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. 2019 Feb 27;8:e42282. doi: 10.7554/eLife.42282

Basalin is an evolutionarily unconstrained protein revealed via a conserved role in flagellum basal plate function

Samuel Dean 1,, Flavia Moreira-Leite 1, Keith Gull 1
Editors: Philippe Bastin2, Anna Akhmanova3
PMCID: PMC6392502  PMID: 30810527

Abstract

Most motile flagella have an axoneme that contains nine outer microtubule doublets and a central pair (CP) of microtubules. The CP coordinates the flagellar beat and defects in CP projections are associated with motility defects and human disease. The CP nucleate near a ‘basal plate’ at the distal end of the transition zone (TZ). Here, we show that the trypanosome TZ protein ‘basalin’ is essential for building the basal plate, and its loss is associated with CP nucleation defects, inefficient recruitment of CP assembly factors to the TZ, and flagellum paralysis. Guided by synteny, we identified a highly divergent basalin ortholog in the related Leishmania species. Basalins are predicted to be highly unstructured, suggesting they may act as ‘hubs’ facilitating many protein-protein interactions. This raises the general concept that proteins involved in cytoskeletal functions and appearing organism-specific, may have highly divergent and cryptic orthologs in other species.

Research organism: Other

Introduction

Flagellar motility is important for cell propulsion and the generation of fluid flow over tissues. The axonemes of most motile flagella have a central pair (CP) apparatus that is comprised of two microtubules, C1 and C2, and their projections (Mitchell and Sale, 1999). The CP apparatus is essential to coordinate the action of dyneins so that the flagellum beat can be propagated efficiently and defects in the CP apparatus cause cell motility defects. For example, loss of Hydin, a component of the C2 projection, causes ciliary bending and beating impairment in mice (Lechtreck et al., 2008), defective beat switching in Chlamydomonas (Lechtreck and Witman, 2007), and loss of locomotion in trypanosomes (Dawe et al., 2007). Mutations in murine Hydin are associated with hydrocephalus (Davy and Robinson, 2003) and human hydin is also associated with hydrocephalus (Callen et al., 1990) and primary ciliary dyskinesia (Olbrich et al., 2012). Trypanosome and Leishmania mutants of PF16 (a C1 projection component) are paralysed (Branche et al., 2006; Beneke et al., 2017) and PF20 (which bridges the C1 and C2 microtubules) mutants have reduced flagellar motility (Branche et al., 2006).

In contrast to the outer axonemal microtubules, which are extensions of the basal body microtubules, the CP does not elongate directly from the basal body. Rather, the proximal end of one or both CP microtubules is embedded in an electron dense structure at the base of the axoneme termed the basal plate (Höög et al., 2014; May-Simera and Kelley, 2012).

Although the basal plate is ideally located to nucleate the CP, the lack of basal plate mutants or known basal plate components has hampered efforts to determine its function and our knowledge of the role of the basal plate in CP assembly is limited. Ablating trypanosome gamma tubulin results in immotile flagella with no CP (McKean et al., 2003), suggesting that CP nucleation is mediated by the gamma tubulin ring complex. In agreement with this notion, gamma tubulin was localised to the flagellum base in trypanosomes (Zhou and Li, 2015; Scott et al., 1997) and the TZ stellate structure in Chlamydomonas (Silflow et al., 1999). (Silflow et al., 1999). Knockouts of the microtubule severing protein katanin in Chlamydomonas and Tetrahymena lack the CP (Sharma et al., 2007; Dymek et al., 2004; Dymek and Smith, 2012), suggesting a role for microtubule severing in CP assembly. Mating katanin knockout gametes with wild type gametes caused cytoplasmic complementation and CP assembly at sub-distal regions of preformed flagellar axonemes in the resulting zygote, suggesting that CP formation does not require specific nucleating factors to be located at the base of the axoneme (Lechtreck et al., 2013).

Previously, we reported the development and functional analysis of a trypanosome TZ proteome (Dean et al., 2016). Here, we have analysed the function of a particular TZ protein that we have named basalin. Mutational analysis shows that RNAi ablation of basalin leads to paralysis and CP nucleation defects. Importantly, the TZs of cells induced for basalin RNAi possess a flagellum but are missing the basal plate, providing insights into the relationship between the basal plate and CP formation. At first sight, and intriguingly for a protein involved in such a conserved function, basalin appeared by homology searches to be a Trypanosoma brucei clade-specific protein. However, using syntenic comparison of the genomes we discovered a putative syntenic version of basalin in the L. mexicana genome. Deletion of this gene in L. mexicana reproduced the missing basal plate phenotype observed upon basalin RNAi in T. brucei, suggesting that these proteins are related but extraordinarily divergent in sequence. This establishes that proteins with intrinsic disorder are important for evolutionary conserved cytoskeletal functions and raises the general concept that such proteins involved in cytoskeletal functions and apparently appearing to be organism-specific, may have highly divergent and cryptic orthologs in other species responsible for conserved functions.

Results

Basalin knockdown generates flagellum paralysis, short flagella and a cytokinesis defect

Basalin (Tb927.7.3130) was identified as a putative basal plate constituent since it localised to the extreme distal TZ (Dean et al., 2016). We found that when basalin was ablated, the flagella of affected cells were paralysed (Video 1) and approximately nine microns shorter than that of uninduced cells (Figure 1—figure supplement 1). Cells exhibiting a supernumerary complement of DNA containing structures - the nucleus and the kinetoplast (the mass of mitochondrial DNA) - were also observed (Figure 1—figure supplement 1) indicative of a cytokinesis defect and concomitant reduction in population growth. There were a number of associated morphometric effects, such as a pronounced reduction in the distance between the kinetoplast and nucleus, and an increase in the length of the ‘free’ flagellum that extends beyond the anterior of the cell body (Figure 1—figure supplement 1). These defects are likely to be consequences of cell division defects caused by the shortened flagellum at cytokinesis (Absalon et al., 2008b; Absalon et al., 2008a; Robinson et al., 1995; Sunter et al., 2015; Hayes et al., 2014).

Video 1. An RNAi screen for paralysed flagella identifies basalin.

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DOI: 10.7554/eLife.42282.002
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Basalin ablation causes central pair defects

To determine the reason for flagellum paralysis after basalin RNAi, we repeated these RNAi induction experiments in cells expressing axonemal marker proteins tagged with a fluorescent protein. We analysed the RNAi phenotype 48 hours after RNAi induction, as this represents the first time-point after induction when basalin was undetectable at the TZ in a large proportion of induced cells, and correlates with the initial observations of morphological aberrations and growth inhibition (Figure 1—figure supplement 1). Two components of the CP complex (PF16 and Hydin), a component of the radial spokes (RSP2) and a component of the dynein arms were chosen as markers for this analysis. PF16 (a C1 elaboration) was absent in 63% of cells with a single flagellum after 48 hours RNAi (Figure 1). Dividing cells with an old flagellum that had a strong PF16 signal and a new flagellum that was negative for PF16 were often observed after RNAi, consistent with the pattern of basalin absence from the new flagellum only after RNAi (Figure 1—figure supplement 1). Although tagged Hydin (a C2 elaboration) was still detected after basalin RNAi, its signal was fainter and more punctate in 31% of induced cells (compared with the uninduced) (Figure 1). Hydin remained associated with the flagellum even after detergent extraction using a non-ionic detergent, demonstrating that the residual Hydin was stably associated with the flagellum of basalin ablated cells. Flagellum localisation of RSP2 and the axonemal dynein was unaffected by basalin RNAi, suggesting that the radial spokes and dynein arms (doublet microtubules) were not significantly altered.

Figure 1. Basalin ablation causes central pair defects.

Basalin RNAi was performed in cells expressing tagged markers for different axonemal components, showed that: (A) PF16 (Tb927.1.2670, C1 projection) is absent from affected flagella, (B) hydin (Tb927.6.3150, C2 projection) is reduced and punctate, but (C) RSP2 (Tb927.5.2850, radial spokes marker) and (D) dynein (Tb927.7.820, dynein arm marker) flagellar localisation are unaffected. (E) TEM cross-sections through the axoneme demonstrate that the central pair microtubules are missing from the axonemes in cells induced for basalin RNAi. (F) The presence of axoneme marker proteins (N > 200 for each marker at each timepoint) and (G) the number of axonemal microtubules were quantified before (N = 15) and after (N = 31) basalin RNAi.

Figure 1—source data 1. Quantification of axonemal marker presence in 1F cells after 48 hours basalin RNAi.
elife-42282-fig1-data1.xlsx (8.6KB, xlsx)
DOI: 10.7554/eLife.42282.005
Figure 1—source data 2. Quantification of axonemal microtubule arrangement after 48 hours basalin RNAi.
elife-42282-fig1-data2.xlsx (8.5KB, xlsx)
DOI: 10.7554/eLife.42282.006

Figure 1.

Figure 1—figure supplement 1. Quantitation of basalin knockdown and phenotype in trypanosome cells.

Figure 1—figure supplement 1.

(A) Basalin was ablated in cells expressing mNeonGreen::basalin and cytoskeletons were scored on whether they were positive or negative for basalin at the TZ. RNAi caused ablation such that > 80% of cells did not have detectable basalin at 72 hours. (B) Examples of dividing cells undergoing basalin RNAi. Non-induced dividing cells have four basalin spots that corresponds to localisation at the TZ and pro-basal bodies of both old and new flagella. In cells induced for basalin RNAi where the signal is absent from new flagella, there is only one spot that is associated with the old transition zone and the pro-basal body signal is absent. (C) Quantitation of basalin signal at the old and new flagella in dividing cells shows that dividing cells with positive old/negative new (POS/NEG) are first observed after 24 hours RNAi and increase in frequency to almost 40% after 48 hours. (D) Growth rates of cells non-induced and induced for basalin RNAi demonstrate that growth rate defect is first observed between 24–48 hours, co-incident with the first cells that are negative for basalin. Representative data of three biological replicates is shown. (E) Staining the DNA of cells using Hoechst shows that only the expected kinetoplast-nucleus numbers are observed at 0 hours (i.e. 1k1n, 2k1n, 2k2n), but there is an increase in the proportion of aberrant cells after 48 and 72 hours basalin RNAi. (F) There is an accumulation of aberrant morphologies after RNAi. This includes G) a reduction in the kinetoplast-nucleus (k–n) distance, (H) an increase in the length of the flagellum that extends beyond the anterior of the cell body (flagellum overhang), and I) a reduction in the overall flagellum length.
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The flagellum paralysis and PF16 absence suggested a CP defect and hence we analysed the axonemal ultrastructure by transmission electron microscopy (TEM) of cells induced for basalin RNAi. In uninduced cells, all of the axonemal microtubules were clearly visible in all cross-sections of the axoneme, whereas in cells undergoing RNAi for 48 hours, both CP microtubules were missing in 68% of axoneme cross-sections, and 1 CP microtubule was missing in a further 20% of axoneme cross-sections (Figure 1G).

