#PAGE_PARAMS# #ADS_HEAD_SCRIPTS# #MICRODATA#

Mms19 promotes spindle microtubule assembly in Drosophila neural stem cells


Authors: Rohan Chippalkatti aff001;  Boris Egger aff003;  Beat Suter aff001
Authors place of work: Cell Biology, University of Bern, Berne, Switzerland aff001;  Graduate School for Cellular and Biomedical Sciences, University of Bern, Berne, Switzerland aff002;  Department of Biology, University of Fribourg, Fribourg, Switzerland aff003
Published in the journal: Mms19 promotes spindle microtubule assembly in Drosophila neural stem cells. PLoS Genet 16(11): e1008913. doi:10.1371/journal.pgen.1008913
Category: Research Article
doi: https://doi.org/10.1371/journal.pgen.1008913

Summary

Mitotic divisions depend on the timely assembly and proper orientation of the mitotic spindle. Malfunctioning of these processes can considerably delay mitosis, thereby compromising tissue growth and homeostasis, and leading to chromosomal instability. Loss of functional Mms19 drastically affects the growth and development of mitotic tissues in Drosophila larvae and we now demonstrate that Mms19 is an important factor that promotes spindle and astral microtubule (MT) growth, and MT stability and bundling. Mms19 function is needed for the coordination of mitotic events and for the rapid progression through mitosis that is characteristic of neural stem cells. Surprisingly, Mms19 performs its mitotic activities through two different pathways. By stimulating the mitotic kinase cascade, it triggers the localization of the MT regulatory complex TACC/Msps (Transforming Acidic Coiled Coil/Minispindles, the homolog of human ch-TOG) to the centrosome. This activity of Mms19 can be rescued by stimulating the mitotic kinase cascade. However, other aspects of the Mms19 phenotypes cannot be rescued in this way, pointing to an additional mechanism of Mms19 action. We provide evidence that Mms19 binds directly to MTs and that this stimulates MT stability and bundling.

Keywords:

Aurora – Cell cycle and cell division – Centrosomes – Larvae – Microtubules – Mitosis – Tubulins – Nuclear bodies

Introduction

The fidelity of chromosome segregation during mitotic divisions depends on the proper regulation of the structure and dynamics of spindle microtubules. Numerous mitotic factors, including different mitotic kinases and microtubule (MT) associated proteins, meticulously regulate the formation, orientation, polymerization, and catastrophe of spindle MTs to ensure that the chromatids are evenly delivered to the two products of the division process, the daughter cells. The mitotic spindle not only regulates chromosome segregation, its proper spindle architecture, and orientation profoundly impacts development and cellular physiology. Spindle size and architecture dynamically adapt to changes in cellular morphology within and between organisms. Early embryonic divisions in organisms such as C. elegans and X. laevis occur in the large volumes of the egg and blastomeres whereas in the later stages of embryogenesis cell sizes are dramatically smaller [1,2]. The mitotic spindle is scaled according to the cell size by MT-regulatory proteins, indicating that cell division is in tune with the developmental progression of these organisms [3]. The MT associated protein Tpx2 mediates spindle architecture variations in mouse neuronal stem cells (NSCs), where astral MTs predominate the early developmental stages and inner spindle MTs predominate during the later developmental stages [4]. This points to the importance of MT regulatory proteins in regulating spindle architecture during development. Studying such novel proteins can reveal structural and dynamic aspects of spindle assembly and their role in development and cellular physiology.

Mms19 was identified as a gene required for nucleotide excision repair (NER) [5]. The protein Mms19 can be found as part of the Cytoplasmic Iron-Sulfur Assembly complex (CIA), which mediates the incorporation of iron-sulfur clusters into NER proteins such as Xpd [6,7]. However, a distinct, apparently DNA repair-independent, function of Mms19 came to light because its knock-down caused numerous mitotic spindle abnormalities in human cells [8]. Downregulation of Mms19 in young Drosophila embryos also revealed spindle abnormalities and chromosome segregation defects, and these phenotypes were linked to the mitotic control pathway when results by Nag and co-workers revealed that Mms19 acts as a positive regulator of the Cdk Activating Kinase (CAK) activity [9]. CAK has dual roles during the cell cycle. It activates the mitotic Cdk1 during mitosis but is recruited by Xpd to form the holoTFIIH complex during interphase [10]. The incorporation into TFIIH causes CAK to phosphorylate an entirely different set of substrates and allows CAK to perform its functions in transcription. Nag et al proposed that Mms19 binds to Xpd during mitosis and that this binding competes with the binding of Xpd to the TFIIH subunits. Mms19 binding to Xpd could thereby release CAK to activate its mitotic targets. In this model, reduced levels of Mms19 prevent sufficient dissociation of the Xpd-CAK complexes, hindering the establishment of the required levels of the mitotic CAK activity. Indeed, overexpressing CAK complex components in the Mms19 loss-of-function (Mms19P) background rescued the mitotic defects to a large degree [9].

The remarkable findings by Nag et al uncovered a novel mitotic pathway for Mms19. But this study mostly focused on young Drosophila embryos, which are unusual in that all somatic nuclei share a common cytoplasm, in which the mitotic divisions take place. Furthermore, their cell cycle consists of only S and M phases, without intervening G phases. In this situation with the shared cytoplasm, the absence of Mms19 often causes microtubules emanating from one spindle pole to contact the chromosomes of a neighboring nucleus. It is therefore difficult to extrapolate these findings to mononuclear, diploid cells that are isolated from their neighbors by plasma membranes and go through a full cell cycle with G phases. Furthermore, even though the spindle abnormalities observed in the absence of Mms19 could be linked to compromised CAK activity, the pathway acting downstream of CAK is not understood. Finally, overexpression of the CAK complex brought about only a partial rescue of the Mms19P defects, pointing towards additional, possibly CAK-independent spindle regulatory roles of Mms19.

The objective of this study was thus to investigate the mitotic function of Mms19 in normal diploid cells with the goal of dissecting the precise pathway through which Mms19 acts to regulate mitotic spindle assembly and cell cycle progression. Because Mms19P larvae lack imaginal discs, we chose the larval brain neuroblasts (NBs) as a model to analyze the mitotic roles of Mms19 in cells with a full cycle. The newly identified Mms19 phenotypes allowed us to pinpoint steps in the pathways that require Mms19 activity. We found that Mms19 is required in NBs for timely progression through the cell cycle and consequently for establishing normal cell numbers in the NB lineage. Mms19 is also required for the growth and assembly of spindle and astral microtubules (MTs). Our results connect these defects to the mis-localization of the microtubule regulator TACC, suggesting that TACC is a crucial downstream target of the mitotic kinase cascade through CAK-Cdk1-Aurora kinases. Additionally, and apparently unrelated to the CAK-Cdk1 axis, we also identified a direct interaction in vitro between Mms19 and microtubules and found that Mms19 promotes microtubule stability and bundle formation.

Results

Mms19P brains show a microcephaly phenotype

Normal Drosophila larvae spend on average 5–7 days at 25°C to pass through the larval stages. In contrast, Mms19P larvae take not only at least 8–10 days to reach the size of outgrown WT third instar larvae, but they also spend a total of around 15 days in the 3rd larval instar stage before they die (see Table 1 for details about the fly stocks used). These larvae display a typical mitotic phenotype without recognizable imaginal disc tissues [9]. Even though outgrown Mms19P larvae lack imaginal discs, their brain is still present, although it is much smaller, displaying a microcephaly phenotype (Fig 1A–1B). Additionally, the optic lobe (OL) appears deformed and underdeveloped. Compared to the wild type, the total volume of the Mms19P brains and the volumes of the central brains (CBs) and OLs, too, are drastically reduced (Fig 1D–1F). We also stained the brains of all genotypes with antibodies against Miranda (Mira, which marks CB NBs; see Table 2 for details about all antibodies used for staining), to count the number of CB NBs. Surprisingly, however, the number of CB NBs per brain lobe did not significantly change between the controls and the Mms19P brains (Fig 1C). This implies that the Mms19P NBs have been properly determined and are present. It was reported previously that aneuploidy resulting from defective spindle checkpoint function causes premature differentiation of NBs and a reduction in brain size [11]. We performed fluorescent in situ hybridization to screen for aneuploid NBs in the WT as well as Mms19P brains but did not find significantly elevated levels of aneuploidy in the mutant (S1 Fig; P = 0.1493). The reduced central brain size might then result from dying differentiating neuronal cells or, more likely, from NBs that divide only slowly, thereby contributing fewer Ganglion Mother Cells (GMCs) and neurons to the CB. The OL develops from the invagination of a group of ectodermal cells in the head region during late embryogenesis [12]. In the wild type, these cells, called neuroepithelial (NE) cells, start proliferating after larval hatching and generate the distinct regions of the OL after several rounds of divisions [13]. The drastic reduction of the OL volume seen in Mms19P larvae contributes the largest part to the overall reduction of the brain size seen. Although this points to a requirement for Mms19 also in these highly proliferative NE cells, we focused on the better studied CB NBs as these cells are large and very well suited to analyze mitotic phases and possible defects in spindle assembly.

