein light chain, Tctex-1, which binds directly to both dynein intermediate chain (IC) and rhodopsin. In this report, we show that the S82E mutant of Tctex-1, which mimics Tctex-1 phosphorylated at serine 82, has a reduced affinity for dynein IC but not for rhodopsin. Velocity sedimentation experiments further suggest that S82E is not incorporated into the dynein complex. The dominant-negative effect of S82E causes rhodopsin mislocalization in polarized Madin-Darby canine kidney (MDCK) cells. The S82A mutant, which mimics dephosphorylated Tctex-1, can be incorporated into dynein complex but is impaired in its release. Expression of S82A also causes disruption of the apical localization of rhodopsin in MDCK cells. Taken together, these results suggest that the dynein complex disassembles to release cargo due to the specific phosphorylation of Tctex-1 at the S82 residue and that this process is critical for the apical delivery of membrane cargoes.     

Structure and dynamics of the homodimeric dynein light chain km23

km23 (96 residues, 11 kDa) is the mammalian ortholog of Drosophila roadblock, the founding member of LC7/robl/km23 class of dynein light chains. km23 has been shown to be serine-phosphorylated following TGFbeta receptor activation and to bind the dynein intermediate chain in response to such phosphorylation. Here, we report the three-dimensional solution structure of km23, which is shown to be that of a homodimer, similar to that observed for the heterodimeric complex formed between p14 and MP1, two distantly related members of the MglB/robl superfamily, but distinct from the LC8 and Tctex-1 classes of dynein light chains, which also adopt homodimeric structures. The conserved surface residues of km23, including three serine residues, are located predominantly on a single face of the molecule. Adjacent to this face is a large cleft formed by the incomplete overlap of loops from opposite monomers. As shown by NMR relaxation data collected at two fields, several cleft residues are flexible on the ns-ps and ms-mus timescales. Based on these observations, we propose that the patch of conserved residues on the central face of the molecule corresponds to the site at which km23 binds the dynein intermediate chain and that the flexible cleft formed between the overlap of loops from the two monomers corresponds to the site at which km23 binds other partners, such as the TGFbeta type II receptor or Smad2.     

Light chain-dependent self-association of dynein intermediate chain

Dynein light chains are bivalent dimers that bind two copies of dynein intermediate chain IC to form a cargo attachment subcomplex. The interaction of light chain LC8 with the natively disordered N-terminal domain of IC induces helix formation at distant IC sites in or near a region predicted to form a coiled-coil. This fostered the hypothesis that LC8 binding promotes IC self-association to form a coiled-coil or other interchain helical structure. However, recent studies show that the predicted coiled-coil sequence partially overlaps the light chain LC7 recognition sequence on IC, raising questions about the apparently contradictory effects of LC8 and LC7. Here, we use NMR and fluorescence quenching to localize IC self-association to residues within the predicted coiled-coil that also correspond to helix 1 of the LC7 recognition sequence. LC8 binding promotes IC self-association of helix 1 from each of two IC chains, whereas LC7 binding reverses self-association by incorporating the same residues into two symmetrical, but distant, helices of the LC7-IC complex. Isothermal titration experiments confirm the distinction of LC8 enhancement of IC self-association and LC7 binding effects. When all three light chains are bound, IC self-association is shifted to another region. Such flexibility in association modes may function in maintaining a stable and versatile light chain-intermediate chain assembly under changing cellular conditions.     

Interactions between the leucine-zipper motif of cGMP-dependent protein kinase and the C-terminal region of the targeting subunit of myosin light chain phosphatase

