Sagar Bhogaraju

Molecular basis of tubulin transport within the cilium by IFT74 and IFT81.

Cilium Conundrum The cilium has emerged as the antenna of eukaryotic cells, having numerous functions in sensory reception and developmental signaling. Several disorders, such as polycystic kidney disease, are the result of compromised cilia structure. Bhogaraju et al. (p. 1009) elucidate how the intraflagellar transport machinery recognizes tubulin, a ciliary cargo that is integral to cilium maintenance and formation and is constantly turned over at the cilium tip. Two proteins cooperate to promote tubulin transport to and into cilia. Intraflagellar transport (IFT) of ciliary precursors such as tubulin from the cytoplasm to the ciliary tip is involved in the construction of the cilium, a hairlike organelle found on most eukaryotic cells. However, the molecular mechanisms of IFT are poorly understood. Here, we found that the two core IFT proteins IFT74 and IFT81 form a tubulin-binding module and mapped the interaction to a calponin homology domain of IFT81 and a highly basic domain in IFT74. Knockdown of IFT81 and rescue experiments with point mutants showed that tubulin binding by IFT81 was required for ciliogenesis in human cells.

Architecture and function of IFT complex proteins in ciliogenesis

Cilia and flagella (interchangeable terms) are evolutionarily conserved organelles found on many different types of eukaryotic cells where they fulfill important functions in motility, sensory reception and signaling. The process of Intraflagellar Transport (IFT) is of central importance for both the assembly and maintenance of cilia, as it delivers building blocks from their site of synthesis in the cell body to the ciliary assembly site at the tip of the cilium. A key player in this process is the multi-subunit IFT-complex, which acts as an adapter between the motor proteins required for movement and the ciliary cargo proteins. Since the discovery of IFT more than 15 years ago, considerable effort has gone into the purification and characterization of the IFT complex proteins. Even though this has led to very interesting findings and has greatly improved our knowledge of the IFT process, we still know very little about the overall architecture of the IFT complex and the specific functions of the various subunits. In this review we will give an update on the knowledge of the structure and function of individual IFT proteins, and the way these proteins interact to form the complex that facilitates IFT.

Intraflagellar transport complex structure and cargo interactions

Intraflagellar transport (IFT) is required for the assembly and maintenance of cilia, as well as the proper function of ciliary motility and signaling. IFT is powered by molecular motors that move along the axonemal microtubules, carrying large complexes of IFT proteins that travel together as so-called trains. IFT complexes likely function as adaptors that mediate interactions between anterograde/retrograde motors and ciliary cargoes, facilitating cargo transport between the base and tip of the cilium. Here, we provide an up-to-date review of IFT complex structure and architecture, and discuss how interactions with cargoes and motors may be achieved.

Crystal Structure of the Intraflagellar Transport Complex 25/27.

The cilium is an important organelle that is found on many eukaryotic cells, where it serves essential functions in motility, sensory reception and signalling. Intraflagellar transport (IFT) is a vital process for the formation and maintenance of cilia. We have determined the crystal structure of Chlamydomonas reinhardtii IFT25/27, an IFT sub‐complex, at 2.6 Å resolution. IFT25 and IFT27 interact via a conserved interface that we verify biochemically using structure‐guided mutagenesis. IFT27 displays the fold of Rab‐like small guanosine triphosphate hydrolases (GTPases), binds GTP and GDP with micromolar affinity and has very low intrinsic GTPase activity, suggesting that it likely requires a GTPase‐activating protein (GAP) for robust GTP turnover. A patch of conserved surface residues contributed by both IFT25 and IFT27 is found adjacent to the GTP‐binding site and could mediate the binding to other IFT proteins as well as to a potential GAP. These results provide the first step towards a high‐resolution structural understanding of the IFT complex.

Intraflagellar transport proteins 172, 80, 57, 54, 38, and 20 form a stable tubulin-binding IFT-B2 complex

Intraflagellar transport (IFT) relies on the IFT complex and is required for ciliogenesis. The IFT‐B complex consists of 9–10 stably associated core subunits and six “peripheral” subunits that were shown to dissociate from the core structure at moderate salt concentration. We purified the six “peripheral” IFT‐B subunits of Chlamydomonas reinhardtii as recombinant proteins and show that they form a stable complex independently of the IFT‐B core. We suggest a nomenclature of IFT‐B1 (core) and IFT‐B2 (peripheral) for the two IFT‐B subcomplexes. We demonstrate that IFT88, together with the N‐terminal domain of IFT52, is necessary to bridge the interaction between IFT‐B1 and B2. The crystal structure of IFT52N reveals highly conserved residues critical for IFT‐B1/IFT‐B2 complex formation. Furthermore, we show that of the three IFT‐B2 subunits containing a calponin homology (CH) domain (IFT38, 54, and 57), only IFT54 binds αβ‐tubulin as a potential IFT cargo, whereas the CH domains of IFT38 and IFT57 mediate the interaction with IFT80 and IFT172, respectively. Crystal structures of IFT54 CH domains reveal that tubulin binding is mediated by basic surface‐exposed residues.

