Diffusion and distal linkages govern interchromosomal dynamics during meiotic prophase.

SignificanceEssential for sexual reproduction, meiosis is a specialized cell division required for the production of haploid gametes. Critical to this process are the pairing, recombination, and segregation of homologous chromosomes (homologs). While pairing and recombination are linked, it is not known how many linkages are sufficient to hold homologs in proximity. Here, we reveal that random diffusion and the placement of a small number of linkages are sufficient to establish the apparent "pairing" of homologs. We also show that colocalization between any two loci is more dynamic than anticipated. Our study provides observations of live interchromosomal dynamics during meiosis and illustrates the power of combining single-cell measurements with theoretical polymer modeling.

Psychedelics Promote Structural and Functional Neural Plasticity.

Atrophy of neurons in the prefrontal cortex (PFC) plays a key role in the pathophysiology of depression and related disorders. The ability to promote both structural and functional plasticity in the PFC has been hypothesized to underlie the fast-acting antidepressant properties of the dissociative anesthetic ketamine. Here, we report that, like ketamine, serotonergic psychedelics are capable of robustly increasing neuritogenesis and/or spinogenesis both in vitro and in vivo. These changes in neuronal structure are accompanied by increased synapse number and function, as measured by fluorescence microscopy and electrophysiology. The structural changes induced by psychedelics appear to result from stimulation of the TrkB, mTOR, and 5-HT2A signaling pathways and could possibly explain the clinical effectiveness of these compounds. Our results underscore the therapeutic potential of psychedelics and, importantly, identify several lead scaffolds for medicinal chemistry efforts focused on developing plasticity-promoting compounds as safe, effective, and fast-acting treatments for depression and related disorders.

Megator, an essential coiled-coil protein that localizes to the putative spindle matrix during mitosis in Drosophila.

We have used immunocytochemistry and cross-immunoprecipitation analysis to demonstrate that Megator (Bx34 antigen), a Tpr ortholog in Drosophila with an extended coiled-coil domain, colocalizes with the putative spindle matrix proteins Skeletor and Chromator during mitosis. Analysis of P-element mutations in the Megator locus showed that Megator is an essential protein. During interphase Megator is localized to the nuclear rim and occupies the intranuclear space surrounding the chromosomes. However, during mitosis Megator reorganizes and aligns together with Skeletor and Chromator into a fusiform spindle structure. The Megator metaphase spindle persists in the absence of microtubule spindles, strongly implying that the existence of the Megator-defined spindle does not require polymerized microtubules. Deletion construct analysis in S2 cells indicates that the COOH-terminal part of Megator without the coiled-coil region was sufficient for both nuclear as well as spindle localization. In contrast, the NH2-terminal coiled-coil region remains in the cytoplasm; however, we show that it is capable of assembling into spherical structures. On the basis of these findings we propose that the COOH-terminal domain of Megator functions as a targeting and localization domain, whereas the NH2-terminal domain is responsible for forming polymers that may serve as a structural basis for the putative spindle matrix complex.

Tissue remodeling during maturation of the Drosophila wing.

The final step in morphogenesis of the adult fly is wing maturation, a process not well understood at the cellular level due to the impermeable and refractive nature of cuticle synthesized some 30 h prior to eclosion from the pupal case. Advances in GFP technology now make it possible to visualize cells using fluorescence after cuticle synthesis is complete. We find that, between eclosion and wing expansion, the epithelia within the folded wing begin to delaminate from the cuticle and that delamination is complete when the wing has fully expanded. After expansion, epithelial cells lose contact with each other, adherens junctions are disrupted, and nuclei become pycnotic. The cells then change shape, elongate, and migrate from the wing into the thorax. During wing maturation, the Timp gene product, tissue inhibitor of metalloproteinases, and probably other components of an extracellular matrix are expressed that bond the dorsal and ventral cuticular surfaces of the wing following migration of the cells. These steps are dissected using the batone and Timp genes and ectopic expression of alphaPS integrin, inhibitors of Armadillo/beta-catenin nuclear activity and baculovirus caspase inhibitor p35. We conclude that an epithelial-mesenchymal transition is responsible for epithelial delamination and dissolution.

Structures and dynamics of Drosophila Tpr inconsistent with a static, filamentous structure.

Here we report immunofluorescence localizations of the Drosophila Tpr protein which are inconsistent with a filament-forming protein statically associated with nuclear pore complex-associated intranuclear filaments. Using tissues from throughout the Drosophila life cycle, we observe that Tpr is often localized to discontinuous, likely granular or particulate structures in the deep nuclear interior. These apparent granules have no obvious connectivity to pore complexes in the nuclear periphery, and are often localized on the surfaces of chromosomes and to the perinucleolar region. Most strikingly, after 1 h of heat shock, the great majority of the Tpr in the deep nuclear interior accumulates at a single heat shock puff, while Tpr in the nuclear periphery appears unchanged. This heat shock puff, 93D, is a known repository for many components of pre-mRNA metabolism during heat shock. Although we do not observe Tpr at sites of transcription under normal conditions, the 93D heat shock result leads us to favor a role for Tpr in mRNA metabolism, such as the transport of mRNA through the nuclear interior to nuclear pore complexes. Consistent with this, we observe networks of Tpr containing granules spanning between the nucleolus and the nuclear periphery which are also decorated by an anti-SR protein antibody. Since we also observe Drosophila Tpr in reticular or fibrous structures in other nuclei, such as salivary gland polytene nuclei, these results indicate that Tpr can exist in at least two structural forms, and suggest that Tpr may relocalize or even change structural forms in response to cellular needs.