Basalin ablation inhibits central pair nucleation

To gain further insights into the CP assembly defects caused by basalin ablation, we reproduced the basalin RNAi in cells expressing both basalin and PF16 tagged with different colour fluorescent proteins. This allowed us to unambiguously identify flagella with missing basalin and, by examining detergent extracted ‘cytoskeletons’ prepared from cells undergoing division, determine the effect upon PF16 assembly into newly made axonemes.

We then examined PF16 labelling in the new flagellum of dividing cells after 48 hours basalin RNAi, using cell cycle position defined by the number of kinetoplast and nuclei to determine the ‘age’ of new flagella. In basalin-negative new flagella in dividing cells, PF16 was nearly always absent at the earliest stages of elongation (97% of new flagella in cells with one kinetoplast and one nucleus, 1k1n, were missing PF16; Figure 2). However, at more advanced cell-cycle stages, new flagella in dividing cells were more likely to be positive for PF16 (28% and 45% of new flagella were PF16 positive in 2k1n and 2k2n cells, respectively). Strong, detergent resistant ‘lines’ of PF16 were observed in RNAi cells that were often in close association with the basal body, possibly reflecting self-aggregation of PF16 in the cytoplasm (Figure 2E–H). Close examination of the basalin-negative/PF16-positive RNAi cells revealed that PF16 incorporation was incomplete: the PF16 signal was either fragmented or missing from substantial portions of the flagellum altogether (Figure 2F–I). Therefore, in basalin-negative flagella, CP nucleation appears to be delayed and, when it occurs, it does so at a lower frequency and does not extend the entire length of the axoneme.

Figure 2. Basalin ablation inhibits central pair nucleation.

Figure 2.

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Basalin was ablated in trypanosomes expressing mNG::basalin and PF16::mScarlet-I to determine the effect of basalin ablation upon newly built axonemes. (A–C) Shows non-induced cells. (A) A cell with one nucleus and one kinetoplast (1k1n) shows PF16 incorporation into the axoneme in the early stages of flagellum construction. (B) and C) show cells with 2k1n and 2k2n, respectively. (D–H) Shows cells after 48 hours basalin RNAi induction. (D) A flagellum in the very early stages of construction is missing both basalin and PF16. Older new flagella that are absent for basalin are either D) missing PF16 altogether or have incomplete PF16 assembly into the flagellum, including F) a fragmented or intermittent signal, (G) a proximal signal that does not extend to the flagellum tip, and H) a distal signal that is missing from the proximal portion of the axoneme. (I) Quantification of non-induced vs induced dividing cells at different cell-cycle positions shows that the probability of PF16 being assembled into newly-made axonemes increases with cell-cycle progression (non-induced 1k1n N = 22, 2k1n N = 50, 2k2n N = 45; induced 1k1n N = 38, 2k1n N = 60, 2k2n N = 62).

Figure 2—source data 1. Quantification of axonemal PF16 incorporation in dividing cells after 48 hours basalin RNAi.
elife-42282-fig2-data1.xlsx (8.6KB, xlsx)
DOI: 10.7554/eLife.42282.008

Basalin is essential for building the TZ basal plate

To study the effect of basalin RNAi upon TZ structures, we analysed longitudinal sections of the TZ by TEM. In non-induced cells, the characteristic electron density of the basal plate was clearly observed in all longitudinal sections through the centre of the proximal region of the flagellum (comprising the basal body, the TZ and the proximal axoneme). However, after 48 hours of basalin RNAi, most longitudinal sections of the proximal flagellum either lacked a visible basal plate (57%) or had a greatly reduced basal plate only (33%) (Figure 3). TZ structures such as the collarette remained. The proportion of flagella lacking a basal plate correlates with the proportion of axoneme cross-sections with no CP (Figure 1). From this, we conclude that ablating basalin prevents the basal plate from being built and that this is associated with the absence of the CP in most axoneme cross-sections.

Figure 3. Basalin RNAi produces cells without a basal plate in the flagellum.

Figure 3.

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(A) TEM longitudinal sections through the centre of the proximal flagellum (including the transition zone and the proximal end of the axoneme), before (A) and after (B) RNAi. (C) The presence and absence of a basal plate in transition zone longitudinal sections was quantified at 0 (N = 22) and 48 hours (N = 19) basalin RNAi induction.

Figure 3—source data 1. Quantification of basal plate presence in TZ longitudinal sections after 48 hours basalin RNAi.
elife-42282-fig3-data1.xlsx (8.5KB, xlsx)
DOI: 10.7554/eLife.42282.010

Basalin localises to the basal plate area of the TZ

Basalin was previously localised to the TZ region by eYFP tagging (Dean et al., 2016). We tried immunogold labelling of detergent-treated cells (cytoskeletons) mounted onto TEM grids; however, we were not able to obtain reproducible gold labelling, possibly because of embedment of basalin within the basal plate. Hence, to obtain more precise localisation data on basalin, we expressed basalin fused to the bright green fluorophore ‘mNeonGreen’ (Shaner et al., 2013) in a cell line expressing mScarlet-I::TZP103.8 (Bindels et al., 2017) and analysed these cells by two-colour microscopy. TZP103.8 (Tb927.11.5750) was for chosen for co-localization because it was previously mapped by two-colour microscopy to a position immediately distal to the basal plate, and it is also required for CP assembly (Dean et al., 2016). Using this method, basalin was localised to a position ~100 nm more proximal than TZP103.8 (Figure 4), which corresponds to the expected position of the basal plate. A faint basalin signal was also observed in the pro-basal body (Figure 4A), and this signal increased in intensity as the pro-basal body matured (Figure 4B), eventually becoming visible on both basal body/pro-basal body pairs in late dividing cells (Figure 4C–E). The position of basalin in the expected location of the basal plate, combined with the basal plate absence after basalin RNAi, indicate that basalin is an essential component required for basal plate formation and function.

Figure 4. Basalin and TZP103.8 localisation through the cell cycle.

Figure 4.

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(A) In non-dividing cells, basalin localises just proximal to the TZP103.8 TZ signal and faintly to the pro-basal body. (B) As the pro-basal body matures an moves to the posterior relative to the old flagellum, the basalin signal at the new transition zone increases in intensity and a faint TZP103.8 signal is detected. (C) – (E) The TZP103.8 signal intensity increases at later stages of the cell cycle, and basalin is detected on the newly formed pro-basal bodies of both old and new flagella.

Basalin is essential for the efficient recruitment of TZP103.8 to the TZ

Since basalin represents the best candidate for a central component of the basal plate, we therefore next asked what affect ablation of basalin had on recruitment of other proteins which may have a function in the basal plate. Given the similarity in their phenotypes and localisations, we addressed the dependency between basalin and TZP103.8 regarding their recruitment to the TZ. For this purpose, we targeted each individual protein for RNAi separately in a cell line co-expressing fluorescently-tagged copies of both proteins. RNAi targeting basalin was effective as judged by its absence from affected TZs. Strikingly, this resulted in loss of TZP103.8 from affected TZs such that it was either undetectable or almost undetectable by fluorescence microscopy (Figure 5B,D). In contrast, basalin was still recruited efficiently to the flagellum when TZP103.8 was ablated (Figure 5C,D). Importantly, TZP103.8 RNAi resulted in a lack of CP microtubules but did not cause the disappearance of the basal plate (Dean et al., 2016), although the electron density at the basal plate was somewhat reduced in 11/32 TZ longitudinal sections ((Dean et al., 2016) and Figure 5—figure supplement 1). Basalin and TZP103.8 remained associated with isolated flagella, even after extraction with near-saturating concentrations of sodium chloride or potassium chloride (data not shown), suggesting they are core structural components of these structures.

Figure 5. TZP103.8 depends on basalin for its localisation to the transition zone.

Basalin or TZP103.8 were ablated by RNAi in cells co-expressing mScarlet::TZP103.8 (red) and mNeonGreen::basalin (green) to determine their dependency relationship at the transition zone. (A) In uninduced cells, basalin and TZP103.8 were both detected at the transition zone. (B) When basalin was ablated by RNAi, TZP103.8 was not efficiently recruited to the transition zone. (C) In contrast, when TZP103.8 was ablated, basalin still localised to the transition zone. Top panels show cytoskeletons prepared from non-dividing cells, bottom panels show cytoskeletons prepared from dividing cells. (D) Quantification of basalin/TZP103.8 presence at the transition zone in non-induced cells (N > 150) and after 48 hours RNAi of basalin (N = 168) or TZP103.8 (N = 127) confirms the differential dependencies at the transition zone.

Figure 5—source data 1. Quantification of basalin and TZP103.8 presence at the TZ after 48 hours basalin or TZP103.8 RNAi.
elife-42282-fig5-data1.xlsx (8.6KB, xlsx)
DOI: 10.7554/eLife.42282.014

Figure 5.

Figure 5—figure supplement 1. Thin-section transmission electron microscopy (TEM) analysis of the basal plate after TZP103.8 RNAi.

Figure 5—figure supplement 1.

