9 2 Arrangement Of Flagella

Common cold Spring Harb Perspect Biol. 2017 Feb; 9(two): a028118.

The Central Apparatus of Cilia and Eukaryotic Flagella

Abstruse

The motile cilium is a circuitous organelle that is typically comprised of a 9+2 microtubule skeleton; ix doublet microtubules surrounding a pair of central singlet microtubules. Like the doublet microtubules, the fundamental microtubules course a scaffold for the assembly of poly peptide complexes forming an intricate network of interconnected projections. The central microtubules and associated structures are collectively referred to as the central apparatus (CA). Studies using a diversity of experimental approaches and model organisms have led to the discovery of a number of highly conserved protein complexes, unprecedented high-resolution views of projection structure, and new insights into regulation of dynein-driven microtubule sliding. Here, nosotros review recent progress in defining mechanisms for the assembly and role of the CA and include possible implications for the importance of the CA in human wellness.

Motile cilia and eukaryotic flagella are characterized by the canonical "9+2" arrangement of microtubules in which 9 doublet microtubules surround a primal pair of singlet microtubules. These key microtubules and their associated poly peptide projections are collectively referred to every bit the cardinal apparatus (CA) (Fig. one). Although there are a few exceptions to the 9+2 arrangement of microtubules, the CA is remarkably well conserved throughout eukaryotes and is idea to have been present in cilia of the last mutual eukaryotic ancestor (Mitchell 2004). Since researchers first discovered the nearly crystalline arrangement of proteins that course the axoneme, they have tried to answer two central questions: How exercise these structures assemble? What is their role in motility? Answering these questions has required a sophisticated assortment of structural, biochemical, genetic, and functional approaches. Hither, nosotros review new insights into the structure and composition of the CA, possible mechanisms for associates, and the role of the CA in regulating ciliary and flagellar motility.

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Fundamental appliance (CA) structure. (A) Transmission electron microscopy (TEM) paradigm of an axoneme transverse section from Chlamydomonas reinhardtii. The central microtubules and their associated projections are surrounded past the outer doublet microtubules. (B) Diagram of axoneme transverse section seen in A. (C) Diagram of CA with projections labeled. DMT, Doublet microtubule; IDA, inner dynein arm; ODA, outer dynein arm; RS, radial spoke.

CENTRAL APPARATUS Structure

Unlike the nine doublet microtubules, the microtubules of the CA are not continuous with the basal body. The primal microtubules extend from a region nigh the transition zone, elongate beyond the doublet microtubules, and end in a capping structure at the tip of the cilium (Ringo 1967; Dentler and Rosenbaum 1977; Dentler 1984). This cap has not been biochemically characterized, but structurally it contains two major components: a "bead" attached to the membrane, and two plates attached to the central microtubules (Dentler 1984). Each microtubule of the CA is structurally and biochemically distinct (reviewed below) and are referred to as C1 and C2. The portions of the cardinal microtubules that extend across the outer doublets are devoid of poly peptide projections (Ringo 1967). In add-on to protein projections associated with the surface of the microtubules, the Nicastro laboratory has shown that the internal lumen of the C2 microtubule of Chlamydomonas contains two small densities (Carbajal-Gonzalez et al. 2013), which they refer to as microtubule inner proteins, or MIPs, named MIP-C2a and MIP-C2b. MIP-C2a repeats every 16 nm and is 50 kDa in size, whereas MIP-C2b has an 8-nm periodicity and is but 35 kDa in size. These proteins are non seen in the flagella of sea urchin Strongylocentrotus purpuratus sperm, maybe indicating a specialization unique to Chlamydomonas cilia (Carbajal-Gonzalez et al. 2013).

Advances in electron microscopy (EM) in the 1960s and 1970s opened the door to our electric current agreement of CA structure. Using both Chlamydomonas and Tetrahymena, early work identified structural differences in the CA projections (Chasey 1969; Hopkins 1970). The microtubule with longer projections was termed C1, and the other C2. The longest projections on C1 are designated C1a and C1b and accept a xvi-nm echo period along the length of C1. The prominent projections on C2 (C2a and C2b) have the same 16-nm repeat period. Afterward work using the newly developed rapid-freeze deep-etch method of EM revealed additional complexities including a sheath-like structure surrounding the CA (Goodenough and Heuser 1985). Advances in digital imaging and epitome-averaging techniques led to the discovery of smaller projections on both primal microtubules: C2c repeating every xvi nm, and C1c and C1d that repeat every 32 nm (Mitchell and Sale 1999; Mitchell 2003b). The central microtubules are held together past a bridging construction that repeats at 16-nm intervals and is likely involved in CA stability (see section on Composition of the Central Apparatus).

