Methods for construction and analysis of computational models in systems biology : applications to the modelling of the heat shock response and the self-assembly of intermediate filaments
Mizera, Andrzej (2011-08-26)
Mizera, Andrzej
Turku Centre for Computer Science (TUCS)
26.08.2011
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https://urn.fi/URN:ISBN:978-952-12-2616-8
https://urn.fi/URN:ISBN:978-952-12-2616-8
Tiivistelmä
Systems biology is a new, emerging and rapidly developing, multidisciplinary
research field that aims to study biochemical and biological systems from
a holistic perspective, with the goal of providing a comprehensive, system-
level understanding of cellular behaviour. In this way, it addresses one of
the greatest challenges faced by contemporary biology, which is to compre-
hend the function of complex biological systems. Systems biology combines
various methods that originate from scientific disciplines such as molecu-
lar biology, chemistry, engineering sciences, mathematics, computer science
and systems theory. Systems biology, unlike “traditional” biology, focuses
on high-level concepts such as: network, component, robustness, efficiency,
control, regulation, hierarchical design, synchronization, concurrency, and
many others. The very terminology of systems biology is “foreign” to “tra-
ditional” biology, marks its drastic shift in the research paradigm and it
indicates close linkage of systems biology to computer science.
One of the basic tools utilized in systems biology is the mathematical
modelling of life processes tightly linked to experimental practice. The stud-
ies contained in this thesis revolve around a number of challenges commonly
encountered in the computational modelling in systems biology. The re-
search comprises of the development and application of a broad range of
methods originating in the fields of computer science and mathematics for
construction and analysis of computational models in systems biology. In
particular, the performed research is setup in the context of two biolog-
ical phenomena chosen as modelling case studies: 1) the eukaryotic heat
shock response and 2) the in vitro self-assembly of intermediate filaments,
one of the main constituents of the cytoskeleton. The range of presented
approaches spans from heuristic, through numerical and statistical to ana-
lytical methods applied in the effort to formally describe and analyse the
two biological processes. We notice however, that although applied to cer-
tain case studies, the presented methods are not limited to them and can
be utilized in the analysis of other biological mechanisms as well as com-
plex systems in general. The full range of developed and applied modelling
techniques as well as model analysis methodologies constitutes a rich mod-
elling framework. Moreover, the presentation of the developed methods,
their application to the two case studies and the discussions concerning
their potentials and limitations point to the difficulties and challenges one
encounters in computational modelling of biological systems. The problems
of model identifiability, model comparison, model refinement, model inte-
gration and extension, choice of the proper modelling framework and level
of abstraction, or the choice of the proper scope of the model run through
this thesis.
research field that aims to study biochemical and biological systems from
a holistic perspective, with the goal of providing a comprehensive, system-
level understanding of cellular behaviour. In this way, it addresses one of
the greatest challenges faced by contemporary biology, which is to compre-
hend the function of complex biological systems. Systems biology combines
various methods that originate from scientific disciplines such as molecu-
lar biology, chemistry, engineering sciences, mathematics, computer science
and systems theory. Systems biology, unlike “traditional” biology, focuses
on high-level concepts such as: network, component, robustness, efficiency,
control, regulation, hierarchical design, synchronization, concurrency, and
many others. The very terminology of systems biology is “foreign” to “tra-
ditional” biology, marks its drastic shift in the research paradigm and it
indicates close linkage of systems biology to computer science.
One of the basic tools utilized in systems biology is the mathematical
modelling of life processes tightly linked to experimental practice. The stud-
ies contained in this thesis revolve around a number of challenges commonly
encountered in the computational modelling in systems biology. The re-
search comprises of the development and application of a broad range of
methods originating in the fields of computer science and mathematics for
construction and analysis of computational models in systems biology. In
particular, the performed research is setup in the context of two biolog-
ical phenomena chosen as modelling case studies: 1) the eukaryotic heat
shock response and 2) the in vitro self-assembly of intermediate filaments,
one of the main constituents of the cytoskeleton. The range of presented
approaches spans from heuristic, through numerical and statistical to ana-
lytical methods applied in the effort to formally describe and analyse the
two biological processes. We notice however, that although applied to cer-
tain case studies, the presented methods are not limited to them and can
be utilized in the analysis of other biological mechanisms as well as com-
plex systems in general. The full range of developed and applied modelling
techniques as well as model analysis methodologies constitutes a rich mod-
elling framework. Moreover, the presentation of the developed methods,
their application to the two case studies and the discussions concerning
their potentials and limitations point to the difficulties and challenges one
encounters in computational modelling of biological systems. The problems
of model identifiability, model comparison, model refinement, model inte-
gration and extension, choice of the proper modelling framework and level
of abstraction, or the choice of the proper scope of the model run through
this thesis.