Frontiers in Physiology (Nov 2016)

Systematic Characterization of dynamic parameters of intracellular Calcium Signals

  • Laurent Mackay,
  • Nick Mikolajewicz,
  • Nick Mikolajewicz,
  • Svetlana V. Komarova,
  • Svetlana V. Komarova,
  • Anmar Khadra

DOI
https://doi.org/10.3389/fphys.2016.00525
Journal volume & issue
Vol. 7

Abstract

Read online

Dynamic processes, such as intracellular calcium signaling, are hallmark of cellular biology. As real-time imaging modalities become widespread, a need for analytical tools to reliably characterize time-series data without prior knowledge of the nature of the recordings becomes more pressing. The goal of this study is to develop a signal-processing algorithm for MATLAB that autonomously computes the parameters characterizing prominent single transient responses (TR) and/or multi-peaks responses (MPR). The algorithm corrects for signal contamination and decomposes experimental recordings into contributions from drift, TRs and MPRs. It subsequently provides numerical estimates for the following parameters: time of onset after stimulus application, activation time (time for signal to increase from 10% to 90% of peak), and amplitude of response. It also provides characterization of the (i) TRs by quantifying their area under the curve, response duration (time between ½ amplitude on ascent and descent of the transient), and decay constant of the exponential decay region of the deactivation phase of the response, and (ii) MPRs by quantifying the number of peaks, mean peak magnitude, mean periodicity, standard deviation of periodicity, oscillatory persistence (time between first and last discernable peak) and duty cycle (fraction of period during which system is active) for all the peaks in the signal, as well as coherent oscillations (i.e. deterministic spikes). We demonstrate that the signal detection performance of this algorithm is in agreement with user-mediated detection and that parameter estimates obtained manually and algorithmically are correlated. We then apply this algorithm to study how metabolic acidosis affects purinergic (P2) receptor-mediated calcium signalling in osteoclast precursor cells. Our results reveal that acidosis significantly attenuates the amplitude and AUC calcium responses at high ATP concentrations. Collectively, our data validated this algorithm as a general framework for comprehensively analyzing dynamic time-series.

Keywords