Recent application of cryo-electron tomography (cryo-ET) has provided unprecedented views of CA structure and revealed four entirely new protein projections termed C1e, C1f, C2d, and C2e (Fig. 2) (Carbajal-Gonzalez et al. 2013). These new views indicate that the projections actually form a continuous network surrounding the two central microtubules and may explicate the sheath structure observed in previous studies (Carbajal-Gonzalez et al. 2013).

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Detailed structural elements of the fundamental appliance (CA). Isosurface renderings derived from cryo-electron tomography (cryo-ET) of the Chlamydomonas CA viewed in transverse department. The projections form an interconnected network surrounding the two singlet microtubules with connections between C1a and C2a and C1b and C2b. The bridge construction connecting the 2 microtubules is in gray. MIP-C2a is highlighted inside the lumen of the C2 microtubule. The projections labeled C1e, C1f, C2d, and C2e likely correspond to the fabric previously described as a sheath. (From Carbajal-Gonzalez et al. 2013; reprinted, with permission, from Wiley.)

Finally, the entire CA structure is known to twist in a left-handed helix (Omoto and Kung 1980; Kamiya 1982; Goodenough and Heuser 1985; Mitchell and Nakatsugawa 2004). This helix contains i 360° twist over the length of the Chlamydomonas cilium, whereas in Paramecium the number of twists per cilium length varies (Omoto and Kung 1980; Kamiya 1982). CA twist in Chlamydomonas occurs with or without RS heads, indicating that twist is not due to CA contact with the RSs (Mitchell and Nakatsugawa 2004). In add-on, CAs extruded from the axoneme retain a helical structure (Kamiya 1982). The part of this twist is unknown, merely it may have a role in regulating movement.

COMPOSITION OF THE Primal Appliance

Our current agreement of the composition of the projections is largely based on biochemical approaches and written report of Chlamydomonas mutants (for example, Witman et al. 1978; Adams et al. 1981). In ane form of mutants, the entire CA fails to get together (pf15, pf18, pf19, and pf20); these mutants have immotile flagella. The identity of the PF18 factor is unknown; however, the other 3 loci take been studied extensively. PF20 is a WD repeat-containing protein localized to the bridge structure connecting the 2 central microtubules and is hypothesized to stabilize the central tubules (Smith and Lefebvre 1997). PF15 and PF19, encode the p80 and p60 subunits, respectively, of the microtubule-severing protein katanin (Dymek et al. 2004; Dymek and Smith 2012) (see section on Associates of the Cardinal Appliance for further discussion of PF15 and PF19).

The second form of Chlamydomonas mutants lack subsets of CA projections and includes pf6, cpc1, and pf16. The C1a projection is defective from pf6 flagella (Dutcher et al. 1984). PF6 encodes a large (240-kDa) poly peptide that contains numerous proline-rich domains (Rupp et al. 2001). Additional biochemical studies led to the discovery of a PF6-containing complex that includes calmodulin (CaM) and 4 other proteins (Tabular array 1). The PF6 protein probable plays a scaffolding role in the assembly of this complex to form C1a (Wargo et al. 2005).

Tabular array ane.

