A Unique Virulence Gene Occupies a Principal Position in Immune Evasion by the Malaria Parasite Plasmodium falciparum.

Mutually exclusive gene expression, whereby only one member of a multi-gene family is selected for activation, is used by the malaria parasite Plasmodium falciparum to escape the human immune system and perpetuate long-term, chronic infections. A family of genes called var encodes the chief antigenic and virulence determinant of P. falciparum malaria. var genes are transcribed in a mutually exclusive manner, with switching between active genes resulting in antigenic variation. While recent work has shed considerable light on the epigenetic basis for var gene activation and silencing, how switching is controlled remains a mystery. In particular, switching seems not to be random, but instead appears to be coordinated to result in timely activation of individual genes leading to sequential waves of antigenically distinct parasite populations. The molecular basis for this apparent coordination is unknown. Here we show that var2csa, an unusual and highly conserved var gene, occupies a unique position within the var gene switching hierarchy. Induction of switching through the destabilization of var specific chromatin using both genetic and chemical methods repeatedly led to the rapid and exclusive activation of var2csa. Additional experiments demonstrated that these represent "true" switching events and not simply de-silencing of the var2csa promoter, and that activation is limited to the unique locus on chromosome 12. Combined with translational repression of var2csa transcripts, frequent "default" switching to this locus and detection of var2csa untranslated transcripts in non-pregnant individuals, these data suggest that var2csa could play a central role in coordinating switching, fulfilling a prediction made by mathematical models derived from population switching patterns. These studies provide the first insights into the mechanisms by which var gene switching is coordinated as well as an example of how a pharmacological agent can disrupt antigenic variation in Plasmodium falciparum.

p27 deficiency is associated with migration defects in PDGF-expressing gliomas in vivo.

p27(Kip1) is a cyclin dependent kinase inhibitor that functions as a tumor suppressor in a variety of different cancers. While p27 has a well established role in regulating the cell cycle, it has also been shown to regulate cellular migration by influencing the activation state of the small GTPase RhoA. We recently demonstrated that loss of p27 enhances tumor progression and leads to a dramatic decrease in survival in PDGF-induced oligodendrogliomas. Here we show that p27 deficient PDGF-expressing glial cells contained elevated levels of Rho-GTP and were less migratory than wild type cells. Migration defects in p27 deficient cells were rescued by either Rho kinase inhibition or expression of p27 or CK(-), a mutant of p27 that cannot bind cyclins/cdks. The RCAS/tv-a retroviral system was used to specifically induce PDGF-expressing gliomas in mice. Many of the p27 deficient mice died earlier than wild type mice and displayed hydrocephalus which was associated with periventricular tumors that failed to invade the normal brain parenchyma. Invasion failure was reversed by co-expression of PDGF with either the GAP domain of p190(RhoGAP), a negative regulator of Rho, or p27, or CK(-). These results suggest that p27 mediated regulation of the Rho pathway is cell cycle independent and demonstrate for the first time a migration defect in cancer cells that is associated with p27 deficiency in vivo in a mouse tumor model.