Cytoplasmic flows localize injected oskar RNA in Drosophila oocytes.

BACKGROUND: The oskar (osk) gene encodes a determinant of posterior identity in Drosophila, and the localization of osk RNA to the pole plasm at the posterior pole of the oocyte is essential for development of the embryo. The mechanisms by which osk RNA is localized are unknown. RESULTS: To study the mechanisms underlying localization of osk RNA, we have injected fluorescently labelled RNA into oocytes at stages 9, 10 and 11. Injected osk RNA localizes to the pole plasm, reproducing localization of the endogenous RNA. In oocytes at stages 10 and 11, the long-range movement of injected osk RNA is promoted by a vigorous, microtubule-dependent cytoplasmic flow, or ooplasmic streaming. Treatment with colchicine, a microtubule-destabilizing drug, inhibits ooplasmic streaming and prevents localization of the RNA from an injection site distal to the posterior pole. If the RNA is injected close to the posterior pole, however, it localizes even in the presence of colchicine. Similarly, in small oocytes, such as stage 9 oocytes, localization of injected osk RNA is insensitive to colchicine. CONCLUSIONS: These results reveal that microtubule-dependent cytoplasmic flows could contribute to the long-range transport of osk RNA, whereas microtubule-independent processes could mediate short-range transport. These results also highlight the role of the osk RNA anchor in the localization process.

Requirement for Drosophila cytoplasmic tropomyosin in oskar mRNA localization.

The localization of oskar (osk) RNA to the posterior pole of the developing fruit fly (Drosophila) oocyte induces the assembly of pole plasm, causing development of the abdomen and germ line. Failure to localize oskar RNA results in embryos that lack abdomen and germ cells. Conversely, mis-targeting of oskar RNA to the anterior of the oocyte causes formation of ectopic abdomen and germ cells at the anterior pole. Maternal mutants that have reduced pole plasm activity produce sterile adults with normal abdominal development, suggesting that germ cells are more sensitive than abdomen to defects in pole plasm assembly. Thus mutations in genes that reduce oskar RNA localization or activity can be recovered as viable sterile adults. In a screen for mutants defective in germ cell formation, we isolated nine alleles of the tropomyosin II gene. Here we show that mutations in tropomyosin II (TmII) virtually abolish oskar RNA localization to the posterior pole, suggesting an involvement of the actin network in oskar RNA localization.

Microtubule-independent motility and nuclear targeting of adenoviruses with fluorescently labeled genomes.

A novel adenovirus system for analyzing the adenovirus entry pathway has been developed that contains green fluorescent protein bound to the encapsidated viral DNA (AdLite viruses). AdLite viruses enter host cells and accumulate around the nuclei and near the microtubule organizing centers (MTOC). In live cells, individual AdLite particles were observed trafficking both toward and away from the nucleus. Depolymerization of microtubules during infection prevented AdLite accumulation around the MTOC; however, it did not abolish perinuclear localization of AdLite particles. Furthermore, depolymerization of microtubules did not affect AdLite motility and did not affect gene expression from wild-type adenovirus and adenovirus-derived vectors. These data revealed that adenovirus intracellular motility and nuclear targeting can be supported by a mechanism that does not rely on the microtubule network.

Activation of heat-shock response by an adenovirus is essential for virus replication.

Successful viral infection requires viruses to redirect host biochemistry to replicate the viral genome, and produce and assemble progeny virions. Cellular heat-shock responses, which are characterized as elevation and relocalization of heat-shock proteins, occur during replication of many viruses. Such responses might be host reactions to the synthesis of foreign protein, or might be irrelevant consequences of the viral need to activate transcription. Alternatively, as heat-shock proteins can facilitate protein folding, activating a heat-shock response might be a specific virus function ensuring proper synthesis of viral proteins and virions. It is not possible to determine whether heat-shock response is essential for virus replication, because the implicated viral genes (such as Ad5 EIA, ref. 10) also control other essential replication steps. Here we report that expression of Gam1, a protein encoded by the avian virus CELO (ref. 11), elevates and relocalizes hsp70 and hsp40. Gam1-negative CELO is replication-defective; however, Gam1 function can be partially replaced by either heat shock or forced hsp40 expression. Thus, an essential function of Gam1 during virus replication is to activate host heat-shock responses with hsp40 as a primary target.