Partner: Mark Alber

University of Notre Dame (US)

Recent publications
1.Gejji R., Kaźmierczak B., Alber M., Classification and stability of global inhomogeneous solutions of a macroscopic model of cell motion, MATHEMATICAL BIOSCIENCES, ISSN: 0025-5564, DOI: 10.1016/j.mbs.2012.03.009, Vol.238, pp.21-31, 2012
Abstract:

Many micro-organisms use chemotaxis for aggregation, resulting in stable patterns. In this paper, the amoeba Dictyostelium discoideum serves as a model organism for understanding the conditions for aggregation and classification of resulting patterns. To accomplish this, a 1D nonlinear diffusion equation with chemotaxis that models amoeba behavior is analyzed. A classification of the steady state solutions is presented, and a Lyapunov functional is used to determine conditions for stability of inhomogenous solutions. Changing the chemical sensitivity, production rate of the chemical attractant, or domain length can cause the system to transition from having an asymptotic steady state, to having asymptotically stable single-step solution and multi-stepped stable plateau solutions.

Keywords:

Aggregation, Chemotaxis, Inhomogenous stability, Lyapunov functional, Plateau solutions, Dictyostelium discoideum

Affiliations:
Gejji R.-Ohio State University (US)
Kaźmierczak B.-IPPT PAN
Alber M.-University of Notre Dame (US)
2.Alber M., Gejji R., Kaźmierczak B., Existence of global solutions of a macroscopic model of cellular motion in a chemotactic field, APPLIED MATHEMATICS LETTERS, ISSN: 0893-9659, DOI: 10.1016/j.aml.2009.05.013, Vol.22, No.11, pp.1645-1648, 2009
Abstract:

Existence of global classical solutions of a class of reaction–diffusion systems with chemotactic terms is demonstrated. This class contains a system of equations derived recently as a continuous limit of the stochastic discrete cellular Potts model. This provides mathematical justification for using numerical solutions of this system for modeling cellular motion in a chemotactic field.

Keywords:

Reaction–diffusion systems, Nonlinear diffusion, Global existence, Continuous limit, Cellular motion, Chemotaxis

Affiliations:
Alber M.-University of Notre Dame (US)
Gejji R.-Ohio State University (US)
Kaźmierczak B.-IPPT PAN
3.Newman S.A., Christley S., Glimm T., Hentschel H.G., Kaźmierczak B., Zhang Y.T., Zhu J., Alber M., Multiscale models for vertebrate limb development, CURRENT TOPICS IN DEVELOPMENTAL BIOLOGY, ISSN: 0070-2153, Vol.81, pp.311-340, 2008
Abstract:

Dynamical systems in which geometrically extended model cells produce and interact with diffusible (morphogen) and nondiffusible (extracellular matrix) chemical fields have proved very useful as models for developmental processes. The embryonic vertebrate limb is an apt system for such mathematical and computational modeling since it has been the subject of hundreds of experimental studies, and its normal and variant morphologies and spatiotemporal organization of expressed genes are well known. Because of its stereotypical proximodistally generated increase in the number of parallel skeletal elements, the limb lends itself to being modeled by Turing-type systems which are capable of producing periodic, or quasiperiodic, arrangements of spot- and stripe-like elements. This chapter describes several such models, including, (i) a system of partial differential equations in which changing cell density enters into the dynamics explicitly, (ii) a model for morphogen dynamics alone, derived from the latter system in the “morphostatic limit” where cell movement relaxes on a much slower time-scale than cell differentiation, (iii) a discrete stochastic model for the simplified pattern formation that occurs when limb cells are placed in planar culture, and (iv) several hybrid models in which continuum morphogen systems interact with cells represented as energy-minimizing mesoscopic entities. Progress in devising computational methods for handling 3D, multiscale, multimodel simulations of organogenesis is discussed, as well as for simulating reaction–diffusion dynamics in domains of irregular shape.

Affiliations:
Newman S.A.-New York Medical College (US)
Christley S.-University of Chicago (US)
Glimm T.-Western Washington University (US)
Hentschel H.G.-Emory University (US)
Kaźmierczak B.-IPPT PAN
Zhang Y.T.-University of Notre Dame (US)
Zhu J.-University of Notre Dame (US)
Alber M.-University of Notre Dame (US)
4.Alber M., Glimm T., Hentschel H.G., Kaźmierczak B., Zhang Y.T., Zhu J., Newman S.A., The morphostatic limit for a model of skeletal pattern formation in the vertebrate limb, BULLETIN OF MATHEMATICAL BIOLOGY, ISSN: 0092-8240, DOI: 10.1007/s11538-007-9264-3, Vol.70, pp.460-483, 2007
Abstract:

A recently proposed mathematical model of a “core” set of cellular and molecular interactions present in the developing vertebrate limb was shown to exhibit pattern-forming instabilities and limb skeleton-like patterns under certain restrictive conditions, suggesting that it may authentically represent the underlying embryonic process (Hentschel et al., Proc. R. Soc. B 271, 1713–1722, 2004). The model, an eight-equation system of partial differential equations, incorporates the behavior of mesenchymal cells as “reactors,” both participating in the generation of morphogen patterns and changing their state and position in response to them. The full system, which has smooth solutions that exist globally in time, is nonetheless highly complex and difficult to handle analytically or numerically. According to a recent classification of developmental mechanisms (Salazar-Ciudad et al., Development 130, 2027–2037, 2003), the limb model of Hentschel et al. is “morphodynamic,” since differentiation of new cell types occurs simultaneously with cell rearrangement. This contrasts with “morphostatic” mechanisms, in which cell identity becomes established independently of cell rearrangement. Under the hypothesis that development of some vertebrate limbs employs the core mechanism in a morphostatic fashion, we derive in an analytically rigorous fashion a pair of equations representing the spatiotemporal evolution of the morphogen fields under the assumption that cell differentiation relaxes faster than the evolution of the overall cell density (i.e., the morphostatic limit of the full system). This simple reaction–diffusion system is unique in having been derived analytically from a substantially more complex system involving multiple morphogens, extracellular matrix deposition, haptotaxis, and cell translocation. We identify regions in the parameter space of the reduced system where Turing-type pattern formation is possible, which we refer to as its “Turing space.” Obtained values of the parameters are used in numerical simulations of the reduced system, using a new Galerkin finite element method, in tissue domains with nonstandard geometry. The reduced system exhibits patterns of spots and stripes like those seen in developing limbs, indicating its potential utility in hybrid continuum-discrete stochastic modeling of limb development. Lastly, we discuss the possible role in limb evolution of selection for increasingly morphostatic developmental mechanisms.

Keywords:

Limb development, Chondrogenesis, Mesenchymal condensation, Reaction–diffusion model

Affiliations:
Alber M.-University of Notre Dame (US)
Glimm T.-Western Washington University (US)
Hentschel H.G.-Emory University (US)
Kaźmierczak B.-IPPT PAN
Zhang Y.T.-University of Notre Dame (US)
Zhu J.-University of Notre Dame (US)
Newman S.A.-New York Medical College (US)
5.Alber M., Hentschel H.G.E., Kaźmierczak B., Newman S.A., Existence of solutions to a new model of biological pattern formation, JOURNAL OF MATHEMATICAL ANALYSIS AND APPLICATIONS, ISSN: 0022-247X, DOI: 10.1016/j.jmaa.2004.11.026, Vol.308, pp.175-194, 2005
Abstract:

In this paper we study the existence of classical solutions to a new model of skeletal development in the vertebrate limb. The model incorporates a general term describing adhesion interaction between cells and fibronectin, an extracellular matrix molecule secreted by the cells, as well as two secreted, diffusible regulators of fibronectin production, the positively-acting differentiation factor (“activator”) TGF-β, and a negatively-acting factor (“inhibitor”). Together, these terms constitute a pattern forming system of equations. We analyze the conditions guaranteeing that smooth solutions exist globally in time. We prove that these conditions can be significantly relaxed if we add a diffusion term to the equation describing the evolution of fibronectin.

Affiliations:
Alber M.-University of Notre Dame (US)
Hentschel H.G.E.-Emory University (US)
Kaźmierczak B.-IPPT PAN
Newman S.A.-New York Medical College (US)
6.Chaturvedi R., Huang C., Kaźmierczak B., Schneider T., Izaguirre J., Glimm T., Hentschel H.G.E., Glazier J., Newman S., Alber M., On multiscale approaches to three-dimensional modelling of morphogenesis, JOURNAL OF THE ROYAL SOCIETY INTERFACE, ISSN: 1742-5689, DOI: 10.1098/rsif.2005.0033, Vol.2, pp.237-253, 2005
Abstract:

In this paper we present the foundation of a unified, object-oriented, three-dimensional biomodelling environment, which allows us to integrate multiple submodels at scales from subcellular to those of tissues and organs. Our current implementation combines a modified discrete model from statistical mechanics, the Cellular Potts Model, with a continuum reaction–diffusion model and a state automaton with well-defined conditions for cell differentiation transitions to model genetic regulation. This environment allows us to rapidly and compactly create computational models of a class of complex-developmental phenomena. To illustrate model development, we simulate a simplified version of the formation of the skeletal pattern in a growing embryonic vertebrate limb.

Affiliations:
Chaturvedi R.-University of Notre Dame (US)
Huang C.-University of Notre Dame (US)
Kaźmierczak B.-IPPT PAN
Schneider T.-University College London (GB)
Izaguirre J.-University of Notre Dame (US)
Glimm T.-Western Washington University (US)
Hentschel H.G.E.-Emory University (US)
Glazier J.-Indiana University (US)
Newman S.-New York Medical College (US)
Alber M.-University of Notre Dame (US)
7.Alber M., Glimm T., Hentschel H.G.E., Kaźmierczak B., Newman S., Stability of an n-dimensional patterns in a generalized turing system: implications for a biological patterns formation, NONLINEARITY, ISSN: 0951-7715, DOI: 10.1088/0951-7715/18/1/007, Vol.18, pp.125-138, 2005
Abstract:

The stability of Turing patterns in an n-dimensional cube (0, π)n is studied, where n ≥ 2. It is shown by using a generalization of a classical result of Ermentrout concerning spots and stripes in two dimensions that under appropriate assumptions only sheet-like or nodule-like structures can be stable in an n-dimensional cube. Other patterns can also be stable in regions comprising products of lower-dimensional cubes and intervals of appropriate length. Stability results are applied to a new model of skeletal pattern formation in the vertebrate limb.

Affiliations:
Alber M.-University of Notre Dame (US)
Glimm T.-Western Washington University (US)
Hentschel H.G.E.-Emory University (US)
Kaźmierczak B.-IPPT PAN
Newman S.-New York Medical College (US)