<i>Mms19</i><sup><i>P</i></sup> brains display a microcephaly (small brain) phenotype.
Fig. 1. Mms19P brains display a microcephaly (small brain) phenotype.
3rd instar larval brain NBs were visualized by staining for Miranda (red, cytoplasmic). They were also stained for pH3 (white, nuclear) and DNA (blue, Hoechst 33342 dye). (A)-(B) A WT brain lobe can be subdivided into the OL (shaded green) and the CB (shaded red). Mms19P brains are significantly smaller, with a diminished OL. Overexpressing the CAK complex components driven by daughterless-Gal4 (da>CAK) in the Mms19P background appeared to slightly rescue this phenotype but this rescue was not statistically significant (brain volume: P>0.99; OL volume: P>0.99). Mms19::eGFP expressed in the Mms19P background rescued the Mms19P phenotype. Daughterless driven CAK expression in the WT background did not seem to bring about any noticeable defects in brain size or morphology. Counting the number of CB NBs (in the Red shaded area) staining positively for Mira revealed that the number of NBs per brain lobe is similar across all genotypes (C) (WT: n = 15 brains, 30 lobes, 3 experiments; Mms19P: n = 15 brains, 30 lobes, 3 experiments; da>CAK, Mms19P: n = 9 brains, 18 lobes, 3 experiments; Mms19::eGFP, Mms19P: n = 9 brains, 18 lobes, 3 experiments; da>CAK; WT: n = 6 brains, 12 lobes, 2 experiments). (D) the volume of the brain is significantly reduced in the Mms19P and da>CAK, Mms19P brains. Furthermore, segmentation and volume measurement of the OL and CB revealed a significant reduction in Mms19P and da>CAK, Mms19P brains (E)-(F). Brain volume and morphology were restored to WT levels when Mms19::eGFP was expressed in Mms19P brains (D)-(F). (WT: n = 14 brains, 28 lobes, 3 experiments; Mms19P: n = 11 brains, 22 lobes, 3 experiments; da>CAK, Mms19P: n = 15 brains, 30 lobes, 3 experiments; Mms19::eGFP, Mms19P: n = 14 brains, 28 lobes, 3 experiments; da>CAK; WT: n = 8 brains, 16 lobes, 2 experiments). Statistical significance (SS) was determined by the Kruskal-Wallis test. Multiple columns were compared using Dunn’s post test, ****(P<0.0001), ***(P<0.001), scale = 50μm.
Tab. 1. Fly stocks used for these studies.
Fly stocks used for these studies.
Tab. 2. Primary and secondary antibodies used for immunostainings.
Primary and secondary antibodies used for immunostainings.

To verify the requirement for Mms19 for normal brain development, we expressed wild-type Mms19 fused to eGFP (Mms19::eGFP) under the control of the endogenous Mms19 promoter in the Mms19P background to test whether the observed phenotype can be rescued by Mms19 activity. Mms19::eGFP fully rescued the brain morphology, the volumes of the whole brain lobe as well as the CB and OL sizes (Fig 1A, 1D–1F). This not only confirmed that the defects observed in the mutant are indeed due to the absence of Mms19 activity and not due to a second site mutation on this chromosome, it also showed that the Mms19::eGFP fusion protein is functional.

A mitotic activity of Mms19 was described to promote the Cdk-activating kinase activity of the Cdk7/CycH/Mat1 complex (CAK complex; [9]). The responsible mechanism appears to be a competitive binding of Mms19 to Xpd, which would otherwise recruit CAK to TFIIH, where it assumes a different substrate specificity and is unable to activate the M-Cdk Cdk1. The key result that led to this model was that the lack of imaginal discs caused by the absence of Mms19 activity could be rescued considerably by expressing the CAK complex components under the control of the Upstream Activating Sequence (UAS) enhancer, using the daughterless(da)-Gal4 driver in the Mms19P background (da>CAK, Mms19P) [9]. We, therefore, tested whether it was possible to rescue the small brain phenotype by the identical strategy. This was not the case, as in da>CAK, Mms19P brains both CBs and OLs remained smaller (Fig 1A, 1D–1F), the number of CB NBs was similar as in the wild type (Fig 1C) and the overall brain volume was reduced. These observations indicated that the mitotic cells in the Mms19P brains probably did not proliferate enough to produce the normal amount of neuronal tissue and that this defect might not only be caused by insufficient CAK activity. We also considered whether the expression of CAK under da-Gal4 control might cause the abnormalities leading to the reduced brain size. For this, we dissected brains from larvae expressing da>CAK in the wild-type background. However, we did not find significant changes in either the brain morphology (Fig 1A), the CB NB numbers (Fig 1C), or the CB and OL volumes (Fig 1E and 1F). This result, therefore, points to the possibility that Mms19 acts through two different pathways to achieve normal organ size.

In Mms19P mutant brains a higher proportion of NBs are in mitosis

In order to better understand the microcephaly phenotype, we performed 5-Ethynyl-2’-deoxyuridine (EdU) incorporation assays coupled with phosphorylated Histone H3 (pH3) staining and examined defects in cell cycle progression in the NBs. Based on pH3 and EdU staining, the cells can be allocated to one of the following phases: only EdU = S, i.e. cells in S phase; pH3 without EdU = M, i.e. cells undergoing mitosis; both EdU and pH3 = G2/M, i.e. cells transiting from S to G2/M phase; and neither EdU nor pH3 (= G1/G0, i.e. Gap phase; S2A Fig). As it is difficult to determine from pH3 staining alone, whether the cells are in the G2 phase or in M, we combined the double-positive cells as well as the pH3 positive cells in the same category and referred to this as ‘mitotic phase’. CB NBs were additionally marked with antibodies against Miranda (Mira) and the number of cells was counted in each class. The results are represented as a percentage of the total number of NBs per brain lobe. We observed that about half the NBs were not labeled (i.e. G1/G0 cells: 47–56%; S2B Fig) and the relative differences between the genotypes were small. However, lack of Mms19 caused a clear increase in the fraction of cells in the mitotic phase (37% compared to 28% in the wild type; S2D Fig). This result could either mean that more cells undergo divisions or that the Mms19P NBs are either trapped in M phase or proceed more slowly through it.

NBs depend on Mms19 for timely and coordinated spindle assembly and orientation

To study how Mms19 contributes to spindle assembly and progression through mitosis, we utilized a transgene that expresses EB1::GFP, a MT plus end binding and tracking protein that labels growing MT ends [14]. Live imaging of NBs expressing EB1::GFP revealed the dynamics of the formation of the mitotic spindle and allowed us to measure progression through the early part of the M-phase, including the period from Nuclear Envelope Break-Down (NEBD) to the onset of anaphase B. NEBD was determined by the appearance of the GFP signal in the nuclear region, which lacks a GFP signal until NEBD. To determine the onset of anaphase B, we analyzed the distribution of EB1::GFP and the spindle morphology throughout mitosis. EB1 localization and behavior during anaphase B has been studied previously [1517]. At the beginning of anaphase B, the spindle starts to elongate and this elongation is accompanied by an overall reduction in EB1::GFP fluorescence. We observed this pattern in WT NBs, where at 7 min post NEBD, the spindle slightly elongated, concomitant with a decrease in EB1::GFP fluorescence. NBs expressing EB1::GFP in the wild-type background started anaphase B approximately 6–8 min after NEBD (Fig 2A and 2C; S1 mov). On the other hand, NBs expressing EB1::GFP in an Mms19P background reached anaphase B onset only around 16–20 min after NEBD (Fig 2B and 2C; S3 mov).

NBs depend on <i>Mms19</i> for timely and coordinated spindle assembly and orientation.
Fig. 2. NBs depend on Mms19 for timely and coordinated spindle assembly and orientation.
(A-C) WT NBs typically start anaphase B 6–7 min after the onset of NEBD. (B) Mms19P NBs require on average 15–20 min to reach anaphase B onset. (B-C) n = 30 NBs per genotype, 1 experiment. The quantitative assessment of the duration of WT and Mms19P mitoses is compared in (C). SS was determined by an unpaired t-test (***P<0.001); Scale = 5μm. In this particular Mms19P NB (B) the spindle poles are not fully separated at NEBD and the spindle initially appears kinked. (D) To analyze centrosome positioning defects, we measured the angle between the two centrosomes relative to the center of the nucleus, just before NEBD. (E) In most WT NBs, the angle between the centrosomes fell between 135° and 180°. However, 20% of the mutant NBs displayed centrosome separation defects as the angle was lower than 135°. N = 25 per genotype, 1 experiment. Additionally, in some of the Mms19P NBs analyzed, the spindles changed their orientation throughout the course of mitosis, indicating spindle orientation defects. (F) Spindle orientation in the WT NBs is tightly coupled to the apical-basal polarity axis and this is reflected by the angle formed by the spindle with respect to the basal Mira crescent. (G) In a fraction of Mms19P NBs the spindle appears misoriented with respect to (w.r.t) the Mira crescent localization. (H-J) Quantification of the spindle angle revealed that a considerably higher number of Mms19P NBs are oriented at an angle of more than 10° w.r.t Mira. Significance was calculated using Fisher’s exact test, *(P = 0.0309). n = 65 NBs per genotype, 3 experiments, scale = 5μm.

Interestingly, in some of the EB1::GFP expressing Mms19P NBs, the spindle formation started before the two centrosomes had finished migrating to the opposite sides of the nucleus (Fig 2B; S3 mov). As a result, at 3 min, a kinked spindle was observed, which eventually straightened out at 5 mins. To quantify defects in centrosome migration/positioning, we used a method described previously [18] to measure the angle between the 2 centrosomes just before NEBD (Fig 2D). In all of the WT cells, the angle between the centrosomes was in the range of 135° to 180°. But in around 20% of Mms19P NBs, severe centrosome mispositioning was noted as the angles fell into the range of 45° to 135° (E). In one case of an Mms19P NB spindle, only one centrosome started nucleating MTs (S5C Fig; S8 mov). The spindle remained monopolar until 6 min post-NEBD and only then, a bipolar spindle became apparent. Further, around 20% of the spindles in Mms19P NBs changed their orientation during the course of mitosis (Fig 2B; S3 mov), while all wild-type spindles examined remained firmly anchored at the cortex and did not change their orientation (Fig 2A).