Proteins associated with the fundamental apparatus

Structure/localization	Protein	Molecular mass (kDa)	Accession number	Description	References
C1a projection	PF6^a	240	{"type":"entrez-protein","attrs":{"text":"AAK38270","term_id":"13676773","term_text":"AAK38270"}}AAK38270	Contains alanine-proline rich domains; ASH domain	Rupp et al. 2001; Wargo et al. 2005
	C1a-86	86	{"type":"entrez-protein","attrs":{"text":"AAZ31187","term_id":"71384457","term_text":"AAZ31187"}}AAZ31187	Contains a PKA RII-like LRR domain	Wargo et al. 2005
	C1a-34	34	{"type":"entrez-protein","attrs":{"text":"AAZ31186","term_id":"71384450","term_text":"AAZ31186"}}AAZ31186	Contains a coiled-coil region	Wargo et al. 2005
	C1a-32	32	{"type":"entrez-protein","attrs":{"text":"AAZ31185","term_id":"71384437","term_text":"AAZ31185"}}AAZ31185	Similar to C1a-34	Wargo et al. 2005
	C1a-xviii	eighteen	{"blazon":"entrez-protein","attrs":{"text":"AAZ31184","term_id":"71384428","term_text":"AAZ31184"}}AAZ31184	Contains MORN domains	Wargo et al. 2005
	Calmodulin	eighteen	{"type":"entrez-poly peptide","attrs":{"text":"AAA33083","term_id":"167411","term_text":"AAA33083"}}AAA33083	Calcium-binding protein	Wargo et al. 2005
C1b projection	CPC1	265	{"type":"entrez-protein","attrs":{"text":"AAT40992","term_id":"48249492","term_text":"AAT40992"}}AAT40992	Contains EF-hand domain; adenylate kinase domains	Zhang and Mitchell 2004; Mitchell et al. 2005
	C1b-350 (FAP42)	350	{"blazon":"entrez-protein","attrs":{"text":"EDP00757","term_id":"158274977","term_text":"EDP00757"}}EDP00757	Contains 5 guanylate kinase domains; i adenylate kinase domain	Mitchell et al. 2005
	C1b-135 (FAP69)	135	{"type":"entrez-protein","attrs":{"text":"EDP06190","term_id":"158280432","term_text":"EDP06190"}}EDP06190	Armadillo echo-containing protein	Mitchell et al. 2005
	HSP70	78	{"blazon":"entrez-poly peptide","attrs":{"text":"P25840","term_id":"24638460","term_text":"P25840"}}P25840	Chaperone/heat shock poly peptide	Zhang and Mitchell 2004; Mitchell et al. 2005
	Enolase	56	{"type":"entrez-poly peptide","attrs":{"text":"P13683","term_id":"123091","term_text":"P13683"}}P13683	Glycolytic enzyme	Mitchell et al. 2005
C1d projection	Pcdp1 (FAP221)^a	100	{"type":"entrez-protein","attrs":{"text":"ADD85929","term_id":"344222107","term_text":"ADD85929"}}ADD85929	Calmodulin-bounden protein	DiPetrillo and Smith 2010
	FAP54	318	{"type":"entrez-protein","attrs":{"text":"AFG30957","term_id":"382929942","term_text":"AFG30957"}}AFG30957	Contains no known functional domains	DiPetrillo and Smith 2010
	FAP46	289	{"blazon":"entrez-protein","attrs":{"text":"AFG30956","term_id":"382929940","term_text":"AFG30956"}}AFG30956	Contains no known functional domains	DiPetrillo and Smith 2010
	FAP74	204	{"type":"entrez-poly peptide","attrs":{"text":"ADD85930","term_id":"291264234","term_text":"ADD85930"}}ADD85930	Contains no known functional domains	DiPetrillo and Smith 2010
	C1d-87	87	{"blazon":"entrez-protein","attrs":{"text":"EDP09774","term_id":"158284024","term_text":"EDP09774"}}EDP09774	WD echo-containing poly peptide	Chocolate-brown et al. 2012
C1 microtubule	PF16^a	57	{"type":"entrez-protein","attrs":{"text":"AAC49169","term_id":"1101777","term_text":"AAC49169"}}AAC49169	Armadillo echo-containing protein	Dutcher et al. 1984; Smith and Lefebvre 1996
	PP1c	35	{"type":"entrez-poly peptide","attrs":{"text":"AAD38850","term_id":"5053101","term_text":"AAD38850"}}AAD38850	Phosphatase	Yang et al. 2000
	C1 kinesin	110		Kinesin-like protein	Fox et al. 1994
C1–C2 span	PF20^a	63	{"blazon":"entrez-protein","attrs":{"text":"AAB41727","term_id":"1813638","term_text":"AAB41727"}}AAB41727	WD echo-containing protein	Smith and Lefebvre 1997
C2b project	Hydin^a	540	{"type":"entrez-protein","attrs":{"text":"EDP09735","term_id":"158283985","term_text":"EDP09735"}}EDP09735	Contains iv ASH domains	Lechtreck and Witman 2007
C2c project	KLP1	96	{"type":"entrez-protein","attrs":{"text":"P46870","term_id":"1170672","term_text":"P46870"}}P46870	Kinesin-like protein	Bernstein et al. 1994; Yokoyama et al. 2004
Other	Katanin p60	threescore	{"type":"entrez-poly peptide","attrs":{"text":"AAF12877","term_id":"6466293","term_text":"AAF12877"}}AAF12877	Catalytic subunit of katanin; AAA ATPase	Dymek and Smith 2012
Other	Katanin p80	lxxx	{"type":"entrez-poly peptide","attrs":{"text":"EDP00085","term_id":"158274302","term_text":"EDP00085"}}EDP00085	Regulatory subunit of katanin; WD repeat-containing poly peptide	Dymek et al. 2004

