Characterization of the Adaptor Protein XB130, a Tyrosine Kinase Substrate and a Novel Component of the Lamellipodia

Lodyga, Monika

10 January 2012

Adaptor proteins play a vital role in the propagation of cellular signals. Although they lack endogenous catalytic activity, they contain a variety of protein binding modules, which enable them to promote specific and efficient interactions with their binding partners. They form integrative platforms for a variety of molecules (e.g. lipids, tyrosine kinases, cytoskeletal and signaling proteins), and thereby link and coordinate key functions such as cell growth, motility and shape determination. Our laboratory has recently cloned a novel, 130 kDa adaptor protein, named XB130, as a structural homolog of actin-filament-associated-protein (AFAP-110), a stress fiber-binding Src substrate. However, the molecular interactions and functions of this novel adaptor remained to be elucidated. To characterize the function of XB130 we asked two general questions: (1) Is XB130 involved in the signal transduction pathways of tyrosine kinases? And (2) Is XB130 capable of regulating the cytoskeleton and/or is it regulated by the cytoskeleton? To address these questions first we investigated the tissue distribution of XB130 and discovered that it is abundantly expressed in thyroid. Therefore we asked whether it is a target of the thyroid-specific tyrosine kinase, RET/PTC, a genetically rearranged, constitutively active enzyme that plays a pathogenic role in papillary thyroid cancer. We found that XB130 is a RET/PTC substrate that couples RET/PTC signaling to phosphatidylinositol 3-kinase (PI3K) activation through its phosphorylation dependent interaction with the regulatory subunit p85 of PI3K. XB130 plays an important role in PI3K signaling, as downregulation of XB130 in TPC1 papillary thyroid cancer cells, harboring the RET/PTC1 kinase, strongly reduced Akt activity and concomitantly inhibited cell cycle progression and survival in suspension. In the second part we demonstrate that XB130 is a novel Rac- and cytoskeleton-regulated protein that exhibits high affinity to lamellipodial (branched) F-actin and impacts motility and invasiveness of tumor cells. In conclusion, my work characterized a novel adaptor protein and assigned two well-defined pathophysiological functions to it in the context of thyroid cancer cells.

adaptor protein

tyrosine kinase

RET/PTC

PI3K

XB130

AFAP1L2

cytoskeleton

lamellipodia

papillary thyroid cancer

0379

0307

XB130: in silico and invivo Studies of a Novel Signal Adaptor Protein

Rubacha, Matthew

15 February 2010

XB130 is a relatively unstudied novel signal adaptor protein. In the first phase of this study, an in silico search for proteins related to XB130 was conducted. Two other proteins (AFAP and AFAP1L1) were found to have a significant similarity to XB130 and were compared in detail. After an analysis of these three proteins, it was proposed that they are members of a novel protein family, termed the “AFAP family of signal adaptor proteins”. XB130 has previously been found to regulate cell cycle progression, death, and migration in lung epithelial cells. It was therefore hypothesized that XB130 is protective in acute lung injury (ALI) and important for facilitating repair after injury. XB130 was found to be differentially regulated in ALI depending on the initial insult. Engineering XB130 transgenic mice to further characterize the role of XB130 in lung injury/regeneration revealed that this protein could be essential for early embryo development.

adaptor protein

acute lung injury

embryonic development

protein family

AFAP

XB130

0719

XB130: in silico and invivo Studies of a Novel Signal Adaptor Protein

Rubacha, Matthew

15 February 2010

XB130 is a relatively unstudied novel signal adaptor protein. In the first phase of this study, an in silico search for proteins related to XB130 was conducted. Two other proteins (AFAP and AFAP1L1) were found to have a significant similarity to XB130 and were compared in detail. After an analysis of these three proteins, it was proposed that they are members of a novel protein family, termed the “AFAP family of signal adaptor proteins”. XB130 has previously been found to regulate cell cycle progression, death, and migration in lung epithelial cells. It was therefore hypothesized that XB130 is protective in acute lung injury (ALI) and important for facilitating repair after injury. XB130 was found to be differentially regulated in ALI depending on the initial insult. Engineering XB130 transgenic mice to further characterize the role of XB130 in lung injury/regeneration revealed that this protein could be essential for early embryo development.

adaptor protein

acute lung injury

embryonic development

protein family

AFAP

XB130

0719

Characterization of the Adaptor Protein XB130, a Tyrosine Kinase Substrate and a Novel Component of the Lamellipodia

Lodyga, Monika

10 January 2012

Adaptor proteins play a vital role in the propagation of cellular signals. Although they lack endogenous catalytic activity, they contain a variety of protein binding modules, which enable them to promote specific and efficient interactions with their binding partners. They form integrative platforms for a variety of molecules (e.g. lipids, tyrosine kinases, cytoskeletal and signaling proteins), and thereby link and coordinate key functions such as cell growth, motility and shape determination. Our laboratory has recently cloned a novel, 130 kDa adaptor protein, named XB130, as a structural homolog of actin-filament-associated-protein (AFAP-110), a stress fiber-binding Src substrate. However, the molecular interactions and functions of this novel adaptor remained to be elucidated. To characterize the function of XB130 we asked two general questions: (1) Is XB130 involved in the signal transduction pathways of tyrosine kinases? And (2) Is XB130 capable of regulating the cytoskeleton and/or is it regulated by the cytoskeleton? To address these questions first we investigated the tissue distribution of XB130 and discovered that it is abundantly expressed in thyroid. Therefore we asked whether it is a target of the thyroid-specific tyrosine kinase, RET/PTC, a genetically rearranged, constitutively active enzyme that plays a pathogenic role in papillary thyroid cancer. We found that XB130 is a RET/PTC substrate that couples RET/PTC signaling to phosphatidylinositol 3-kinase (PI3K) activation through its phosphorylation dependent interaction with the regulatory subunit p85 of PI3K. XB130 plays an important role in PI3K signaling, as downregulation of XB130 in TPC1 papillary thyroid cancer cells, harboring the RET/PTC1 kinase, strongly reduced Akt activity and concomitantly inhibited cell cycle progression and survival in suspension. In the second part we demonstrate that XB130 is a novel Rac- and cytoskeleton-regulated protein that exhibits high affinity to lamellipodial (branched) F-actin and impacts motility and invasiveness of tumor cells. In conclusion, my work characterized a novel adaptor protein and assigned two well-defined pathophysiological functions to it in the context of thyroid cancer cells.

adaptor protein

tyrosine kinase

RET/PTC

PI3K

XB130

AFAP1L2

cytoskeleton

lamellipodia

papillary thyroid cancer

0379

0307