Abstract
Biological cells in a population are variable in practically every property. Much is known about how variability of single cells is reflected in the statistical properties of infinitely large populations; however, many biologically relevant situations entail finite times and intermediate-sized populations. The statistical properties of an ensemble of finite populations then come into focus, raising questions concerning inter-population variability and dependence on initial conditions. Recent technologies of microfluidic and microdroplet-based population growth realize these situations and make them immediately relevant for experiments and biotechnological application. We here study the statistical properties, arising from metabolic variability of single cells, in an ensemble of micro-populations grown to saturation in a finite environment such as a micro-droplet. We develop a discrete stochastic model for this growth process, describing the possible histories as a random walk in a phenotypic space with an absorbing boundary. Using a mapping to Polya’s Urn, a classic problem of probability theory, we find that distributions approach a limiting inoculum-dependent form after a large number of divisions. Thus, population size and structure are random variables whose mean, variance and in general their distribution can reflect initial conditions after many generations of growth. Implications of our results to experiments and to biotechnology are discussed.
Highlights
Biological cell populations exhibit a broad distribution of phenotypes, even if genetically homogenous
Deterministic (Average) Dynamics A homogeneous population growing in a microdroplet, starting with initial conditions of cell number and resource (N0,S0), will grow to a stopping time tà when the resource is depleted
Recent advances in microdroplet and microfluidic technology for growing cell populations have the potential to provide basis for many practical applications. They open up an interesting regime for cell population behavior that has previously been unexplored
Summary
Biological cell populations exhibit a broad distribution of phenotypes, even if genetically homogenous Such variability has been observed in practically every single-cell phenotypic property that was measured, including cell size, protein content, division rate and more. In the standard approach to the problem, from single cell properties that have some stochastic components emerge the statistical properties of a large (practically infinite) population Within this approach, variability in division rate seems to be a most important property for population dynamics, and its implications have been widely studied, especially in the context of fluctuating environments [15,16,17,18,19]
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