Nitric oxide induces vasodilation by elevating the production of cGMP, an activator of cGMP-dependent protein kinase (PKG). PKG subsequently causes smooth muscle relaxation in part via activation of myosin light chain phosphatase (MLCP). To date, the interaction between PKG and the targeting subunit of MLCP (MYPT1) is not fully understood. Earlier studies by one group of workers showed that the binding of PKG to MYPT1 is mediated by the leucine-zipper motifs at the N and C termini, respectively, of the two proteins. Another group, however, reported that binding of PKG to MYPT1 did not require the leucine-zipper motif of MYPT1. In this work we fully characterized the interaction between PKG and MYPT1 using biophysical techniques. For this purpose we constructed a recombinant PKG peptide corresponding to a predicted coiled coil region that contains the leucine-zipper motif. We further constructed various C-terminal MYPT1 peptides bearing various combinations of a predicted coiled coil region, extensions preceding this coiled coil region, and the leucine-zipper motif. Our results show, firstly, that while the leucine-zipper motif at the N terminus of PKG forms a homodimeric coiled coil, the one at the C terminus of MYPT1 is monomeric and non-helical. Secondly, the leucine-zipper motif of PKG binds to that of MYPT1 to form a heterodimer. Thirdly, when the leucine-zipper motif of MYPT1 is absent, the PKG leucine-zipper motif binds to the coiled coil region and upstream segments of MYPT1 via formation of a heterotetramer. These results provide rationalization of some of the findings by others using alternative binding analyses.     

The roadblock light chain binds a novel region of the cytoplasmic Dynein intermediate chain

Cytoplasmic dynein is the major minus-end directed microtubule-based motor in eukaryotic cells. It is composed of a number of different subunits including three light chain families: Tctex1, LC8, and roadblock. The incorporation of the roadblock light chains into the cytoplasmic dynein complex had not been determined. There are two roadblock genes in mammals, ROBL-1 and ROBL-2. We find that both members of the roadblock family bind directly to all of the intermediate chain isoforms of mammalian cytoplasmic dynein. This was determined with three complementary approaches. A yeast two-hybrid assay demonstrated that both roadblock light chains interact with intermediate chain isoforms from the IC74-1 and IC74-2 genes in vivo. This was confirmed in vitro with both a solid phase blot overlay assay and a solution-binding assay. The roadblock-binding domain on the intermediate chain was mapped to an approximately 72 residue region. The binding domain is downstream of each of the two alternative splice sites in the intermediate chains. This location is consistent with the finding that both roadblock-1 and roadblock-2 show no binding specificity for a single IC74-1 or IC74-2 intermediate chain isoform. In addition, this roadblock-binding domain is significantly downstream from both the Tctex1- and LC8-binding sites, supporting the hypothesis that multiple light chain family members can bind to the same intermediate chain.     

Dyneins across eukaryotes: a comparative genomic analysis

Dyneins are large minus-end-directed microtubule motors. Each dynein contains at least one dynein heavy chain (DHC) and a variable number of intermediate chains (IC), light intermediate chains (LIC) and light chains (LC). Here, we used genome sequence data from 24 diverse eukaryotes to assess the distribution of DHCs, ICs, LICs and LCs across Eukaryota. Phylogenetic inference identified nine DHC families (two cytoplasmic and seven axonemal) and six IC families (one cytoplasmic). We confirm that dyneins have been lost from higher plants and show that this is most likely because of a single loss of cytoplasmic dynein 1 from the ancestor of Rhodophyta and Viridiplantae, followed by lineage-specific losses of other families. Independent losses in Entamoeba mean that at least three extant eukaryotic lineages are entirely devoid of dyneins. Cytoplasmic dynein 2 is associated with intraflagellar transport (IFT), but in two chromalveolate organisms, we find an IFT footprint without the retrograde motor. The distribution of one family of outer-arm dyneins accounts for 2-headed or 3-headed outer-arm ultrastructures observed in different organisms. One diatom species builds motile axonemes without any inner-arm dyneins (IAD), and the unexpected conservation of IAD I1 in non-flagellate algae and LC8 (DYNLL1/2) in all lineages reveals a surprising fluidity to dynein function.     

