Silvia Bonaccorsi

Spindle assembly in Drosophila neuroblasts and ganglion mother cells

n most animal mitotic cells, spindle formation is mediated by the centrosomes, which nucleate radial arrays of microtubules called asters. The fast-growing (plus) ends of astral microtubules are then captured by the kinetochores of chromosomes, allowing the formation of a bipolar spindle. In contrast, in meiotic cells of females from several animal species and in mitotic cells of higher plants, in which there are no centrosomes, microtubules grow from multiple sites around the chromatin and are then focused into a bipolar spindle through the combined action of both plus-endand minus-end-directed microtubule-associated molecular motors. Although it has been suggested that centrosome-containing and centrosome-free cells share common mechanisms for spindle-pole assembly, in most centrosome-containing cells the removal of centrosomes prevents spindle formation. Here we analyse mitotic division of neuroblasts and ganglion mother cells (GMCs) from the Drosophila central nervous system. The neuroblasts are stem cells that divide asymmetrically, producing another neuroblast and a smaller GMC, which is itself cleaved once into a pair of equally sized neurons. We show that both neuroblasts and GMCs, which normally contain centrosomes, can form functional anastral spindles when their centrosomes are removed as a result of mutations in the asterless (asl) gene. Thus, these cells can switch from a centrosomebased to a centrosome-independent spindle-assembly pathway. To analyse spindle assembly in Drosophila neuroblasts and GMCs, we made fixed preparations of brains from late-third-instar larvae. These preparations were stained simultaneously for chromatin, tubulin and either of the centrosome-associated proteins centrosomin or γ-tubulin. In both neuroblasts and GMCs, the I

Drosophila SPD-2 Is an Essential Centriole Component Required for PCM Recruitment and Astral-Microtubule Nucleation

SPD-2 is a C. elegans centriolar protein required for both centriole duplication and pericentriolar material (PCM) recruitment [1-4]. SPD-2 is conserved in Drosophila (DSpd-2) and is a component of the fly centriole [5-7]. The analysis of a P element-induced hypomorphic mutation has shown that DSpd-2 is primarily required for PCM recruitment at the sperm centriole but is dispensable for both centriole duplication and aster formation [5]. Here we show that null mutations carrying early stop codons in the DSpd-2 coding sequence suppress astral microtubule (MT) nucleation in both neuroblasts (NBs) and spermatocytes. These mutations also disrupt proper Miranda localization in dividing NBs, as previously observed in mutants lacking astral MTs [8-10]. Spermatocyte analysis revealed that DSpd-2 is enriched at both the centrioles and the PCM and is required for the maintenance of cohesion between the two centrioles but not for centriole duplication. We found that DSpd-2 localization at the centrosome requires the wild-type activity of Asl but is independent of the function of D-PLP, Cnn, gamma-tubulin, DGrip91, and D-TACC. Conversely, DSpd-2 mutants displayed normal centrosomal accumulations of Asl and D-PLP, strongly reduced amounts of Cnn, gamma-tubulin, and DGrip91, and diffuse localization of D-TACC. These results indicate that DSpd-2 functions in a very early step of the PCM recruitment pathway.

Feo, the Drosophila Homolog of PRC1, Is Required for Central-Spindle Formation and Cytokinesis

We performed a functional analysis of fascetto (feo), a Drosophila gene that encodes a protein homologous to the Ase1p/PRC1/MAP65 conserved family of microtubule-associated proteins (MAPs). These MAPs are enriched at the spindle midzone in yeast and mammals and at the fragmoplast in plants, and are essential for the organization and function of these microtubule arrays. Here we show that the Feo protein is specifically enriched at the central-spindle midzone and that its depletion either by mutation or by RNAi results in aberrant central spindles. In Feo-depleted cells, late anaphases showed normal overlap of the antiparallel MTs at the cell equator, but telophases displayed thin MT bundles of uniform width instead of robust hourglass-shaped central spindles. These thin central spindles exhibited diffuse localizations of both the Pav and Asp proteins, suggesting that these spindles comprise improperly oriented MTs. Feo-depleted cells also displayed defects in the contractile apparatus that correlated with those in the central spindle; late anaphase cells formed regular contractile structures, but these structures did not constrict during telophase, leading to failures in cytokinesis. The phenotype of Feo-depleted telophases suggests that Feo interacts with the plus ends of central spindle MTs so as to maintain their precise interdigitation during anaphase-telophase MT elongation and antiparallel sliding.

