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Current
Genomics
ISSN: 1389-2029
Current Genomics
Volume 8, Number 1, March 2007
Contents
Validation of Computational Methods in Genomics
Pp. 1-19
E.R. Dougherty, J. Hua and M.L. Bittner
[Abstract] [Full
text article]
Challenges and Solutions in Proteomics
Pp. 21-28
H. Huang, H.D. Shukla, C. Wu and S. Saxena
[Abstract] [Full
text article]
Nutrigenomics, β-Cell
Function and Type 2 Diabetes Pp. 29-42
R. Nino-Fong, T.M. Collins and C.B. Chan
[Abstract] [Full
text article]
Ribosomal Proteins and Colorectal Cancer
Pp. 43-49
L. Mao-De and X. Jing
[Abstract] [Full
text article]
Pas de deux: Natural Killer Receptors and
MHC Class I Ligands in Primates Pp. 51-57
L. Walter
[Abstract] [Full
text article]
H2A.Z-Mediated Genome-Wide Chromatin Specialization
Pp. 59-66
J.M. Eirín-López and J. Ausió
[Abstract] [Full
text article]
The Development of Chromosome Microdissection and
Microcloning Technique and its Applications in Genomic Research
Pp. 67-72
R.-N. Zhou and Z.-M. Hu
[Abstract] [Full
text article]
Abstracts
[Back to top]
Validation of Computational Methods in Genomics
E.R. Dougherty, J. Hua and M.L. Bittner
[Full
text article]
High-throughput technologies for genomics provide tens
of thousands of genetic measurements, for instance, gene-expression
measurements on microarrays, and the availability of these
measurements has motivated the use of machine learning (inference)
methods for classification, clustering, and gene networks.
Generally, a design method will yield a model that satisfies
some model constraints and fits the data in some manner. On
the other hand, a scientific theory consists of two parts:
(1) a mathematical model to characterize relations between
variables, and (2) a set of relations between model variables
and observables that are used to validate the model via
predictive experiments. Although machine learning algorithms
are constructed to hopefully produce valid scientific models,
they do not ipso facto do so. In some cases, such
as classifier estimation, there is a well-developed error
theory that relates to model validity according to various
statistical theorems, but in others such as clustering, there
is a lack of understanding of the relationship between the
learning algorithms and validation. The issue of validation
is especially problematic in situations where the sample size
is small in comparison with the dimensionality (number of
variables), which is commonplace in genomics, because the
convergence theory of learning algorithms is typically asymptotic
and the algorithms often perform in counter-intuitive ways
when used with samples that are small in relation to the number
of variables. For translational genomics, validation is perhaps
the most critical issue, because it is imperative that we
understand the performance of a diagnostic or therapeutic
procedure to be used in the clinic, and this performance relates
directly to the validity of the model behind the procedure.
This paper treats the validation issue as it appears in two
classes of inference algorithms relating to genomics –
classification and clustering. It formulates the problem and
reviews salient results.
[Back to top]
Challenges and Solutions in Proteomics
H. Huang, H.D. Shukla, C. Wu and S. Saxena
[Full
text article]
The accelerated growth of proteomics data presents both opportunities
and challenges. Large-scale proteomic profiling of biological
samples such as cells, organelles or biological fluids has
led to discovery of numerous key and novel proteins involved
in many biological/disease processes including cancers, as
well as to the identification of novel disease biomarkers
and potential therapeutic targets. While proteomic data analysis
has been greatly assisted by the many bioinformatics tools
developed in recent years, a careful analysis of the major
steps and flow of data in a typical high-throughput analysis
reveals a few gaps that still need to be filled to fully realize
the value of the data. To facilitate functional and pathway
discovery for large-scale proteomic data, we have developed
an integrated proteomic expression analysis system, iProXpress,
which facilitates protein identification using a comprehensive
sequence library and functional interpretation using integrated
data. With its modular design, iProXpress complements and
can be integrated with other software in a proteomic data
analysis pipeline. This novel approach to complex biological
questions involves the interrogation of multiple data sources,
thereby facilitating hypothesis generation and knowledge discovery
from the genomic-scale studies and fostering disease diagnosis
and drug development.
[Back to top]
Nutrigenomics, β-Cell
Function and Type 2 Diabetes
R. Nino-Fong, T.M. Collins and C.B. Chan
[Full
text article]
“Nutrigenomics” refers to the ability of nutrients
to alter gene expression. Insulin secreting β-cells
exhibit genomic and molecular changes that enhance their function
when acutely exposed to physiological concentrations of glucose
and fatty acids. However, chronic exposure, such as occurs
in the hyperlipidemic, hyperglycemic state of obesity/prediabetes
can exert deleterious effects on β-cell
function through alteration of gene expression. The genomic
underpinnings of so-called glucolipotoxicity on the β-cell
and its relationship to development of type 2 diabetes will
be discussed in this review article. For example, free fatty
acids influence β-cell
gene expression by direct interaction with transcription factors
such as peroxisome proliferator-activated receptors. Glucose
responsive genes include the insulin gene as well as genes
involved in β-cell
survival and other functions. In addition, obesity is now
recognized as a condition of chronic, low-level inflammation.
