An ATM/Chk2-mediated DNA damage-responsive signaling pathway suppresses Epstein-Barr virus transformation of primary human B cells.

Epstein-Barr virus (EBV), an oncogenic herpesvirus that causes human malignancies, infects and immortalizes primary human B cells in vitro into indefinitely proliferating lymphoblastoid cell lines, which represent a model for EBV-induced tumorigenesis. The immortalization efficiency is very low, suggesting that an innate tumor suppressor mechanism is operative. We identify the DNA damage response (DDR) as a major component of the underlying tumor suppressor mechanism. EBV-induced DDR activation was not due to lytic viral replication, nor did the DDR marks colocalize with latent episomes. Rather, a transient period of EBV-induced hyperproliferation correlated with DDR activation. Inhibition of the DDR kinases ATM and Chk2 markedly increased transformation efficiency of primary B cells. Further, the viral latent oncoprotein EBNA3C was required to attenuate the EBV-induced DDR. We propose that heightened oncogenic activity in early cell divisions activates a growth-suppressive DDR that is attenuated by viral latency products to induce cell immortalization.

CLN3p impacts galactosylceramide transport, raft morphology, and lipid content.

Juvenile neuronal ceroid lipofuscinosis (JNCL) belongs to the neuronal ceroid lipofuscinoses characterized by blindness/seizures/motor/cognitive decline and early death. JNCL is caused by CLN3 gene mutations that negatively modulate cell growth/apoptosis. CLN3 protein (CLN3p) localizes to Golgi/Rab4-/Rab11-positive endosomes and lipid rafts, and harbors a galactosylceramide (GalCer) lipid raft-binding domain. Goals are proving CLN3p participates in GalCer transport from Golgi to rafts, and GalCer deficits negatively affect cell growth/apoptosis. GalCer/mutant CLN3p are retained in Golgi, with CLN3p rescuing GalCer deficits in rafts. Diminishing GalCer in normal cells by GalCer synthase siRNA negatively affects cell growth/apoptosis. GalCer restores JNCL cell growth. WT CLN3p binds GalCer, but not mutant CLN3p. Sphingolipid content of rafts/Golgi is perturbed with diminished GalCer in rafts and accumulation in Golgi. CLN3-deficient raft vesicular structures are small by transmission electron microscopy, reflecting altered sphingolipid composition of rafts. CLN1/CLN2/CLN6 proteins bind to lysophosphatidic acid/sulfatide, CLN6/CLN8 proteins to GalCer, and CLN8 protein to ceramide. Sphingolipid composition/morphology of CLN1-/CLN2-/CLN6-/CLN8- and CLN9-deficient rafts are altered suggesting changes in raft structure/lipid stoichiometry could be common themes underlying these diseases.

Ras mediates radioresistance through both phosphatidylinositol 3-kinase-dependent and Raf-dependent but mitogen-activated protein kinase/extracellular signal-regulated kinase kinase-independent signaling pathways.

Cells transformed by the oncogenic small GTPase, Ras, display a radioresistant phenotype in response to ionizing radiation (IR). To determine the mechanisms by which Ras mediates radioresistance in epithelial cells, we assessed the importance of three major survival pathways that can be activated by Ras [phosphatidylinositol 3-kinase (PI3-K)>Akt, nuclear factor kappaB (NF-kappaB), and Raf>mitogen-activated protein kinase/extracellular signal-regulated kinase kinase (MEK)>extracellular signal-regulated kinase] as necessary or sufficient for Ras-mediated radioresistance in matched pairs of RIE-1 rat intestinal epithelial cells expressing oncogenic Ras or empty vector (RIE-Ras and RIE-vector). Inhibiting PI3-K with LY294002 sensitized RIE-1 cells to IR in a dose-dependent manner, indicating that PI3-K is necessary for radioresistance, whereas inhibition of NF-kappaB with the super-repressor IkappaBalpha had little effect on survival. Expression of either the constitutively active catalytic subunit of PI3-K, p110alpha-CAAX, or the Ras effector domain mutant 12V/40C, which retains binding to PI3-K but is impaired in binding to other Ras effectors, was sufficient to confer partial radioresistance. Expression of either a constitutively active form of the serine/threonine kinase Raf-1 or the Ras effector domain mutant 12V/35S, which retains binding to Raf but is impaired in binding to other Ras effectors, was also sufficient to confer partial radioresistance. Surprisingly, however, even complete inhibition of MEK activity by using U0126 resulted in no change in post-IR survival whatsoever. Thus, whereas Raf contributes to Ras-mediated radioresistance, this is accomplished through a MEK-independent pathway. Taken together, these results indicate that multiple pathways, including both PI3-K-dependent and Raf-dependent but MEK-independent signaling, are required for Ras-mediated radioresistance in epithelial cells. Finally, we demonstrate that Ras-mediated radioresistance can be uncoupled from Ras-mediated transformation, in that PI3-K is required for radioresistance but not transformation, whereas MEK and NF-kappaB are required for transformation but not radioresistance in RIE-1 epithelial cells.

R-Ras C-terminal sequences are sufficient to confer R-Ras specificity to H-Ras.

Activated versions of the similar GTPases, H-Ras and R-Ras, have differing effects on biological phenotypes: Activated H-Ras strongly transforms many fibroblast cell lines causing dramatic changes in cell shape and cytoskeletal organization. In contrast, R-Ras transforms fewer cell lines and the transformed cells display only some of the morphological changes associated with H-Ras transformation. H-Ras cells can survive in the absence of serum whereas R-Ras cells seem to die by an apoptotic-like mechanism in response to removal of serum. H-Ras can suppress integrin activation and R-Ras specifically antagonizes this effect. To map sequences responsible for these differences we have generated and investigated a panel of H-Ras and R-Ras chimeras. We found that the C-terminal 53 amino acids of R-Ras were necessary and sufficient to specify the contrasting biological properties of R-Ras with respect to focus morphology, reactive oxygen species (ROS) production and reversal of H-Ras-induced integrin suppression. Surprisingly, we found chimeras in which the focus formation and integrin-mediated phenotypes were separated, suggesting that different effectors could be involved in mediating these responses. An integrin profile of H-Ras and R-Ras cell pools showed no significant differences; both activated H-Ras and R-Ras expressing cells were found to have reduced beta(1) activity, suggesting that the activity state of the beta(1) subunit is not sufficient to direct an H-Ras transformed cell morphology.