The Class I PITP Giotto Is Required for Drosophila Cytokinesis

Phosphatidylinositol transfer proteins (PITPs) are highly conserved polypeptides that bind phosphatidylinositol or phosphatidylcholine monomers, facilitating their transfer from one membrane compartment to another . Although PITPs have been implicated in a variety of cellular functions, including lipid-mediated signaling and membrane trafficking, the precise biological roles of most PITPs remain to be elucidated . Here we show for the first time that a class I PITP is involved in cytokinesis. We found that giotto (gio), a Drosophila gene that encodes a class I PITP, serves an essential function required for both mitotic and meiotic cytokinesis. Neuroblasts and spermatocytes from gio mutants both assemble regular actomyosin rings. However, these rings fail to constrict to completion, leading to cytokinesis failures. Moreover, gio mutations cause an abnormal accumulation of Golgi-derived vesicles at the equator of spermatocyte telophases, suggesting that Gio is implicated in membrane-vesicle fusion. Consistent with these results, we found that Gio is enriched at the cleavage furrow, the ER, and the spindle envelope. We propose that Gio mediates transfer of lipid monomers from the ER to the equatorial membrane, causing a specific local enrichment in phosphatidylinositol. This change in membrane composition would ultimately facilitate vesicle fusion, allowing membrane addition to the furrow and/or targeted delivery of proteins required for cytokinesis.

Spindle assembly and cytokinesis in the absence of chromosomes during Drosophila male meiosis

Alarge body of work indicates that chromosomes play a key role in the assembly of both acentrosomal and centrosome-containing spindles. In animal systems, the absence of chromosomes either prevents spindle formation or allows the assembly of a metaphase-like spindle that fails to evolve into an ana-telophase spindle. Here, we show that Drosophila secondary spermatocytes can assemble morphologically normal spindles in the absence of chromosomes. The Drosophila mutants fusolo and solofuso are severely defective in chromosome segregation and produce secondary spermatocytes that are devoid of chromosomes. The centrosomes of these anucleated cells form robust asters that give rise to bipolar spindles that undergo the same ana-telophase morphological transformations that characterize normal spindles. The cells containing chromosome-free spindles are also able to assemble regular cytokinetic structures and cleave normally. In addition, chromosome-free spindles normally accumulate the Aurora B kinase at their midzones. This suggests that the association of Aurora B with chromosomes is not a prerequisite for its accumulation at the central spindle, or for its function during cytokinesis.

Relationships between the central spindle and the contractile ring during cytokinesis in animal cells

During late anaphase and telophase, animal cells develop a bundle of antiparallel, interdigitating microtubules between the two daughter nuclei. Recent data indicate that this structure, called the central spindle, plays an essential role during cytokinesis. Studies in Drosophila and on vertebrate cells strongly suggest that the molecular signals for cytokinesis specifically emanate from the central spindle midzone. Moreover, the analysis of Drosophila mutants defective in cytokinesis has revealed a cooperative interaction between the central spindle microtubules and the contractile ring: when either of these structures is perturbed, the proper assembly of the other is disrupted. Based on these results we propose a model for the role of the central spindle during cytokinesis. We suggest that the interaction between central spindle microtubules and cortical actin filaments leads to two early events crucial for cytokinesis: the positioning of the contractile ring, and the stabilization of the plus ends of the interdigitating microtubules that comprise the central spindle. The latter event would provide the cell with a specialized microtubule scaffold that could mediate the translocation of plus‐end‐directed molecular motors to the cells equator. Among the cargoes transported by these motors could be proteins involved in the regulation and execution of cytokinesis. Microsc. Res. Tech. 49:202–208, 2000.