The C1b project is lacking in cpc1 flagella (Mitchell and Sale 1999). These mutant flagella often lack portions of the C2b projection as well, possibly indicating structural connections between these two projections (Mitchell and Sale 1999; Zhang and Mitchell 2004). CPC1 is a 265-kDa protein composed of an EF-hand domain and an adenylate kinase domain. Along with CPC1, the C1b projection contains four other identified proteins including the chaperone protein HSP70 and the glycolytic enzyme enolase, which were identified through cosedimentation in sucrose gradients (Table 1) (Mitchell et al. 2005).

Mutations in PF16 cause the disassembly of the C1 microtubule when flagella are demembranated (Dutcher et al. 1984). PF16 is a 57-kDa protein equanimous of eight continuous armadillo repeat motifs (Smith and Lefebvre 1996, 2000). Armadillo repeats are involved in poly peptide–protein interactions (Peifer et al. 1994), suggesting that PF16 forms complexes that stabilize the C1 microtubule. The pf16 mutant has been invaluable for defining the composition of C1 and C2. Proteins that remain associated with the axoneme in a pf16 mutant are good candidates for C2-associated proteins.

Biochemical approaches have revealed the identities of additional CA-associated proteins. Experiments designed to place axonemal CaM interacting proteins led to the discovery of a second CaM-containing circuitous of 5 proteins associated with C1 (Table 1) (DiPetrillo and Smith 2010). When expression of complex components is reduced, the C1d projection fails to assemble and the cells bear witness uncoordinated flagellar movement (DiPetrillo and Smith 2010). A strain with a mutation in a single complex component has the same phenotype (Brownish et al. 2012). Furthermore, the C1d poly peptide FAP221 is homologous to the mouse primary ciliary dyskinesia protein 1 (see section on Central Apparatus in Mammalian Health and Human Disease) (Lee et al. 2008; DiPetrillo and Smith 2010).

2 other proteins are associated with the C1 microtubule. Protein phosphatase 1 was identified in cilia from Paramecium and Chlamydomonas (Friderich et al. 1992; Yang et al. 2000). In addition, a 110-kDa kinesin has been localized to C1 through the use of mutants and polyclonal antibodies (Fox et al. 1994; Johnson et al. 1994). Localization of these proteins to specific projections has non been adamant.

Two proteins have been assigned to C2 projections: KLP1 and Hydin. The report that led to the discovery of the 110-kDa C1 kinesin, also led to the identification of KLP1 (Fox et al. 1994; Johnson et al. 1994). KLP1 is tightly spring to the axoneme in a pf16 mutant, thereby localizing it to the C2 microtubule (Bernstein et al. 1994). KLP1 is a member of the kinesin-9 family of proteins and when its expression is knocked down, the C2c projection and a portion of the C2b projection neglect to assemble (Yokoyama et al. 2004).

Although many studies in Chlamydomonas accept preceded the identification of mammalian homologs (encounter section on Central Apparatus in Mammalian Wellness and Man Disease), a written report in mammals led to the discovery of Hydin. Mice that take the hy3 mutation in the Hydin gene prove hydrocephalus (Davy and Robinson 2003). Furthermore, similar mutations in trypanosomes pb to motility defects (Broadhead et al. 2006). Knockdown of Hydin in Chlamydomonas causes the failure of the C2b project to assemble and, in some instances, the destabilization of the C1b and C2c projections too (Lechtreck and Witman 2007). As noted above, the destabilization of the C1b projection due to mutations in CPC1 leads to the reciprocal destabilization of the C2b projection (Mitchell and Sale 1999; Yokoyama et al. 2004; Lechtreck and Witman 2007). Based on its size, Hydin may human activity as a scaffold for other CA-associated proteins.

