174 research outputs found
Fan-out in Gene Regulatory Networks
In synthetic biology, gene regulatory circuits are often constructed by
combining smaller circuit components. Connections between components are
achieved by transcription factors acting on promoters. If the individual
components behave as true modules and certain module interface conditions are
satisfied, the function of the composite circuits can in principle be
predicted. In this paper, we investigate one of the interface conditions:
fan-out. We quantify the fan-out, a concept widely used in electric
engineering, to indicate the maximum number of the downstream inputs that an
upstream output transcription factor can regulate. We show that the fan-out is
closely related to retroactivity studied by Del Vecchio, et al. We propose an
efficient operational method for measuring the fan-out that can be applied to
various types of module interfaces. We also show that the fan-out can be
enhanced by self-inhibitory regulation on the output. We discuss the potential
role of the inhibitory regulations found in gene regulatory networks and
protein signal pathways. The proposed estimation method for fanout not only
provides an experimentally efficient way for quantifying the level of
modularity in gene regulatory circuits but also helps characterize and design
module interfaces, enabling the modular construction of gene circuits.Comment: 28 pages, 5 figure
SBML Reaction Finder: Retrieve and extract specific reactions from the BioModels database
Summary: The SBML Reaction Finder (SRF) application leverages the deep semantic annotations in the BioModels database to provide efficient retrieval and extraction of individual reactions from SBML models. We hope that the SRF will be useful to quantitative modelers who seek to accelerate their modeling efforts by reusing previously published representations of specific chemical reactions.

Availability and Implementation: The SRF is open source, coded in Java, and distributed under the Mozilla Pubic License Version 1.1. Windows, Macintosh and Linux distributions are available for download at 
http://sourceforge.net/projects/sbmlrxnfinder.

TinkerCell: Modular CAD Tool for Synthetic Biology
Synthetic biology brings together concepts and techniques from engineering
and biology. In this field, computer-aided design (CAD) is necessary in order
to bridge the gap between computational modeling and biological data. An
application named TinkerCell has been created in order to serve as a CAD tool
for synthetic biology. TinkerCell is a visual modeling tool that supports a
hierarchy of biological parts. Each part in this hierarchy consists of a set of
attributes that define the part, such as sequence or rate constants. Models
that are constructed using these parts can be analyzed using various C and
Python programs that are hosted by TinkerCell via an extensive C and Python
API. TinkerCell supports the notion of a module, which are networks with
interfaces. Such modules can be connected to each other, forming larger modular
networks. Because TinkerCell associates parameters and equations in a model
with their respective part, parts can be loaded from databases along with their
parameters and rate equations. The modular network design can be used to
exchange modules as well as test the concept of modularity in biological
systems. The flexible modeling framework along with the C and Python API allows
TinkerCell to serve as a host to numerous third-party algorithms. TinkerCell is
a free and open-source project under the Berkeley Software Distribution
license. Downloads, documentation, and tutorials are available at
www.tinkercell.com.Comment: 23 pages, 20 figure
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