Pediatric Proteomics: An Introduction

Young, Jeanne, Stone, William L.

01 January 2012

The overall goal of this series is to detail the paradigm shift that proteomics will bring to the practice of pediatric medicine and research. Proteomics is the global study of proteins in a biological system, tissue or bodily fluid. This first review will provide a brief overview of proteomics and describe its niche in the other "omics" of system biology. The underlying technology and methodology will be outlined as well as the obstacles that must be surmounted before pediatric proteomics is optimally useful for clinicians. The potential of proteomics in the area of personalized pediatric medicine will also be discussed since this is of particular clinical relevance. The second article in this series will focus on the application of proteomics to neonatology with particular emphasis on diseases where oxidative stress plays a key pathophysiological role.

medicine

pediatrics

protein chip

proteomics

review

systems biology

Pediatrics

A Functional Protein Chip for Combinatorial Pathway Optimization and In Vitro Metabolic Engineering

Jung, Gyoo Yeol, Stephanopoulos, Gregory

01 1900

Pathway optimization is, in general, a very demanding task due to the complex, nonlinear and largely unknown interactions of enzymes, regulators and metabolites. While in vitro reconstruction and pathway analysis is a viable alternative, a major limitation of this approach is the availability of the pathway enzymes for reliable pathway reconstruction. Here, we report the application of RNA display methods for the construction of fusion (chimeric) molecules, comprising mRNA and the protein they express, that can be used for the above purpose. The chimeric molecule is immobilized via hybridization of its mRNA end with homologous capture DNA spotted on a substrate surface. We show that the protein (enzyme) end of the fusion molecule retains its function under immobilized conditions and that the enzymatic activity is proportional to the amount of capture DNA spotted on the surface of a microarray or 96-well microplate. The relative amounts of all pathway enzymes can thus be changed at will by changing the amount of the corresponding capture DNA. Hence, entire pathways can be reconstructed and optimized in vitro from genomic information alone by generating chimeric molecules for all pathway enzymes in a single in vitro translation step and hybridizing on 96-well microplates where each well contains a different combination of capture DNA. We provide validation of this concept with the sequential reactions catalyzed by luciferase and nucleoside diphosphate kinase and further illustrate this method with the optimization of the five-step pathway for trehalose synthesis. Multi-enzyme pathways leading to the synthesis of specialty molecules can thus be optimized from genomic information about the pathway enzymes, provided the latter retain their activity under the in vitro immobilized conditions. / Singapore-MIT Alliance (SMA)

functional protein chip

in vitro metabolic engineering

combinatorial pathway optimization

trehalose synthesis

Protein Lab-on-a-Chips on Polyer Substrates for Point-of-Care Testing (POCT) of Cardiac Biomarkers

Kai, Junhai

02 October 2006

No description available.

Lab-on-a-chip

Cardiac biomarker

multi-analyte

Protein chip

Chemiluminescence

immunoassay

BioMEMS

Polymer microfabrication

Immobilisation de biomolécules pour l’analyse multiparamétrique sur biopuces : application au génotypage érythrocytaire haut-débit / Biomolecule immobilisation for multiparametric analysis on biochips : application to high-throughput blood group genotyping

Le Goff, Gaëlle

14 October 2011

Les travaux présentés dans cette thèse s’intéressent à l’immobilisation de biomolécules pour le développement d’outils d’analyse multiparamétrique pour la caractérisation d’échantillons biologiques et le diagnostic, sur un support de type biopuce couplé à une détection colorimétrique.Un premier axe de recherche concerne le développement de tests d’hybridation d’acides nucléiques et d’immunotests à haut-débit automatisés sur plaque de filtration. Cette méthode a permis la mise au point d’un test de génotypage automatisé pour le dépistage transfusionnel haut-débit (génotypage érythrocytaire étendu) en collaboration avec l’Établissement Français du Sang Rhône-Alpes (EFS-RA). Il permet d’analyser 96 échantillons en quatre heures, et de caractériser six génotypes par échantillon. Cet outil a fait l’objet d’une validation sur un panel de 293 donneurs.La seconde partie des travaux présentés s’intéresse au développement d’un procédé d’immobilisation d’oligonucléotides sur un polymère particulier (PolyshrinkTM) pour l’élaboration d’un système d’analyse miniaturisé. Plusieurs stratégies d’activation ont été envisagées et ont abouti à la mise au point d’une technique d’immobilisation d’oligonucleotides in situ dans des plots d’hydrogel. La méthode de fabrication permet d’obtenir une matrice de plots d’hydrogel de 60 µm de diamètre et d’une hauteur de 6 µm en moyenne. En outre, il a été démontré que les oligonucléotides immobilisés dans les plots pouvaient détecter de façon quantitative et sélective les cibles complémentaires présentes dans l’échantillon analysé en utilisant une détection par colorimétrie ou par chimiluminescence. / The work reported in this thesis focuses on biomolecules immobilization for the development of multiparametric analysis tools on a biochip coupled with a colorimetric detection, applied to the characterization of biological samples and to diagnosis.The first concern was the development of high-throughput automated hybridization tests and immunotests on a filtration plate. This method led to the elaboration of an automated platform for extended blood group genotyping in collaboration with the Etablissement Français du Sang Rhône-Alpes (EFS-RA). It enables to analyze 96 samples in four hours and to characterize six genotypes per sample. Its analytical performances were validated on a panel of 293 blood donors.The second part of this work aimed to elaborate a new strategy for oligonucleotide immobilization on an innovative polymer (PolyshrinkTM) for the development of miniaturized analysis systems. Several approaches were evaluated and led to an in-situ immobilization of oligonucleotides in hydrogel dots technique. This method leads to 6 µm hydrogel dots with a diameter of 60 µm. Moreover it was demonstrated that such immobilized oligonucleotides were able to detect targets specifically and quantitatively using either a chemiluminescent or a colorimetric detection.

Allergie

Biopuce

Colorimétrie

Diagnostic

Génotypage érythrocytaire

Haut-débit

Hydrogel

Membrane

Polymorphisme d’un nucléotide

PolyshrinkTM

Puce à ADN

Puce à protéines

Allergy

Biochip

Colorimetry

Diagnosis

Blood group genotyping

High-throughput

Hydrogel

Membrane

Single nucleotide polymorphism

PolyshrinkTM

DNA chip

Protein chip