Transmembrane signaling in cilia and flagella

Summary Ciliary and flagellar membranes are dynamic. Ciliary and flagellar membranes have diverged widely during evolution and perform many specialized functions. Transmembrane signaling is an important component of the function of ciliary and flagellar surfaces in general. In this review, I discuss some of the functions performed by ciliary and flagellar surfaces and I present three different ciliary and flagellar signaling systems associated with rather different dynamic events performed by ciliary and flagellar surfaces. Two of these are associated withChlamydomonas flagella and one is associated with vertebrate olfactory cilia. Calcium regulation of protein phosphorylation appears to be important in regulating glycoprotein movements in theChlamydomonas flagellar membrane. Changes in levels of cAMP and cAMP-dependent protein phosphorylation are clearly central to the signaling associated with mating events in gametic flagella ofChlamydomonas, although calcium clearly has an important, if poorly understood, role to play. There is no known role for G proteins in flagellar membrane events inChlamydomonas. In contrast, mammalian olfactory cilia possess an odorant activated, G protein regulated adenylate cyclase and conductance channels that are directly gated by cyclic nucleotides. A second class of odorants that do not affect adenylate cyclase activity appear to act through G protein activated phospholipase C and changes in IP₃ second messenger levels. These examples demonstrate the diversity in the signaling pathways associated with ciliary and flagellar membranes.Abbreviations CaPK-2 calcium-dependent protein kinase - db-cAMP dibutyryl cAMP - Fab fragment antigen binding - IgE immunoglobulin E - IP₃ myo-inositol trisphosphate - IP₄ myo-inositol tetrakisphosphate - OBP odorant binding protein - PIP₂ phosphoinositol bisphosphate - TFP trifluoperazine - WGA wheat germ agglutinin     

Molecular chaperones and protein folding in plants

Protein folding in vivo is mediated by an array of proteins that act either as foldases or molecular chaperones. Foldases include protein disulfide isomerase and peptidyl prolyl isomerase, which catalyze the rearrangement of disulfide bonds or isomerization of peptide bonds around Pro residues, respectively. Molecular chaperones are a diverse group of proteins, but they share the property that they bind substrate proteins that are in unstable, non-native structural states. The best understood chaperone systems are HSP70/DnaK and HSP60/GroE, but considerable data support a chaperone role for other proteins, including HSP100, HSP90, small HSPs and calnexin. Recent research indicates that many, if not all, cellular proteins interact with chaperones and/or foldases during their lifetime in the cell. Different chaperone and foldase systems are required for synthesis, targeting, maturation and degradation of proteins in all cellular compartments. Thus, these diverse proteins affect an exceptionally broad array of cellular processes required for both normal cell function and survival of stress conditions. This review summarizes our current understanding of how these proteins function in plants, with a major focus on those systems where the most detailed mechanistic data are available, or where features of the chaperone/foldase system or substrate proteins are unique to plants.     

Molecular chaperones in cellular protein folding

The discovery of “molecular chaperones” has dramatically changed our concept of cellular protein folding. Rather than folding spontaneously, most newly synthesized polypeptide chains seem to acquire their native conformation in a reaction mediated by these versatile helper proteins. Understanding the structure and function of molecular chaperones is likely to yield useful applications for medicine and biotechnology in the future.     

Molecular chaperones in protein quality control

Proteins must fold into their correct three-dimensional conformation in order to attain their biological function. Conversely, protein aggregation and misfolding are primary contributors to many devastating human diseases, such as prion-mediated infections, Alzheimer's disease, type II diabetes and cystic fibrosis. While the native conformation of a polypeptide is encoded within its primary amino acid sequence and is sufficient for protein folding in vitro, the situation in vivo is more complex. Inside the cell, proteins are synthesized or folded continuously; a process that is greatly assisted by molecular chaperones. Molecular chaperones are a group of structurally diverse and mechanistically distinct proteins that either promote folding or prevent the aggregation of other proteins. With our increasing understanding of the proteome, it is becoming clear that the number of proteins that can be classified as molecular chaperones is increasing steadily. Many of these proteins have novel but essential cellular functions that differ from that of more "conventional" chaperones, such as Hsp70 and the GroE system. This review focuses on the emerging role of molecular chaperones in protein quality control, i.e. the mechanism that rids the cell of misfolded or incompletely synthesized polypeptides that otherwise would interfere with normal cellular function.     

Making sense of cilia and flagella

Data reported at an international meeting on the sensory and motile functions of cilia, including the primary cilium found on most cells in the human body, have thrust this organelle to the forefront of studies on the cell biology of human disease.     

Molecular chaperones and protein quality control

In living cells, both newly made and preexisting polypeptide chains are at constant risk for misfolding and aggregation. In accordance with the wide diversity of misfolded forms, elaborate quality-control strategies have evolved to counter these inevitable mishaps. Recent reports describe the removal of aggregates from the cytosol; reveal mechanisms for protein quality control in the endoplasmic reticulum; and provide new insight into two classes of molecular chaperones, the Hsp70 system and the AAA+ (Hsp100) unfoldases.     

Molecular chaperones: structure of a protein disaggregase

The ring-forming molecular chaperone Hsp104/ClpB is a member of the AAA+ protein family which rescues proteins from aggregated states. The newly determined crystal structure of ClpB provides new insights into the mechanism of protein disaggregation, suggesting a crowbar activity mediated by a unique coiled-coil domain.     

Molecular chaperones and protein kinase quality control

The Hsp90-Cdc37 chaperone pair has special responsibility for folding of protein kinases. This function has made Hsp90 a target for new chemotherapeutic approaches, and several compounds are currently being tested for their ability to inhibit many different kinases simultaneously. Not all kinases are sensitive to these inhibitors, however, and this difference might depend on how each kinase interacts with Hsp90 and Cdc37 during folding of the nascent chain and thereafter. Indeed, several kinases require the persistent presence of both chaperones after initial folding and some of these kinases seem to be particularly sensitive to Hsp90 inhibitors. This requirement might relate to conformational changes that take place during the protein kinase activity cycle.     

