Kurt Ballmer-Hofer

Reconstitution of Two Recombinant LSm Protein Complexes Reveals Aspects of Their Architecture, Assembly, and Function

Sm and Sm-like (LSm) proteins form complexes engaging in various RNA-processing events. Composition and architecture of the complexes determine their intracellular distribution, RNA targets, and function. We have reconstituted the human LSm1–7 and LSm2–8 complexes from their constituent components in vitro. Based on the assembly pathway of the canonical Sm core domain, we used heterodimeric and heterotrimeric sub-complexes to assemble LSm1–7 and LSm2–8. Isolated sub-complexes form ring-like higher order structures. LSm1–7 is assembled and stable in the absence of RNA. LSm1–7 forms ring-like structures very similar to LSm2–8 at the EM level. Our in vitro reconstitution results illustrate likely features of the LSm complex assembly pathway. We prove the complexes to be functional both in an RNA bandshift and an in vivo cellular transport assay.

A role for the small GTPase Rac in polyomavirus middle-T antigen-mediated activation of the serum response element and in cell transformation.

The oncogenic proteins encoded by papovaviruses, the tumor antigens, have been extensively used as model systems to study mitogenic signaling and cell transformation. These proteins stimulate cell growth in cultured cells and induce tumors in virus infected or transgenic animals. One of these proteins, polyomavirus middle-T, acts like a constitutively activated tyrosine growth factor receptor. Middle-T recruits several cellular enzymes into a multifunctional complex located at cellular membranes. This results in the activation of cellular enzymes involved in the regulation of cell signaling, like tyrosine kinases of the Src family, a phosphatidylinositol 3-kinase and a GDP/GTP exchange factor for Ras. These activities are all required for stimulation of cell growth by middle-T and activate members of the MAP kinase family. Here we investigate the role of T antigen-activated pathways in the stimulation of transcription of immediate early genes. These genes are essential for progression of resting cells into S phase. Our data show that Rho family GTPases play an essential role in cell transformation by middle-T. Furthermore, we demonstrate that the c-fos promoter is activated by two Ras-initiated signaling cascades. One is Raf-dependent and requires binding of SHC and PI 3-kinase to the middle-T complex. This pathway signals via ternary complex factor (TCF) to the serum response element (SRE) of the c-fos promoter. Signaling to TCF by Raf also depends on functional Rac, but not CDC42, as demonstrated in luciferase reporter assays with an ETS domain-containing promoter. The second pathway is Raf-independent, does not require SHC but functional PI 3-kinase, and transduces signals via Rac to serum response factor (SRF). Microinjection of dominant negative Rac1 blocks nuclear translocation of ERK1 in middle-T-expressing cells. This lends support to the idea that the two signaling cascades initiated by Ras show crosstalk at the level of MAP kinase-mediated signaling to nuclear transcription factors.

Signalling by Src Family Kinases: Lessons Learnt from DNA Tumour Viruses

Virus replication and spreading in a host population depends on highly specific interactions of viral proteins with infected cells, resulting in subversion of multiple cellular signal transduction pathways. For instance, viral proteins cause cell cycle progression of the infected host cell in order to establish a cellular environment favourable for virus replication. Of equal importance for successful virus propagation is virus-mediated attenuation of a hosts immune response. Many of the pathways controlling these aspects of cell behaviour are regulated by cellular tyrosine kinases. One particular family of these enzymes, Src family kinases, are involved in processing signals emanating from the plasma membrane upon stimulation by growth factors, by cell-substratum or by cell-cell contact. Two families of DNA viruses, polyoma- and herpesviruses, encode proteins targeted at tyrosine kinases. The middle-T antigens expressed by mouse and hamster polyomavirus associate with and activate Src family tyrosine kinases. Two members of the herpes family of DNA viruses, Epstein-Barr virus (EBV) and herpesvirus saimiri (HVS), encode proteins, LMP2A and Tip, respectively, that associate with cellular tyrosine kinases of the Src and Syk/Zap family. Upon association with these viral proteins, the activity of these tyrosine kinases is changed resulting in altered signal output. Middle-T, LMP2A and Tip are therefore excellent tools to study the regulation of Src family kinases.

Activation-independent nuclear translocation of mitogen activated protein kinase ERK1 mediated by thiol-modifying chemicals

The extracellular signal‐regulated kinases ERK1 and ERK2 are key mediators of mitogenic signals in most cell types. In fibroblasts, sustained activation and nuclear translocation are mandatory for S‐phase induction. The events leading to activation of these kinases are well understood, whereas little is known about the mechanism of their translocation. Using indirect immunofluorescence and biochemical analysis we show that ERK1 can translocate to the nucleus in the absence of activation and phosphorylation by upstream kinases when cells are treated with thiol‐modifying chemicals. We propose that these chemicals inactivate a protein contributing to the cytoplasmic localization of ERK1.

Induction of the Urokinase-Type Plasminogen Activator Gene by Cytoskeleton-Disrupting Agents

The interaction of a cell with specific components of the extracellular matrix can result in alterations of cell-shape and morphology.1’2 To a large extent such structural changes are the consequence of modifications of the cytoskeletal network. Dynamic cytoskeletal changes take place in migrating cells as well as in transformed cells.3 Most likely, migration of normal or metastatic tumor cells requires the expression of specific endogenous genes whose products assist in reshaping the intracellular cytoskeleton and the extracellular matrix. How and whether changes in cell morphology and cytoskeletal components may cause alterations in the expression of certain genes has not yet been investigated extensively.