Head versus tail: germ cell-less initiates axis formation via homeobrain and zen1 in a beetle

Ansari, Salim

21 September 2017

No description available.

570

axis formation

germ cell-less

homeobrain

short-germ segmentation

Tribolium castaneum

Biologie (PPN619462639)

A Systems Level Analysis of the Transcription Factor FoxN2/3 and FGF Signal Transduction in Sea Urchin Larval Skeleton Development and Body Axis Formation

Rho, Ho Kyung

January 2011

<p>Specification and differentiation of a cell is accomplished by changing its gene expression profiles. These processes require temporally and spatially regulated transcription factors (TFs), to induce the genes that are necessary to a specific cell type. In each cell a set of TFs interact with each other or activate their targets; as development progresses, transcription factors receive regulatory inputs from other TFs and a complex gene regulatory network (GRN) is generated. Adding complexity, each TF can be regulated not only at the transcriptional level, but also by translational, and post-translational mechanisms. Thus, understanding a developmental process requires understanding the interactions between TFs, signaling molecules and target genes which establish the GRN.</p><p>In this thesis, two genes, FoxN2/3, a TF and FGFR1, a component of the FGF signaling pathway are investigated. FoxN2/3 and FGFR1 have different mechanisms that function in sea urchin development; FoxN2/3 regulates gene expression and FGFR1 changes phosphorylation of target proteins. However, their ultimate goals are the same: changing the state of an earlier GRN into the next GRN state. </p><p>First, we characterize FoxN2/3 in the primary mesenchyme cell (PMC) GRN. Expression of foxN2/3 begins in the descendants of micromeres at the early blastula stage; and then is lost from PMCs at the mesenchyme blastula stage. foxN2/3 expression then shifts to the secondary mesenchyme cells (SMCs) and later to the endoderm. Here we show that, Pmar1, Ets1 and Tbr are necessary for activation of foxN2/3 in the descendants of micromeres. The later endomesoderm expression is independent of the earlier expression of FoxN2/3 in micromeres and independent of signals from PMCs. FoxN2/3 is necessary for several steps in the formation of larval skeleton. A number of proteins are necessary for skeletogenesis, and early expression of at least several of these is dependent on FoxN2/3. Furthermore, knockdown (KD) of FoxN2/3 inhibits normal PMC ingression. PMCs lacking FoxN2/3 protein are unable to join the skeletogenic syncytium and they fail to repress the transfating of SMCs into the skeletogenic lineage. Thus, FoxN2/3 must be present for the PMC GRN to control normal ingression, expression of skeletal matrix genes, prevention of transfating, and control fusion of the PMC syncytium.</p><p>Second, we show that the FGF-FGFR1 signaling is required for the oral-aboral axis formation in the sea urchin embryos. Without FGFR1, nodal is induced in all of the cells at the early blastula stage and this ectopic expression of nodal requires active p38 MAP kinase. The loss of oral restriction of nodal expression results in the abnormal organization of PMCs and the larval skeleton; it also induces ectopic expression of oral-specific genes and represses aboral-specific genes. The abnormal oral-aboral axis formation also affected fgf and vegf expression patterns; normally these factors are expressed in two restricted areas of the ectoderm between the oral and the aboral side, but when FGFR1 is knocked down, Nodal expands, and in response the expression of the FGF and VEGF ligands expands, and this in turn affects the abnormal organization of larval skeleton.</p> / Dissertation

Developmental Biology

Body axis formation

Fibroblast growth factor

Forkhead transcription factor

Gene regulatory network

Sea urchin

Specification

Dynamics of Cilia and Flagella / Bewegung von Zilien und Geißeln

Hilfinger, Andreas

14 January 2006

Cilia and flagella are hair-like appendages of eukaryotic cells. They are actively bending structures that exhibit regular beat patterns and thereby play an important role in many different circumstances where motion on a cellular level is required. Most dramatic is the effect of nodal cilia whose vortical motion leads to a fluid flow that is directly responsible for establishing the left-right axis during embryological development in many vertebrate species, but examples range from the propulsion of single cells, such as the swimming of sperm, to the transport of mucus along epithelial cells, e.g. in the ciliated trachea. Cilia and flagella contain an evolutionary highly conserved structure called the axoneme, whose characteristic architecture is based on a cylindrical arrangement of elastic filaments (microtubules). In the presence of a chemical fuel (ATP), molecular motors (dynein) exert shear forces between neighbouring microtubules, leading to a bending of the axoneme through structural constraints. We address the following two questions: How can these organelles generate regular oscillatory beat patterns in the absence of a biochemical signal regulating the activity of the force generating elements? And how can the beat patterns be so different for apparently very similar structures? We present a theoretical description of the axonemal structure as an actively bending elastic cylinder, and show that in such a system bending waves emerge from a non-oscillatory state via a dynamic instability. The corresponding beat patterns are solutions to a set of coupled partial differential equations presented herein.

Axonem

Bewegung bei kleinen Reynolds Zahlen

Biophysik

Flagellen

Geißeln

Molekulare Motoren

Nodale Zilien

Physik

Selbstorganisierte Schlagmuster

Situs inversus

Spermien

Wimpern

Zilien

Situs inversus

axoneme

biophysics

cilia

dynein

flagella

left-right axis formation

low Reynolds number dynamics

molecular motors

nodal cilia

physics

spermatozoa

spontaneous oscillations

ddc:530

rvk:UF 5000

Cilie

Flagelline

Geißel &amp;lt;Biologie&amp;gt;

Molekularer Motor

Reynolds-Zahl

Selbstorganisation

Spermium

Zilie

Dynamics of Cilia and Flagella

Hilfinger, Andreas

07 February 2006

Cilia and flagella are hair-like appendages of eukaryotic cells. They are actively bending structures that exhibit regular beat patterns and thereby play an important role in many different circumstances where motion on a cellular level is required. Most dramatic is the effect of nodal cilia whose vortical motion leads to a fluid flow that is directly responsible for establishing the left-right axis during embryological development in many vertebrate species, but examples range from the propulsion of single cells, such as the swimming of sperm, to the transport of mucus along epithelial cells, e.g. in the ciliated trachea. Cilia and flagella contain an evolutionary highly conserved structure called the axoneme, whose characteristic architecture is based on a cylindrical arrangement of elastic filaments (microtubules). In the presence of a chemical fuel (ATP), molecular motors (dynein) exert shear forces between neighbouring microtubules, leading to a bending of the axoneme through structural constraints. We address the following two questions: How can these organelles generate regular oscillatory beat patterns in the absence of a biochemical signal regulating the activity of the force generating elements? And how can the beat patterns be so different for apparently very similar structures? We present a theoretical description of the axonemal structure as an actively bending elastic cylinder, and show that in such a system bending waves emerge from a non-oscillatory state via a dynamic instability. The corresponding beat patterns are solutions to a set of coupled partial differential equations presented herein.

info:eu-repo/classification/ddc/530

ddc:530