Drosophila larval NBs are characterized by a defined apical-basal polarity [19] where the atypical Protein Kinase C (aPKC)-Bazooka-Pins complex localizes to the apical cortex while Miranda localizes to the basal cortex (Fig 2F). Retention of NB identity and self-renewal depends on the inheritance of the aPKC-containing apical complex whereas differentiation of the GMC relies on the inheritance of the Mira-bound cargo of the basal cortex [23]. Therefore, the orientation of the mitotic spindle is tightly coupled to this apical-basal polarity axis [20,21]. We therefore further examined the spindle orientation defects in fixed cells labeled with the polarity marker Miranda (Mira), which localizes to the basal cortex of the NB, forming a crescent-like pattern. We found that most of the wild-type spindles form at an angle of 10 degrees or lower relative to Mira (Fig 2G, 2H and 2J). On the other hand, Mms19P NBs more frequently failed to align their spindles within 10 degrees (Fig 2G, 2I and 2J) and the largest tilt that we observed was around 60°. However, a marked effect on cell fate determination is only observed when the spindle angle gets close to 90° [22,23]. In such cases, even though both daughter cells inherit a part of the Mira-containing basal cargo, this is not sufficient to drive differentiation. Instead, both cells assume a NB identity, leading to an increase in NB numbers per brain lobe [23]. Consistent with this spindle orientation defect being insufficient to cause major NB amplifications, we did not see a significant difference in NB numbers per brain lobe between the wild type and Mms19P (Fig 1C). Therefore, the relatively minor spindle orientation defect due to lack of Mms19 does not appear to lead to differentiation problems but impedes efficient mitosis. We conclude that in the absence of Mms19, spindle formation is not properly coordinated with cell cycle progression. Furthermore, defects in centrosome migration and in spindle assembly and orientation contribute to mitotic delays in Mms19P NBs.

Mms19 is cell autonomously required to maintain normal cell numbers

In the experiments with the Mms19P mutants, Mms19 was absent from all larval cells. In this situation, the mitotic delay could be due to a systemic effect or due to the lack of a cell-autonomous activity of Mms19. To test whether Mms19 is specifically required in the mitotic cells for the timely progression through mitosis, we generated Mms19P mosaic NB clones in an otherwise wild-type background. Mosaic clones were induced in NBs 24hrs after larval hatching (ALH) and the expansion of these clones was analyzed by dissecting the brains in mid-third instar larvae 72hrs ALH. For this experiment, we focused on the type I NBs on the ventral side. On average, 45 cells per clone were found in control clones, but only around 30–35 cells in Mms19P clones (P<0.05; S3A–S3C Fig), indicating that the cell-autonomous loss of Mms19 activity hinders the establishment of normal cell numbers in the NB lineage. This observation reaffirms our conclusion that the absence of Mms19 delays mitosis in NBs and that this mitotic delay probably causes more Mms19P NBs to linger in M-phase (S2 Fig).

Mms19 is required to form spindles of normal length and density

Mms19P spindles were found to be generally shorter than the wild-type ones (Fig 3A–3D). In normal NB spindles, the centrosomes were anchored close to the cell cortex, with spindle MTs emanating from them and extending to the chromosomes (Fig 3A and 3A’). But in around a quarter of the mutant cells, even though the chromosomes were aligned at the metaphase plate, the centrosomes were not connected to the cell cortex and were only a short distance away from the metaphase plate (Fig 3B and 3B’). In order to quantify this defect, we measured the length of the spindles across all genotypes and found that the spindles in Mms19P and da>CAK, Mms19P were generally shorter than the wild-type control spindles (S3 Table). As the NBs were also considerably smaller in Mms19P and da>CAK, Mms19P brains, we additionally displayed the spindle length relative to the cell diameter (Fig 3C). A ratio closer to 1 indicates that the centrosomes were anchored close to the cell cortex, as in a healthy spindle. On the other hand, if the ratio was equal to or lower than 0.6, the spindle was defined as a ‘short spindle’ because the centrosomes were further inside the cell. We found a significant reduction in this ratio in Mms19P and da>CAK, Mms19P NB spindles (Fig 3C and 3D). Mms19P NBs contained around 20% short spindles while this number went up to 30% for da>CAK, Mms19P (Fig 3D). The failure of CAK to rescue the Mms19P phenotype was not due to mitotic defects induced by over-active CAK; because NBs overexpressing CAK in the wild-type background displayed a spindle length/ cell diameter ratio comparable to wild-type NBs (Fig 3C and 3D). On the other hand, expression of Mms19::eGFP in the Mms19P background rescued the short spindle phenotype and only 3% of the NBs displayed it. These findings once again highlight the possibility of a CAK independent function of Mms19 in regulating spindle architecture.

<i>Mms19</i> is required to form a spindle of normal length and density.
Fig. 3. Mms19 is required to form a spindle of normal length and density.
(A-A’) Z projection of a typical bipolar spindle in a wild-type (WT) NB with the spindle poles anchored to the cell cortex. (B-B’) short spindle found in Mms19P NBs. The spindle is abnormally short and the spindle poles are detached from the cortex. (C) In order to quantify spindle elaboration, we normalized the spindle length to the cell diameter and calculated the ratio. This ratio decreases significantly for Mms19P NBs. (**P = 0.0027). This phenotype is rescued by expressing Mms19::eGFP in the Mms19P background (**P = 0.0067) but da>CAK fails to rescue the short spindles (P>0.99). SS was calculated using Kruskal-Wallis test, columns were compared using Dunn’s post test. (D) If this ratio was equal to or less than 0.6, we considered the spindle as ‘short spindle’. The graph compares the percentage of ‘short spindles’ across different genotypes. Significance was calculated using Fisher’s exact test, (****P<0.0001, **P = 0.0025). WT; Mms19P; da>CAK, Mms19P; Mms19::eGFP, Mms19P: n = 90 NBs, 3 experiments. da>CAK, WT: n = 30, 2 experiments. (E-F) Relative density of astral MTs was quantified and compared across all genotypes. Maximum intensity projections of mitotic NBs were obtained (E) and the relative density of astral MTs was quantified by first calculating the inner spindle MT density (inner dotted ellipse) and then subtracting this from the MT intensity from the entire cell (outer dotted circle). This value was then divided by the inner spindle intensity to obtain the relative astral MT density (F). (G) Astral MT density and (H) inner spindle fluorescent intensity was measured in fixed NBs immunostained for α-Tubulin and compared across all the genotypes. Both astral and inner spindle densities were decreased significantly in Mms19P NBs as compared to WT NBs. Additional expression of da>CAK appeared to partially rescue the phenotype, but this rescue was not statistically significant (astral: P = 0.2633; inner spindle: P = 0.1789). Mms19::eGFP, when expressed in the Mms19P background, rescued the phenotypes. WT; Mms19P; da>CAK, Mms19P; Mms19::eGFP, Mms19P: n = 60 NBs, 3 experiments. da>CAK, WT: n = 27, 2 experiments. SS was calculated using Kruskal-Wallis test, columns were compared using Dunn’s post test. ****P<0.0001, ***P<0.001; **P<0.01, *P<0.05, scale = 5μm.

To determine the effect of Mms19 on MT formation and stability, we measured astral as well as inner spindle MT density. For astral MT quantification (Fig 3F), we used the method described by Yang and co-workers [24] and found a significant reduction in the Mms19P NBs as compared to the wild type (Fig 3E–3G). The inner spindle density was also reduced in the Mms19P NBs (Fig 3H). This phenotype appeared to be slightly rescued by CAK overexpression and was fully rescued by expressing Mms19::eGFP in the Mms19P background. Reduced astral MT stability could be linked to the spindle positioning and orientation defects described previously (Fig 2B, 2E, 2G–2J) as astral MTs were shown to contact the cell cortex and regulate spindle positioning [25]. Mms19 is thus necessary for the formation of fully assembled spindles and astral MTs.

Mms19 assists MT polymerization in vivo

To assess whether the abnormal spindle phenotypes in Mms19P NBs could arise due to defects in MT growth in vivo, we studied NBs expressing EB1::GFP. Live imaging of EB1::GFP revealed the path of elongation of single MTs, akin to that of a comet, and the movement speed of the GFP signal reflects the growth speed of the MT plus ends. Wild-type and Mms19P larval brains expressing EB1::GFP were dissected and live imaging was performed. The speed of the EB1::GFP particles was then tracked manually using ImageJ. The measurements indicated that the spindle MTs of wild-type NBs polymerized at a rate that is significantly higher than the rate observed in Mms19P NBs (Fig 4A–4C; WT- S4 mov; Mms19P- S5 mov). To assess whether the MT assembly function of Mms19 is restricted to mitotic spindles, we also tested whether the absence of Mms19 also affects MT polymerization in the post-mitotic glia cells. Measuring EB1 comet speeds in glia cells showed a decrease in MT growth for Mms19P glia as compared to wild-type glia (Fig 4D–4F; WT- S6 mov; Mms19P- S7 mov). These results established that Mms19 assists MT polymerization and growth in vivo in mitotic NBs and in post-mitotic glia. The reduced MT growth rate described here seems to be a major factor for the delay in spindle assembly observed in Mms19P brain NBs. Whereas approximately 3 minutes after the onset of NEBD, wild-type spindles had fully assembled (Fig 2A; S1 mov), most Mms19P ‘spindles’ appeared to be short at 3min post-NEBD, and their MT density seemed much lower than in the wild type (S2 mov; S8 mov).

<i>Mms19</i> assists MT polymerization <i>in vivo</i>.
Fig. 4. Mms19 assists MT polymerization in vivo.
(A-B) WT and Mms19P NBs expressing EB1::GFP were imaged live, and time-lapse movies were acquired to calculate the velocity of EB1::GFP labelled MT ‘plus’ ends. The left panel shows the image of a single time frame. The central panel shows a projection of 20 time points (taken over 10s). In the far right panel, individual EB1::GFP comets are tracked. The velocities represented in (C) show reduced MT growth velocity in Mms19P NB spindles. n = 11 cells per genotype, 4–5 tips analyzed from each cell, 1 experiment. (D-E) EB1::GFP expressing surface glia cells were imaged live to analyze the MT plus end velocities. The left panel shows a single time frame and the right-side panel shows a projection of 20 time points (taken over 10s). The velocities represented in (F) show reduced MT growth velocity in Mms19P glia. n = 15 brains from each genotype, 7–8 tips analyzed from each brain, 1 experiment. SS for C and F was calculated using unpaired t-test, (***P<0.001), scale bar = 5μm.