Longitudinal TEM sections through the proximal region of the flagellum were analyzed for the presence and morphology of the basal plate (arrowheads). (A) Representative images of showing the basal plate in non-induced cells. (B) All 11/32 longitudinal images that show a reduction in the electron density at the centre of the basal plate, after 72 hours of TZP103.8 RNAi. (C) Table showing the proportion of longitudinal images of the proximal flagellum displaying basal plate reduction, in induced and non-induced samples. Scale bars, 200 nm.
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Gamma tubulin basal body localisation is independent of basalin and TZP103.8 TZ localisation

Gamma tubulin has an essential role in assembling the axonemal CP (Zhou and Li, 2015; McKean et al., 2003). Therefore, we investigated whether there was a functional link between gamma-tubulin localization and the recruitment of basalin or TZP103.8 to the TZ. Firstly, we expressed gamma tubulin tagged with mNeonGreen in cells expressing either basalin or TZP103.8 tagged with mScarlet (Figure 6). Gamma tubulin localised ~400 nm proximal to basalin and TZP103.8, with no overlap of signal between gamma tubulin and these TZPs. This is consistent with previous data that localised components of the gamma tubulin ring complex to the basal body area in trypanosomes (Zhou and Li, 2015). RNAi targeting basalin caused a general reduction in the gamma tubulin signal, but did not inhibit the recruitment of gamma tubulin to the basal body (Figure 6C and D). Similarly, although RNAi targeting gamma tubulin resulted in the expected paralysed flagellum phenotype (data not shown), it did not prevent recruitment of basalin or TZP103.8 to the TZ (Figure 6E and F).

Figure 6. Co-localisation and dependency of gamma tubulin with basalin and TZP103.8.

Figure 6.

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Gamma tubulin localises to the base of the flagellum more proximal to (A) basalin and (B) TZP103.8. (C) and (D) Ablating basalin does not prevent gamma tubulin from being recruited to the base of the flagellum (0 hr N = 107, 48 hr N = 102). (E) and (F) Ablating gamma tubulin does not prevent basalin or TZP103.8 from being recruited to the TZ (N > 100).

Figure 6—source data 1. Quantification of TZP103.8 and gamma tubulin presence at the TZ in 1F cells after 48 hours basalin RNAi.
elife-42282-fig6-data1.xlsx (8.5KB, xlsx)
DOI: 10.7554/eLife.42282.016

Basalin has a highly divergent syntenic ortholog in Leishmania mexicana

Initial bioinformatics analyses using homology search approaches such as Orthofinder (Emms and Kelly, 2015) suggested that basalin had a highly restricted evolutionary distribution and was not detected outside the Trypanosoma spp.. These results were unexpected, given the widespread evolutionary presence of a flagellum/cilium basal plate and the fundamental and conserved nature of CP nucleation within motile cilia and flagella. Other kinetoplastid species have a motile flagellum in at least one lifecycle stage and one might therefore expect to detect a conserved protein ortholog. However, sequence analysis even failed to detect an ortholog of basalin in the Leishmania species, which are separated from T. brucei by only 300 million years (Overath et al., 2001; Stevens and Gibson, 1999; Stevens and Rambaut, 2001). Moreover, even in the very closely related Trypanosoma congolense the ortholog appeared very highly divergent to that in T. brucei (Figure 7—figure supplement 1). A striking property of most of the kinetoplastid genomes available (including that of trypanosomes and Leishmania) is that they are highly syntenic, which may be linked to their polycistronic transcription. Genome sequencing has revealed that kinetoplastid genes are arranged in directional gene clusters and that, even when there is extensive sequence divergence, synteny is highly conserved (Ghedin et al., 2004). Leishmania spp. are kinetoplastid parasites that can also build a motile flagellum with an axonemal CP and a discrete basal plate in the distal TZ. Thus, we searched for a L. mexicana ortholog of basalin by scanning the syntenic genomic region.

Intriguingly, although gene synteny either side of the basalin gene is highly conserved between T. brucei and L. mexicana, the syntenic locus of basalin in L. mexicana is occupied by LmxM.22.1070, which is not a clear sequence homolog of basalin (Figure 7). However, we re-examined the BLASTP scores between T. brucei and L. mexicana and noticed that LmxM.22.1070 was indeed the reciprocal best BLASTP hit for basalin in L. mexicana, but the basalin-LmxM.22.1070 reciprocal BLASTP homologies were extremely weak (e = 0.27 and 1.9, respectively). An HHpred-driven protein comparison (Söding, 2005; Zimmermann et al., 2018) between basalin and LmxM.22.1070 demonstrated that most of the conserved residues lie in, or near, predicted helices (Figure 7—figure supplement 1). Although neither protein contained conserved domains that could provide functional clues, some coiled-coils and alpha helices were detected and, importantly, both proteins were predicted to be ~65% intrinsically disordered (Figure 7—figure supplement 1). We therefore set out to determine whether basalin and LmxM.22.1070 were divergent syntenic orthologs. To this end, we expressed LmxM.22.1070 tagged with mNeonGreen in L. mexicana, and demonstrated that this protein localised to the basal body and pro-basal body areas of the flagellum (Halliday et al., 2018) (Figure 8). RNAi is not possible in L. mexicana and so we produced LmxM.22.1070 knockouts generated using CRISPR/CAS9 (Beneke et al., 2017). These were viable but had substantial morphological aberrations (Figure 9—figure supplement 1). Similar to basalin RNAi cells, LmxM.22.1070 knockout cells had a strong motility defect (Video 2) slower doubling times and substantially shorter flagella, with most cells having no ‘free’ flagellum extending from the flagellar pocket (the cell surface invagination from which the flagellum emerges). Knockout cells were shorter and more round than the parental cells, consistent with the important link between flagellum biogenesis and cell shape (Sunter and Gull, 2017; Sunter et al., 2018).

Figure 7. Gene synteny and sequence homology between basalin (Tb927.7.3130) and LmxM.22.1070.

(A) Basalin and LmxM.22.1070 genes are at syntenic positions along chromosome Leishmania mexicana chromosome 22 and Trypanosoma brucei chromosome 7, respectively. (B) Basalin and LmxM.22.1070 are very weak reciprocal best BLAST-P hits.

Figure 7.

Figure 7—figure supplement 1. A bioinformatics comparison of basalin and LmxM.22.1070.

Figure 7—figure supplement 1.

(A) A protein sequence alignment between basalin and its T. congolense ortholog (TcIL3000_7_2290). (B) A HHpred-driven comparison between basalin and LmxM.22.1070 demonstrates that most sequence conservation is in the helical segments. (C) Both proteins have coiled-coils towards the C terminus of the protein.
Figure 7—figure supplement 2. Basalin and LmxM.22.1070 are predicted to have extensive disorder.

Figure 7—figure supplement 2.

(A) Basalin and LmxM.22.1070 show similar levels of intrinsic disorder, with ~65% disordered residues and 15–17 regions of disorder. (B) Quick2D predicts extensive disorder in basalin and LmxM.22.1070 with helices at the N and C termini (Hanson et al., 2017; Zimmermann et al., 2018; Jones and Cozzetto, 2015; Dosztányi et al., 2005).
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Figure 8. Localisation of LmxM.22.1070 in L. mexicana promastigotes through the cell cycle recapitulates that of basalin in trypanosomes.

Figure 8.

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LmxM.22.1070 was tagged at its endogenous locus with an N terminal mNeonGreen using CRISPR/CAS9 (Beneke et al., 2017) and its localisation throughout the cell cycle visualised in methanol-fixed ‘cytoskeletons’. (A) In non-dividing cells, LmxM.22.1070 localises to a position consistent with the transition zone and the pro-basal body. (B) - E) As the cell divides, the basal bodies are duplicated and LmxM.22.1070 is detected on the basal body and pro-basal body of both flagella in dividing cells.

Video 2. LmxM.22.1070 knockout Leishmania mexicana cells are mostly paralysed with little or no flagellum visible.

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DOI: 10.7554/eLife.42282.021
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EM analysis demonstrated that, as with basalin RNAi in trypanosomes, the CP was absent from a large proportion (41%) of the axonemal cross-sections examined (Figure 9). Importantly, we could not detect a basal plate or an associated CP in any longitudinal sections through the TZ in LmxM.22.1070 knockout cells or in an EM tomogram (Figure 9—figure supplement 1), while a basal plate was nearly always observed at the TZ of parental cells (Figure 9). The morphological and growth defects were largely rescued by LmxM.22.1070 episome-based expression, but not by T. brucei basalin expression using the same system (Figure 9—figure supplement 1).

Figure 9. Knockout of LmxM.22.1070 in L. mexicana promastigotes causes flagella to be built without the central pair microtubules and a basal plate.

(A) and (B) TEM cross-sections through the axoneme show that the central pair is absent in knockout cells. (C) Quantification of the microtubules arrangement in KO axonemes shows that > 40% of cross sections (N = 51) are missing their CP, and that this phenotype is more penetrant in the proximal axoneme (N = 21) versus the distal axoneme (N = 30). The asterisk refers to the microtubules being disorganised. (D) and (E) TEM longitudinal sections through the transition zone demonstrate that the basal plate is absent. (F) Quantification shows that the basal plate was not observed any the transition zones that were examined in KO cells.

Figure 9—source data 1. Quantification of axoneme microtubule arrangement in Leishmania mexicana LmxM.22.1070 KO cells.
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DOI: 10.7554/eLife.42282.024

Figure 9.

Figure 9—figure supplement 1. Phenotypic analysis of Leishmania mexicana LmxM.22.1070 knockout cells.

Figure 9—figure supplement 1.

