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<p style="margin-right:0.7cm;margin-left:0.7cm" align="justify">

<font size=5>

Signal transduction of TGF-ß </font><br>

<font size=3>Daniel Horbelt, Sonja Niedrig and Petra Knaus</center></font>



</p><p style="margin-right:0.7cm;margin-left:0.7cm" align="justify">



<p style="margin-right:0.7cm;margin-left:0.7cm" align="justify">Transforming growth factor-beta (TGF-²) is a modulator in developmental processes and a regulator in homeostasis. Dysregulation of TGF-² signaling is associated with human diseases such as cancer and cardiovascular disease. Hereditary defects predispose to metabolic, musculoskeletal, and cardiovascular malfunctions. Even though the principal functions and pathways of TGF-² signaling have been elucidated in the past decades, increasing levels of complexity regarding its role in vivo and its signaling mechanisms have emerged, emphasizing the highly context specific nature of this pathway. TGF-² signaling is initiated by binding of the ligand to the type II receptor (T²RII). Subsequently, the type I receptor (T²RI, ALK5) is recruited into a hetero-oligomeric signaling complex. T²RI is then phosphorylated and activated by T²RII, and in turn phosphorylates the intracellular mediators of TGF-² signaling, the Smad proteins. Upon phosphorylation Smads accumulate in the nucleus to regulate transcription.</p>

<p style="margin-right:0.7cm;margin-left:0.7cm" align="justify">We are investigating the "signalotypes" of pathway components that exhibit an abnormal functionality as a consequence of disease-related inherited or somatic mutations. Mutations in T²RII (TGFBR2 gene) were recently found associated with a group of diseases that feature significant phenotypic similarity with Marfan syndrome (MFS). Analysis of mutations in T²RII which are associated with Loeys-Dietz syndrome (LDS), type 2 Marfan syndrome (MFS2), or familial thoracic aortic aneurysms and dissections (FTAAD) revealed a correlation between clinical severity and signaling activity.</p>

<p style="margin-right:0.7cm;margin-left:0.7cm" align="justify">Results from this study suggest that the balance of canonical TGF-ß-Smad signaling and non-canonical ERK signaling is a determinant for the development of thoracic aortic aneurysms and dissections (TAAD) on one hand and additional manifestations including skeletal and craniofacial phenotypes on the other hand.</p>

<center><img src=images/tgfbeta-Daniel.jpg></center>

<p style="margin-right:0.7cm;margin-left:0.7cm" align="justify">Figure : Mutations in T²RII that are associated which are associated with Loeys-Dietz syndrome (LDS), type II Marfan syndrome (MFS2), or familial thoracic aortic aneurysms and dissections (FTAAD), shown in a model of the T²RII kinase domain. Mutated residues are indicated, and replacing amino acids are given in red. The predominant diagnosis is represented in bold. 

modified from Horbelt et al. (2010), J Cell Sci 123</p>



<p style="margin-right:0.7cm;margin-left:0.7cm" align="justify">In terms of a more general investigation of TGF-² signaling we are focusing on proteins that interact with and modulate signaling of the TGF-² receptors. To identify novel proteins involved in the modulation of TGF-ß signaling we screened for proteins interacting with the cytoplasmic domain of the TGF-² type II receptor and characterized the impact of candidates on the TGF-ß pathway</p>







<p style="margin-right:0.7cm;margin-left:0.7cm" align="justify">



<font size=5>

Signal transduction of TGF-ß </font><br>

<font size=3>Britta Wittek, Florian Scheich</center></font>

</p><p style="margin-right:0.7cm;margin-left:0.7cm" align="justify">



Transforming growth factor-ß (TGF-ß) signals through membrane-bound serine/threonine kinase

receptors, which upon stimulation phosphorylate Smad-proteins and thereby trigger their

nuclear translocation and transcriptional activity. Although the three isoforms of TGF-ß are

highly homologous at the level of sequence, analysis of their in vivo function by gene knock

outs revealed striking differences suggesting that there is no significant redundancy between