Mms19 is required for spindle re-assembly

To learn more about the Mms19 function in spindle MT growth, we performed the in vivo spindle re-growth assay described by Gallaud and co-workers [18]. With this procedure, the NB spindles were depolymerized by incubation on ice for 30 min (Fig 5A, left panel). Large centrosomal asters were observed in the WT NBs after they were shifted back to 25°C for 30s (Fig 5A, central panel). MT fibers also appeared to be nucleated around the chromatin (i.e. in the central region between the centrosomes; Fig 5A, central panel). Wild-type NB spindles then regained their standard size and morphology within 90 sec after being shifted back to 25°C (Fig 5A, right panel). In Mms19P NBs, we also observed a weak astral MT mesh at 30s. However, the spindles failed to re-form to the normal shape after 90 sec. Instead, they remained abnormally short (Fig 5B and 5F). Interestingly, whereas the Mms19::eGFP fusion protein was able to rescue this phenotype, CAK overexpression was unable to do so (Fig 5C and 5D). To validate this short spindle phenotype, we calculated the spindle sizes relative to the cell diameter after 90 sec incubation at 25°C (Fig 5F). Even though Mms19P cells are smaller, their normalized spindle size was still significantly smaller than the wild-type one. When CAK was overexpressed in Mms19P NBs, the normalized spindle length did not show a significant rescue even though Mms19::eGFP was able to rescue the Mms19P mutant phenotype (Fig 5F and 5G). The lack of rescue by CAK overexpression does not seem to be caused by a CAK gain-of-function activity, because, again, wild-type NBs that overexpressed CAK did not display such defects in spindle length (Fig 5E–5G). This result shows that Mms19 has an important role in establishing proper spindle MT length and that a CAK independent activity of Mms19 is also involved in this.

<i>Mms19</i> is required for spindle re-assembly.
Fig. 5. Mms19 is required for spindle re-assembly.
After cold treatment, spindle re-assembly was analyzed at 0 sec (i.e. immediately after cold treatment; left panel), 30 sec (central panel), and 90 sec (right panel) after shifting them to 25°C. For this, the tissue was fixed and immunostained for α-tubulin. At 0 sec in the WT NBs (A), only centrosomes were visible, but after incubation at 30 sec, few fibers had nucleated from the centrosomes and around the chromatin. At 90 sec, the spindle regained its normal shape and density. In Mms19P NBs (B), spindles did not regain the normal shape after 90 sec. Additionally, the microtubule density was reduced in these stunted spindles. Expression of Mms19::eGFP in the mutant background (C), rescued spindle reformation, but overexpression of CAK (D) rescued only slightly and the length and density of MT still appeared reduced (B,D,F: P>0.99). (E) Overexpression of CAK in the WT background did not affect spindle re-growth. (F) The scatter plot shows the spindle length relative to the cell diameter after 90 sec incubation at 25°C. The normalization eliminates variations due to varying cell sizes. SS was calculated by Kruskal-Wallis test, columns were compared by Dunn’s post test (***P<0.001), (**P<0.01). (G) The graph compares the percentage of ‘short spindles’ across different genotypes. SS was calculated using Fisher’s exact test (****P<0.001). Scale = 5μm. WT; Mms19P; da>CAK, Mms19P; Mms19::eGFP, Mms19P: n = 60 NBs, 3 experiments. da>CAK, WT: n = 20, 2 experiments.

Centrosomal localization of the MT regulator TACC depends on Mms19

Transforming Acidic Coiled-Coil (TACC), a downstream target of Aurora A kinase, is a critical regulator of centrosomal MTs. During mitosis, Aurora A phosphorylates TACC and stimulates its localization on the centrosomes, where TACC further recruits mini-spindles (Msps). Loss-of-function mutations in either Aurora A, TACC, or msps show drastic abnormalities in astral and spindle MTs [26,27]. As Mms19P NBs display defects in centrosomal separation, spindle length, and astral MTs, we examined whether Aurora A and TACC might be involved in the same process as Mms19 and if the absence of functional Mms19 impedes TACC localization and function. We, therefore, stained wild-type and Mms19P NBs for TACC and observed a strong signal at the wild-type centrosomes (Fig 6A). On the other hand, in >50% of Mms19P NBs, TACC did not show any enrichment on the centrosomes (Fig 6B and 6D). Similar results were also obtained with the TACC interactor Msps (S4A–S4D Fig). As TACC acts downstream of the Aurora A kinase, we also examined the localization of Aurora A and found it to be depleted from centrosomes in Mms19P NBs (S4E–S4G Fig). Because Aurora A itself acts downstream of Cdk1 [28], this defect might be caused by insufficient CAK activity in Mms19 mutants [9]. We tested this hypothesis by over-expressing the three CAK components in the Mms19P background (da>CAK, Mms19P). Indeed, upon CAK overexpression, the fraction of spindles displaying centrosomal TACC almost reached wild-type levels (Fig 6C and 6D). To quantify the enrichment of TACC on centrosomes, we compared the fluorescence intensity of centrosomal TACC to the TACC fluorescence intensity on the spindle. This ratio decreased in Mms19P NBs but was rescued in da>CAK, Mms19P NBs (Fig 6E). It was also reported that Aurora A loss-of-function can cause centrosome fragmentation [26]. Co-staining Mms19P NBs with antibodies against the centrosomal protein γ-Tubulin showed that even when the TACC signal was not seen on centrosomes, the centrosomal γ-Tubulin was still present, indicating that TACC mislocalization is not caused by centrosome fragmentation (Fig 6F and 6G). These findings indicate that centrosomal localization of TACC and its stimulation of astral and spindle MT stability or growth is at least partially dependent on Mms19 and CAK activity.

Centrosomal localization of the MT regulator TACC depends on <i>Mms19</i>.
Fig. 6. Centrosomal localization of the MT regulator TACC depends on Mms19.
(A) A mitotic NB shows TACC localization at the spindle poles. (B, D) >50% of analyzed Mms19p NBs fail to localize TACC to spindle poles. SS was calculated using Fisher’s exact test (****P<0.0001). (C, D) TACC localization was restored upon expression of additional CAK subunits (Cdk7, CycH, and Mat1) in the Mms19P background. (E) The amount of TACC localized on the centrosomes was quantified by comparing the fluorescent intensity of the centrosomal TACC signal to the TACC signal on the spindles. A ratio greater than 1 was considered as clear centrosomal TACC, while a ratio equal to or less than 1 indicated unlocalized TACC. SS was calculated by Kruskal-Wallis test, columns were compared by Dunn’s post test (***P<0.001), scale = 5μm. n = 25 NBs per genotype, 3 experiments. (F, G) NBs were stained with antibodies against γ-Tubulin to test for centrosomal localization. (F) TACC co-colocalized with γ-Tubulin on wild-type centrosomes. (G) In the mutant NB, TACC fails to concentrate at γ-Tubulin foci.

Mms19 binds to MTs and stimulates MT assembly

To explore the possibility that Mms19 also functions through different activities, we prepared protein extracts from flies expressing Mms19::eGFP driven by its endogenous promoter [9]. We subjected them to immunoprecipitations (IP) and analyzed co-purifying proteins by Mass spectrometry (S1 Table). Adult wild-type flies and Imp::eGFP expressing flies, respectively, served as controls to exclude any non-specific binding to beads and GFP, respectively. Amongst the proteins exclusively bound to Mms19::eGFP were the CIA proteins Mip18, Ciao1, and Ant2, which form a complex with Mms19 to mediate Fe-S cluster delivery [6,7]. The fact that we recovered these proteins efficiently, indicated that the purification was efficient. Because Mms19 functions on microtubules and our second control, IMP::eGFP, is also involved in MT dependent processes, we additionally inspected the data for tubulin and MT binding proteins that are enriched by the Mms19::eGFP IP compared to the wild-type control without an eGFP tag (S2 Table). This comparison revealed a clear enrichment of tubulin and several Microtubule Associated Proteins (MAPs). Some of the associated proteins were not present in the wild type control, some were present in the Mms19::eGFP and IMP::eGFP fractions, and others exclusively in the Mms19::eGFP fraction. These results, therefore, suggested that Mms19 might directly or indirectly bind to MTs.

To validate the interaction of Mms19 with tubulin, we next tested whether purified Mms19::5xHis and α/β-Tubulin dimers interact in vitro. Mms19::5xHis was purified from E.coli to avoid co-purification of MAPs, and this purified protein fraction showed a single band when separated by SDS-PAGE and stained with Coomassie Blue (Fig 7A). Mms19::5XHis was incubated at an equimolar ratio with purified porcine brain α/β-Tubulin and then bound to the Ni-NTA resin. All incubations and washing steps were carried out at 4°C. Copurifying proteins were then assessed by western blotting (see Table 3 for details regarding the antibodies used). A band corresponding to α-Tubulin was observed when tubulin was incubated with Mms19::5xHis (Fig 7B and 7C), but tubulin alone did not bind to the resin, pointing to a direct interaction between tubulin and Mms19::5xHis.

Mms19::5xHis binds to tubulin and stimulates MT assembly <i>in vitro</i>.
Fig. 7. Mms19::5xHis binds to tubulin and stimulates MT assembly in vitro.
(A) Mms19 tagged with 5X Histidine was purified from E. coli. A single band at approximately 100KDa is seen when the purified protein fraction is separated by SDS-PAGE and stained with Coomassie Blue. Mms19::5xHis-tubulin interaction was investigated using a pull-down assay with Ni-NTA resin. Tubulin binding to Mms19::5xHis is expected to result in co-purification of tubulin with Mms19::5xHis. (B) Input panels show tubulin added, either alone or with Mms19. (C) Tubulin was found binding to the resin only upon prior incubation with Mms19::5xHis (tubulin added alone did not bind to the resin). (D) MTs only (without Mms19::5xHis added) were visualized by negative stain EM. Here, an MT fiber can be seen depolymerizing (indicated by arrow). (E) In an MT-Mms19::5xHis mixture, discreet particles can be seen binding laterally along the surface of MTs. (F) Measuring the length of MT fibers revealed that MTs were generally longer when incubated together with Mms19::5xHis compared to MTs to which only the BRB80 buffer was added. n = 150 MTs per condition, 3 experiments, ss was calculated using student’s t-test, ****P<0.0001. MT bundles containing 2 (G) or more than 2 MTs (H) were more frequently observed upon the addition of Mms19::5xHis to MTs. The number of bundles observed in each condition is quantified in (I).
Tab. 3. Antibodies used for probing western blots.
Antibodies used for probing western blots.