Cryoelectron tomography of radial spokes in cilia and flagella

Radial spokes (RSs) are ubiquitous components in the 9 + 2 axoneme thought to be mechanochemical transducers involved in local control of dynein-driven microtubule sliding. They are composed of >23 polypeptides, whose interactions and placement must be deciphered to understand RS function. In this paper, we show the detailed three-dimensional (3D) structure of RS in situ in Chlamydomonas reinhardtii flagella and Tetrahymena thermophila cilia that we obtained using cryoelectron tomography (cryo-ET). We clarify similarities and differences between the three spoke species, RS1, RS2, and RS3, in T. thermophila and in C. reinhardtii and show that part of RS3 is conserved in C. reinhardtii, which only has two species of complete RSs. By analyzing C. reinhardtii mutants, we identified the specific location of subsets of RS proteins (RSPs). Our 3D reconstructions show a twofold symmetry, suggesting that fully assembled RSs are produced by dimerization. Based on our cryo-ET data, we propose models of subdomain organization within the RS as well as interactions between RSPs and with other axonemal components.     

1001 model organisms to study cilia and flagella

Most mammalian cell types have the potential to assemble at least one cilium. Immotile cilia participate in numerous sensing processes, while motile cilia are involved in cell motility and movement of extracellular fluid. The functional importance of cilia and flagella is highlighted by the growing list of diseases due to cilia defects. These ciliopathies are marked by an amazing diversity of clinical manifestations and an often complex genetic aetiology. To understand these pathologies, a precise comprehension of the biology of cilia and flagella is required. These organelles are remarkably well conserved throughout eukaryotic evolution. In this review, we describe the strengths of various model organisms to decipher diverse aspects of cilia and flagella biology: molecular composition, mode of assembly, sensing and motility mechanisms and functions. Pioneering studies carried out in the green alga Chlamydomonas established the link between cilia and several genetic diseases. Moreover, multicellular organisms such as mouse, zebrafish, Xenopus, Caenorhabditis elegans or Drosophila, and protists such as Paramecium, Tetrahymena and Trypanosoma or Leishmania each bring specific advantages to the study of cilium biology. For example, the function of genes involved in primary ciliary dyskinesia (due to defects in ciliary motility) can be efficiently assessed in trypanosomes.     

Molecular chaperones involved in chloroplast protein import.

Transport of cytoplasmically synthesized precursor proteins into chloroplasts, like the protein transport systems of mitochondria and the endoplasmic reticulum, appears to require the action of molecular chaperones. These molecules are likely to be the sites of the ATP hydrolysis required for precursor proteins to bind to and be translocated across the two membranes of the chloroplast envelope. Over the past decade, several different chaperones have been identified, based mainly on their association with precursor proteins and/or components of the chloroplast import complex, as putative factors mediating chloroplast protein import. These factors include cytoplasmic, chloroplast envelope-associated and stromal members of the Hsp70 family of chaperones, as well as stromal Hsp100 and Hsp60 chaperones and a cytoplasmic 14-3-3 protein. While many of the findings regarding the action of chaperones during chloroplast protein import parallel those seen for mitochondrial and endoplasmic reticulum protein transport, the chloroplast import system also has unique aspects, including its hypothesized use of an Hsp100 chaperone to drive translocation into the organelle interior. Many questions concerning the specific functions of chaperones during protein import into chloroplasts still remain that future studies, both biochemical and genetic, will need to address.     

Ca2+ channels and signalling in cilia and flagella

Ca(2+) plays a key role in the regulation of ciliary and flagellar movement. This article focuses on the initial steps of this regulation: how and where Ca(2+) enters cilia and flagella to trigger specific changes in axonemal motility. This knowledge is fundamental for understanding the sites, molecular targets and mechanisms of action of Ca(2+) within the cilium of flagellum.     

On the numbering of peripheral doublets in cilia and flagella

The nine microtubular doublets of cilia and flagella have distinctive features that make it possible to assign an index number to each of them. Such an indexing has been used for a long time for animal cilia and flagella, whereas other indexing systems have been proposed recently for plant cilia. It is shown here that the similarity between cilia from animals and cilia from plants and protists is so great that the same indexing system can be used for all cilia regardless of their derivation.     

Peroxiredoxin 1 is involved in disassembly of flagella and cilia

Cilia/flagella are evolutionarily conserved cellular organelles. In this study, we demonstrated that Dunaliella salina Peroxiredoxin 1 (DsPrdx1) localized to the flagella and basal bodies, and was involved in flagellar disassembly. The link between DsPrdx1 and flagella of Dunaliella salina (D. salina) encouraged us to explore the function of its human homologue, Homo sapiens Peroxiredoxin 1 (HsPrdx1) in development and physiology. Our results showed that HsPrdx1 was overexpressed, and cilia were lost in esophageal squamous cell carcinoma (ESCC) cells compared with the non-cancerous esophageal epithelial cells Het-1A. Furthermore, when HsPrdx1 was knocked down by short hairpin RNA (shRNA) lentivirus in ESCC cells, the phenotype of cilia lost can be reversed, and the expression levels of tumor suppressor genes LKB1 and p-AMPK were increased, and the activity of the oncogene Aurora A was inhibited compared with those in cells transfected with scrambe-shRNA lentivirus. These findings firstly showed that Prdx1 is involved in disassembly of flagella and cilia, and suggested that the abnormal expression of the cilia-related gene including Prdx1 may affect both ciliogenesis and cancernogenesis.