TGF-ß1, -ß2 and -ß3. While signaltransduction by TGF-ß1 has been well character-ized, receptor

binding and activation by the TGF-ß2 isoform is still unclear. We have shown that TßRII-B, an

alternatively spliced variant of TßRII is a TGF-ß2 binding receptor which interacts with all

known TGF-ß receptors through the ligands TGF-ß1 or TGF-ß2. This receptor mediates

TGF-ß2-signaling directly via the Smad-pathway in the absence of any Type III receptor

(Betaglycan).<br>

TßRII-B shows a ubiquitous expression pattern as examined by northern-blot-analysis.

The expression of TßRII-B at the cell surface was shown in cells such as osteoblasts and

osteosarcomas, to C2C12 myoblasts and to the multipotent fibroblastic cell line C3H10T1/2.

The focus of current studies is to understand the mechanisms of the interaction between

TGFß2 and TßRII-B in immunological and functional approaches and how the signaling cascade

differs from TßRIII-dependent TGFß2-signaling. In addition we examine TGF-ß isoform specific

signalling pathways which might be independent or parallel to the Smad pathway. 



<br><br><hr width=550>



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<p style="margin-right:0.7cm;margin-left:0.7cm" align="center">

<font size=5>

Signal transduction of TGF-ß in cytotoxic T cells</font><br>

<font size=3>Kristina Feldmann, Petra Knaus</center></font>

<p>

<center><img src=images/facs2.jpg></center>



</p><p style="margin-right:0.7cm;margin-left:0.7cm" align="justify">



The biological significance of growth inhibition by TGF-ß becomes apparent

upon malfunction of this mechanism during tumor progression. TGF-ß has a

strong antiproliferative activity which is lost in different forms of cancer due to

mutations in the TGF-ß receptor genes as well as in the genes for the Smads.

Upon this TGF-ß resistance of tumor cells, the level of endogenously expressed

and secreted TGF-ß raises dramatically, causing angiogenesis in the vicinity of

the tumor as well as immunosuppression.<br>

In order to study the immunosuppressive role of TGF-ß we are investigating

TGF-ß induced signalling specifically on cytotoxic T-cells. The effect of TGF-ß is

being studied on the level of T-cell differentiation, proliferation and activation

towards specific target cells. In order to manipulate the TGF-ß pathway we are

establishing retro- and adenoviral transduction of primary murine splenocytes and

T-cell lines, expressing specific TGF-ß signalling molecules. The aim of this

project is to understand the effect of TGF-ß secreted from the tumor on mature

T-cells in order to develop genetherapeutic strategies for the "redirected-killing of

specific tumor cells".

</p><p style="margin-right:0.7cm;margin-left:0.7cm" align="justify">

The figure shows FACS-analysis of primary murine spleen cells which were

transduced to express GFP. In the upper panel, the Dot Blot depicts the single

spleen cells sorted for size (X-axis) and granularity (Y-axis). The gated cells

represent the proliferating spleen cells. In the lower panel, histograms show

GFP-expression (X-axis) and cell number (Y-axis). The blue histogram shows

non-transduced control cells. In red, transduced cells are shown.

</p><p style="margin-right:0.7cm;margin-left:0.7cm" align="justify">

To learn more about TGF-ß-signal transduction <a href=tgfpic.html target=_pic>

click here</a>.





<br><br><hr width=550>





<center>

<p style="margin-right:0.7cm;margin-left:0.7cm" align="center">

<font size=5>Crosstalk between the TGF-ß and NGF-pathway</font><br>

<font size=3>Marion Lutz, Petra Knaus<br>

Collaboration: K. Unsicker (University of Heidelberg), K. Krieglstein (University

of Saarland), D. Lindemann (University of Würzburg)</center></font>

<p>

<center><img width=530 src=images/neurites20.jpeg></center>



</p><p style="margin-right:0.7cm;margin-left:0.7cm" align="justify">



Several members of the TGF-ß superfamily play key roles in the development,

repair and survival of neurons. TGF-ß2 and -ß3 are most prominently expressed

along growing axonal tracts both in the peripheral and central nervous system. 