To better understand the mechanism of modulation of the MT dynamics by Mms19, we complemented the biochemical experiments with a high-resolution optical method. Polymerized MTs were incubated at room temperature (RT) with either BRB80/solvent buffer or with Mms19::5xHis, purified upon expression in E. coli (Fig 7A). These samples were then visualized by negative stain electron microscopy (EM). MT fibers in general appeared to be less stable upon the addition of BRB80/solvent alone (at RT) as some MT fibers were observed undergoing de-polymerization (Fig 7D) under these conditions. Remarkably, MTs incubated with Mms19::5xHis were comparatively longer (Fig 7E and 7F) and more bundled (Fig 7G, 7H and 7I). Furthermore, the Mms19::5xHis containing samples contained particles not found in the samples without Mms19 and these particles appeared along the lateral MT surface (Fig 7E and 7H). It thus appears that Mms19 might bind along the surface of MTs, facilitating their assembly or stabilizing MTs, and possibly stimulating inter-MT contacts.

Discussion

Mms19 was initially identified as a gene that acts in the nucleotide excision repair (NER) pathway. In this DNA repair pathway, it provides an Fe-S cluster to other NER enzymes. When evidence emerged about a possible NER independent mitotic activity of Mms19 [8,9], this warranted further investigations into the precise role of Mms19 during mitotic spindle assembly in diploid cells. We now report novel, important roles of Mms19 for astral MT assembly, spindle establishment, and orientation, and mitotic timing in Drosophila NBs. We provide strong evidence that Mms19 regulates spindle assembly by promoting the activity of the Cdk activating kinase CAK, and we identified Aurora A and TACC as its downstream targets in this pathway. Further, in vitro data points to a CAK-independent activity where Mms19 directly binds to tubulin and thereby regulates MT assembly and stability.

The trimeric CAK complex is an essential activator of entry into and progression through the initial phase of mitosis because an activating T-loop phosphorylation by Cdk7 is required to fully activate Cdk1 [29,30]. In this activation, Mms19 seems to perform a crucial task of sequestering Xpd in order to allow CAK to fully activate Cdk1 (S6A Fig). This is evident from the rescue of imaginal disc morphology, the rescue of the TACC localization to the centrosomes, and possibly by a slight rescue of the NB spindle phenotypes by CAK overexpression in the Mms19P background [9] (Fig 3G and 3H; Fig 6). Cdk1 along with other mitotic kinases such as Aurora A and Polo regulate a multitude of mitotic processes including centrosome maturation, bipolar spindle assembly, and mitotic checkpoint activation [31,32]. Centrosome maturation and entry into mitosis were known to be driven by positive feedback loops between Cdk1, Aurora A, and Polo [32,33]. Additionally, it was shown that Cdk1 acts upstream of Aurora A as it activates Aurora A during the G2/M transition [28]. Cdk1 was also shown previously to regulate the cytoplasmic localization of Bora, an activator of Aurora A, in Drosophila sensory organ precursors [34]. Our demonstration that Mms19 is required for the localization of Aurora A to the centrosomes (S4E–S4G Fig) nicely fits into this model because Mms19 promotes the mitotic kinases cascade through CAK-Cdk1 [9], and one function of Cdk1 is to activate Aurora A. Further, Aurora A directly phosphorylates TACC thereby triggering its centrosomal localization [26]. Given that the failure of TACC localization in the absence of Mms19 can be rescued by CAK over-expression, we now propose TACC as a downstream target of the Mms19-CAK-Cdk1 axis. In this process, the modulation of the CAK activity seems to be the main mode of action of Mms19 towards TACC. The best-characterized function of TACC is its interaction with Msps which leads to the stabilization of astral MTs [35]. This activity involves their recruitment to the centrosomes, and we found that not only the centrosomal localization of TACC (Fig 6) but also the one of Msps depends on Mms19 and elevated CAK activity (S4A–S4D Fig). Additionally, it has been reported that Aurora A also mediates the timely degradation of Cyclin B and that NBs lacking functional Aurora A spend more time in mitosis due to delayed Cyclin B degradation [36]. Apart from the spindle assembly defects this effect could also contribute to the mitotic delay observed in Mms19P NBs. The identified pathway downstream of Mms19 might thus promote spindle assembly and regulate mitotic duration.

The phenomenon of centrosome asymmetry is well documented in Drosophila NBs where, after centriole duplication, the daughter centriole retains MT nucleation activity and is anchored to the apical cortex whereas the mother centriole generates an aster just before NEBD [37]. Interestingly, despite this asymmetry, aster formation from both centrosomes happens synchronously in WT NBs. Conversely, a striking feature of some of the Mms19P NBs is the delay in MT assembly from the ‘mother’ centrosome destined for the GMC (S5B and S5C Fig; S3 mov; S8 mov). In the example presented in S8 mov, the ‘mother’ centrosome seems to be unable to nucleate MTs until 7–8 minutes post NEBD. Importantly, even in this case, the spindle is bi-astral, indicating that the centrioles have duplicated normally, producing a functional pair of centrosomes. From this, we can narrow down the function of Mms19 to the assembly of centrosomal MTs. The astral MTs are likely a main target, and their drastic loss in the Mms19 mutants the main cause of the observed defects in centrosome migration and spindle orientation, because both these processes require contact of long astral MTs with the cortex [25,38].

It has been established that mitotic spindle assembly in mammalian cells or in Drosophila NBs is driven by both centrosomal MTs and MTs emanating from the chromatin [39,40]. We focused our studies mainly on the MTs emanating from the centrosomes because we were able to link the Mms19 activity to the localization of TACC and Msps to this place. However, the formation of MTs around the chromatin might also be affected in the Mms19P NBs. Spindle assembly normally also initiates around the chromatin, and an MT meshwork is seen forming in the region around the chromatin [40]. In the MT re-growth assay in the Mms19P NBs (Fig 5B), we observed a MT mesh forming in the region around the chromatin at t = 30s. But compared to wild-type NBs, the length and density of MTs in this region remained abnormally short at t = 90s. Additionally, measuring the inner spindle density (Fig 3H) revealed a significant decrease in Mms19P NBs. As chromatin-nucleated MTs would also contribute to the MT density in the inner spindle, these results indicate defects in the assembly of MTs around chromatin. Furthermore, live imaging of Mms19P NBs (S2 mov, S8 mov) showed that the overall spindle MT mesh was initially very sparse, and only after 7-8min post NEBD, a fully assembled spindle with MT density comparable with wild-type NB spindles became visible. These findings thus indicate that Mms19 is needed for MT formation from both centrosomes and from around the chromatin.

CAK overexpression rescued TACC localization, but it could not fully rescue the spindle assembly/short spindle and the microcephaly phenotypes (Figs 1, 3 and 5). Earlier reports [9,41] suggested a direct interaction between Mms19 and MTs as Mms19 was shown to partially co-localize with spindles in mammalian cells and Drosophila embryos. We made similar observations in NBs expressing Mms19::eGFP (S5D Fig). Mms19::eGFP partially co-localizes with the spindles and seems to be enriched on astral MTs. Additionally, Mms19::eGFP also co-localizes with the MT bundles in the neurite of cultured neurons (S5E and S5F Fig). In this study, we report for the first time a direct interaction between Mms19 and tubulin, and we linked this interaction to an activity of Mms19 in stimulating MT assembly and stability (Fig 7). Even though more work is needed to understand this activity, the first results on this additional function are intriguing and call for its further exploration.

Recently, it was shown that Mip18/Galla-2 and Xpd, which are binding partners of Mms19 [8,9], form a complex called ‘CGX’ (Crumbs/Galla-2/Xpd), and this complex recruits Kpl61F, the fly homolog of Kinesin-5, to the embryonic spindle [42,43]. Kinesin-5 activity is crucial for centrosome separation and bipolar spindle assembly [44]. Even though a direct interaction between Mms19 and Kinesin-5/Kpl61F has not been reported [43] (this work) and we do not see the typical monopolar spindle defect associated with Kpl61F [40] in the Mms19P NBs, it is possible that the absence of Mms19 may compromise the activity of the CGX complex, too, and that the misregulated Kinesin-5/Kpl61F activity might contribute to the observed spindle defects.

Based on our findings and published data [9,45,46], we propose a model that outlines the CAK dependent and independent activities of Mms19 required for efficient mitotic spindle assembly in diploid cells. In the CAK dependent pathway model (S6A and S6B Fig), Mms19 competes with the CAK complex for binding to Xpd [8,9]. We hypothesize that CAK is mostly associated with Xpd during interphase, and integrated into the TFIIH complex, where its mitotic activity is inhibited. Although basal levels of CAK activity might persist, they would not be sufficient for full activation of Cdk1 (S6A Fig). During mitosis, binding of Mms19 to Xpd prevents the interaction between Xpd and the CAK complex and between Xpd and the core TFIIH. This releases the inhibition of the Cdk-activating kinase activity of CAK by Xpd and allows CAK to fully activate Cdk1 to drive mitosis [9,45]. Upon knockdown or inactivation of Mms19, more CAK would remain bound to Xpd and TFIIH, preventing it from optimally activating Cdk1 (S6B Fig). Nevertheless, basal levels of free CAK would remain present. Such reduced levels of CAK activity might still allow the cells to enter mitosis but would be unable to activate adequate levels of Cdk1. The low levels of Cdk1 activity would thereby affect the downstream pathways, such as the localization of TACC and Msps through Aurora A (S6B Fig). Additionally, we now found evidence for a CAK-independent activity where Mms19 directly binds to MTs, promotes MT stability, and stimulates inter-MT contacts (Fig 7, S6C Fig).

Mms19, a gene initially described as a NER regulator, evidently has clear and essential additional roles as a mitotic gene and as an MT regulator. Given the critical roles it fulfills, the proper control of Mms19 expression and localization must be crucial for the proper functioning of Mms19. Future studies should therefore address the transcriptional and post-translational control of Mms19 expression and localization and how this impacts its functions in cell physiology, development, and diseases.

