dictyNews
Electronic Edition
Volume 26, number 6
February 24, 2006

Please submit abstracts of your papers as soon as they have been
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or by using the form at
http://dictybase.org/db/cgi-bin/dictyBase/abstract_submit.

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useful information is available at dictyBase - http://dictybase.org.


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  Abstracts
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Dabp1 regulates pseudopodium number in chemotaxing Dictyostelium cells

Yanqin Wang and Theresa J. O'Halloran


Journal of Cell Science, in press

In Dictyostelium, chemotactic aggregation is a dynamic pathway in which 
cells respond to extracellular signals, polarize, and move with strong 
persistence into aggregation centers. Actin and actin-associated proteins 
play an important role in controlling the morphological changes and the 
directed movement of cells during chemotactic aggregation. Recently we 
identified a homologue of Abp1 in Dictyostelium (Dabp1). The first actin 
binding protein identified in yeast, abp1 plays a key role in actin-based 
endocytosis in these cells.  More recently, a role in receptor-mediated 
endocytosis has been identified for Abp1 in mammalian cells.  To explore 
possible functions of Dabp1 in Dictyostelium, we examined the phenotypes 
of cells that overexpressed the Dabp1 protein and cells that eliminated 
Dabp1 expression.  In these mutants most actin-based processes were intact. 
However, cell motility was altered during early development. During 
chemotactic streaming up to 25% (+4%) of Dabp1 null cells had multiple 
pseudopods while 92% wildtype cells had a single leading edge and a single 
uropod. Similarly, about 90% of cells that overexpressed Dabp1 projected 
multiple pseudopodia during chemotactic streaming, and displayed reduced 
rates of cell movement.  Expression of the SH3 domain of Dabp1 showed this 
domain to be an important determinant in regulating pseudopod number.  
These results suggest that Dabp1 controls pseudopod number and motility 
in early stages of chemotactic aggregation in Dictyostelium.


Submitted by: Terry OĠHalloran [t.ohalloran@mail.utexas.edu]
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Calmodulin-Mediated Signaling in Dictyostelium discoideum: CaMBOT Isolation 
and Characterization of the Novel Poly-Domain Protein Nucleomorphin and 
Other Calmodulin Binding Proteins.

Danton H. O'Day, Department of Biology, University of Toronto at Mississauga,
Mississauga, Ontario L5L 1C6 CANADA 

Chapter 6, In: "Focus on Cellular Signalling Research", Nova Science 
Publishers, Inc. (in press)

Calmodulin (CaM) is an essential protein in the model eukaryote Dictyostelium
discoideum where it mediates numerous events including chemotaxis, 
gametogenesis, fertilization, and spore germination. Profiling using the 
CaM-binding overlay technique (CaMBOT) has revealed that well over four-dozen 
calcium-dependent and -independent CaM-binding proteins (CaMBPs) are present 
in Dictyostelium, some of which are linked to these CaM-mediated processes.
Individual CaMBPs have been localized to specific sub-cellular locales and to 
show varying patterns of developmental expression. CaMBOT also is used to 
isolate cDNAs encoding CaMBPs from an expression library from mid-to-late 
multicellular development of Dictyostelium. Previously studied CaMBPs such as 
calcineurin A (CNA) and regulatory myosin light chain (RMLC) were identified 
in this way. Novel proteins were also identified. Nucleomorphin is a novel 
nuclear CaMBP, expressed as two main isoforms NumA1 and 2, which localizes to 
the nucleoplasmic periphery. NumA has at least one bipartite NLS 
(48KKSYQDPEIIAHSRPRK66) and a single CaM-binding domain 
(171EDVSRFIKGKLLQKQQKIYKDLERF195) that interacts with CaM in both a 
Ca2+-dependent and Ca2+-independent manner. NumA1 contains an extensive 
glu/asp or DEED repeat that regulates nuclear number. Yeast two hybrid and 
co-immunoprecipitation studies have identified calcium binding protein CBP4a 
as an interacting protein that binds to the DEED repeat. NumA2 also has a 
breast cancer C-terminus (BRCT) domain, two poly-N tracts plus a second, 
putative CaMBD. Proteins not previously known to be CaMBPs were also 
identified by CaMBOT probing of the Dictyostelium developmental expression
library, including phosphoglycerate kinase, thymidine kinase and histone H1. 
Dictyostelium phosphoglycerate kinase (DdPGK) binds CaM in a Ca2+-dependent 
manner with CaM negatively regulating its activity in vitro. The identified 
CaMBD shows 80% identity with PGKs from diverse organisms and is localized 
adjacent to mutation sites underlying certain human diseases. Thymidine 
kinase (DdTK1) is a Ca2+-dependent CaMBP and its in vitro activity is 
slightly enhanced by CaM and inhibited by CaM antagonists. Histone H1 (DdH1) 
was isolated as a CaMBP and binds CaM in vitro but its mode of CaM-binding 
remains elusive. Each of the CaMBPs we have identified is discussed in terms 
of its individual roles as well as its potential interaction with other 
CaMBPs and other proteins in regulating specific CaM-dependent cellular 
processes including the cell cycle.


Submitted by: Dan OĠDay [doday@utm.utoronto.ca]
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The contribution of the endoplasmic reticulum to Ca2+ signals in 
Dictyostelium depends on extracellular Ca2+

Paul R. Fisher* and Zofia Wilczynska.
Department of Microbiology, La Trobe University, Victoria 3086, Australia.


FEMS Microbiology Letters, in press

We recently reported the first molecular genetic evidence that Dictyostelium 
Ca2+ responses to chemoattractants include a contribution from the 
endoplasmic reticulum (ER) - responses are enhanced in mutants lacking 
calreticulin or calnexin, two major Ca2+-binding proteins in the ER, even 
though the influx of Ca2+ into the mutants is reduced. Compared to wild type 
cells, the ER in the mutants contributes at least 30-70 nM additional Ca2+ 
to the responses. Here we report that this additional ER contribution to the 
cytosolic Ca2+ signal depends upon extracellular Ca2+ - it does not occur in 
the absence of extracellular Ca2+, increases to a maximum as the 
extracellular Ca2+ levels rise to 10 uM and then remains constant at 
extracellular Ca2+ concentrations up to at least 250 uM. These results 
suggest that Ca2+ influx causes the intracellular release, in the simplest 
scenario by a mechanism involving Ca2+-induced Ca2+ release from the ER. By 
way of contrast, we show that Ca2+ responses to mechanical stimulation are
reduced, but still occur in the absence of extracellular Ca2+. Unlike the 
responses to chemoattractants, mechanoresponses thus include contributions 
from the ER that are independent of extracellular Ca2+.


Submitted by: Paul Fisher [fisher@lumi.micro.latrobe.edu.au]
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[End dictyNews, volume 26, number 6]