SummaryChromosome missegregation during mitosis or meiosis is a hallmark of cancer and the main cause of prenatal death in humans. The gain or loss of specific chromosomes is thought to be random, with cell viability being essentially determined by selection. Several established pathways including centrosome amplification, sister-chromatid cohesion defects, or a compromised spindle assembly checkpoint can lead to chromosome missegregation. However, how specific intrinsic features of the kinetochore—the critical chromosomal interface with spindle microtubules—impact chromosome segregation remains poorly understood. Here we used the unique cytological attributes of female Indian muntjac, the mammal with the lowest known chromosome number (2n = 6), to characterize and track individual chromosomes with distinct kinetochore size throughout mitosis. We show that centromere and kinetochore functional layers scale proportionally with centromere size. Measurement of intra-kinetochore distances, serial-section electron microscopy, and RNAi against key kinetochore proteins confirmed a standard structural and functional organization of the Indian muntjac kinetochores and revealed that microtubule binding capacity scales with kinetochore size. Surprisingly, we found that chromosome segregation in this species is not random. Chromosomes with larger kinetochores bi-oriented more efficiently and showed a 2-fold bias to congress to the equator in a motor-independent manner. Despite robust correction mechanisms during unperturbed mitosis, chromosomes with larger kinetochores were also strongly biased to establish erroneous merotelic attachments and missegregate during anaphase. This bias was impervious to the experimental attenuation of polar ejection forces on chromosome arms by RNAi against the chromokinesin Kif4a. Thus, kinetochore size is an important determinant of chromosome segregation fidelity.
Coherent-hybrid STED: high contrast sub-diffraction imaging using a bi-vortex depletion beam
Stimulated emission depletion (STED) fluorescence microscopy squeezes an excited spot well below the wavelength scale using a doughnut-shaped depletion beam. To generate a doughnut, a scale-free vortex phase modulation (2D-STED) is often used because it provides maximal transverse confinement and radial-aberration immunity (RAI) to the central dip. However, RAI also means blindness to a defocus term, making the axial origin of fluorescence photons uncertain within the wavelength scale provided by the confocal detection pinhole. Here, to reduce the uncertainty, we perturb the 2D-STED phase mask so as to change the sign of the axial concavity near focus, creating a dilated dip. By providing laser depletion power, the dip can be compressed back in three dimensions to retrieve lateral resolution, now at a significantly higher contrast. We test this coherent-hybrid STED (CH-STED) mode in x-y imaging of complex biological structures, such as the dividing cell. The proposed strategy creates an orthogonal direction in the STED parametric space that uniquely allows independent tuning of resolution and contrast using a single depletion beam in a conventional (circular polarization-based) STED setup.
During the cell cycle it is critical that the duplicated DNA faithfully segregates to give rise to two genetically identical daughter cells. An even distribution of the genome during mitosis is mediated by mitotic spindle microtubules, assisted by, among others, motor proteins of the kinesin superfamily. Chromokinesins are members of the kinesin superfamily that harbour a specifi c DNA-binding domain. The best characterized chromokinesins belong to the kinesin-4/Kif4 and kinesin-10/Kif22 families, respectively. Functional analysis of chromokinesins in several model systems revealed their involvement in chromosome arm orientation and oscillations. This is consistent with their originally proposed role in the generation of polar ejection forces that assist chromosome congression to the spindle equator. Kinesin-12/Kif15 members comprise a third family of chromokinesins, but their role remains less understood. Noteworthy, all chromokinesins exhibit chromosome-independent localization on spindle microtubules, and recent works have signifi cantly extended the portfolio of mitotic processes in which chromokinesins play a role, from error correction and DNA compaction, to the regulation of spindle microtubule dynamics. Chromokinesin family and structure The kinesin superfamily has been implicated in the transport of organelles, proteins and mRNAs to specifi c cellular destinations, in an ATPand microtubule-dependent manner. Chromokinesins (Figure 1A) are distinct due to their ability to associate with chromosomes during mitosis. Their localization on chromatin was originally reported for Chk, a kinesin-4/Kif4 family member in embryonic chicken cells, and respective orthologues in Xenopus (Xklp1), humans (Kif4a and Kif4b) and C. elegans (Klp19). The putative Drosophila kinesin-10/Kif22, Nod, also associates with DNA-a fi nding that was subsequently confi rmed in other kinesin-10/Kif22 family members,
During cell division in eukaryotes a microtubule-based network undergoes drastic changes and remodeling to assemble a mitotic spindle competent to segregate chromosomes. Several model systems have been widely used to dissect the molecular and structural mechanisms behind mitotic spindle assembly and function. These include budding and fission yeasts, which are ideal for genetic and molecular approaches, but show limitations in high-resolution live-cell imaging, while being evolutionarily distant from humans. On the other hand, systems that were historically used for their exceptional properties for live-cell imaging of mitosis (e.g., newt lung cells and Haemanthus endosperm cells) lack the necessary genomic tools for molecular studies. In a CRISPR-Cas9 era, human cultured cells have conquered the privilege to be positioned among the most powerful genetically manipulatable systems, but their high chromosome number remains a significant bottleneck for the molecular dissection of mitosis in mammals. We believe that we can significantly broaden this scenario by establishing a unique placental mammal model system that combines the powerful genetic tools and low chromosome number of fission yeast and Drosophila melanogaster, with the exceptional cytological features of a rat kangaroo cell. This system is based on hTERTimmortalized fibroblasts from a female Indian muntjac, a placental mammal with the lowest known chromosome number (n ¼ 3). Here we describe a series of methodologies established in our laboratory for the study of mitosis in Indian muntjac. These include standard techniques such as immunofluorescence, western blotting, and FISH, but also several state-of-the-art methodologies, including live-cell imaging, cell confinement, RNAi, super-resolution STED microscopy, and laser microsurgery.