Materials and methods

Dissection and immunostaining of larval brains

Larval brains were dissected and stained as described [47]. Briefly, wandering third instar larvae were dissected in PBS and fixed for 15min in 4% paraformaldehyde supplemented with 0.3% Triton X-100, 100mM PIPES (pH 6.9), 1mM MgSO42 and 1mM EGTA (to stabilize MTs). After 3 washes in PBS+0.1% TritonX-100 (PBST), primary antibodies were added (Table 2). After overnight incubation, the brains were washed 3x with PBST, stained with secondary antibodies (Table 2), and mounted on glass slides in Aqua Polymount mounting medium (Polysciences; for details on reagents and kits, see Table 4).

Tab. 4. Kits and reagents used for these studies.
Kits and reagents used for these studies.

For MT regrowth assays, brains were dissected in Schneider’s medium (supplemented with 10% fetal bovine serum) at 25°C and incubated on ice for 30 min to depolymerize MTs. Brains were then incubated for different time points in a 25°C water bath, followed by fixation and immunostaining. This experiment was performed three times and 20 spindles were analyzed in each iteration. Slides were imaged on a Leica TCS-SP8 microscope (Leica Microsystems) equipped with a 63X, NA 1.4 Plan Apochromat objective. Images were acquired using LAS X software and analyzed using Fiji/ImageJ [48] (see Table 5 for details regarding the special software used).

Tab. 5. Software used.
Software used.

Measuring brain compartment volumes

Whole brain lobes were immunostained with antibodies against Miranda (Mira) and phospho-Histone 3 (pH3), and DNA was visualized with Hoechst 33342. Z stacks were acquired with a TCS-SP8 confocal microscope on a 63X, 1.4NA Plan-Apochromat objective with 1μm spacing between each optical section. Segmentation, volume measurement, and 3D reconstruction was performed by using the TrackEM2 plugin in Fiji [49].

MARCM crosses

For generating mosaic clones we used the methods described previously [50] with modifications. Briefly, the driver stock hs-flp; tub-Gal4, UAS-mCD8::GFP/CyO, actin::GFP; FRT82B, tub-Gal80/TM6, Tb was crossed to +; FRT82B, Mms19P/TM6, Tb. GFP-Balancer negative 24hr old larvae were selected and heat shocked at 37°C in a glass vial submerged in a water bath for 15min. Larvae were then returned to 25°C and the brains of the non-Tubby larvae were dissected 48hrs later.

Live imaging

Brains expressing EB1::GFP were dissected and mounted on stainless steel chambers as described in [51]. Brains were then imaged using a 100X, NA 1.3 oil immersion objective on a Visiscope Spinning disk microscope (Visitron GmbH) fitted with Nikon Ni2 stand, a CSU-W1 scanner unit, and a Photometrics Evolve 512 EMCCD camera. Images were acquired for 60 seconds with 500ms time intervals at 200ms exposure at 60% laser power (488nm). To track the particle velocities, the particles were manually traced in Fiji/ImageJ [48]. Probably due to limited resolution, it was not possible to unambiguously account for merging or splitting events, and therefore only particles with a linear trajectory, which did neither split nor merge, were analyzed. At least 4–5 particles from each spindle were analyzed from a total of 11 cells per genotype. For surface glia quantification, at least 7–8 particles were analyzed from each of the 15 brains. Stacks were exported to.AVI movies at 14 frames per second.

To measure the NEBD to Anaphase B duration, EB1::GFP expressing brains were mounted as described above and imaged at 40% laser power with a 63X, 1.3 NA objective of a Nikon W1 LIPSI spinning disk microscope fitted with a Photometrics Prime 95B CMOS camera. Movies were acquired on Nikon’s NIS elements software for 2hrs with an interval of 1 min at 200 ms exposure. Z-stacks were acquired simultaneously with 2μm distance between successive optical sections. Movies were analyzed and processed with Fiji/ImageJ. Stacks were exported to.AVI movies at 12 frames per second.

Quantification of spindle orientation

The orientation of the mitotic spindle was examined with respect to the basal Mira crescent. A reference line was drawn passing approximately through the center of the Mira crescent and the angle between the spindle and this reference line was determined using the ImageJ angle tool.

EdU incorporation

Click-it EdU kit (Invitrogen) was used to measure EdU incorporation. Brains were dissected in PBS and incubated in Schneider’s medium supplemented with 10μM 5-Ethynyl-2’-deoxyuridine (EdU) for 2hrs at 25°C. EdU is an analog of Thymidine and is incorporated by S phase cells during DNA replication. EdU is then detected due to its binding to a dye-azide conjugate. Brains were subsequently fixed with 4% PFA and incubated with primary antibodies (anti-Mira to mark NBs and anti-pH3 to mark mitotic cells) and secondary antibodies. Subsequently, they were processed for EdU detection following the manufacturer instructions.

Preparation of whole-fly extract

1g of flies were collected in Eppendorf tubes and frozen in liquid nitrogen. Frozen flies were crushed into a fine powder using a pre-cooled mortar pestle. The powder was incubated in lysis buffer (25mM Hepes, 150mM NaCl, 1mM EDTA, 0.1% TritonX-100, 1mM phenylmethylsulfonyl fluoride (PMSF), 1 complete EDTA-free protease inhibitor tablet (Roche/Sigma-Aldrich) for 30 min and then centrifuged in an Eppendorf tube for 30 min at 16,000 g and 4°C. The supernatant was saved and snap-frozen in liquid nitrogen.

Immunoprecipitation to prepare extract for Mass Spectrometry

ProteinG-Mag Sepharose (GE) beads were washed 3X with PBS, incubated for 2hrs with anti-GFP antibody (3E6, provided by Anne Marcil). Beads were then incubated with the crude extracts for 6hrs at 4°C. Following 3 washes with the wash buffer (25mM Hepes, 150mM Nacl, 1mM EDTA, 1mM PMSF, 1 tablet complete EDTA free protease inhibitor tablet), bound proteins were eluted by 15 min incubation in urea elution buffer (6–8 M Urea, 20 mM Tris pH 7.5, and 100 mM NaCl) or glycine elution buffer (100mM Glycine, pH 2.6. These eluates were neutralized by adding 150mM Tris-Cl, pH 8.8).

Mass-spectrometry

Eluted proteins in 8M urea were processed essentially as described by Engel and colleagues [52]. Briefly, proteins were reduced by the addition of 1/10 volume of 0.1 M DTT and incubated for 30 min at 37°C, followed by alkylation with a five-fold molar excess of iodoacetamide and incubation for 30 min at 37°C. Proteins were precipitated at -20°C by the addition of 5 volumes cold acetone and incubation for 30 min at -20°C. All liquid was carefully removed, and the pellet dried in ambient air for 15 min before reconstitution of the proteins in 8 M urea, 50 mM Tris-HCl pH 8.0 to a final protein concentration between 0.2–0.3 mg/mL. Protein concentration was determined by Bradford assay. An aliquot corresponding to 5 μg protein was diluted to a final urea concentration of 2 M urea with 20 mM Tris-HCl pH 8.0, and 2 mM CaCl2. Proteins were digested by trypsin (1:50 (w/w) trypsin/protein ratio) for 6 hours at 37°C. The digests were acidified with TFA (1%) and analyzed by LC-MS/MS (EASY-nLC 1000 coupled to a QExactive HF mass spectrometer, ThermoFisher Scientific) with three repetitions injecting an aliquot of 500 ng protein. Peptides were trapped on an Acclaim PepMap100 C18 pre-column (3μm, 100 Å, 75μm x 2 cm, ThermoFisher Scientific, Reinach, Switzerland) and separated by backflush on a C18 column (3μm, 100 Å, 75μm x 15 cm, Nikkyo Technos, Tokyo, Japan) by applying a 40 min gradient of 5% acetonitrile to 40% in water, 0.1% formic acid, at a flow rate of 300 nl/min. Peptides of m/z 400–1400 were detected at a resolution of 60,000 m/z 250 with automatic gain control (AGC) target of 1E06 and maximum ion injection time of 50 ms. A top fifteen data-dependent method for precursor ion fragmentation was applied with the following settings: resolution 15,000, AGC of 1E05, maximum ion time of 110 ms, charge inclusion of 2+ to 7+ ions, peptide match on, and dynamic exclusion for 20 sec, respectively.

Fragment spectra data were converted to mgf with ProteomeDiscoverer 2.0 and peptide identification made with EasyProt software searching against the forward and reversed UniprotKB Drosophila melanogaster protein database (Release 2016_11), complemented with commonly found protein sequences of contaminating proteins, with the following parameters: parent mass error tolerance of 10 p.p.m., trypsin cleavage mode with three missed cleavages, static carbamidomethylation on Cys, variable oxidation on Met and acetylation on protein N-terminus. On the basis of reversed database peptide spectrum matches, a 1% false discovery rate was set for acceptance of target database matches, and only proteins with at least two different peptide sequences identified were allowed.

Immunoprecipitation/pull-down assays

50μg of purified Mms19 (Tagged with 5X Histidine at C-terminus, synthesized by Genscript Inc and solubilized in 20mM Tris, 150mM NaCl, 0.5 M Arginine) was incubated with 50μg purified porcine tubulin (Purchased from Cytoskeleton Inc) at 4°C for 2 hrs. This mixture was subsequently incubated with Ni-NTA agarose (equilibrated with 20mM Tris-Cl and 250mM NaCl) for 1 hr at 4°C. The beads were then washed three times with wash buffer containing 20mM Tris, 250mM NaCl, and 20mM Imidazole, and the bound proteins were eluted by adding elution buffer (20mM Tris, 250mM NaCl, and 500mM Imidazole) to the resin on ice for 10 min. The eluate was then analyzed by probing Western blots with anti-Mms19 antibodies and rabbit anti-alpha-Tubulin antibodies.

