An important aspect of Ca2+ signaling is the ability of cells to generate i
ntracellular Ca2+ waves. In this study we have analyzed the cellular and su
bcellular kinetics of Ca2+ waves in a neuroendocrine transducer cell, the m
elanotrope of Xenopus laevis, using the ratiometric Ca2+ probe indo-1 and v
ideo-rate UV confocal laser-scanning microscopy. The purpose of the present
study was to investigate how local Ca2+ changes contribute to a global Ca2
+ signal; subsequently we quantified how a Ca2+ wave is kinetically reshape
d as it is propagated through the cell. The combined kinetics of all subcel
lular Ca2+ signals determined the shape of the total cellular Ca2+ signal,
but each subcellular contribution to the cellular signal was not constant i
n time. Near the plasma membrane, [Ca2+](i) increased and decreased rapidly
, processes that can be described by a linear and exponential function, res
pectively. In more central parts of the cell slower kinetics were observed
that were best described by a Hill equation. This reshaping of the Ca2+ wav
e was modeled with an equation derived from a low-pass RC filter. We propos
e that the differences in spatial kinetics of the Ca2+ signal serves as a m
echanism by which the same cellular Ca2+ signal carries different regulator
y information to different subcellular regions of the cell, thus evoking di
fferential cellular responses.