(A) PCR confirms the loss of LmxM.22.1070 in a knockout clone and subsequent addback of LmxM.22.1070 and basalin. (B) LmxM.22.1070 knockout cells grow more slowly than the parental cells. Transfection of a episome addback vector containing LmxM.22.1070 rescues this phenotype, but basalin does not. (C) The doubling times of the populations were calculated based on the data points over 4 days. The asterisk indicates a statistically significant difference compared to the parental cells (T test, p=0.005). (D) Parent and LmxM.22.1070 addback cells have the wildtype morphology, having an elongated cell body and a long flagellum. In contrast, knockout cells and basalin addback cells have a short, round cell body and most cells do not have a flagellum that is visible outside the flagellar pocket of the cell. (E) Cytoskeletons prepared from the four cell lines were stained with the TAT anti tubulin antibody to measure the length of the portion of the flagellum that protrudes beyond the flagellar pocket. ~90% of knockout and basalin addback cells did not have a flagellum that extended beyond the flagellar pocket, and those flagella that did tended to be shorter than the wild type cells. (E) A virtual slice through a Leishmania LmxM.22.1070 KO tomogram shows that no central pair is evident in the flagellum.
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To evaluate PF16 incorporation in cells lacking LmxM.22.1070, we reproduced the KO in Leishmania cells expressing PF16::eYFP and examined cytoskeletons by fluorescence microscopy (Figure 10). In parental cells, PF16 exhibited the expected strong signal running from the base to the tip of the axoneme (Figure 10A). However, in those KO cells that had a clearly visible, protruding flagellum, PF16 was either completely absent (40%) or missing from a substantial portion of the flagellum (40%) (Figure 10B–F,I). Interestingly, KO cells with no protruding flagellum had a more penetrant phenotype, with PF16 missing from the area of the cell corresponding to the flagellum in 90% of cells (Figure 10G,I). These short, non-protruding flagella may be ‘newer’ flagella that have had less time for stochastic, ectopic assembly of PF16 and the CP. Consistent with this, cells with two ‘free’ flagella were not observed in KO cells, probably because the new flagellum remained short (and therefore hidden inside the flagella pocket) in most cells.

Figure 10. Incorporation of PF16 into LmxM.22.1070 knockout cells.

Figure 10.

Open in a new tab

LmxM.22.1070 was knocked out in Leishmania cells expressing a single allele of PF16 tagged with a C terminal eYFP and cytoskeletons were analysed by fluorescence microscopy. (A) A parental and (B) a KO cell with PF16 incorporated into the entire length of the axoneme. KO cells with (C) PF16 absent from the entire external axoneme, or (D-F) with incomplete PF16 incorporation. A KO cell where PF16 was either (G) absent or (H) present from the region of the cell corresponding to the proximal flagellum. Axoneme incorporation of PF16 was quantified I n (I) log stage cultures (parent N = 152, KO external flagellum = 62, KO no external flagellum = 152, KO total = 214).

Figure 10—source data 1. Quantification of PF16 axoneme incorporation in LmxM.22.1070 KO cells.
elife-42282-fig10-data1.xlsx (8.6KB, xlsx)
DOI: 10.7554/eLife.42282.026

Therefore, a combination of bioinformatics, localisation and functional evidence demonstrates that LmxM.22.1070 is a highly divergent syntenic ortholog of basalin. Basalin is ‘conserved’ in the kinetoplastids and possibly in many other organisms where it remains cryptic because of extreme sequence diversity and lack of clues from synteny.

Discussion

In this work, we describe basalin (Tb927.7.3130), a protein identified in our trypanosome flagellum transition zone proteome (Dean et al., 2016), and show that it is required for construction of the basal plate of the flagellum. Whilst a shorter axoneme is built in cells in which basalin was ablated, the absence of the basal plate leads a strong defect in CP assembly and flagellum immotility. Basalin appears to be fundamental for basal plate formation and to our knowledge this is the first example of a protein required for basal plate formation. Moreover, mutant analysis clearly demonstrates the link between the TZ basal plate structure and CP assembly. The discovery that, in basalin negative flagella, early new flagella lack PF16 and that the probability of PF16 incorporation into the axoneme increases in late new flagella, strongly argues for a defect in CP nucleation at the axoneme base, with subsequent ‘ectopic’ assembly in a relatively small (10–20%) of elongating axonemes. The alternative hypothesis - that the CP is nucleated correctly but loses contact with the top of the TZ and then shortens or collapses due to a stability defect - is unlikely because one would expect to see flagella in the very early stages of elongation that are positive for PF16, with decreasing frequency of PF16-positive new flagella in later cell cycle stages.

Basalin is required for recruitment of another, unrelated protein, TZP103.8, also required for CP formation. However, gamma tubulin, which again is required for CP formation, can still associate with the basal body in the absence of basalin, suggesting complex pathways are involved in CP formation. It is unlikely that the alternative view that the lack of a CP causes basal plate absence is correct since the basal plate remains in other mutants that lack the CP, such as TZP103.8 (Figure 5—figure supplement 1 and (Dean et al., 2016)) and PF16 (Beneke et al., 2017; Branche et al., 2006) ablation mutants.

Although all examined TZs of Leishmania LmxM.22.1070 KO cells were missing their basal plate and the associated CP, 31% and 10% of axonemal cross-sections revealed a 9 + 2 and 9 + 1 axoneme, respectively. Moreover, PF16 assembly was observed in trypanosome axonemes in which TbBasalin was undetectable, indicating that some CP assembly occurs in the absence of the basal plate. How are these CPs formed in the absence of a basal plate? In TbBasalin RNAi cells, very new flagella in the early stages of construction were PF16 negative, and the probability of (often ectopic) PF16 assembly into the axoneme increased as the flagellum elongated. Further, in LmxBasalin KO cells, PF16 incorporation was much less likely in the very short, non-protruding flagella that likely correspond to the newest flagella in the population, and when PF16 was incorporation into the protruding flagella is was usually incomplete. All of this evidence, taken together suggests that in the absence of the basal plate, CP nucleation happens at a relatively low frequency and ectopically, in the distal axoneme. Therefore, the observed CPs may reflect stochastic self-assembly of the CP microtubules inside axonemes, possibly due to mis-localisation of nucleating factors in the absence of the basal plate. Consistent with this, studies in Chlamydomonas demonstrate that the CP can self-assemble at different points along pre-formed flagella during cytoplasmic complementation of katanin mutants (Lechtreck et al., 2013). Under the normal conditions of an elongating flagellum, the presence of a basal plate-located nucleating factor may facilitate the assembly of a full CP running from the basal plate to tip.

Gamma tubulin and the gamma tubulin ring complex are essential for CP nucleation in trypanosomes (McKean et al., 2003; Zhou and Li, 2015), but the mechanism by which this occurs is not clear. Our data using fluorescent protein tagging, and previous findings using small epitope tags, localised gamma tubulin to the proximal end of the basal body, at a position ~400 nm proximal to the site of CP nucleation. A clear structural ortholog of the normal cilium TZ basal plate is not evident in the Chlamydomonas flagellum, but gamma tubulin has been located to the algae-specific stellate structure within its TZ (Silflow et al., 1999) possibly indicating a role in CP nucleation. However, in mutants where the stellate structure was lost the central pair ‘penetrated’ into the basal body, suggesting it may in fact function as a barrier (Jarvik and Suhan, 1999; Koblenz et al., 2003). In contrast, the CP was not observed in the TZ in our kinetoplastid basal plate mutants, suggesting these structures are not analogous.

The concentration of gamma tubulin signal at the trypanosome basal body may represent a pre-assembly pool, possibly interacting with alpha and beta tubulins and cofactors for more distal CP assembly. Alternatively, there could be a small, undetected focus of gamma tubulin within the TZ basal plate area, although other proteins can be easily located at the basal plate. Thus, gamma tubulin may be nucleating the CP directly at the basal plate, or if the more delocalised concentration of gamma tubulin at the basal body proximal end is real then this may indicate that CP nucleation takes place at a slight distance from the basal plate. In this latter model the basal plate may act to capture a CP structure whose assembly is initiated elsewhere, rather than nucleating the CP. However, in both the nucleating and capturing models there must be number control, that is two and only two CP microtubules are incorporated into the centre of the axoneme. Chlamydomonas mutants that are missing radial spokes have 4 CP microtubules; similarly, axonemes from SAS6 mutants that have 10 doublets also have 4 CP microtubules, suggesting that the space available within the axoneme plays a role in limiting CP number (Lechtreck et al., 2013; Mitchell, 2009; Nakazawa et al., 2014). However, the origin of the extra CP in these mutants is not clear, and could be caused by a nucleation phenotype or by a single CP that breaks and slides or grows to form two parallel CPs. The absence of extra CPs in basalin mutants argues that CP number is still constrained, but does not rule out number control via specific CP nucleating or capturing sites within the basal plate.

At the base of the flagellum in L. mexicana parental cells, the ‘lumen’ of the transition zone has a different electron density from that of the inner region of the axoneme, with the basal plate delimiting a clear ‘border’ between the TZ and axoneme inner regions. In contrast, longitudinal sections through the centre of the proximal flagellum of basalin KO cells revealed no clear border between the inner regions of the TZ and the axoneme, as these regions had a homogeneous electron density, which may indicate a boundary function for the Leishmania basal plate. However, axonemal structures, such as radial spokes and dynein arms, did not penetrate into the TZ in Leishmania or trypanosome basal plate mutants, suggesting that the TZ/axoneme boundary remained intact despite the loss of the basal plate.

Initial analyses failed to find basalin orthologs outside the Trypanosoma spp. and it was only after rigorous examination of the synteny, BLAST score, localisation and function that we were able to conclude the LmxM.22.1070 is the L. mexicana ortholog of basalin. Analysis of the trypanosome nuclear pore complex (NPC) architecture suggested common ancestry with yeast and metazoan NPCs despite the lack of sequence conservation (DeGrasse et al., 2009). However, basalin divergence is far more extreme because sequence homology was not clear even within the kinetoplastids. Interestingly, both TbBasalin and LmxBasalin are predicted to contain ~65% intrinsically disordered residues. Proteins with a high degree of intrinsic disorder have been shown to associate with different elements of the cytoskeleton, including microtubules, actin, intermediate filaments and motor proteins (reviewed in Guharoy et al., 2013). Their roles include acting as hub proteins in protein-protein interaction networks (Dosztányi et al., 2006; Dunker et al., 2005), scaffold proteins that cause ‘enforced proximity’ of proteins to promote their interaction (Buday and Tompa, 2010), or acting as molecular ‘glue’ that becomes rigid once the protein complex has formed (Uversky, 2015). Often only a few specific peptides are conserved and these proteins acquire structure upon interaction with a binding partner (Davey et al., 2012; Cumberworth et al., 2013). Therefore, it may be that basalin is under little selective pressure to retain its primary sequence and that a few specific residues in a disordered polypeptide are sufficient to retain its interactions and function. Supporting this, the HHpred-driven alignment of TbBasalin and LmxBasalin suggests that a core helical scaffold is conserved that is rather plastic to insertions of sequences predicted as ‘disordered’. Nonetheless, it is worth noting that the expression of TbBasalin in L. mexicana did not rescue the LmxBasalin knockout phenotype, demonstrating some degree of biochemical divergence.

