Current Proteomics
ISSN: 1570-1646
Current Proteomics
Volume 4 Number 3, October 2007
Contents
Current Status of Computational Approaches for Protein
Identification Using Tandem Mass Spectra Pp. 121-130
X. Zhang, C. Oh, C.P. Riley and C. Buck
[Abstract]
Quantitative Proteomic Approaches to Investigate
the Membrane Proteome in Neuropsychiatric Disorders
Pp. 131-140
M.K. Chan and S. Bahn
[Abstract]
Proteomic Studies on Plant-Pathogen Interaction in Compatible
and Incompatible Systems Pp. 141-156
Y.K.-C. Butt and S.C.-L. Lo
[Abstract]
Potential Targets of P. acnes for New Treatments
of P. acnes-Associated Diseases Pp. 157-161
T. Nakatsuji and C.-M. Huang
[Abstract]
Novel Intracellular Signaling Mechanism Revealed by
Functional Analyses of Myristoyl Moiety of NAP22 and a Comprehensive
Analysis of Nα-Myristoylated
Proteins Pp. 162-173
N. Hayashi
[Abstract]
Human Heart Failure: A Proteomics Perspective
Pp. 174-181
A. Goel, R. Rakwal and G.K. Agrawal
[Abstract]
Soybean Proteomics Pp. 182-186
S. Komatsu, M. Toorchi and K. Yukawa
[Abstract]
Abstracts
[Back to top]
Current Status of Computational Approaches for Protein Identification
Using Tandem Mass Spectra
X. Zhang, C. Oh, C.P. Riley and C. Buck
Proteomics is a still-evolving combination of technologies
to describe and characterize all expressed proteins in a biological
system. Because of upper limits on mass detection of mass
spectrometers, the bottom-up approach is most widely employed
in which tryptic peptides are quantified and identified from
complex protein mixtures. Protein identification from tandem
mass spectra is still a challenge in proteomics. Two approaches
have been developed to identify proteins from tandem mass
spectra, database searching and de novo sequencing.
These approaches typically have positive identification rates
of only ~10-20%, and exhibit high false positive identification
rates. This review surveys existing algorithms developed for
database searching and de novo sequencing, with a
focus on recent developments for tandem mass spectrum quality
assessment, peptide identification using annotated spectra
libraries, statistical approaches to assess identification
quality, and methods for constrained searches. We also review
research comparing the performance of existing protein identification
packages.
[Back to top]
Quantitative Proteomic Approaches to Investigate
the Membrane Proteome in Neuropsychiatric Disorders
M.K. Chan and S. Bahn
Disease and drug-related alterations in the brain membrane
proteome are of particular interest for investigations into
neuropsychiatric disorders. Despite decades of research into
neurotransmitters and their receptors, our understanding of
complex neuropsychiatric disorders has failed to advance substantially.
Therefore, global membrane protein profiling studies that
are non-hypothesis driven and exploratory are a complementary
approach to elucidate the underlying pathomechanisms associated
with psychiatric disorders. Although membrane proteins play
critical roles in almost all cellular processes, their unique
biochemical properties have challenged current quantitative
proteomics approaches. The aim of the present review is to
critically evaluate and discuss the use and applicability
of current quantitative proteomic platforms, sample preparation
methods and statistical tools in view of their application
to membrane proteome analysis of brain tissue.
[Back to top]
Proteomic Studies on Plant-Pathogen Interaction in Compatible
and Incompatible Systems
Y.K.-C. Butt and S.C.-L. Lo
Studies employing proteomic technologies to study interactions
of host plant with pathogenic bacteria are limited. Most studies
on plant-pathogen interactions usually employed genetic approaches,
such as the use of in vivo expression technology
(IVET) and DNA microarray. However, because of the intrinsic
nature of these techniques, issues on time frame, mechanisms
involved as well as localization are virtually unknown. Therefore,
assimilation of knowledge in our understanding of the plant-pathogen
interactions at the mechanical front and protein level is
slow. Further, majority of these studies on plant-pathogen
interactions focused either on the Type III secretary system
(TTSS) and virulence factors of the pathogens or the activation
of plant defense responses. Details of invasion strategies
of microbial pathogens and the interplay between host and
these pathogens are largely unknown. Investigations using
proteomic technologies in these fields can provide information
on subcellular localization of proteins of interest, time
frame of expression, post-translational modifications and
even quantitative measurements of differentially expressed
proteins. These are vital information in deciphering the biological
events happening in both plant and pathogen perspectives during
the invasion proc-ess. Moreover, data from proteomic investigations,
in association with those obtained from DNA microarray studies
could be amalgamated to construct a list of candidates whose
roles in plant-pathogen interactions can be further studied.