ASSEMBLY OF THE CENTRAL Appliance

Mutants that fail to get together the entire CA have contributed to our understanding of CA assembly. Although PF20 has been implicated in stabilizing the central microtubules, katanin may play a direct function in the formation of the cardinal microtubules. Katanin is a hexameric protein composed of an AAA ATPase catalytic subunit (p60, encoded by the PF19 gene) and a regulatory subunit with WD echo domains (p80, encoded by the PF15 gene) (Hartman et al. 1998; Dymek et al. 2004; Dymek and Smith 2012). Mutations in either subunit yield a central pairless phenotype. Katanin severs microtubules by the bounden of its p60 hexamer to tubulin, whereas the p80 subunit potentially targets and enhances this activity (Hartman et al. 1998; McNally et al. 2000). The pf19 mutation inhibits the microtubule-severing activity of the p60 subunit (Dymek and Smith 2012). Therefore, severing activity is necessary for the assembly of the central tubules. It seems paradoxical that the assembly of microtubules requires microtubule-severing activity; however, in that location is precedent for katanin's involvement in the formation of noncentrosomal microtubule arrays in plants and neurons (Karabay et al. 2004; Yu et al. 2005; Gardiner and Marc 2011). Recall that the key microtubules are non nucleated from the basal body and are also noncentrosomal microtubules.

Several other proteins are linked to central microtubule assembly. Studies in Drosophila identified the basal trunk poly peptide Bld10p/CEP135 equally important for associates. Bld10p is localized to the primal cartwheel structure of the basal body (Carvalho-Santos et al. 2012). In Drosophila, a single microtubule exists before the formation of the central microtubules and is stabilized by Bld10p. Presumably, the stabilization of this microtubule is necessary for the eventual germination of ii central microtubules (Carvalho-Santos et al. 2012). Information technology is unknown whether the requirement for Bld10p in CA assembly is unique to Drosophila.

RNA interference has revealed that γ-tubulin and its associated ring complex are necessary for CA assembly in trypanosomes (McKean et al. 2003; Zhou and Li 2015). In addition, in Tetrahymena, central pair formation depends on the glycylation domain of β-tubulin and if this domain is mutated, cilia are short and neglect to form central microtubules (Thazhath et al. 2004). Three possible roles for glycylation have been proposed. Commencement, glycylation may be necessary for intraflagellar transport (IFT)-mediated ship of CA proteins (Thazhath et al. 2004). Curt doublet microtubules, just not fundamental pair microtubules, assemble in Tetrahymena IFT mutants and in sea urchin eggs in which IFT was inhibited by antibodies (Brownish et al. 1999, 2003). Perhaps glycylation is necessary for tubulin'due south clan with anterograde IFT particles. Second, glycylation may be necessary for central microtubule nucleation at the transition zone (Thazhath et al. 2004). Finally, β-tubulin glycylation may stabilize the growing distal ends of the central microtubules or mediates associations with cap-specific proteins (Thazhath et al. 2004).

Why has development favored a pair of singlet key microtubules? The answer may be as unproblematic as infinite dependence. Chlamydomonas pf14 mutants lack RSs; therefore, the eye of the axoneme contains more than empty infinite than in wild-type. Mutant pf14 axonemes have been observed to contain 2 pairs of central microtubules with identical and right polarities and complete poly peptide projections (Lechtreck et al. 2013). Another example includes mutations in BLD12. Bld12p is the Chlamydomonas homolog of Sas6 in Caenorhabditis elegans and forms the cartwheel structure of the basal body that establishes ninefold symmetry (Nakazawa et al. 2007). Mutations in BLD12 cause misshaped basal bodies that can manifest as an expansion of the axonemal diameter; in these cases, a corresponding increment in the number of CAs is observed (Nakazawa et al. 2014). These results provide evidence that the number of CAs that assemble may exist determined by the commanded infinite within the axoneme. A primal question remains: Why is the CA typically a pair of microtubules as opposed to a unmarried or 3 or more than microtubules?

Assembly and targeting of the CA projections to the key microtubules is as well an active area of enquiry. Several ciliary structures, including dynein arm and RS components, form preassembly complexes in the cytoplasm that are and so transported into the cilium (Fowkes and Mitchell 1998; Diener et al. 2011; Viswanadha et al. 2014). Do CA proteins assemble in preassembly complexes earlier targeting to the axoneme? Proteins are transported into the cilium in one of two ways: IFT or diffusion. Are CA projection proteins transported through IFT or diffusion?

These questions take recently been studied in Chlamydomonas flagellar regeneration and dikaryon rescue experiments performed in the Lechtreck laboratory (Lechtreck et al. 2013; Wren et al. 2013). Observations of flagellar regeneration accept revealed time-dependent assembly in which the projections gather onto the central microtubules earlier dynein arm assembly, despite the ascertainment that the central microtubules form subsequently the outer doublets. Interestingly, the direction of associates depends on whether the cell is in the procedure of de novo flagellar assembly (regeneration) or if the CA is assembling in an assembled central pairless axoneme (dikaryon rescue). In regenerating flagella, central microtubule growth begins proximal to the transition zone and continues distally. Still, in dikaryon rescue experiments using pf15 or pf19 cells, subdistal microtubule associates occurred with projection proteins assembling tip to base. These observations indicate that the CA is capable of assembling contained of other structures in the axoneme and that microtubule nucleation tin can occur from either distal or proximal regions of the flagellum. This laboratory has also shown that PF16 uses IFT to enter the cilium suggesting that other CA proteins may besides (Wren et al. 2013).