Transient Tertiary Structures of Disordered Dynein Intermediate Chain Regulate its Interactions with Multiple Partners

The N-terminal domain of dynein intermediate chain (N–IC) is central to the cytoplasmic dynein ‘cargo attachment subcomplex’ and regulation of motor activity. It is a prototypical intrinsically disordered protein (IDP), serving as a primarily disordered polybivalent molecular scaffold for numerous binding partners, including three dimeric dynein light chains and coiled coil domains of dynein partners dynactin p150^Glued and NudE. At the very N-terminus, a 40 amino acid single alpha helix (SAH) forms the major binding site for both p150^Glued and NudE, while a shorter nascent helix (H2) separated from SAH by a disordered linker, is necessary for tight binding to dynactin p150^Glued but not to NudE. Here we demonstrate that transient tertiary interactions in this highly dynamic protein underlie the differences in its interactions with p150^Glued and NudE. NMR paramagnetic relaxation enhancement experiments and restrained molecular dynamics simulations identify interactions between the two non-contiguous SAH and H2 helical regions, the extent of which correlates with the length and stability of H2, showing clearly that tertiary and secondary structure formation are coupled in IDPs. These interactions are significantly attenuated when N–IC is bound to NudE, suggesting that NudE binding shifts the conformational ensemble to one that is more extended and with less structure in H2. While the intrinsic disorder and flexibility in N–IC modulate its ability to serve as a binding platform for numerous partners, deviations of this protein from random-coil behavior provide a process for regulating these binding interactions and potentially the dynein motor.     

Tumor suppressor REIC/Dkk-3 interacts with the dynein light chain, Tctex-1

REIC/Dkk-3 is a member of the Dickkopf family proteins known as Wnt-antagonists, and REIC/Dkk-3 expression is downregulated in a broad range of cancer types. REIC/Dkk-3 acts as a tumor suppressor in multiple cancer cell lines by inducing apoptosis through endoplasmic reticulum (ER) stress signaling. However, the intracellular interaction partners of REIC/Dkk-3 have not been fully elucidated. By employing yeast two-hybrid screening, we identified the human dynein light chain, Tctex-1, as a novel interaction partner of REIC/Dkk-3. We further disclosed that the interaction involves the 136–157 amino acid region of REIC/Dkk-3 by using the mammalian two-hybrid system. Interestingly, this binding region of REIC/Dkk-3 with Tctex-1 contains an amino acid sequence motif [-E-X-G-R-R-X-H-] which was previously reported as the Tctex-1 binding domain of dynein intermediate chain (DIC). Immunocytochemistry demonstrated that both REIC/Dkk-3 and Tctex-1 were localized around the ER of human fibroblasts, and the similar distribution pattern of the proteins suggests that their interaction occurs around the ER. This is the first study showing the interaction of a Dickkopf family protein with a dynein motor complex protein. The link between REIC/Dkk-3 and Tctex-1 may be of significance for understanding the molecular functions of the proteins in ER stress signaling and intracellular dynein motor dynamics, respectively.     

Dynein LIC1 localizes to the mitotic spindle and midbody and LIC2 localizes to spindle poles during cell division

CD-1 (cytoplasmic dynein-1) is a multisubunit motor protein complex involved in intracellular trafficking and mitosis. The dynein LIC (light intermediate chain) subunits, LIC1 (DLIC-1, gene symbol DYNC1LI1) and LIC2 (DLIC-2, gene symbol DYNC1LI2), associate with the dynein HC (heavy chain) in a mutually exclusive manner and thus define distinct functional CD-1 complexes. Here, we analysed the mitotic distribution of LIC1 and LIC2. We found that from metaphase through anaphase, LIC1 localizes to the mitotic spindle and concentrates within the midbody during the abscission step of cytokinesis. Conversely, LIC2 strongly localizes to the spindle poles from prophase through telophase. These data suggest distinct functions for LIC1 and LIC2-containing CD-1 complexes during cell division.     

