dictyNews
Electronic Edition
Volume 28, number 11
May 4, 2007

Please submit abstracts of your papers as soon as they have been
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Abstracts
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Stochastic signal processing and transduction in chemotactic response of 
eukaryotic cells

Masahiro Ueda and Tatsuo Shibata

Laboratories for Nanobiology, Graduate School of Frontier Biosciences, 
Osaka University, Suita, Osaka 565-0871, Japan
Department of Mathematical and Life Sciences, University of Hiroshima, 
Higashi-Hiroshima, Hiroshima 739-8526, Japan


Biophysical Journal, in press

Single molecule imaging analysis of chemotactic response in eukaryotic cells 
has revealed a stochastic nature in the input signals and the signal 
transduction processes. This leads to a fundamental question on the signaling 
processes: how does the signaling system operate under stochastic fluctuations 
or noise? Here we report a stochastic model of chemotactic signaling in which 
noise and signal propagation along transmembrane signaling by chemoattractant 
receptors can be analyzed quantitatively. The results obtained from this 
analysis reveal that the second messenger production reactions by the 
receptors generate noisy signals, which contain intrinsic noise inherently 
generated at this reaction and extrinsic noise propagated from the 
ligand-receptor-binding. Such intrinsic and extrinsic noises limit directional 
sensing ability of chemotactic cells, which can explain the dependence of 
chemotactic accuracy on chemical gradients that have been observed 
experimentally. Our analysis also reveals regulatory mechanisms for signal 
improvements in the stochastically-operating signaling system by analyzing 
how signal-to-noise ratio (SNR) of chemotactic signals can be improved or 
deteriorated by the stochastic properties of receptors and second messenger 
molecules. Theoretical consideration of noisy signal transduction by 
chemotactic signaling systems can further be applied to other signaling 
systems in general. 


Submitted by: Masahiro Ueda [ueda@phys1.med.osaka-u.ac.jp]
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Input-output relationship in galvanotactic response 
of Dictyostelium cells 

Masayuki J. Sato, Michihito Ueda, Hiroaki Takagi, Tomonobu M. Watanabe, 
Toshio Yanagida, and Masahiro Ueda

Laboratories for Nanobiology, Graduate School of Frontier Biosciences, 
Osaka University, 1-3 Yamadaoka, Suita, Osaka, 565-0871, Japan. 
Advanced Technology Research Laboratories, Matsushita Electric Industrial Co., 
Ltd., 3-4 Hikaridai, Seika-cho, Soraku-gun, Kyoto 619-0237, Japan. 

Biosystems 88, 261-272.

Under a direct current electric field, Dictyostelium cells exhibit migration 
towards the cathode direction. To determine the input-output relationship of 
the cellŐs galvanotactic response, we developed an experimental instrument in 
which electric signals applied to the cells are highly reproducible and the 
motile response are analyzed quantitatively. With no electric field, the cells 
moved randomly in all directions. Upon applying an electric field, cell 
migration speeds became about 1.3 times faster than those in the absence of an 
electric field. Such kinetic effects of electric fields on the migration were 
observed for cells stimulated between 0.25 to 10 V/cm of the field strength. 
The directions of cell migrations were biased toward the cathode in a positive 
manner with field strength, showing galvanotactic response in a dose-dependent 
manner. Quantitative analysis of the relationship between field strengths and 
directional movements revealed that the biased movements of the cells depend on 
the square of electric field strength, which can be described by one simple 
phenomenological equation. The threshold strength for the galvanotaxis was 
between 0.25 and 1 V/cm. Galvanotactic efficiency reached to half-maximum at 
2.6 V/cm, which corresponds to an approximately 8 mV voltage difference between 
the cathode and anode direction of 10 microm wide, round cells. Based on these 
results, possible mechanisms of galvanotaxis in Dictyostelium cells were 
discussed. This development of experimental system, together with its good 
microscopic accessibility for intracellular signaling molecules, makes 
Dictyostelium cells attractive as a model organism for elucidating stochastic 
processes in the signaling systems responsible for cell motility and its 
regulations. 


Submitted by: Masahiro Ueda [ueda@phys1.med.osaka-u.ac.jp]
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Dictyostelium differentiation-inducing factor-1 (DIF-1) induces GLUT1 
translocation and promotes glucose uptake in mammalian cells

Waka Omata, Hiroshi Shibata, Msahiro Nagasawa, Itaru Kojima, Haruhisa Kikuchi, 
Yoshiteru Oshima, Kohei Hosaka and Yuzuru Kubohara

Institute for Molecular and Cellular Regulation, Gunma University, Janan.


FEBS Journal, In press

The differentiation-inducing factor-1 (DIF-1) is a signal molecule that induces 
stalk cell formation in the cellular slime mold Dictyostelium discoideum, while 
DIF-1 and its analogs have been shown to possess anti-proliferative activity 
in vitro in mammalian tumor cells.  In the present study, we have investigated 
the effects of DIF-1 and its analogs on normal (non-transformed) mammalian cells.  
Without affecting the cell morphology and cell number, DIF-1 at micromolar levels 
dose-dependently promoted the glucose uptake in confluent 3T3-L1 fibroblasts, 
which was not inhibited with wortmannin or LY293002 [inhibitors for 
phosphatidylinositol 3-kinase (PI3K)].  DIF-1 affected neither the expression 
level of GLUT1 (glucose transporter 1) nor the activities of four key enzymes 
involved in glucose metabolism, such as hexokinase, fluctose-6-phosphate kinase, 
pyruvate kinase, and glucose-6-phosphate dehydrogenase.  Most importantly, 
stimulation with DIF-1 was found to induce the translocation of GLUT1 from 
intracellular vesicles to the plasma membranes in the cells.  In differentiated 
3T3-L1 adipocytes, DIF-1 induced the translocation of GLUT1 (but not of GLUT4) 
and promoted glucose uptake, which was not inhibited with wortmannin.  These 
results indicate that DIF-1 induces GLUT1 translocation and thereby promotes 
glucose uptake, at least in part, via a PI3K/Akt-independent pathway in mammalian 
cells.  Furthermore, analogs of DIF-1 that possess stronger anti-tumor activity 
than DIF-1 were less effective in promoting glucose consumption, suggesting that 
the mechanism of the action of DIF-1 for stimulating glucose uptake should be 
different from that for suppressing tumor cell growth. 


Submitted by: Yuzuru Kubohara [kubohara@showa.gunma-u.ac.jp]
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[End dictyNews, volume 28, number 11]