Neuronal in vitro cultures

Dissociated brain cells were cultured in vitro according to a protocol previously described [53]. Briefly, 15–20 third instar larvae were dissected in PBS and washed 3 times with Rinaldini solution (800 mg NaCl, 20 mg KCl, 5 mg NaH2PO4, 100 mg NaHCO3, 100 mg glucose, in 100 ml distilled water). The brains were then incubated in 0.5% collagenase I in Rinaldini solution for 60 min and subsequently washed 4 times in Schneider’s medium. The treated tissues were then dissociated by pipetting 100–200 times. The resulting cell mixture was passed through a 40μm mesh to remove cell clusters, and the brain cells were then incubated for 24hrs at 25°C. After 24hrs incubation, the cells were plated on concanavalin A-coated coverslips, fixed and stained.

Preparation of MTs for EM

To obtain polymerized MTs, 20μM tubulin was incubated in the presence of 10μM taxol at 37°C for 30min. The sample was then subjected to ultra-centrifugation for 10min at 100,000 g at 4°C in a Beckman Airfuge ultracentrifuge. The supernatant containing un-polymerized dimers was then removed and the pellet was reconstituted with either 15μl BRB80/solvent (BRB80 components: 80mM PIPES buffer, 1mM EGTA, 2mM MgCl2 + Mms19 solvent constituents: 20mM Tris-CL, 150mM NaCl, 0.5M Arginine) or 15 μl of 0.5μM Mms19::5xHis in BRB80/solvent.

Negative stain EM

5 μl of samples were applied on glow discharged, carbon-coated copper EM grids for 1min. The excess sample was then washed off by dipping the grid in milli-Q water. The sample on the grid was then fixed/negatively stained with 2% Uranyl acetate for 30 sec and then the excess fluid was removed by using filter paper. The samples were imaged at a nominal magnification of 63,000x or 87,000x on a FEI Tecnai Spirit EM operated at 80eV and fitted with a digital camera. MT length and number of MT bundles were quantified from images obtained from three independent experiments.

Fluorescent in situ hybridization (FISH)

The protocol for FISH was adapted from [54] with minor modifications. Briefly, third instar larval brains were dissected in PBS and fixed with 4% PFA. The brains were then washed 3 times for 10min each with 2xSSCT (0.3M Sodium Chloride, 0.03M Sodium Citrate and 0.1% Tween 20) followed by 10min washes respectively with 2xSSCT/20% Formamide, 2xSSCT/40% Formamide, 2xSSCT/50% Formamide. 100ng of the oligonucleotide probe: 5’ Cy5-AACACAACACAACACAACACAACACAACACAACAC that binds to a specific region on the 2nd chromosome [54] was then added to the Hybridization buffer (20% dextran sulfate, 2xSSCT, 50% Formamide) and this solution was incubated with the brains in a PCR tube. The probes were then denatured at 92°C for 3 min and then allowed to anneal with the chromosomal DNA overnight at 37°C. The sample was then washed thrice at 37°C with the following solutions for 20min each: 2xSSCT/50% Formamide, 2xSSCT/40% Formamide, 2xSSCT/20% Formamide. After two more washes with 2xSSCT, the sample was stained with Hoechst, mounted using Aqua-poly mount, and imaged on a Leica SP8 confocal microscope with a 63x objective.

Statistical analysis

Data were analyzed using Graph Pad prism 5.0 software. Means of two groups were compared and significance calculated by using unpaired student’s t-test. Percentages were compared and significance was calculated by using Fisher’s exact test. Multiple groups were compared, and significance calculated using the Kruskal-Wallis test and the Dunn’s post test.

Supporting information

S1 Fig [a]
NBs do not display elevated levels of aneuploidy.

S2 Fig [a]
Higher fraction of NBs in mitosis.

S3 Fig [a]
is cell autonomously required to maintain normal cell numbers in MARCM clones.

S4 Fig [b]
is necessary for centrosomal localization of Aurora A and Msps in NBs.

S5 Fig [a]
MT assembly defects in NBs and Mms19::eGFP localization in NBs and in neurons.

S6 Fig [a]
Model for the function of Mms19 towards MTs.

S1 Table [pdf]
The table lists proteins found to exclusively co-purify with Mms19::eGFP.

S2 Table [pdf]
Proteins that bound to the anti-GFP antibody coated beads from all three fly extracts are listed.

S3 Table [xlsx]
List of data points used to build the graphs and the tests to determine statistical significance for each data set and the corresponding P values.

S1 Movie [avi]
Analysis of mitosis duration in WT NB: WT brains expressing EB1::GFP were dissected, mounted on a stainless steel chamber (Cabernard et al, 2013) and NB mitosis was imaged with a 63x objective on a spinning disk confocal microscope.

S2 Movie [avi]
Analysis of mitosis duration in NB: Mitosis was visualized in brain NBs expressing EB1::GFP.

S3 Movie [avi]
Spindle assembly defect in NB: In around 10% of EB1::GFP expressing brain NBs, the spindle starts assembling before the centrosomes have migrated to the opposite sides, forming a ‘kinked’ spindle at 4min post NEBD onset.

S4 Movie [avi]
Analysis of EB1::GFP labelled MT velocity in WT NBs: In order to determine the speed of growing MT tips, WT brains expressing EB1::GFP were dissected, mounted on a stainless steel chamber (Cabernard et al, 2013) and spindles were imaged with a 100x objective on a spinning disk confocal microscope.

S5 Movie [avi]
Analysis of EB1::GFP labelled MT velocity in NBs: Live imaging was performed on brain NB spindles to determine the velocity of growing MT tips.

S6 Movie [avi]
Measuring MT plus tip speeds in post mitotic surface glia of WT brains: In order to determine whether affects MT growth in post mitotic cells, WT brains expressing EB1::GFP were dissected, mounted on a stainless steel chamber (Cabernard et al, 2013) and MT growth in surface glia was imaged with a 100x objective on a spinning disk confocal microscope.

S7 Movie [avi]
Measuring MT plus tip speeds in post mitotic surface glia of brains: MT growth in EB1::GFP expressing surface glia was visualized using spinning disk confocal microscopy.

S8 Movie [avi]
Spindle assembly delay in NBs: Mitotic spindle assembly was visualized in brain NBs expressing EB1::GFP.


Zdroje

1. Wühr M, Chen Y, Dumont S, Groen AC, Needleman DJ, Salic A, et al. Evidence for an Upper Limit to Mitotic Spindle Length. Curr Biol. 2008. doi: 10.1016/j.cub.2008.07.092 18718761

2. Hara Y, Kimura A. Cell-Size-Dependent Spindle Elongation in the Caenorhabditis elegans Early Embryo. Curr Biol. 2009. doi: 10.1016/j.cub.2009.07.050 19682904

3. Crowder ME, Strzelecka M, Wilbur JD, Good MC, Von Dassow G, Heald R. A comparative analysis of spindle morphometrics across metazoans. Curr Biol. 2015. doi: 10.1016/j.cub.2015.04.036 26004761

4. Vargas-Hurtado D, Brault JB, Piolot T, Leconte L, Da Silva N, Pennetier C, et al. Differences in Mitotic Spindle Architecture in Mammalian Neural Stem Cells Influence Mitotic Accuracy during Brain Development. Curr Biol. 2019. doi: 10.1016/j.cub.2019.07.061 31495584

5. Prakash L, Prakash S. Three additional genes involved in pyrimidine dimer removal in Saccharomyces cerevisiae: RAD7, RAD14 and MMS19. MGG Mol Gen Genet. 1979. doi: 10.1007/BF00333097 392238

6. Gari K, Ortiz AML, Borel V, Flynn H, Skehel JM, Boulton SJ. MMS19 links cytoplasmic iron-sulfur cluster assembly to DNA metabolism. Science (80-). 2012. doi: 10.1126/science.1219664 22678361

7. Stehling O, Vashisht AA, Mascarenhas J, Jonsson ZO, Sharma T, Netz DJA, et al. MMS19 assembles iron-sulfur proteins required for DNA metabolism and genomic integrity. Science (80-). 2012. doi: 10.1126/science.1219723 22678362

8. Ito S, Tan LJ, Andoh D, Narita T, Seki M, Hirano Y, et al. MMXD, a TFIIH-Independent XPD-MMS19 Protein Complex Involved in Chromosome Segregation. Mol Cell. 2010;39: 632–640. doi: 10.1016/j.molcel.2010.07.029 20797633

9. Nag R, Niggli S, Sousa-Guimaraes S, Vazquez-Pianzola P, Suter B. Mms19 is a mitotic gene that permits Cdk7 to be fully active as a Cdk-activating kinase. Development. 2018;145. doi: 10.1242/dev.156802 29361561

10. Cameroni E, Stettler K, Suter B. On the traces of XPD: Cell cycle matters—untangling the genotype-phenotype relationship of XPD mutations. Cell Division. 2010. doi: 10.1186/1747-1028-5-24 20840796

11. Gogendeau D, Siudeja K, Gambarotto D, Pennetier C, Bardin AJ, Basto R. Aneuploidy causes premature differentiation of neural and intestinal stem cells. Nat Commun. 2015. doi: 10.1038/ncomms9894 26573328

12. Green P, Hartenstein AY, Hartenstein V. The embryonic development of the Drosophila visual system. Cell Tissue Res. 1993. doi: 10.1007/BF00333712 8402833

13. Meinertzhagen I, Hanson T. The development of the optic lobe. In: Bate M, Martiney-Arias A, editors The development of Drosophila melanogaster Cold Spring Harbor Laboratory Press, Cold Spring Harbor, New York. 1993. pp. 1363–1491.

