To fully understand animal transcription networks, it is essential to accurately measure the spatial and temporal expression patterns of transcription factors and their targets. We describe a registration technique that takes image-based data from hundreds of Drosophila blastoderm embryos, each costained for a reference gene and one of a set of genes of interest, and builds a model VirtualEmbryo. This model captures in a common framework the average expression patterns for many genes in spite of significant variation in morphology and expression between individual embryos. We establish the method's accuracy by showing that relationships between a pair of genes' expression inferred from the model are nearly identical to those measured in embryos costained for the pair. We present a VirtualEmbryo containing data for 95 genes at six time cohorts. We show that known gene-regulatory interactions can be automatically recovered from this data set and predict hundreds of new interactions.
The Arp2/3 protein complex has been implicated in the control of actin polymerization in cells. The
human complex consists of seven subunits which include the actin related proteins Arp2 and Arp3, and
five others referred to as p41-Arc, p34-Arc, p21-Arc,
p20-Arc, and p16-Arc (Arp complex). We have determined the predicted amino acid sequence of all seven
subunits. Each has homologues in diverse eukaryotes,
implying that the structure and function of the complex
has been conserved through evolution. Human Arp2
and Arp3 are very similar to family members from
other species. p41-Arc is a new member of the Sop2
family of WD (tryptophan and aspartate) repeat–containing proteins and may be posttranslationally modified, suggesting that it may be involved in regulating the
activity and/or localization of the complex. p34-Arc,
p21-Arc, p20-Arc, and p16-Arc define novel protein
families. We sought to evaluate the function of the
Arp2/3 complex in cells by determining its intracellular
distribution. Arp3, p34-Arc, and p21-Arc were localized to the lamellipodia of stationary and locomoting fibroblasts, as well to Listeria monocytogenes assembled
actin tails. They were not detected in cellular bundles of
actin filaments. Taken together with the ability of the
Arp2/3 complex to induce actin polymerization, these
observations suggest that the complex promotes actin
assembly in lamellipodia and may participate in lamellipodial protrusion.
The yeast [PSI+] factor propagates by a prion-like mechanism involving self-replicating Sup35p amyloids. We identified multiple Sup35p mutants that either are poorly recruited into, or cause curing of, wildtype amyloids in vivo. In vitro, these mutants showed markedly decreased rates of amyloid formation, strongly supporting the protein-only prion hypothesis. Kinetic analysis suggests that the prion state replicates by accelerating slow conformational changes rather than by providing stable nuclei. Strikingly, our mutations map exclusively within a short glutamine/asparagine-rich region of Sup35p, and all but one occur at polar residues. Even after replacement of this region with polyglutamine, Sup35p retains its ability to form amyloids. These and other considerations suggest similarities between the prion-like propagation of [PSI+] and polyglutamine-mediated pathogenesis of several neurodegenerative diseases.
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