In complex colloidal systems, particle-poor regions can develop within particle-rich phases during sedimentation or creaming. These particle-poor regions are overlooked by 1D profiles, which are typically used to assess particle distributions in a sample. Alternative methods to visualise and quantify these regions are required to better understand phase separation, which is the focus of this paper. Magnetic resonance imaging has been used to monitor the development of compositional heterogeneity in a vesicle-polymer mixture undergoing creaming. T relaxation time maps were used to identify the distribution of vesicles, with vesicle-poor regions exhibiting higher T relaxation times than regions richer in vesicles. Phase separated structures displayed a range of different morphologies and a variety of image analysis methods, including first-order statistics, Fourier transformation, grey level co-occurrence matrices and Moran's I spatial autocorrelation, were used to characterise these structures, and quantify their heterogeneity. Of the image analysis techniques used, Moran's I was found to be the most effective at quantifying the degree and morphology of phase separation, providing a robust, quantitative measure by which comparisons can be made between a diverse range of systems undergoing phase separation. The sensitivity of Moran's I can be enhanced by the choice of weight matrices used.
Surfactant multilamellar vesicles (SMLVs) play a key role in the formulation of many industrial products, such as detergents, foodstuff, and cosmetics. In this Letter, we present the first quantitative investigation of the flow behavior of single SMLVs in a shearing parallel plate apparatus. We found that SMLVs are deformed and oriented by the action of shear flow while keeping constant volume and exhibit complex dynamic modes (i.e., tumbling, breathing, and tank treading). This behavior can be explained in terms of an excess area (as compared to a sphere of the same volume) and of microstructural defects, which were observed by 3D shape reconstruction through confocal microscopy. Furthermore, the deformation and orientation of SMLVs scale with radius R in analogy with emulsion droplets and elastic capsules (instead of R(3), such as in unilamellar vesicles). A possible application of the physical insight provided by this Letter is in the rationale design of processing methods of surfactant-based systems.
Protective mechanisms based on RNA silencing directed against the propagation of transposable elements are highly conserved in eukaryotes. The control of transposable elements is mediated by small noncoding RNAs, which derive from transposonrich heterochromatic regions that function as small RNA-generating loci. These clusters are transcribed and the precursor transcripts are processed to generate Piwi-interacting RNAs (piRNAs) and endogenous small interfering RNAs (endo-siRNAs), which silence transposable elements in gonads and somatic tissues. The flamenco locus is a Drosophila melanogaster small RNA cluster that controls gypsy and other transposable elements, and has played an important role in understanding how small noncoding RNAs repress transposable elements. In this study, we describe a cosuppression mechanism triggered by new euchromatic gypsy insertions in genetic backgrounds carrying flamenco alleles defective in gypsy suppression. We found that the silencing of gypsy is accompanied by the silencing of other transposons regulated by flamenco, and of specific flamenco sequences from which small RNAs against gypsy originate. This cosuppression mechanism seems to depend on a post-transcriptional regulation that involves both endo-siRNA and piRNA pathways and is associated with the occurrence of developmental defects. In conclusion, we propose that new gypsy euchromatic insertions trigger a post-transcriptional silencing of gypsy sense and antisense sequences, which modifies the flamenco activity. This cosuppression mechanism interferes with some developmental processes, presumably by influencing the expression of specific genes. KEYWORDS transposon; small RNA; RNA silencing; primary transcript; ecdysis E UKARYOTIC genomes consist in part of sequences derived from a wide variety of transposable elements (TEs), some of which can mobilize to new genomic locations (de Koning et al. 2011). A genomic consequence of their mobilization is the induction of new mutations and chromosomal rearrangements that may have deleterious effects on fitness. However, they may also provide a fundamental contribution to genetic variation and evolutionary changes (Fedoroff 2012;Warren et al. 2015;Elbarbary et al. 2016;Mita and Boeke 2016). TE activation is suppressed by specific silencing mechanisms that act both at the transcriptional level, through chromatin modifications, and at the post-transcriptional level (Buchon and Vaury 2006). Piwi-interacting RNAs (piRNAs), a distinct class of 24-to 30-nt-long RNAs produced by a Dicer-independent biogenesis pathway, are involved in the recognition and selective silencing of transposons during gametogenesis (Sarot et al. 2004;Kalmykova et al. 2005). In the Drosophila ovary germline, the coordinated action of aubergine (aub), Argonaute 3 (AGO3), and piwi suppresses activity of a broad group of TEs through the formation of piRNAs involving both a primary processing and a secondary "ping-pong" amplification loop (Brennecke et al. 2007;Gunawardane et al. 2007;Li et al. 2009;Malone...
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