Given the difficulties in identifying the relationship between the trypanosome and Leishmania orthologs, more distant orthologs in other organisms would not be detected using BLAST-based methods. This raises the intriguing possibility that basalin has distant orthologs in other organisms and represents a key player in a fundamental mechanism of basal plate formation and CP assembly. The discovery that a fundamental and conserved flagellum structure and function involves such widely divergent orthologues was totally dependent on our use of kinetoplastids such as Leishmania and trypanosomes, whose genomes have retained an enormous degree of synteny. This is one of the few groups of organisms where this type of syntenic genome analysis is possible. This raises the fundamental issue that the proportion of lineage-specific proteins in flagellar proteomes of the various model systems is likely to have been over-estimated, and that some proteins that have been categorised as clade specific may, in fact, be highly divergent ancient proteins.

Materials and methods

Light and electron microscopy

Live cells and detergent extracted ‘cytoskeletons’ were prepared for light and electron microscopy as described (Dean et al., 2015). All protein localisations in this study were performed by modifying genes at their chromosomal locus to encode an N or C terminal fluorescence protein tag, which was then visualised using its native fluorescence. Images were acquired using a Leica wide-field fluorescence microscope with a 63 × 1.4 NA objective using an sCMOS camera (Andor) and analysed using FIJI. Where the purpose was to determine the relative localisation of proteins within the cell, the microscope’s chromatic aberration was measured using TetraSpec beads (Thermofisher) and then automatically corrected using a custom python script executed in FIJI (Source Code File 1). DNA was visualized by treating cells or cytoskeletons with 1 μg.mL−1 Hoechst 33342. Time lapse movies were captured using an Olympus CKX41 inverted phase-contrast microscope and a Hamamatsu ORCA-ER camera using 100 ms exposure at maximum frame rate. Transmission electron microscopy samples were imaged in a Tecnai T12 microscope (FEI), equipped with a OneView 16-megapixel camera (Gatan).

Cell culture and cell lines

Trypanosome SMOX 927 cells (Poon et al., 2012) and L. mexicana CAS9/T7 cells (Beneke et al., 2017) were cultured in SDM79 (Brun and Schönenberger, 1979) or M199 (Dean et al., 2015) for all experiments. Trypanosome and Leishmania cell lines were generated as described (Dean et al., 2015; Beneke et al., 2017). RNAi was induced using 2 μg.mL−1 doxycycline. Cell densities were measured using a CASYcounter.

Molecular cloning

Primer annealing sites for making RNAi constructs were designed by RNAit (Redmond et al., 2003) and the resulting amplicon was cloned into the RNAi stemloop vector pQuadra (Inoue et al., 2005). Primers for tagging trypanosome proteins were designed using TAGit (Dean et al., 2015) and primers for generating Leishmania knockout cell lines were designed using LeishGEdit (Beneke et al., 2017).

Bioinformatics

Evolutionary analyses was initially based on Orthofinder output (Emms and Kelly, 2015) with subsequent refinement using BLASTP (TriTrypDB v38 with low complexity filter) and gene synteny (Aslett et al., 2010). Various algorithms were used to predict protein alignment (Mergealign (Collingridge and Kelly, 2012), HHpred (Zimmermann et al., 2018; Söding, 2005)), coiled-coils (Pair2 (McDonnell et al., 2006)) and intrinsic disorder (PrDOS (Ishida and Kinoshita, 2007)). Synteny was calculated using TriTrypDB’s (Aslett et al., 2010; Aurrecoechea et al., 2017) inbuilt OrthoMCL with a 1e−5 cut-off and the graphic reproduced using Adobe Illustrator.

Supplemental material

Figure 1—figure supplement 1 describes the quantitation of basalin knockdown and phenotype in trypanosome cells. Figure 5—figure supplement 1 shows longitudinal sections of the TZ after 48 hours TZP103.8 RNAi. Figure 7—figure supplement 1 a bioinformatics analysis comparing basalin with its L. mexicana ortholog. Figure 9—figure supplement 1 is a phenotypic analysis of Leishmania mexicana LmxM.22.1070 knockout cells. Video 1 shows trypanosome cells undergoing basalin RNAi. Video 2 shows LmxM.22.1070 knockout Leishmania mexicana cells.

Acknowledgements

Work in the KG laboratory is funded by the Wellcome Trust (WT066839MA and 104627/Z/14/Z). We thank Professor Matthew Higgins for his advice on basalin structure, Dr Fernando Bazan for his advice on basalin alignments, Dr Susanne Warrenfeltz and Dr Omar Harb from EuPathDB for their help on basalin synteny, and Tom Beneke for his advice on Leishmania CRISPR. The authors declare no competing financial interests.

Funding Statement

The funders had no role in study design, data collection and interpretation, or the decision to submit the work for publication.

Contributor Information

Samuel Dean, Email: samuel.dean@path.ox.ac.uk.

Philippe Bastin, Institut Pasteur, France.

Anna Akhmanova, Utrecht University, Netherlands.

Funding Information

This paper was supported by the following grants:

  • Wellcome Trust WT066839MA to Keith Gull.

  • Wellcome Trust 104627/Z/14/Z to Keith Gull.

Additional information

Competing interests

No competing interests declared.

Author contributions

Conceptualization, Formal analysis, Validation, Investigation, Visualization, Methodology, Writing—original draft, Writing—review and editing.

Formal analysis, Investigation, Visualization, Writing—review and editing.

Formal analysis, Funding acquisition, Project administration, Writing—review and editing.

Additional files

Source code 1. Python script to correct chromatic aberration using multi-chromatic reference beads.
elife-42282-code1.py (7.8KB, py)
DOI: 10.7554/eLife.42282.027
Transparent reporting form
elife-42282-transrepform.docx (245.8KB, docx)
DOI: 10.7554/eLife.42282.028

Data availability

All data generated or analysed during this study are included in the manuscript and supporting files.

