Modulating the bicoid gradient in space and time

Background The formation of the Bicoid (Bcd) gradient in the early Drosophila is one of the most fascinating observations in biology and serves as a paradigm for gradient formation, yet its mechanism is still not fully understood. Two distinct models were proposed in the past, the SDD and the ARTS model. Results We define novel cis- and trans-acting factors that are indispensable for gradient formation. The first one is the poly A tail length of the bcd mRNA where we demonstrate that it changes not only in time, but also in space. We show that posterior bcd mRNAs possess a longer poly tail than anterior ones and this elongation is likely mediated by wispy (wisp), a poly A polymerase. Consequently, modulating the activity of Wisp results in changes of the Bcd gradient, in controlling downstream targets such as the gap and pair-rule genes, and also in influencing the cuticular pattern. Attempts to modulate the Bcd gradient by subjecting the egg to an extra nuclear cycle, i.e. a 15th nuclear cycle by means of the maternal haploid (mh) mutation showed no effect, neither on the appearance of the gradient nor on the control of downstream target. This suggests that the segmental anlagen are determined during the first 14 nuclear cycles. Finally, we identify the Cyclin B (CycB) gene as a trans-acting factor that modulates the movement of Bcd such that Bcd movement is allowed to move through the interior of the egg. Conclusions Our analysis demonstrates that Bcd gradient formation is far more complex than previously thought requiring a revision of the models of how the gradient is formed.

Polarity protein distribution on the metaphase furrow regulates hexagon dominated plasma membrane organization in syncytial Drosophila embryos

Epithelial cells have a polarised distribution of protein complexes on the lateral membrane and are present as a polygonal array dominated by hexagons. Metazoan embryogenesis enables the study of temporal formation of the polygonal array and mechanisms that regulate its distribution. The plasma membrane of the syncytial Drosophila blastoderm embryo is organized as a polygonal array during cortical division cycles with an apical membrane and lateral furrow in between adjacent nuclei. We find that polygonal plasma membrane organization arises in syncytial division cycle 11 and hexagon dominance occurs with increase in furrow length in cycle 12. This is coincident with DE-cadherin and Bazooka enrichment at edges and the septin, Peanut enrichment at vertices of the base of the furrow. DE-cadherin depletion leads to loss of hexagon dominance. Bazooka and Peanut depletion leads to a delay in occurrence of hexagon dominance from nuclear cycle 12 to 13. Hexagon dominance in Bazooka and Peanut mutants occurs with furrow extension and correlates with increase in DE-cadherin in syncytial cycle 13. We conclude that a change in polarity complex distribution leads to loss of furrow stability thereby changing the polygonal organization of the blastoderm embryo.Highlight Summary for TOCMetazoan embryogenesis starts with the formation of polygonal epithelial-like cells. We show that hexagon dominance in polygonal epithelial-like plasma membrane organization occurs in nuclear cycle 12 in the syncytial blastoderm Drosophila embryo. DE-cadherin and Bazooka distribution along the lateral furrow regulates this hexagon dominance.

Bicoid gradient formation and function in the Drosophila pre-syncytial blastoderm

Bicoid (Bcd) protein distributes in a concentration gradient that organizes the anterior/posterior axis of the Drosophila embryo. It has been understood that bcd RNA is sequestered at the anterior pole during oogenesis, is not translated until fertilization, and produces a protein gradient that functions in the syncytial blastoderm after 9–10 nuclear divisions. However, technical issues limited the sensitivity of analysis of pre-syncytial blastoderm embryos and precluded studies of oocytes after stage 13. We developed methods to analyze stage 14 oocytes and pre-syncytial blastoderm embryos, and found that stage 14 oocytes make Bcd protein, that bcd RNA and Bcd protein distribute in matching concentration gradients in the interior of nuclear cycle 2–6 embryos, and that Bcd regulation of target gene expression is apparent at nuclear cycle 7, two cycles prior to syncytial blastoderm. We discuss the implications for the generation and function of the Bcd gradient.