Summary Background Biofilm formation represents a major microbial virulence attribute especially at epithelial surfaces such as the skin. Malassezia biofilm formation at the skin surface has not yet been addressed. Objective The present study aimed to evaluate Malassezia colonisation pattern on a reconstructed human epidermis (RhE) by imaging techniques. Methods Malassezia clinical isolates were previously isolated from volunteers with pityriasis versicolor and seborrhoeic dermatitis. Yeast of two strains of M furfur and M sympodialis were inoculated onto the SkinEthic™ RHE. The tissues were processed for light microscopy, wide‐field fluorescence microscopy and scanning electron microscopy. Results Colonisation of the RhE surface with aggregates of Malassezia yeast entrapped in a multilayer sheet with variable amount of extracellular matrix was unveiled by imaging techniques following 24, 48, 72 and 96 hours of incubation. Whenever yeast were suspended in RPMI medium supplemented with lipids, the biofilm substantially increased with a dense extracellular matrix in which the yeast cells were embedded. Slight differences were found in the biofilm architectural structure between the two tested species with an apparently higher entrapment and viscosity in M furfur biofilm. Conclusion Skin isolates of M furfur and M sympodialis were capable of forming biofilm in vitro at the epidermal surface simulating in vivo conditions. Following 24 hours of incubation, without added lipids, rudimental matrix was barely visible, conversely to the reported at plastic surfaces. The amount of biofilm apparently increased progressively from 48 to 96 hours. A structural heterogeneity of biofilm between species was found.
Coherent-hybrid STED: a tunable photo-physical pinhole for super-resolution imaging at high contrast
Resolution in microscopy is not limited by diffraction as long as a nonlinear sample response is exploited. In a paradigmatic example, stimulated-emission depletion (STED) fluorescence microscopy fundamentally 'breaks' the diffraction limit by using a structured optical pattern to saturate depletion on a previously excited sample area. Two-dimensional (2D) STED, the canonical low-noise STED mode, structures the STED beam by using a vortex phase mask, achieving a significant lateral resolution improvement over confocal fluorescence microscopy. However, axial resolution and optical sectioning remain bound to diffraction. Here we use a tunable coherent-hybrid (CH) beam to improve optical sectioning, markedly reducing background fluorescence. CH-STED, which inherits the 2D-STED immunity to spherical aberration, diversifies the depletion strategy, allowing an optimal balance between two key metrics (lateral resolution and background suppression) to be found. CH-STED is used to perform high-contrast imaging of complex biological structures, such as the mitotic spindle and the neuron cell body.
Aneuploidy, the gain or loss of chromosomes, arises through problems in chromosome segregation during mitosis or meiosis and has been implicated in cancer and developmental abnormalities in humans [1]. Possible routes to aneuploidy include a compromised spindle assembly checkpoint (SAC), cohesion defects, centrosome amplification, as well as improper kinetochore-microtubule attachments [2]. However, none of these established routes takes into account the intrinsic features of the kinetochore -the critical chromosomal interface with spindle microtubules. Kinetochore size and respective microtubule binding capacity varies between different animal and plant species [3][4][5][6][7][8][9][10], among different chromosomes from the same species (including humans) [3,[11][12][13][14][15], and in response to microtubule attachments throughout mitosis [16][17][18]. How kinetochore size impacts chromosome segregation remains unknown. Addressing this fundamental question in human cells is virtually impossible, because most of the 23 pairs of chromosomes cannot be morphologically distinguished, while detection of 2-3 fold differences in kinetochore size is limited by diffraction and cannot be resolved by conventional light microscopy in living cells. Here we used the unique cytological attributes of female Indian muntjac, the mammal with the lowest known chromosome number (n=3), to track individual chromosomes with distinct kinetochore sizes throughout mitosis. We found that chromosomes with larger kinetochores bi-orient more easily and are biased to congress to the equator in a motor-independent manner. However, they are also more prone to establish erroneous merotelic attachments and lag behind during anaphase. Thus, we uncovered an intrinsic kinetochore feature -size -as an important determinant of chromosome segregation fidelity.3 Results and Discussion:Kinetochore size is generally determined by the length of α-satellite DNA, the presence of a CENP-B-box, and the proportional incorporation of CENP-A at centromeres [19][20][21][22]. Additional size changes are due to an expandable module formed by CENP-C and outer kinetochore proteins involved in SAC signaling, as well as motor proteins, such as CENP-E and cytoplasmic dynein [12,17, 23]. In humans, the length of α-satellite DNA arrays at centromeres ranges from 200 kb on the Y chromosome, to >5 Mb on chromosome 18 [24], leading to an 3 fold variability in the amount of centromeric CENP-A and respective kinetochore size among different chromosomes [11][12][13][14][19][20][21]. To investigate the relevance of kinetochore size for chromosome congression and segregation during mitosis we took advantage from the unique cytological features of the Indian muntjac (IM), a small deer whose females have the lowest known chromosome number (n=3) in mammals [25]. As the result of tandem fusions during evolution, IM chromosomes are large and morphologically distinct (one metacentric and two acrocentric pairs). Specifically relevant for our purposes, one of the acrocentric chromosomes ...
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