Bibliography

  1. Absalon S, Blisnick T, Kohl L, Toutirais G, Doré G, Julkowska D, Tavenet A, Bastin P. Intraflagellar transport and functional analysis of genes required for flagellum formation in trypanosomes. Molecular Biology of the Cell. 2008a;19:929–944. doi: 10.1091/mbc.e07-08-0749. [DOI] [PMC free article] [PubMed] [Google Scholar]
  2. Absalon S, Blisnick T, Bonhivers M, Kohl L, Cayet N, Toutirais G, Buisson J, Robinson D, Bastin P. Flagellum elongation is required for correct structure, orientation and function of the flagellar pocket in trypanosoma brucei. Journal of Cell Science. 2008b;121:3704–3716. doi: 10.1242/jcs.035626. [DOI] [PubMed] [Google Scholar]
  3. Aslett M, Aurrecoechea C, Berriman M, Brestelli J, Brunk BP, Carrington M, Depledge DP, Fischer S, Gajria B, Gao X, Gardner MJ, Gingle A, Grant G, Harb OS, Heiges M, Hertz-Fowler C, Houston R, Innamorato F, Iodice J, Kissinger JC, Kraemer E, Li W, Logan FJ, Miller JA, Mitra S, Myler PJ, Nayak V, Pennington C, Phan I, Pinney DF, Ramasamy G, Rogers MB, Roos DS, Ross C, Sivam D, Smith DF, Srinivasamoorthy G, Stoeckert CJ, Subramanian S, Thibodeau R, Tivey A, Treatman C, Velarde G, Wang H. TriTrypDB: a functional genomic resource for the trypanosomatidae. Nucleic Acids Research. 2010;38:D457–D462. doi: 10.1093/nar/gkp851. [DOI] [PMC free article] [PubMed] [Google Scholar]
  4. Aurrecoechea C, Barreto A, Basenko EY, Brestelli J, Brunk BP, Cade S, Crouch K, Doherty R, Falke D, Fischer S, Gajria B, Harb OS, Heiges M, Hertz-Fowler C, Hu S, Iodice J, Kissinger JC, Lawrence C, Li W, Pinney DF, Pulman JA, Roos DS, Shanmugasundram A, Silva-Franco F, Steinbiss S, Stoeckert CJ, Spruill D, Wang H, Warrenfeltz S, Zheng J. EuPathDB: the eukaryotic pathogen genomics database resource. Nucleic Acids Research. 2017;45:D581–D591. doi: 10.1093/nar/gkw1105. [DOI] [PMC free article] [PubMed] [Google Scholar]
  5. Beneke T, Madden R, Makin L, Valli J, Sunter J, Gluenz E. A CRISPR Cas9 high-throughput genome editing toolkit for kinetoplastids. Royal Society Open Science. 2017;4:170095. doi: 10.1098/rsos.170095. [DOI] [PMC free article] [PubMed] [Google Scholar]
  6. Bindels DS, Haarbosch L, van Weeren L, Postma M, Wiese KE, Mastop M, Aumonier S, Gotthard G, Royant A, Hink MA, Gadella TW. mScarlet: a bright monomeric red fluorescent protein for cellular imaging. Nature Methods. 2017;14:53–56. doi: 10.1038/nmeth.4074. [DOI] [PubMed] [Google Scholar]
  7. Branche C, Kohl L, Toutirais G, Buisson J, Cosson J, Bastin P. Conserved and specific functions of axoneme components in trypanosome motility. Journal of Cell Science. 2006;119:3443–3455. doi: 10.1242/jcs.03078. [DOI] [PubMed] [Google Scholar]
  8. Brun R, Schönenberger Cultivation and in vitro cloning or procyclic culture forms of Trypanosoma brucei in a semi-defined medium. Short communication. Acta Tropica. 1979;36:289–292. [PubMed] [Google Scholar]
  9. Buday L, Tompa P. Functional classification of scaffold proteins and related molecules. FEBS Journal. 2010;277:4348–4355. doi: 10.1111/j.1742-4658.2010.07864.x. [DOI] [PubMed] [Google Scholar]
  10. Callen DF, Baker EG, Lane SA. Re-evaluation of GM2346 from a del(16)(q22) to t(4;16)(q35;q22.1) Clinical Genetics. 1990;38:466–468. doi: 10.1111/j.1399-0004.1990.tb03614.x. [DOI] [PubMed] [Google Scholar]
  11. Collingridge PW, Kelly S. MergeAlign: improving multiple sequence alignment performance by dynamic reconstruction of consensus multiple sequence alignments. BMC Bioinformatics. 2012;13:117. doi: 10.1186/1471-2105-13-117. [DOI] [PMC free article] [PubMed] [Google Scholar]
  12. Cumberworth A, Lamour G, Babu MM, Gsponer J. Promiscuity as a functional trait: intrinsically disordered regions as central players of interactomes. Biochemical Journal. 2013;454:361–369. doi: 10.1042/BJ20130545. [DOI] [PubMed] [Google Scholar]
  13. Davey NE, Van Roey K, Weatheritt RJ, Toedt G, Uyar B, Altenberg B, Budd A, Diella F, Dinkel H, Gibson TJ. Attributes of short linear motifs. Mol. BioSyst. 2012;8:268–281. doi: 10.1039/C1MB05231D. [DOI] [PubMed] [Google Scholar]
  14. Davy BE, Robinson ML. Congenital hydrocephalus in hy3 mice is caused by a frameshift mutation in Hydin, a large novel gene. Human Molecular Genetics. 2003;12:1163–1170. doi: 10.1093/hmg/ddg122. [DOI] [PubMed] [Google Scholar]
  15. Dawe HR, Shaw MK, Farr H, Gull K. The hydrocephalus inducing gene product, hydin, positions axonemal central pair microtubules. BMC Biology. 2007;5:33. doi: 10.1186/1741-7007-5-33. [DOI] [PMC free article] [PubMed] [Google Scholar]
  16. Dean S, Sunter J, Wheeler RJ, Hodkinson I, Gluenz E, Gull K. A toolkit enabling efficient, scalable and reproducible gene tagging in trypanosomatids. Open Biology. 2015;5:140197. doi: 10.1098/rsob.140197. [DOI] [PMC free article] [PubMed] [Google Scholar]
  17. Dean S, Moreira-Leite F, Varga V, Gull K. Cilium transition zone proteome reveals compartmentalization and differential dynamics of ciliopathy complexes. PNAS. 2016;113:E5135–E5143. doi: 10.1073/pnas.1604258113. [DOI] [PMC free article] [PubMed] [Google Scholar]
  18. DeGrasse JA, DuBois KN, Devos D, Siegel TN, Sali A, Field MC, Rout MP, Chait BT. Evidence for a shared nuclear pore complex architecture that is conserved from the last common eukaryotic ancestor. Molecular & Cellular Proteomics. 2009;8:2119–2130. doi: 10.1074/mcp.M900038-MCP200. [DOI] [PMC free article] [PubMed] [Google Scholar]
  19. Dosztányi Z, Csizmók V, Tompa P, Simon I. The pairwise energy content estimated from amino acid composition discriminates between folded and intrinsically unstructured proteins. Journal of Molecular Biology. 2005;347:827–839. doi: 10.1016/j.jmb.2005.01.071. [DOI] [PubMed] [Google Scholar]
  20. Dosztányi Z, Chen J, Dunker AK, Simon I, Tompa P. Disorder and sequence repeats in hub proteins and their implications for network evolution. Journal of Proteome Research. 2006;5:2985–2995. doi: 10.1021/pr060171o. [DOI] [PubMed] [Google Scholar]
  21. Dunker AK, Cortese MS, Romero P, Iakoucheva LM, Uversky VN. Flexible nets: The roles of intrinsic disorder in protein interaction networks. FEBS Journal. 2005;272:5129–5148. doi: 10.1111/j.1742-4658.2005.04948.x. [DOI] [PubMed] [Google Scholar]
  22. Dymek EE, Lefebvre PA, Smith EF. PF15p is the chlamydomonas homologue of the Katanin p80 subunit and is required for assembly of flagellar central microtubules. Eukaryotic Cell. 2004;3:870–879. doi: 10.1128/EC.3.4.870-879.2004. [DOI] [PMC free article] [PubMed] [Google Scholar]
  23. Dymek EE, Smith EF. PF19 encodes the p60 catalytic subunit of katanin and is required for assembly of the flagellar central apparatus in chlamydomonas. Journal of Cell Science. 2012;125:3357–3366. doi: 10.1242/jcs.096941. [DOI] [PMC free article] [PubMed] [Google Scholar]
  24. Emms DM, Kelly S. OrthoFinder: solving fundamental biases in whole genome comparisons dramatically improves orthogroup inference accuracy. Genome Biology. 2015;16:157. doi: 10.1186/s13059-015-0721-2. [DOI] [PMC free article] [PubMed] [Google Scholar]
  25. Ghedin E, Bringaud F, Peterson J, Myler P, Berriman M, Ivens A, Andersson B, Bontempi E, Eisen J, Angiuoli S, Wanless D, Von Arx A, Murphy L, Lennard N, Salzberg S, Adams MD, White O, Hall N, Stuart K, Fraser CM, El-Sayed NM. Gene synteny and evolution of genome architecture in trypanosomatids. Molecular and Biochemical Parasitology. 2004;134:183–191. doi: 10.1016/j.molbiopara.2003.11.012. [DOI] [PubMed] [Google Scholar]
  26. Guharoy M, Szabo B, Contreras Martos S, Kosol S, Tompa P. Intrinsic structural disorder in cytoskeletal proteins. Cytoskeleton. 2013;70:550–571. doi: 10.1002/cm.21118. [DOI] [PubMed] [Google Scholar]
  27. Halliday C, Billington K, Wang Z, Dean S, Sunter JD, Wheeler RJ. Cellular landmarks of Trypanosoma Brucei and leishmania mexicana. Molecular and Biochemical Parasitology. 2018 doi: 10.1016/j.molbiopara.2018.12.003. [DOI] [PMC free article] [PubMed] [Google Scholar]
  28. Hanson J, Yang Y, Paliwal K, Zhou Y. Improving protein disorder prediction by deep bidirectional long short-term memory recurrent neural networks. Bioinformatics. 2017;33:685–692. doi: 10.1093/bioinformatics/btw678. [DOI] [PubMed] [Google Scholar]
  29. Hayes P, Varga V, Olego-Fernandez S, Sunter J, Ginger ML, Gull K. Modulation of a cytoskeletal calpain-like protein induces major transitions in trypanosome morphology. The Journal of Cell Biology. 2014;206:377–384. doi: 10.1083/jcb.201312067. [DOI] [PMC free article] [PubMed] [Google Scholar]
  30. Höög JL, Lacomble S, O'Toole ET, Hoenger A, McIntosh JR, Gull K. Modes of flagellar assembly in chlamydomonas reinhardtii and trypanosoma brucei. eLife. 2014;3:e01479. doi: 10.7554/eLife.01479. [DOI] [PMC free article] [PubMed] [Google Scholar]
  31. Inoue M, Nakamura Y, Yasuda K, Yasaka N, Hara T, Schnaufer A, Stuart K, Fukuma T. The 14-3-3 proteins of trypanosoma brucei function in motility, Cytokinesis, and cell cycle. Journal of Biological Chemistry. 2005;280:14085–14096. doi: 10.1074/jbc.M412336200. [DOI] [PubMed] [Google Scholar]
  32. Ishida T, Kinoshita K. PrDOS: prediction of disordered protein regions from amino acid sequence. Nucleic Acids Research. 2007;35:W460–W464. doi: 10.1093/nar/gkm363. [DOI] [PMC free article] [PubMed] [Google Scholar]
  33. Jarvik J, Suhan J. The role of the flagellar transition region: inferences from the analysis of a Chlamydomonas mutant with defective transition region structures. Journal of Cell Science. 1999;99:731–740. [Google Scholar]
  34. Jones DT, Cozzetto D. DISOPRED3: precise disordered region predictions with annotated protein-binding activity. Bioinformatics. 2015;31:857–863. doi: 10.1093/bioinformatics/btu744. [DOI] [PMC free article] [PubMed] [Google Scholar]
  35. Koblenz B, Schoppmeier J, Grunow A, Lechtreck KF. Centrin deficiency in chlamydomonas causes defects in basal body replication, segregation and maturation. Journal of Cell Science. 2003;116:2635–2646. doi: 10.1242/jcs.00497. [DOI] [PubMed] [Google Scholar]
  36. Lechtreck KF, Delmotte P, Robinson ML, Sanderson MJ, Witman GB. Mutations in hydin impair ciliary motility in mice. The Journal of Cell Biology. 2008;180:633–643. doi: 10.1083/jcb.200710162. [DOI] [PMC free article] [PubMed] [Google Scholar]
  37. Lechtreck KF, Gould TJ, Witman GB. Flagellar central pair assembly in chlamydomonas reinhardtii. Cilia. 2013;2:15. doi: 10.1186/2046-2530-2-15. [DOI] [PMC free article] [PubMed] [Google Scholar]
  38. Lechtreck KF, Witman GB. Chlamydomonas reinhardtii hydin is a central pair protein required for flagellar motility. The Journal of Cell Biology. 2007;176:473–482. doi: 10.1083/jcb.200611115. [DOI] [PMC free article] [PubMed] [Google Scholar]
  39. May-Simera HL, Kelley MW. Cilia, wnt signaling, and the cytoskeleton. Cilia. 2012;1:7. doi: 10.1186/2046-2530-1-7. [DOI] [PMC free article] [PubMed] [Google Scholar]
  40. McDonnell AV, Jiang T, Keating AE, Berger B. Paircoil2: improved prediction of coiled coils from sequence. Bioinformatics. 2006;22:356–358. doi: 10.1093/bioinformatics/bti797. [DOI] [PubMed] [Google Scholar]
  41. McKean PG, Baines A, Vaughan S, Gull K. Gamma-tubulin functions in the nucleation of a discrete subset of microtubules in the eukaryotic flagellum. Current Biology. 2003;13:598–602. doi: 10.1016/S0960-9822(03)00174-X. [DOI] [PubMed] [Google Scholar]
  42. Mitchell DR. The Chlamydomonas Sourcebook. Elsevier; 2009. The Flagellar Central Pair Apparatus; pp. 235–252. [DOI] [Google Scholar]
  43. Mitchell DR, Sale WS. Characterization of a chlamydomonas insertional mutant that disrupts flagellar central pair microtubule-associated structures. The Journal of Cell Biology. 1999;144:293–304. doi: 10.1083/jcb.144.2.293. [DOI] [PMC free article] [PubMed] [Google Scholar]
  44. Nakazawa Y, Ariyoshi T, Noga A, Kamiya R, Hirono M. Space-dependent formation of central pair microtubules and their interactions with radial spokes. PLOS ONE. 2014;9:e110513. doi: 10.1371/journal.pone.0110513. [DOI] [PMC free article] [PubMed] [Google Scholar]
  45. Olbrich H, Schmidts M, Werner C, Onoufriadis A, Loges NT, Raidt J, Banki NF, Shoemark A, Burgoyne T, Al Turki S, Hurles ME, Köhler G, Schroeder J, Nürnberg G, Nürnberg P, Chung EM, Reinhardt R, Marthin JK, Nielsen KG, Mitchison HM, Omran H, UK10K Consortium Recessive HYDIN mutations cause primary ciliary dyskinesia without randomization of left-right body asymmetry. The American Journal of Human Genetics. 2012;91:672–684. doi: 10.1016/j.ajhg.2012.08.016. [DOI] [PMC free article] [PubMed] [Google Scholar]
  46. Overath P, Haag J, Lischke A, O'hUigin C. The surface structure of trypanosomes in relation to their molecular phylogeny. International Journal for Parasitology. 2001;31:468–471. doi: 10.1016/S0020-7519(01)00152-7. [DOI] [PubMed] [Google Scholar]
  47. Poon SK, Peacock L, Gibson W, Gull K, Kelly S. A modular and optimized single marker system for generating trypanosoma brucei cell lines expressing T7 RNA polymerase and the tetracycline repressor. Open Biology. 2012;2:110037. doi: 10.1098/rsob.110037. [DOI] [PMC free article] [PubMed] [Google Scholar]
  48. Redmond S, Vadivelu J, Field MC. RNAit: an automated web-based tool for the selection of RNAi targets in trypanosoma brucei. Molecular and Biochemical Parasitology. 2003;128:115–118. doi: 10.1016/S0166-6851(03)00045-8. [DOI] [PubMed] [Google Scholar]
  49. Robinson DR, Sherwin T, Ploubidou A, Byard EH, Gull K. Microtubule polarity and dynamics in the control of organelle positioning, segregation, and cytokinesis in the trypanosome cell cycle. The Journal of Cell Biology. 1995;128:1163–1172. doi: 10.1083/jcb.128.6.1163. [DOI] [PMC free article] [PubMed] [Google Scholar]
  50. Scott V, Sherwin T, Gull K. gamma-tubulin in trypanosomes: molecular characterisation and localisation to multiple and diverse microtubule organising centres. Journal of Cell Science. 1997;110:157–168. doi: 10.1242/jcs.110.2.157. [DOI] [PubMed] [Google Scholar]
  51. Shaner NC, Lambert GG, Chammas A, Ni Y, Cranfill PJ, Baird MA, Sell BR, Allen JR, Day RN, Israelsson M, Davidson MW, Wang J. A bright monomeric green fluorescent protein derived from branchiostoma lanceolatum. Nature Methods. 2013;10:407–409. doi: 10.1038/nmeth.2413. [DOI] [PMC free article] [PubMed] [Google Scholar]
  52. Sharma N, Bryant J, Wloga D, Donaldson R, Davis RC, Jerka-Dziadosz M, Gaertig J. Katanin regulates dynamics of microtubules and biogenesis of motile cilia. The Journal of Cell Biology. 2007;178:1065–1079. doi: 10.1083/jcb.200704021. [DOI] [PMC free article] [PubMed] [Google Scholar]
  53. Silflow CD, Liu B, LaVoie M, Richardson EA, Palevitz BA. Gamma-tubulin in chlamydomonas: characterization of the gene and localization of the gene product in cells. Cell Motility and the Cytoskeleton. 1999;42:285–297. doi: 10.1002/(SICI)1097-0169(1999)42:4<285::AID-CM3>3.0.CO;2-Z. [DOI] [PubMed] [Google Scholar]
  54. Söding J. Protein homology detection by HMM-HMM comparison. Bioinformatics. 2005;21:951–960. doi: 10.1093/bioinformatics/bti125. [DOI] [PubMed] [Google Scholar]
  55. Stevens JR, Gibson W. The molecular evolution of trypanosomes. Parasitology Today. 1999;15:432–437. doi: 10.1016/S0169-4758(99)01532-X. [DOI] [PubMed] [Google Scholar]
  56. Stevens J, Rambaut A. Evolutionary rate differences in trypanosomes. Infection, Genetics and Evolution. 2001;1:143–150. doi: 10.1016/S1567-1348(01)00018-1. [DOI] [PubMed] [Google Scholar]
  57. Sunter JD, Varga V, Dean S, Gull K. A dynamic coordination of flagellum and cytoplasmic cytoskeleton assembly specifies cell morphogenesis in trypanosomes. Journal of Cell Science. 2015;128:1580–1594. doi: 10.1242/jcs.166447. [DOI] [PMC free article] [PubMed] [Google Scholar]
  58. Sunter JD, Moreira-Leite F, Gull K. Dependency relationships between IFT-dependent flagellum elongation and cell morphogenesis in leishmania. Open Biology. 2018;8:180124. doi: 10.1098/rsob.180124. [DOI] [PMC free article] [PubMed] [Google Scholar]
  59. Sunter J, Gull K. Shape, form, function and leishmania pathogenicity: from textbook descriptions to biological understanding. Open Biology. 2017;7:170165. doi: 10.1098/rsob.170165. [DOI] [PMC free article] [PubMed] [Google Scholar]
  60. Uversky VN. The multifaceted roles of intrinsic disorder in protein complexes. FEBS Letters. 2015;589:2498–2506. doi: 10.1016/j.febslet.2015.06.004. [DOI] [PubMed] [Google Scholar]
  61. Zhou Q, Li Z. γ-Tubulin complex in Trypanosoma brucei: molecular composition, subunit interdependence and requirement for axonemal central pair protein assembly. Molecular Microbiology. 2015;98:667–680. doi: 10.1111/mmi.13149. [DOI] [PMC free article] [PubMed] [Google Scholar]
  62. Zimmermann L, Stephens A, Nam SZ, Rau D, Kübler J, Lozajic M, Gabler F, Söding J, Lupas AN, Alva V. A completely reimplemented MPI bioinformatics toolkit with a new HHpred server at its core. Journal of Molecular Biology. 2018;430:2237–2243. doi: 10.1016/j.jmb.2017.12.007. [DOI] [PubMed] [Google Scholar]