Fundamental Apparatus Role

The loftier degree of CA conservation in motile cilia implies that at that place is selective pressure for motile cilia to retain the 9+2 microtubule construction. All the same, is the CA really necessary for motility? There are examples of motile cilia that lack a CA. For instance, the mature male gametes of the alga Lithodesmium undulatum contain a nine+0 microtubule system and are fully motile (Manton 1966; Carvalho-Santos et al. 2011). The protozoan Lecudina tuzetae and the arthropod Acerentomon microrhinus accept more than extreme versions of alternate yet motile axonemal structure with six+0 and 14+0, respectively (Schrevel and Besse 1975; Dallai et al. 2010; Carvalho-Santos et al. 2011). In addition, the nodal cilia present during mammalian development have a 9+0 structure and show a more than rotational motility rather than the more than planar symmetric and asymmetric waveforms typical of other flagella and cilia (Nonaka et al. 1998).

Examples of motile cilia that lack a CA are rare. Furthermore, in organisms with motile cilia that assemble a CA, the CA is required for motility. Equally noted above, central pairless mutants of Chlamydomonas prove complete flagellar paralysis. In add-on, mutations in which CA projections are absent too show abnormal flagellar motion. The pf6 mutant flagella defective C1a twitch ineffectively (Rupp et al. 2001) and mutants missing just the carboxy terminus of PF6 are paralyzed as well (Goduti and Smith 2012). The flagella of cpc1 mutants shell at 40 Hz instead of 60 Hz and take axonemes that switch waveforms when exposed to high concentrations of calcium (Mitchell and Auction 1999). Mutations affecting C1d cause slow swimming. In improver, the flagella of these cells are uncoordinated and beat at a frequency of ∼30% that of wild-type (DiPetrillo and Smith 2010, 2011). Hydin mutants missing C2b are locked in a position in which one flagellum is oriented forth the cell body, whereas the other extends away from it in a "easily up/easily down" conformation and mice missing this projection prove cilia stalling (Lechtreck and Witman 2007; Lechtreck et al. 2008). Finally, pf16 flagella are lacking only three proteins still are completely paralyzed (Dutcher et al. 1984). These findings are not limited to Chlamydomonas. Defects in the mammalian CA, like in Hydin mutants, have likewise been shown to affect movement (see department on Key Appliance in Mammalian Health and Human Illness).

Extragenic suppressor mutations that restore movement to paralyzed CA mutants (and RS defective mutants) without restoring the missing CA structures accept provided of import genetic evidence of a mechanism for the CA'southward role in regulating motility (Huang et al. 1982). The suppressor mutations are institute in components of the inner and outer dynein arms along with the N-DRC and propose a regulatory pathway by which the CA regulates dynein activeness through the RSs and regulatory complexes located on the doublet microtubules (Huang et al. 1982; Piperno et al. 1992, 1994; Porter et al. 1992, 1994). Yet, it is of import to annotation that the CA and RS mutants carrying suppressor mutations produce symmetric waveforms of reduced amplitude and beat frequency (Brokaw et al. 1982). This implicates the CA and RSs in the production of proper waveforms necessary for forward swimming.

Despite flagellar paralysis, dynein arms of CA mutants retain their force-generating backdrop. Using a sliding disintegration analysis in which microtubule sliding is uncoupled from flagellar bending, dynein action can be quantified as microtubule sliding velocity (Summers and Gibbons 1971; Okagaki and Kamiya 1986). Using this assay, pf18 and pf15 mutant axonemes have been shown to accept reduced sliding velocities compared with wild-type (Smith 2002b). Plain, dynein activity is reduced in these mutants. Reduced sliding velocities are as well observed for pf16 mutant axonemes showing the importance of the C1 microtubule in regulating dynein. Combining the sliding assay with structural studies has shown that the position of the CA correlates with the position of active doublet sliding (Yoshimura and Shingyoji 1999; Wargo and Smith 2003).