The adipose tissue secretes multiple circulating hormones
termed adipokines, and the relationship between these and
the β-cell
has been termed adipotoxicity. The influence of adipokines
on regulation of insulin secretion and β-cell
survival will be reviewed.
[Back to top]
Ribosomal Proteins and Colorectal Cancer
L. Mao-De and X. Jing
[Full
text article]
The ribosome is essential for protein synthesis. The composition
and structure of ribosomes from several organisms have been
determined, and it is well documented that ribosomal RNAs
(rRNAs) and ribosomal proteins (RPs) constitute this important
organelle. Many RPs also fill various roles that are independent
of protein biosynthesis, called extraribosomal functions.
These functions include DNA replication, transcription and
repair, RNA splicing and modification, cell growth and proliferation,
regulation of apoptosis and development, and cellular transformation.
Previous investigations have revealed that RP regulation in
colorectal carcinomas (CRC) differs from that found in colorectal
adenoma or normal mucosa, with some RPs being up-regulated
while others are down-regulated. The expression patterns of
RPs are associated with the differentiation, progression or
metastasis of CRC. Additionally, the recent literature has
shown that the perturbation of specific RPs may promote certain
genetic diseases and tumorigenesis. Because of the implications
of RPs in disease, especially malignancy, our review sought
to address several questions. Why do expression levels or
categories of RPs differ in different diseases, most notably
in CRC? Is this a cause or consequence of the diseases? What
are their possible roles in the diseases? We review the known
extraribosomal functions of RPs and associated changes in
colorectal cancer and attempt to clarify the possible roles
of RPs in colonic malignancy.
[Back to top]
Pas de deux: Natural Killer Receptors and
MHC Class I Ligands in Primates
L. Walter
[Full
text article]
Major histocompatibility complex (MHC) class I and NK cell
receptor gene regions are a paradigm of genomic plasticity
as they reveal a considerable degree of diversity, exemplified
by high allelic polymorphism, genomic duplications and contractions,
and formation of gene families. Both genetic components show
signs of rapid evolution due to strong selective pressure
to combat pathogens. Comparative analyses of these genomic
regions in various primates revealed considerable differences,
reflecting species-specific adaptations to pathogenic threat
or different strategies to combat infections. MHC and NK receptor
genomic diversity in populations are important factors that
determine susceptibility or resistance to a variety of diseases
including autoimmune and infectious diseases as well as reproductive
success.
[Back to top]
H2A.Z-Mediated Genome-Wide Chromatin Specialization
J.M. Eirín-López and J. Ausió
[Full
text article]
The characterization of the involvement of different histone
post-translational modifications (PTMs) and histone variants
in chromatin structure has represented one of the most recurrent
topics in molecular biology during the last decade (since
1996). The interest in this topic underscores the critical
roles played by chromatin in such important processes as DNA
packaging, DNA repair and recombination, and regulation of
gene expression. The genomic information currently available
has pushed the boundaries of this research a step further,
from the study of local domains to the genome-wide characterization
of the mechanisms governing chromatin dynamics. How the heterchromatin
and euchromatin compartmentalization is established has been
the subject of recent extensive research. Many PTMs, as well
as histone variants have been identified to play a role, including
the replacement of histone H2A by the histone variant H2A.Z.
Several studies have provided support to a role for H2A.Z
(known as Htz1 in yeast) in transcriptional regulation, chromosome
structure, DNA repair and heterochromatin formation. Although
the mechanisms by which H2A.Z defines different structural
regions in the chromatin have long remained elusive, various
reports published last year have shed new insight into this
process. The present mini review focuses its attention on
the genome-wide distribution of H2A.Z, with special attention
to the mechanisms involved in its distribution and exchange
as well as on the role of its N-terminal acetylation.
[Back to top]
The Development of Chromosome Microdissection and
Microcloning Technique and its Applications in Genomic Research
R.-N. Zhou and Z.-M. Hu
[Full
text article]
The technique of chromosome microdissection and microcloning
has been developed for more than 20 years. As a bridge between
cytogenetics and molecular genetics, it leads to a number
of applications: chromosome painting probe isolation, genetic
linkage map and physical map construction, and expressed sequence
tags generation. During those 20 years, this technique has
not only been benefited from other technological advances
but also cross-fertilized with other techniques. Today, it
becomes a practicality with extensive uses. The purpose of
this article is to review the development of this technique
and its application in the field of genomic research. Moreover,
a new method of generating ESTs of specific chromosomes developed
by our lab is introduced. By using this method, the technique
of chromosome microdissection and microcloning would be more
valuable in the advancement of genomic research.
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