Drosophila timeless2 Is Required for Chromosome Stability and Circadian Photoreception

In Drosophila, there are two timeless paralogs, timeless1 (tim1) and timeless2 (tim2, or timeout). Phylogenetic analyses suggest that tim1 originated as a duplication of tim2 around the time of the Cambrian explosion. The function of tim1 as a canonical circadian component is well established, but the role of tim2 in the fly is poorly understood. Many organisms possess a single tim2-like gene that has been implicated in DNA synthesis and, in the case of mammals, somewhat controversially, in circadian rhythmicity. Here we analyze the structure and the functional role of fly tim2. tim2 is a large locus (approximately 75 kb) that harbors several transcribed intronic sequences. Using insertional mutations and tissue-specific RNA interference-mediated downregulation, we find that tim2 is an essential gene required for normal DNA metabolism and chromosome integrity. Moreover, tim2 is involved in light entrainment of the adult circadian clock, via its expression in the T1 basket cells of the optic lobes. tim2s residual role in light entrainment thus provides an evolutionary link that may explain why its derived paralog, tim1, came to play such a major role in both circadian photosensitivity and core clock function.

Transcription of a satellite DNA on twoY chromosome loops ofDrosophila melanogaster

Primary spermatocyte nuclei ofDrosophila melanogaster exhibit three giant lampbrush-like loops formed by thekl-5, kl-3 andks-1 Y chromosome fertility factors. Detailed mapping of satellite DNA sequences along theY chromosome has recently shown that AAGAC satellite repeats are a significant component of thekl-5 andks-1 loop-forming regions. To determine whether these simple repeated sequences are transcribed on the loop structures we performed a series of DNARNA in situ hybridization experiments to fixed loop preparations using as a probe cloned AAGAC repeats. These experiments showed that the probe hybridizes with homologous transcripts specifically associated with thekl-5 andks-1 loops. These transcripts are detected at all stages of development of these two loops, do not appear to migrate to the cytoplasm and are degraded when loops disintegrate during the first meiotic prophase. Moreover, an examination of the testes revealed that the transcription of the AAGAC sequences is restricted to the loops of primary spermatocytes; the other cell types ofD. melanogaster spermatogenesis do not exhibit nuclear or cytoplasmic labeling. These experiments were confirmed by RNA blotting analysis which showed that transcription of the AAGAC sequences occurs in wild-type testes but not inX/O testes. The patterns of hybridization to the RNA blots indicated that the transcripts are highly heterogeneous in size, from large (migration at limiting mobility) to less than 1 kb. We discuss the possible function of the AAGAC satellite transcripts, in the light of the available information on theY chromosome loops ofD. melanogaster.

The Drosophila Lkb1 kinase is required for spindle formation and asymmetric neuroblast division

We have isolated lethal mutations in the Drosophila lkb1 gene (dlkb1), the homolog of C. elegans par-4 and human LKB1 (STK11), which is mutated in Peutz-Jeghers syndrome. We show that these mutations disrupt spindle formation, resulting in frequent polyploid cells in larval brains. In addition, dlkb1 mutations affect asymmetric division of larval neuroblasts (NBs); they suppress unequal cytokinesis, abrogate proper localization of Bazooka, Par-6, DaPKC and Miranda, but affect neither Pins/Gαi localization nor spindle rotation. Most aspects of the dlkb1 phenotype are exacerbated in dlkb1 pins double mutants, which exhibit more severe defects than those observed in either single mutant. This suggests that Dlkb1 and Pins act in partially redundant pathways to control the asymmetry of NB divisions. Our results also indicate that Dlkb1 and Pins function in parallel pathways controlling the stability of spindle microtubules. The finding that Dlkb1 mediates both the geometry of stem cell division and chromosome segregation provides novel insight into the mechanisms underlying tumor formation in Peutz-Jeghers patients.

The peculiar genetic organization of Drosophila heterochromatin

Abstract Cytogenetic analysis of biological functions that map in heterochromatin reveals genetic organizations that resist conventional genetic analysis. It may well be, therefore, that heterochromatin is not mostly biologically inert, containing only a few widely-spaced genes, but contains information that is, however, organized differently from that in euchromatin.