14. Zhu ZC, Gupta KK, Slabbekoorn AR, Paulson BA, Folker ES, Goodson H V. Interactions between EB1 and microtubules: Dramatic effect of affinity tags and evidence for cooperative behavior. J Biol Chem. 2009;284: 32651–32661. doi: 10.1074/jbc.M109.013466 19778897

15. Cheerambathur DK, Civelekoglu-Scholey G, Brust-Mascher I, Sommi P, Mogilner A, Scholey JM. Quantitative analysis of an anaphase B switch: Predicted role for a microtubule catastrophe gradient. J Cell Biol. 2007. doi: 10.1083/jcb.200611113 17576796

16. de Lartigue J, Brust-Mascher I, Scholey JM. Anaphase B spindle dynamics in Drosophila S2 cells: Comparison with embryo spindles. Cell Div. 2011. doi: 10.1186/1747-1028-6-8 21477279

17. Wang H, Brust-Mascher I, Scholey JM. The microtubule cross-linker Feo controls the midzone stability, motor composition, and elongation of the anaphase B spindle in Drosophila embryos. Mol Biol Cell. 2015. doi: 10.1091/mbc.E14-12-1631 25694445

18. Gallaud E, Caous R, Pascal A, Bazile F, Gagné JP, Huet S, et al. Ensconsin/map7 promotes microtubule growth and centrosome separation in Drosophila neural stem cells. J Cell Biol. 2014;204: 1111–1121. doi: 10.1083/jcb.201311094 24687279

19. Homem CCF, Knoblich JA. Drosophila neuroblasts: a model for stem cell biology. Development. 2012;139: 4297–4310. doi: 10.1242/dev.080515 23132240

20. Schuldt AJ, Adams JHJ, Davidson CM, Micklem DR, Haseloff J, St. Johnston D, et al. Miranda mediates asymmetric protein and RNA localization in the developing nervous system. Genes Dev. 1998. doi: 10.1101/gad.12.12.1847 9637686

21. Rolls MM, Albertson R, Shih HP, Lee CY, Doe CQ. Drosophila aPKC regulates cell polarity and cell proliferation in neuroblasts and epithelia. J Cell Biol. 2003. doi: 10.1083/jcb.200306079 14657233

22. Cabernard C, Doe CQ. Apical/Basal Spindle Orientation Is Required for Neuroblast Homeostasis and Neuronal Differentiation in Drosophila. Dev Cell. 2009. doi: 10.1016/j.devcel.2009.06.009 19619498

23. Lee CY, Andersen RO, Cabernard C, Manning L, Tran KD, Lanskey MJ, et al. Drosophila Aurora-A kinase inhibits neuroblast self-renewal by regulating aPKC/Numb cortical polarity and spindle orientation. Genes Dev. 2006. doi: 10.1101/gad.1489406 17182871

24. Yang Y, Liu M, Li D, Ran J, Gao J, Suo S, et al. CYLD regulates spindle orientation by stabilizing astral microtubules and promoting dishevelled-NuMA-dynein/ dynactin complex formation. Proc Natl Acad Sci U S A. 2014. doi: 10.1073/pnas.1319341111 24469800

25. Pearson CG, Bloom K. Dynamic microtubules lead the way for spindle positioning. Nature Reviews Molecular Cell Biology. 2004. doi: 10.1038/nrm1402 15173827

26. Giet R, McLean D, Descamps S, Lee MJ, Raff JW, Prigent C, et al. Drosophila Aurora A kinase is required to localize D-TACC to centrosomes and to regulate astral microtubules. J Cell Biol. 2002. doi: 10.1083/jcb.200108135 11827981

27. Bird AW, Hyman AA. Building a spindle of the correct length in human cells requires the interaction between TPX2 and Aurora A. J Cell Biol. 2008. doi: 10.1083/jcb.200802005 18663142

28. Van Horn RD, Chu S, Fan L, Yin T, Du J, Beckmann R, et al. Cdk1 activity is required for mitotic activation of Aurora A during G 2/M transition of human cells. J Biol Chem. 2010. doi: 10.1074/jbc.M110.141010 20444701

29. Larochelle S, Pandur J, Fisher RP, Salz HK, Suter B. Cdk7 is essential for mitosis and for in vivo Cdk-activating kinase activity. Genes Dev. 1998. doi: 10.1101/gad.12.3.370 9450931

30. Larochelle S, Merrick KA, Terret ME, Wohlbold L, Barboza NM, Zhang C, et al. Requirements for Cdk7 in the Assembly of Cdk1/Cyclin B and Activation of Cdk2 Revealed by Chemical Genetics in Human Cells. Mol Cell. 2007. doi: 10.1016/j.molcel.2007.02.003 17386261

31. D’Angiolella V, Mari C, Nocera D, Rametti L, Grieco D. The spindle checkpoint requires cyclin-dependent kinase activity. Genes Dev. 2003. doi: 10.1101/gad.267603 14561775

32. Wang G, Jiang Q, Zhang C. The role of mitotic kinases in coupling the centrosome cycle with the assembly of the mitotic spindle. Journal of Cell Science. 2014. doi: 10.1242/jcs.151753 25128564

33. Magnaghi-Jaulin L, Eot-Houllier G, Gallaud E, Giet R. Aurora A Protein Kinase: To the Centrosome and Beyond. Biomolecules. 2019;9.

34. Hutterer A, Berdnik D, Wirtz-Peitz F, Žigman M, Schleiffer A, Knoblich JA. Mitotic Activation of the Kinase Aurora-A Requires Its Binding Partner Bora. Dev Cell. 2006. doi: 10.1016/j.devcel.2006.06.002 16890155

35. Lee MJ, Gergely F, Jeffers K, Peak-Chew SY, Raff JW. Msps/XMAP215 interacts with the centrosomal protein D-TACC to regulate microtubule behaviour. Nat Cell Biol. 2001;3: 643–649. doi: 10.1038/35083033 11433296

36. Caous R, Pascal A, Romé P, Richard-Parpaillon L, Karess R, Giet R. Spindle assembly checkpoint inactivation fails to suppress neuroblast tumour formation in aurA mutant Drosophila. Nat Commun. 2015. doi: 10.1038/ncomms9879 26568519

37. Rebollo E, Sampaio P, Januschke J, Llamazares S, Varmark H, González C. Functionally Unequal Centrosomes Drive Spindle Orientation in Asymmetrically Dividing Drosophila Neural Stem Cells. Dev Cell. 2007. doi: 10.1016/j.devcel.2007.01.021 17336911

38. Tang N, Marshall WF. Centrosome positioning in vertebrate development. Journal of Cell Science. 2012. doi: 10.1242/jcs.038083 23277534

39. Walczak CE, Heald R. Mechanisms of Mitotic Spindle Assembly and Function. International Review of Cytology. 2008. doi: 10.1016/S0074-7696(07)65003-7(07)65003–7 18275887

40. Mottier-Pavie V, Cenci G, Vernì F, Gatti M, Bonaccorsi S. Phenotypic analysis of misatofunction reveals roles of noncentrosomal microtubules in Drosophila spindle formation. J Cell Sci. 2011. doi: 10.1242/jcs.072348 21285248

41. Van Wietmarschen N, Moradian A, Morin GB, Lansdorp PM, Uringa EJ. The mammalian proteins MMS19, MIP18, and ANT2 are involved in cytoplasmic iron-sulfur cluster protein assembly. J Biol Chem. 2012. doi: 10.1074/jbc.M112.431270 23150669

42. Yeom E, Hong ST, Choi KW. Crumbs interacts with Xpd for nuclear division control in Drosophila. Oncogene. 2015;34: 2777–2789. doi: 10.1038/onc.2014.202 25065591

43. Hwang JH, Vuong LT, Choi KW. Crumbs, Galla and Xpd are required for Kinesin-5 regulation in mitosis and organ growth in Drosophila. J Cell Sci. 2020. doi: 10.1242/jcs.246801 32501288

44. Amos L. Spindle Assembly: Kinesin-5 Is in Control. Current Biology. 2008. doi: 10.1016/j.cub.2008.10.045 19108775

45. Chen J, Larochelle S, Li X, Suter B. Xpd/Ercc2 regulates CAK activity and mitotic progression. Nature. 2003; 228–232. doi: 10.1038/nature01746 12853965

46. Li X, Urwyler O, Suter B. Drosophila Xpd regulates Cdk7 localization, mitotic kinase activity, spindle dynamics, and chromosome segregation. PLoS Genet. 2010. doi: 10.1371/journal.pgen.1000876 20300654

47. Daul AL, Komori H, Lee CY. Immunofluorescent staining of Drosophila larval brain tissue. Cold Spring Harb Protoc. 2010;5. doi: 10.1101/pdb.prot5460 20647364

48. Schindelin J, Arganda-Carreras I, Frise E, Kaynig V, Longair M, Pietzsch T, et al. Fiji: an open-source platform for biological-image analysis. Nat Methods. 2012;9: 676–682. doi: 10.1038/nmeth.2019 22743772

49. Cardona A, Saalfeld S, Schindelin J, Arganda-Carreras I, Preibisch S, Longair M, et al. TrakEM2 software for neural circuit reconstruction. PLoS One. 2012. doi: 10.1371/journal.pone.0038011 22723842

50. Lee T, Luo L. Mosaic analysis with a repressible cell marker (MARCM) for Drosophila neural development. Trends in Neurosciences. 2001. doi: 10.1016/s0166-2236(00)01791-4 11311363

51. Cabernard C, Doe CQ. Live imaging of neuroblast lineages within intact larval brains in Drosophila. Cold Spring Harb Protoc. 2013;2013: 970–977. doi: 10.1101/pdb.prot078162 24086057

52. Engel H, Mika M, Denapaite D, Hakenbeck R, Muḧlemann K, Heller M, et al. A low-affinity penicillin-binding protein 2x variant is required for heteroresistance in Streptococcus pneumoniae. Antimicrob Agents Chemother. 2014. doi: 10.1128/AAC.02547-14 24777105

53. Egger B, Van Giesen L, Moraru M, Sprecher SG. In vitro imaging of primary neural cell culture from Drosophila. Nat Protoc. 2013. doi: 10.1038/nprot.2013.052 23598446

54. Dernburg AF. In situ hybridization to somatic chromosomes in drosophila. Cold Spring Harb Protoc. 2011. doi: 10.1101/pdb.top065540 21880819


Článek vyšel v časopise

PLOS Genetics


2020 Číslo 11
Nejčtenější tento týden
Nejčtenější v tomto čísle
Kurzy Podcasty Doporučená témata Časopisy
Přihlášení
Zapomenuté heslo

Zadejte e-mailovou adresu, se kterou jste vytvářel(a) účet, budou Vám na ni zaslány informace k nastavení nového hesla.

Přihlášení

Nemáte účet?  Registrujte se

#ADS_BOTTOM_SCRIPTS#