network [3, 85], such manipulation can be handled by standard
procedures which pose no additional conceptual issues
[27, 49]. Beyond the genomic information, the nonlinear dynami-
cal biochemical interactions among the endogenous agents gener-
ate normal tissue attractors and cancer attractors. Due to the
nonlinear biochemical interactions beyond genomic information,
the present hypothesis holds that there is no simple one-to-one
relationship between genotype and phenotype in complex diseases
such as cancer. Instead, genotype is in general related to phenotypes
by a very complex network of biochemical reactions [86, 87]. The
genesis and progression of cancer is assumed as the transition from
the intrinsic normal state to the intrinsic cancer state. A suitable
quantity to describe such a process is the adaptive landscape [11].
Moreover, without any a priori knowledge of genetic mutation
propensity in HCC, our results show that such network-level ana-
lyses are indeed a powerful approach to enable the prediction and a
better understanding of genetic mutations in HCC. This illustrates
the usefulness of network-level analyses as a means to predict and
understand genetic mutations in cancers.3.2 Working
Endogenous Network
and Typical
Bioinformatics
Network
The aim to establish a liver endogenous network is to reveal the
core regulatory mechanisms of HCC genesis and progression at the
systemic level. Many other high-throughput-based frameworks,
such as ENCODE project [88], also have been proposed with
similar aims. Theoretically, the regulatory mechanism can be
deduced from high-throughput data if we have enough data
[89]. Nevertheless, in reality the present genome-wide gene expres-
sion and protein interactions information are far from achieving
this goal [18, 89]. Currently, analysis of high throughput is based
more on statistics which can deduce the network topology and
correlation between these molecular-cellular agents [88]. In the
endogenous network construction, we solve this issue by making
full use of the well-documented gene regulatory network and
signaling transduction pathway which reflect our accumulated
knowledge in molecular biology of liver.
We have realized the hypothesis by establishing working endoge-
nous network for liver. Many other high-throughput-based frame-
works also have been proposed to grasp the regulatory mechanism of
biological systems, such as transcriptomics, ENCODE project, etc.
[88]. Those frameworks play an important role in accelerating our
understanding of biological systems. Nevertheless, it is unlikely that
we can deduce the endogenous molecular-cellular network or other
higher-level descriptions of a tissue solely from genome wide infor-
mation about gene expression and physical interactions between
proteins [18, 90, 91]. The quantitative analysis of high throughput
is based on statistics, less on biological mechanism, they are often
used to deduce the network topology or correlation between these
molecular-cellular agents [88]. Comparedwiththenetwork obtainedEndogenous Molecular-Cellular Network Cancer Theory 237