Simultaneous formation of right- and left-handed anti-parallel coiled-coil interfaces by a coil2 fragment of human lamin A

The elementary building block of all intermediate filaments (IFs) is a dimer featuring a central α-helical rod domain flanked by the N- and C-terminal end domains. In nuclear IF proteins (lamins), the rod domain consists of two coiled-coil segments, coil1 and coil2, that are connected by a short non-helical linker. Coil1 and the C-terminal part of coil2 contain the two highly conserved IF consensus motifs involved in the longitudinal assembly of dimers. The previously solved crystal structure of a lamin A fragment (residues 305-387) corresponding to the second half of coil2 has yielded a parallel left-handed coiled coil. Here, we present the crystal structure and solution properties of another human lamin A fragment (residues 328-398), which is largely overlapping with fragment 305-387 but harbors a short segment of the tail domain. Unexpectedly, no parallel coiled coil forms within the crystal. Instead, the α-helices are arranged such that two anti-parallel coiled-coil interfaces are formed. The most significant interface has a right-handed geometry, which is accounted for by a characteristic 15-residue repeat pattern that overlays with the canonical heptad repeat pattern. The second interface is a left-handed anti-parallel coiled coil based on the predicted heptad repeat pattern. In solution, the fragment reveals only a weak dimerization propensity. We speculate that the C-terminus of coil2 might unzip, thereby allowing for a right-handed coiled-coil interface to form between two laterally aligned dimers. Such an interface might co-exist with a heterotetrameric left-handed coiled-coil assembly, which is expected to be responsible for the longitudinal A_CN contact.     

Dynein intermediate chain mediated dynein-dynactin interaction is required for interphase microtubule organization and centrosome replication and separation in Dictyostelium

Cytoplasmic dynein intermediate chain (IC) mediates dynein-dynactin interaction in vitro (Karki, S., and E.L. Holzbaur. 1995. J. Biol. Chem. 270:28806-28811; Vaughan, K.T., and R.B. Vallee. 1995. J. Cell Biol. 131:1507-1516). To investigate the physiological role of IC and dynein-dynactin interaction, we expressed IC truncations in wild-type Dictyostelium cells. ICDeltaC associated with dynactin but not with dynein heavy chain, whereas ICDeltaN truncations bound to dynein but bound dynactin poorly. Both mutations resulted in abnormal localization to the Golgi complex, confirming dynein function was disrupted. Striking disorganization of interphase microtubule (MT) networks was observed when mutant expression was induced. In a majority of cells, the MT networks collapsed into large bundles. We also observed cells with multiple cytoplasmic asters and MTs lacking an organizing center. These cells accumulated abnormal DNA content, suggesting a defect in mitosis. Striking defects in centrosome morphology were also observed in IC mutants, mostly larger than normal centrosomes. Ultrastructural analysis of centrosomes in IC mutants showed interphase accumulation of large centrosomes typical of prophase as well as unusually paired centrosomes, suggesting defects in centrosome replication and separation. These results suggest that dynactin-mediated cytoplasmic dynein function is required for the proper organization of interphase MT network as well as centrosome replication and separation in Dictyostelium.     

Chlamydomonas outer arm dynein alters conformation in response to Ca2+

We have previously shown that Ca(2+) directly activates ATP-sensitive microtubule binding by a Chlamydomonas outer arm dynein subparticle containing the beta and gamma heavy chains (HCs). The gamma HC-associated LC4 light chain is a member of the calmodulin family and binds 1-2 Ca(2+) with K(Ca) = 3 x 10(-5) M in vitro, suggesting it may act as a Ca(2+) sensor for outer arm dynein. Here we investigate interactions between the LC4 light chain and gamma HC. Two IQ consensus motifs for binding calmodulin-like proteins are located within the stem domain of the gamma heavy chain. In vitro experiments indicate that LC4 undergoes a Ca(2+)-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 Ca(2+). The sedimentation profile of the gamma HC subunit changed subtly upon Ca(2+) addition, suggesting that the entire complex had become more compact, and electron microscopy of the isolated gamma subunit revealed a distinct alteration in conformation of the N-terminal stem in response to Ca(2+) addition. We propose that Ca(2+)-dependent conformational change of LC4 has a direct effect on the stem domain of the gamma HC, which eventually leads to alterations in mechanochemical interactions between microtubules and the motor domain(s) of the outer dynein arm.