The sliding disintegration assay has also revealed transduction pathways that include second messengers, and kinases and phosphatases anchored to the axoneme. Several studies take shown a link between the CA and regulation of inner dynein arms through axonemal kinases and phosphatases (Smith and Auction 1992; Howard et al. 1994; Habermacher and Sale 1996; Yang and Sale 2000; Kikushima 2009). These studies have been reviewed in Wirschell et al. (2011). A relationship between calcium regulation of motion and the CA has also been shown. For instance, increased intraflagellar calcium concentrations tin can increment sliding velocity in key pairless mutants, only not pf16 axonemes (Smith 2002a). Studies of sea urchin sperm too show the importance of calcium signaling through the CA in the localized sliding of specific subsets of doublet microtubules (Nakano et al. 2003). Piece of work in Chlamydomonas indicates that these changes are mediated by axoneme-associated CaM (Smith 2002a) and that CaM is associated with both the C1a and C1d projections (Wargo et al. 2005; DiPetrillo and Smith 2009, 2010). These studies provide testify of a role for the CA in calcium regulation of motility.

Although these studies provide a strong correlation between the CA and regulating microtubule sliding, they practise not provide a mechanism for how this regulation is converted to complex ciliary waveforms. Given the location of the CA in relation to the dynein artillery, CA signals would likely exist mediated by the RSs. This idea was first supported by structural studies of Elliptio gill cilia in which the RS heads brand transient contact with the projections of the CA, causing a tilt in the RSs relative to the longitudinal axis of the cilium (Warner and Satir 1974). RS–CA interactions may also occur in protozoan organisms whose CA rotates during bend propagation (Omoto and Kung 1980; Omoto et al. 1999; Mitchell 2003a). Fifty-fifty though this rotation has been shown to be a passive response to flagellar bending, rotation and twist of the CA may provide of import positional cues that are transmitted via the spokes (Mitchell and Nakatsugawa 2004).

These studies raise the question of whether the CA provides biochemical or mechanical cues or both to regulate microtubule sliding. What is the human relationship between specific poly peptide projections and this regulation? Of the CA projections, C1d is preferentially oriented toward areas of active microtubule sliding (Wargo and Smith 2003; DiPetrillo and Smith 2011). Furthermore, axonemes with expanded diameters show preferential binding between the RSs and specific C1 projections; i site most C1a and one near C1b (Nakazawa et al. 2014). Removing C1a and C1b reveals weaker, even so still seemingly specific, interactions between RS heads and the CA (Nakazawa et al. 2014). These studies indicate that there is specificity in RS–CA interactions; however, a recent report suggests otherwise. Past technology epitope tags on RS heads, Kikkawa's grouping rescued movement in pf6 mutants defective C1a (Oda et al. 2014). The tag extended the RS across the gap creating an artificial interaction that reconstituted motility. These results suggest CA regulation may not crave specific CA–RS interactions but may rely on nonspecific mechanosignaling. Further inquiry is required to reconcile these seemingly conflicting studies.

Additional mechanisms for CA regulation of motility take been proposed from mathematical modeling approaches practical to beating cilia and flagella. Mathematical modeling of sperm flagellar bending led to a "geometric clutch" model (Lindemann 1994; Lindemann and Kanous 1995). In this model, the formation of dynein cross-bridges is limited by the space between doublet microtubules. Therefore, only a subset of dynein tin can be active at whatsoever given fourth dimension. When cross-bridges form, microtubule sliding is induced causing axonemal distortions that result in dynein cantankerous bridges on one side of the axoneme to release and dynein cross-bridges on the opposite side of the axoneme to grade (Lindemann and Mitchell 2007). Bending of the flagellum occurs due to switching of cantankerous-bridge germination and release. In this model, the CA and RSs transmit a transverse force during the switch point (Lindemann 2003). Still, the force-begetting capacity of the CA is unknown and must be determined to understand how the t-force is distributed in the axoneme (Lindemann 2007). For a recent summary of this model, see Lindemann and Lesich (2015).

One surprising contribution the CA may make in regulating motion is maintaining stable intraciliary ATP levels. The CPC1 protein contains an adenylate kinase domain. CPC1-defective mutants take 64% the crush frequency of wild-type flagella, potentially due to a lack of ATP production from recycled ADP. When mutant axonemes are saturated with ATP in flagellar reactivation assays, crush frequency is returned to 90% that of wild-type (Zhang and Mitchell 2004). Reactivation of beating despite the lack of CPC1 in these flagella indicates that in that location are potentially other adenylate kinases to be discovered in the axoneme.