Decision letter

Editor: Philippe Bastin1

In the interests of transparency, eLife includes the editorial decision letter and accompanying author responses. A lightly edited version of the letter sent to the authors after peer review is shown, indicating the most substantive concerns; minor comments are not usually included.

Thank you for submitting your article "Basalin: an evolutionary unconstrained protein revealed via a conserved role in basal plate function" for consideration by eLife. Your article has been reviewed by three peer reviewers, and the evaluation has been overseen by a Reviewing Editor and Anna Akhmanova as the Senior Editor. The reviewers have opted to remain anonymous.

The reviewers have discussed the reviews with one another and the Reviewing Editor has drafted this decision to help you prepare a revised submission.

Comments:

All three reviewers agree that the work is (1) novel, (2) of excellent technical quality and (3) supports the main conclusions. However, one major issue was raised during the discussion regarding the lack of explanation as to how loss of basalin/the basal plate affects the central pair. Some suggestions are mentioned below that could help answer this question. This would considerably strengthen your manuscript and give it a wider scope. The proposed experiments seem accessible given the tools you already have in hand.

Summary:

1) The novel protein basalin is required for the assembly of the basal plate, an electron-dense structure at the base of the central pair (CP) of axonemal microtubules. When basalin is ablated in Trypanosoma, the assembly of the basal plate is impaired, the central pair is mostly absent, the flagella are shorter, and cell growth/cytokinesis are affected.

2) The localization of transition zone protein TZP103.8 depends on basalin, while gamma tubulin accumulates at the basal body independently of basalin.

3) The authors identify a basalin-related protein in Leishmania, which displays little sequence conservation but is required for basal plate assembly, as shown by knockout experiments. The conclusion that proteins with little conservation of primary structure can perform similar functions is well supported. The fluorescence images are beautiful and very convincing. The paper is well written and structured for the most part.

Essential revisions:

How does basal plate loss affect the central pair is an important issue. We propose to perform a time course experiment during RNAi knockdown to monitor central pair presence/absence in trypanosomes. With the tools available (tagged cell lines with CP proteins, possibly TEM), it should be possible to determine whether the CP microtubules are just not made or actually lose contact with the top of the TZ and then shorten. Analysing PF16 and hydin distribution in cells with two flagella at different stages of elongation should provide essential insights. Releasing cells from basalin RNAi could also be a powerful way to monitor the relationship between CP and basal plate/basalin. The CP is still present in the Leishmania knockout and the authors explain this by suggesting the existence of an alternative mechanism of CP formation. It seems that this idea could be tested in Trypanosoma.

Another point to clarify is the differences in CP formation between Trypanosoma and Leishmania (BP-dependent vs. BP-independent). Indeed, the authors use the subtitle "Basalin is essential for building the axonemal central pair" and discuss how gamma tubulin and how the basal plate might determine the number of CP microtubules, both of which is not in agreement with published data (4 CP MTs are formed in the absence of radial spokes) nor their own data (2 CP MTs are still made in Leishmania, which has no BP, and gamma tub is neither at the BP nor is it distribution affected by BP loss/basalin knock-down).