Rat pheochromocytoma cells (PC12 cells) have been used as a model system for

differentiation of neuronal cells. After stimulation with nerve growth factor

(NGF), they stop growing, form processes, and exhibit other markers

characteristic of neurons such as electrical excitability after appropriate stimuli

and formation of synaptic vesicles. <br>

We are studying the effect of TGF-ß on neurite growth from sensory neurons and

PC12 cells, which have been treated with NGF. In order to investigate both the

NGF and TGF-ß pathways we expressed mutant signalling proteins of either

pathway and analysed the effect by reportergen-assays, in vivo-phosphorylation

and by the phenotypic alterations of the cells. We have generated a series of

stable cell lines expressing dominant negative forms of the TGF-ß signalling

molecules under the control of a doxycycline-inducible promoter. Our data

suggest crosstalk between the NGF-induced signalling cascade and the TGF-ß

pathway leading to neuronal differentiation in PC12 and sensory neurons. 

</p><p style="margin-right:0.7cm;margin-left:0.7cm" align="justify">

The figure shows rat pheochromocytoma cells (PC12), that represent a model

system for the differentiation  of neuronal cells. Treatment with Nerve Growth

Factor (NGF) results in growth arrest and in the induction of a differentiation

program  with the characteristics of neurite outgrowth and the formation of

synaptic-like vesicles. <br>

The neurite outgrowth is demonstrated in the photographs above which show

PC12 cells that were cultivated either in growth media without NGF or in media

supplemented with 50 ng/ml NGF for 6 days.





<br><br><hr width=550>





<center>

<p style="margin-right:0.7cm;margin-left:0.7cm" align="center">

<font size=5>Studies on the expression and function of a specific TGF-ß receptor in osteoblasts; 

TGF-ß isoform specific signalling</font><br>

<font size=3>Diana Rotzer, Petra Knaus</font></center>

<p>

<center><img src=images/dibild.jpg></center>



</p><p style="margin-right:0.7cm;margin-left:0.7cm" align="justify">



Transforming growth factor-ß (TGF-ß) signals through membrane-bound

serine/threonine kinase receptors, which upon stimulation phosphorylate

Smad-proteins and thereby trigger their nuclear translocation and transcriptional

activity. Although the three isoforms of TGF-ß are highly homologous at the level

of sequence, analysis of their in vivo function by gene knock outs revealed

striking differences suggesting that there is no significant redundancy between

TGF-ß1, -ß2 and -ß3. While signaltransduction by TGF-ß1 has been well

characterized, receptor binding and activation by the TGF-ß2 isoform is still

unclear. We have shown that TßRII-B, an alternatively spliced variant of TßRII

is a TGF-ß2 binding receptor which interacts with all known TGF-ß receptors

through the ligands TGF-ß1 or TGF-ß2. This receptor mediates TGF-ß2-signaling

directly via the Smad-pathway in the absence of any Type III receptor

(Betaglycan). TßRII-B shows a restricted expression pattern as examined by

RT-PCR and immunoprecipitation after affinity labeling with TGF-ß. The

expression of TßRII-B at the cell surface is restricted to cells such as osteoblasts

and osteosarcomas, to C2C12 myoblasts and to the multipotent fibroblastic cell

line C3H10T1/2. The distinct expression of TßRII-B in cells originating from

tissues where the isoform TGF-ß2 has a predominant role may reflect the

importance of this receptor in TGF-ß isoform specific signalling.<br>

The focus of current studies are to understand the role of this specific TGF-ß type

II receptor in the process of bone formation as well as TGF-ß isoform specific

signalling pathways which might be independent or parallel to the Smad pathway. 



















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