This review aims to summarize current findings on plant-pathogen
interactions in compatible and incompatible systems as well
as the possible contribution of proteomic investigations.
[Back to top]
Potential Targets of P. acnes for New Treatments
of P. acnes-Associated Diseases
T. Nakatsuji and C.-M. Huang
Increasing evidence demonstrated that Propionibacterium
acnes (P. acnes) plays a central role in many
human polymicrobial diseases including acne vulgaris, which
afflicts more than one million people in the U.S. alone. To
date, there are no appropriate therapeutic modalities that
effectively control P. acnes succession during disease
development. By taking advantage of the availability of genome
and proteome of P. acnes, we have highlighted here
the events of P. acnes adhesion and biofilm formation
as potential targets for development of drugs or vaccines
counteracting P. acnes-associated diseases.
[Back to top]
Novel Intracellular Signaling Mechanism Revealed by
Functional Analyses of Myristoyl Moiety of NAP22 and a Comprehensive
Analysis of Nα-Myristoylated
Proteins
N. Hayashi
Mass spectrometry has shown that NAP22, a neuron specific
protein isolated from rat brain is myristoylated, and it was
additionally demonstrated by physicochemical methods that
the myristoylation functioning in tandem with the phospholipid
membrane is also directly involved in the interaction with
calmodulin. Furthermore, besides the myristoy-lated brain
specific protein, Src kinase and the HIV nef gene product
have been shown to interact with calmodulin in the same way.
Interestingly, phosphorylation of the myristoylated proteins
abolishes their interaction with calmodulin. Structural and
functional studies have revealed that, besides the necessary
conditions for myristoylation, the interaction requires certain
additional conditions such as the co-existence of basic amino
acid residues in the myristoylated domain. Thus, myristoylated
proteins in cells regulate signal transduction between the
membrane and cytoplasmic fractions. An algorithm we have developed
to find myristoylated proteins in cells predicts hundreds
of myristoylated proteins. Interestingly, a large portion
of the myristoylated proteins supposed to take part in the
signal transduction between the membrane and cytoplasmic fractions,
such as NAP22 , are included in the the predicted myristoylated
proteins. If the proteins functionally regulated by the posttranslational
protein modification myristoylation are understood as cross-talk
points within the intracellular signal transduction system,
the known signaling pathways can be linked with each other,
and a novel map of this intracellular network constructed.
[Back to top]
Human Heart Failure: A Proteomics Perspective
A. Goel, R. Rakwal and G.K. Agrawal
Cardiac hypertrophy, interstitial fibrosis, and cardiac dysfunction
ultimately lead to cardiac failure. Cardiac failure is one
of the major causes of heart disease and death in our society.
The molecular causes of heart diseases, like many other diseases,
remain largely unknown. Recently, large-scale proteomics studies
have been undertaken to better understand the underlying mechanisms
of molecular causes of heart disease. Many protein alterations
have already been identified in the human diseased myocardium.
Further experiments on these proteins are ongoing to know
their suitability for drug targets, therapeutic proteins,
or disease biomarkers. This review deals with a proteomics
perspective on human heart failure, and is divided into two
parts. The first part provides a glimpse on proteomics technologies
used for identification and quantification of proteins related
to heart disease. The second part is the main focus of this
review and deals with evolving biomarkers and clinical diagnostics,
potential future drugs, clinical approaches in managing heart
failure, and clinical shortcomings, which are discussed to
some detail from the viewpoint of a medical doctor and proteomics
scientists.
[Back to top]
Soybean Proteomics
S. Komatsu, M. Toorchi and K. Yukawa
Although research on non-legume model species such as
Arabidopsis thaliana and rice provides insight into
many fundamental aspects of plant biology, it cannot address
some important aspects of legume biology. Legumes are of immense
importance to human and are an important crop for sustainable
agriculture. Two model species, Lotus japonicas and
Medicago truncatula, would have been the focus of
genome sequencing and functional genomics programmes. Unfortunately,
agricultural legumes are relatively poor model systems for
genetics and genomics research. Even though soybean is an
important crop to supply a major portion of the world’s
demand for vegetable oil and protein, the sequencing of the
soybean genome is in its infancy. So, proteomics would be
a powerful tool for its functional analysis. The purpose of
this review is to discuss the strength and weaknesses of proteomics
technologies and limitations of current techniques for soybean
biology.
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