The final main point to clarify relates to the role of TZP103.8. The authors report in the 2016 PNAS paper that RNAi against TZP103.8 "caused a reduced basal plate", but here in this paper cite the 2016 paper as showing RNAi against 103.8 did not cause disappearance of the BP. Could you please clarify this? For example, 103.8 RNAi causes a BP defect, albeit not "full disappearance", but retains basalin. Thus, the complete lack of BP in basalin KF, which lacks basalin + TXP103.8, could result from combined requirement of basalin and TZP103.8.

eLife. 2019 Feb 27;8:e42282. doi: 10.7554/eLife.42282.031

Author response

Essential revisions:

How does basal plate loss affect the central pair is an important issue. We propose to perform a time course experiment during RNAi knockdown to monitor central pair presence/absence in trypanosomes. With the tools available (tagged cell lines with CP proteins, possibly TEM), it should be possible to determine whether the CP microtubules are just not made or actually lose contact with the top of the TZ and then shorten. Analysing PF16 and hydin distribution in cells with two flagella at different stages of elongation should provide essential insights. Releasing cells from basalin RNAi could also be a powerful way to monitor the relationship between CP and basal plate/basalin. The CP is still present in the Leishmania knockout and the authors explain this by suggesting the existence of an alternative mechanism of CP formation. It seems that this idea could be tested in Trypanosoma.

To address this issue, we made a new trypanosome cell line that targets basalin for RNAi in a cell line that expresses mNG::basalin (green) and PF16::mScarI (red). We chose to use PF16 as a CP marker because, as shown in Figure 1, this gives the clearest “absence vs. presence” pattern. This allowed us to unambiguously identify flagella that are absent for basalin and, by examining detergent extracted “cytoskeletons” prepared from cells undergoing division, examine the effect of basalin ablation upon PF16 assembly into newly-made axonemes.

Basalin-negative new flagella were not observed in a significant number of cells until 48 hours after RNAi. The delayed onset of RNAi penetrance is likely due to a cellular pool of basalin that must be depleted before basalin-negative flagella are observed. We therefore focussed on this timepoint for our analysis.

We then examined PF16 labelling in the new flagellum of dividing cells, using cell cycle position defined by the number of kinetoplasts and nuclei to score the ‘age’ of new flagella. Examining basalin-negative new flagella in dividing cells demonstrated that PF16 was nearly always absent at the earliest stages of elongation. Importantly, at more advanced cell-cycle stages, new flagella in dividing cells were more likely to be positive for PF16 (28% and 45% of new flagella were PF16 positive in 2k1n and 2k2n cells, respectively); however, flagella that were positive for PF16 but negative for basalin had incomplete PF16 incorporation, such that the central pair marker was missing from significant portions of the axoneme.

The discovery that, in basalin negative flagella, early new flagella are negative for PF16 and that the frequency of PF16 incorporation increases in late new flagella, strongly argues for a defect in central pair nucleation at the axoneme base, with subsequent ‘ectopic’ assembly in a relatively small percentage (10-20%) of elongating axonemes. The alternative hypothesis, that the central pair is nucleated correctly but loses contact with the top of the TZ and then shortens or collapses due to a stabilisation defect, is unlikely because one would expect to see flagella in the very early stages of elongation that are positive for PF16, with decreasing frequency of PF16-positive new flagella in later cell cycle stages.

Nevertheless, this new dataset does not rule out a linked/connected role for the basal plate in central pair stabilisation, in addition to its role in central pair nucleation.

The manuscript and figures have been amended to reflect this new data and the addition of this important conclusion.

Another point to clarify is the differences in CP formation between Trypanosoma and Leishmania (BP-dependent vs. BP-independent). Indeed, the authors use the subtitle "Basalin is essential for building the axonemal central pair" and discuss how gamma tubulin and how the basal plate might determine the number of CP microtubules, both of which is not in agreement with published data (4 CP MTs are formed in the absence of radial spokes) nor their own data (2 CP MTs are still made in Leishmania, which has no BP, and gamma tub is neither at the BP nor is it distribution affected by BP loss/basalin knock-down).

Our new analysis of basalin RNAi in trypanosomes expressing mNG::basalin/PF16::mScarI demonstrates that, although PF16 is mostly absent in flagella lacking basalin, PF16 can be assembled into flagellar axonemes in the absence of basalin. Importantly, this incorporation occurs at a higher frequency in “older” new flagella and is incomplete.

This strongly indicates that, in the absence of the trypanosome basal plate, central pair nucleation in these cells is delayed until after the start of axoneme elongation. This is consistent with the LmxBasalin knockout TEM data, which shows that cross-sections of the “external” (i.e., distal) axoneme of flagella outside the pocket are more likely to have a central pair than cross-sections of the proximal axoneme inside the flagellar pocket. These data suggest that delayed, ectopic central pair formation in the absence of basalin can occur in the few Basalin KO cells that manage to elongate an axoneme past the flagellar pocket opening.

To evaluate PF16 incorporation (as a surrogate for central pair formation) in cells lacking basalin, we reproduced the LmxBasalin KO in Leishmania cells expressing PF16::eYFP and examined PF16::eYFP incorporation in cytoskeletons. We were not able to ascertain the “age” of flagella using the cell cycle position of dividing cells because cells with two ‘free’ flagella were not observed in KO cells, likely because the new flagellum remained short and therefore hidden inside the flagellar pocket of the cell. Instead, we examined PF16 assembly into flagella that were protruding (long) and those that did not protrude from the flagellar pocket, reasoning that the long flagella were likely to be the oldest flagella.

This revealed that cells with an external flagellum were more likely to incorporate PF16, and that PF16 assembly into these flagella was incomplete and often missing from substantial portions of the axoneme. Combined with the EM data, this demonstrates that CP and PF16 assembly can occur in flagella that have no basal plate, and suggests that this assembly is often ectopic and aberrant.

In summary, our data does not support a difference in central pair nucleation mechanisms and basal plate function between trypanosomes and Leishmania. The manuscript and subtitle have been changed to reflect this new data.

We have modified our discussion of CP number control to include discussion of CP assembly in radial spoke mutants.

The final main point to clarify relates to the role of TZP103.8. The authors report in the 2016 PNAS paper that RNAi against TZP103.8 "caused a reduced basal plate", but here in this paper cite the 2016 paper as showing RNAi against 103.8 did not cause disappearance of the BP. Could you please clarify this? For example, 103.8 RNAi causes a BP defect, albeit not "full disappearance", but retains basalin. Thus, the complete lack of BP in basalin KF, which lacks basalin + TXP103.8, could result from combined requirement of basalin and TZP103.8.

RNAi targeting TZP103.8 causes a reduced basal plate in some sections, but most sections show little, if any change. In the PNAS paper we showed a section with a reduced basal plate, but did not quantify the proportion of affected axonemes as it was a small part of a much larger study.

To clarify this here, we have re-analysed the data to quantify the number of TZ basal plates that were affected by TZP103.8 RNAi and included the EM data as Figure 5—figure supplement 1.

The following text has been added to the Results section:

“although the electron density at the basal plate was somewhat reduced in 11/32 TZ longitudinal sections ((Dean et al., 2016) Figure 5—figure supplement 1)”

We agree that it is likely that there are proteins other than basalin that contribute to the basal plate structure that are absent from basalin mutants, consistent with our hypothesis that basalin acts as a scaffold protein.

Associated Data

    This section collects any data citations, data availability statements, or supplementary materials included in this article.

    Supplementary Materials

    Figure 1—source data 1. Quantification of axonemal marker presence in 1F cells after 48 hours basalin RNAi.
    elife-42282-fig1-data1.xlsx (8.6KB, xlsx)
    DOI: 10.7554/eLife.42282.005
    Figure 1—source data 2. Quantification of axonemal microtubule arrangement after 48 hours basalin RNAi.
    elife-42282-fig1-data2.xlsx (8.5KB, xlsx)
    DOI: 10.7554/eLife.42282.006
    Figure 2—source data 1. Quantification of axonemal PF16 incorporation in dividing cells after 48 hours basalin RNAi.
    elife-42282-fig2-data1.xlsx (8.6KB, xlsx)
    DOI: 10.7554/eLife.42282.008
    Figure 3—source data 1. Quantification of basal plate presence in TZ longitudinal sections after 48 hours basalin RNAi.
    elife-42282-fig3-data1.xlsx (8.5KB, xlsx)
    DOI: 10.7554/eLife.42282.010
    Figure 5—source data 1. Quantification of basalin and TZP103.8 presence at the TZ after 48 hours basalin or TZP103.8 RNAi.
    elife-42282-fig5-data1.xlsx (8.6KB, xlsx)
    DOI: 10.7554/eLife.42282.014
    Figure 6—source data 1. Quantification of TZP103.8 and gamma tubulin presence at the TZ in 1F cells after 48 hours basalin RNAi.
    elife-42282-fig6-data1.xlsx (8.5KB, xlsx)
    DOI: 10.7554/eLife.42282.016
    Figure 9—source data 1. Quantification of axoneme microtubule arrangement in Leishmania mexicana LmxM.22.1070 KO cells.
    elife-42282-fig9-data1.xlsx (8.7KB, xlsx)
    DOI: 10.7554/eLife.42282.024
    Figure 10—source data 1. Quantification of PF16 axoneme incorporation in LmxM.22.1070 KO cells.
    elife-42282-fig10-data1.xlsx (8.6KB, xlsx)
    DOI: 10.7554/eLife.42282.026
    Source code 1. Python script to correct chromatic aberration using multi-chromatic reference beads.
    elife-42282-code1.py (7.8KB, py)
    DOI: 10.7554/eLife.42282.027
    Transparent reporting form
    elife-42282-transrepform.docx (245.8KB, docx)
    DOI: 10.7554/eLife.42282.028

    Data Availability Statement

    All data generated or analysed during this study are included in the manuscript and supporting files.

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