THE Central Appliance IN MAMMALIAN Wellness AND Human being DISEASE

1 of the most phenomenal findings in cell biology in the past few decades is the identification of diseases that are acquired by ciliary defects known collectively as ciliopathies (Braun and Hildebrandt 2016). These defects can exist in either motile or nonmotile cilia. Here, we focus on proteins in motile cilia that when lacking cause illness in mammals.

In mammalian motile cilia, three proteins with Chlamydomonas homologs are believed to form a circuitous: Spag16 (PF20), Spag6 (PF16), and Spag17 (PF6) (Zhang et al. 2005). Each member of this putative "interactome" is essential for proper ciliary motility and mammalian health. The mammalian homolog of PF20, Spag16, occurs in two isoforms: Spag16L, localized to the cilium and Spag16S, localized to the nucleus (Zhang et al. 2006). Spag16 is essential for male fertility by regulating sperm flagellar motion (Zhang et al. 2006). Farther studies identified Spag16 as essential for man fertility also (Zhang et al. 2007b). The mammalian homolog of PF16, Spag6 (Neilson et al. 1999; Zhang et al. 2002), is essential for mammalian health; mice with mutations in Spag6 prove hydrocephalus, respiratory distress, infertility, and die 8 weeks after birth (Sapiro et al. 2002). Furthermore, Spag6-deficient mice too have reduced ciliary beat out frequency in tracheal epithelial cells and reduced numbers of cilia in both the trachea and brain ependymal cells (Teves et al. 2014). The PF6 homolog, Spag17, is also essential for motility and linked to severe health issues in mice. Spag17-scarce mice show skeletal abnormalities and have enlarged brain ventricles, respiratory distress, and die in an extremely brusque 12 hours after birth (Teves et al. 2013, 2015). These phenotypes are exacerbated in mice that accept both Spag6 and Spag17 mutations (Zhang et al. 2007a). To date, there is no evidence that these iii proteins course a complex in Chlamydomonas.

Additional mammalian homologs of Chlamydomonas proteins include the protein FAP221 associated with C1d, which is mammalian Pcdp1, a protein associated with primary ciliary dyskinesia in mice (Lee et al. 2008). More recently, mammalian homologs of other members of C1d have been identified. Mutations in one of these proteins, CFAP54, lead to symptoms associated with master ciliary dyskinesia such as sperm move defects and an accumulation of mucus in the lungs (McKenzie et al. 2015). These findings farther implicate this small projection as being essential for ciliary movement. Finally, the C2b protein Hydin was first characterized in mice showing hydrocephalus (Davy and Robinson 2003). This hydrocephalus is not due to defects in ciliary length or density in the encephalon, which are normal in Hydin mutants. Instead, the brain cilia lack C2b causing a motility defect termed "cilia stalling"; this leads to a lack of fluid flow in the brain and hydrocephalus (Lechtreck et al. 2008). (For more information about CA proteins in mammals, see Teves et al. 2016.)

These findings can be extended across mouse models to humans. Mutations in projection proteins like Spag16L can cause male infertility, and recessive mutations in Hydin take been linked to primary ciliary dyskinesia in human patients (Zhang et al. 2007b; Olbrich et al. 2012). In addition, in that location are several accounts of patients with main ciliary dyskinesia that lack the entire CA (Bautista-Harris et al. 2000; Stannard et al. 2004). Often, the cilia of these patients will bear witness the transposition of one outer doublet microtubule to the center of the axoneme maybe to function as a CA (Smallman and Gregory 1986; Chilvers et al. 2003; Burgoyne et al. 2014). This item observation is especially interesting for showing the importance of the CA for the regulation of proper ciliary motility in humans. The locations of the mutations in these patients have not been published. Therefore, it is not known whether they correspond to previously identified CA proteins.

QUESTIONS FOR THE Hereafter

By applying a combination of biochemical, structural, and genetic approaches to understanding how motile cilia assemble and function, investigators go along to skin away the layers of complexity associated with the CA. As we make headway identifying the components of essential complexes, our challenge is to map these complexes onto the intricate CA structures revealed by cryo-ET. In add-on, nosotros are only commencement to define the molecular and mechanical mechanisms that couple the CA to regulation of ciliary motility. We demand to combine our knowledge of the limerick and construction of the CA projections with functional assays that permit for computational and mathematical modeling approaches to elucidate the mechanisms of the CA in regulating motility, including the role of second messengers and other signaling molecules. Finally, despite the intriguing discovery that katanin may play a role in nucleating the central microtubules, there are many questions that remain to exist answered about the nucleation of the key microtubules and the assembly of associated structures.

Footnotes

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