dictyNews
Electronic Edition
Volume 34, number 10
March 19, 2010

Please submit abstracts of your papers as soon as they have been
accepted for publication by sending them to dicty@northwestern.edu
or by using the form at
http://dictybase.org/db/cgi-bin/dictyBase/abstract_submit.

Back issues of dictyNews, the Dicty Reference database and other
useful information is available at dictyBase - http://dictybase.org.

Follow dictyBase on twitter:
http://twitter.com/dictybase

=========
Abstracts
=========

Cheating does not explain selective differences at high and low 
relatedness in a social amoeba

Gerda Saxer, Debra A. Brock, David C. Queller and 
Joan E. Strassmann


BMC Evolutionary Biology 2010, 10:76
 
Background
Altruism can be favored by high relatedness among interactants.  We tested 
the effect of relatedness in experimental populations of the social amoeba 
Dictyostelium discoideum, where altruism occurs in a starvation-induced social 
stage when some amoebae die to form a stalk that lifts the fertile spores above 
the soil facilitating dispersal. The single cells that aggregate during the social 
stage can be genetically diverse, which can lead to conflict over spore and 
stalk allocation. We mixed eight genetically distinct wild isolates and 
maintained twelve replicated populations at a high and a low relatedness 
treatment.  After one and ten social generations we assessed the strain 
composition of the populations.  We expected that some strains would be 
out-competed in both treatments. In addition, we expected that low 
relatedness might allow the persistence of social cheaters as it provides 
opportunity to exploit other strains.

Results
We found that at high relatedness a single clone prevailed in all twelve 
populations. At low relatedness three clones predominated in all twelve 
populations. Interestingly, exploitation of some clones by others in the social 
stage did not explain the results. When we mixed each winner against the 
pool of five losers, the winner did not prevail in the spores because all 
contributed fairly to the stalk and spores.  Furthermore, the dominant clone 
at high-relatedness was not cheated by the other two that persisted at low 
relatedness.  A combination of high spore production and short unicellular 
stage most successfully explained the three successful clones at low 
relatedness, but not why one of them fared better at high relatedness.  
Differences in density did not account for the results, as the clones did not 
differ in vegetative growth rates nor did they change the growth rates over 
relevant densities.

Conclusions
These results suggest that social competition and something beyond solitary 
growth differences occurs during the vegetative stage when amoebae eat 
bacteria and divide by binary fission. The high degree of repeatability of our 
results indicates that these effects are strong and points to the importance 
of new approaches to studying interactions in D. discoideum.


Submitted by Gerda Saxer [gsaxer@rice.edu]
--------------------------------------------------------------------------------

A Ras signaling complex controls the RasC-TORC2 pathway and 
directed cell migration

Pascale G. Charest, Zhouxin Shen, Ashley Lakoduk, Atsuo T. Sasaki, 
Steven P. Briggs, and Richard A. Firtel


Developmental Cell, in press

Ras was found to regulate Dictyostelium chemotaxis, but the mechanisms 
that spatially and temporally control Ras activity during chemotaxis remain 
largely unknown. We report the discovery of a Ras signaling complex that 
includes the Ras guanine exchange factor (RasGEF) Aimless, RasGEFH, 
protein phosphatase 2A (PP2A), and a scaffold designated Sca1. The 
Sca1/RasGEF/PP2A complex is recruited to the plasma membrane in a 
chemoattractant- and F-actin-dependent manner and is enriched at the 
leading edge of chemotaxing cells where it regulates F-actin dynamics 
and signal relay by controlling the activation of RasC and the downstream 
TORC2-Akt/protein kinase B (PKB) pathway. In addition, PKB and 
PKB-related PKBR1 phosphorylate Sca1 and regulate the membrane 
localization of the Sca1/RasGEF/PP2A complex, and thereby RasC activity, 
in a negative feedback fashion. Thus, our study uncovered a molecular 
mechanism whereby RasC activity and the spatiotemporal activation of 
TORC2 are tightly controlled at the leading edge of chemotaxing cells.


Submitted by Rick Firtel [rafirtel@ucsd.edu]
==============================================================
[End dictyNews, volume 34, number 10]