Biochemical mapping of interactions within the intraflagellar transport (IFT) B core complex: IFT52 binds directly to four other IFT-B subunits

Cilia and flagella are complex structures emanating from the surface of most eukaroytic cells and serve important functions including motility, signaling, and sensory reception. A process called intraflagellar transport (IFT) is of central importance to ciliary assembly and maintenance. The IFT complex is required for this transport and consists of two distinct multisubunit subcomplexes, IFT-A and IFT-B. Despite the importance of the IFT complex, little is known about its overall architecture. This paper presents a biochemical dissection of the molecular interactions within the IFT-B core complex. Two stable subcomplexes consisting of IFT88/70/52/46 and IFT81/74/27/25 were recombinantly co-expressed and purified. We identify a novel interaction between IFT70/52 and map the interaction domains between IFT52 and the other subunits within the IFT88/70/52/46 complex. Additionally, we show that IFT52 binds directly to the IFT81/74/27/25 complex, indicating that it could mediate the interaction between the two subcomplexes. Our data lead to an improved architectural map for the IFT-B core complex with new interactions as well as domain resolution mapping for several subunits.

Getting tubulin to the tip of the cilium: One IFT train, many different tubulin cargo-binding sites?

Cilia are microtubule‐based hair‐like structures that project from the surfaces of eukaryotic cells. Cilium formation relies on intraflagellar transport (IFT) to move ciliary proteins such as tubulin from the site of synthesis in the cell body to the site of function in the cilium. A large protein complex (the IFT complex) is believed to mediate interactions between cargoes and the molecular motors that walk along axonemal microtubules between the ciliary base and tip. A recent study using purified IFT complexes has identified a tubulin‐binding module in the two core IFT proteins IFT74 and IFT81 that likely serves to bind and transport tubulin within cilia. Here, we calculate the amount of tubulin required to support the observed cilium assembly kinetics and explore the possibility of multiple tubulin binding sites within the IFT complex.

Crystal structure of a Chlamydomonas reinhardtii flagellar RabGAP TBC-domain at 1.8 Å resolution.

Rab GTPases play a crucial role in the regulation of many intracellular membrane trafficking pathways including endocytosis and ciliogenesis. Rab GTPase activating proteins (RabGAPs) increase the GTP hydrolysis rate of Rab GTPases and turn them into guanine nucleotide diphosphate (GDP) bound inactive form. Here, we determined the crystal structure of the putative catalytic domain of a RabGAP (which we name CrfRabGAP) that is found in the flagellar proteome of the unicellular green alga Chlamydomonas reinhardtii. BLAST searches revealed potential human orthologues of CrfRabGAP as TBC1D3 and TBC1D26. Sequence and structural comparison with other canonical RabGAPs revealed that the CrfRabGAP does not contain the canonical catalytic residues required for the activation of Rab GTPases. The function of noncanonical RabGAPs‐like CrfRabGAP might be to serve as Rab effectors rather than activators. Proteins 2014; 82:2282–2287.

Crystal structure of a Chiamydomonas reirjharclui flagellar RabGAP TBC-domain at 1.8 angstrom resolution

Rab GTPases play a crucial role in the regulation of many intracellular membrane trafficking pathways including endocytosis and ciliogenesis. Rab GTPase activating proteins (RabGAPs) increase the GTP hydrolysis rate of Rab GTPases and turn them into guanine nucleotide diphosphate (GDP) bound inactive form. Here, we determined the crystal structure of the putative catalytic domain of a RabGAP (which we name CrfRabGAP) that is found in the flagellar proteome of the unicellular green alga Chlamydomonas reinhardtii. BLAST searches revealed potential human orthologues of CrfRabGAP as TBC1D3 and TBC1D26. Sequence and structural comparison with other canonical RabGAPs revealed that the CrfRabGAP does not contain the canonical catalytic residues required for the activation of Rab GTPases. The function of noncanonical RabGAPs‐like CrfRabGAP might be to serve as Rab effectors rather than activators. Proteins 2014; 82:2282–2287.

Crystal structure of aChlamydomonas reinhardtiiflagellar RabGAP TBC-domain at 1.8 Å resolution: Crystal Structure of CrfRabGAP

Rab GTPases play a crucial role in the regulation of many intracellular membrane trafficking pathways including endocytosis and ciliogenesis. Rab GTPase activating proteins (RabGAPs) increase the GTP hydrolysis rate of Rab GTPases and turn them into guanine nucleotide diphosphate (GDP) bound inactive form. Here, we determined the crystal structure of the putative catalytic domain of a RabGAP (which we name CrfRabGAP) that is found in the flagellar proteome of the unicellular green alga Chlamydomonas reinhardtii. BLAST searches revealed potential human orthologues of CrfRabGAP as TBC1D3 and TBC1D26. Sequence and structural comparison with other canonical RabGAPs revealed that the CrfRabGAP does not contain the canonical catalytic residues required for the activation of Rab GTPases. The function of noncanonical RabGAPs‐like CrfRabGAP might be to serve as Rab effectors rather than activators. Proteins 2014; 82:2282–2287.