5 research outputs found
A Novel Strategy Based on Permanent Protein Modifications Induced by Formaldehyde for Food Safety Analysis
The illegal additions of chemicals
in food products are serious
incidents threatening current public safety. To date, ideal methods
to determine permanent traces of prohibited chemicals in foods are
still lacking. For example, formaldehyde (FA) can be added illegally
as a food preservative. However, most current methods that are dependent
on the direct detection of FA are not able to determine if FA has
ever been added once food products are rinsed completely. Herein,
we present a novel approach relying upon protein modifications induced
by FA (PMIF) to examine FA in foods. We reveal the entire catalog
of PMIFs in food products by combining mass spectrometry analysis
with unrestrictive identification of protein modifications. Consequently,
four obvious PMIFs were identified and confirmed as markers to discriminate
the addition of FA in foods. Our study demonstrates that the approach
based on PMIFs enables detecting the imprinted trace of FA even if
the food products have been washed thoroughly. Our work presents a
novel strategy for analysis of chemical additives, offering broad
potential applications in protein analysis and food safety
An Integrated Approach Based on a DNA Self-Assembly Technique for Characterization of Crosstalk among Combinatorial Histone Modifications
Combinatorial
histone post-translational modifications (HPTMs)
form a complex epigenetic code that can be decoded by specific binding
proteins, termed as readers. Their specific interplays have been thought
to determine gene expression and downstream biological functions.
However, it is still a big challenge to analyze such interactions
due to various limitations including rather weak, transient, and complicated
interactions between HPTMs and readers, the high dynamic property
of HPTMs, and the low abundance of reader proteins. Here we sought
to take advantage of DNA-templated and photo-cross-linking techniques
to design a group of combinatorial histone PTM peptide probes for
the identification of multivalent interactions among histone PTMs
and readers. By use of trimethylation on histone H3K4 (H3K4me3) and
phosphorylation on H3T3, we demonstrated that this approach can be
successfully utilized for identification of the PTM crosstalk on the
same histone. By use of H3K4me3 and acetylation on H4K16, we showed
the potential application of the probe in the multivalent interactions
among PTMs on different histones. Thus, this new chemical proteomics
tool combined with mass spectrometry holds a promising potential in
profiling of the readers of combinatorial HPTMs and characterization
of crosstalk among multiple PTMs on histones and can be adapted for
broad biomedical applications
An Integrated Approach Based on a DNA Self-Assembly Technique for Characterization of Crosstalk among Combinatorial Histone Modifications
Combinatorial
histone post-translational modifications (HPTMs)
form a complex epigenetic code that can be decoded by specific binding
proteins, termed as readers. Their specific interplays have been thought
to determine gene expression and downstream biological functions.
However, it is still a big challenge to analyze such interactions
due to various limitations including rather weak, transient, and complicated
interactions between HPTMs and readers, the high dynamic property
of HPTMs, and the low abundance of reader proteins. Here we sought
to take advantage of DNA-templated and photo-cross-linking techniques
to design a group of combinatorial histone PTM peptide probes for
the identification of multivalent interactions among histone PTMs
and readers. By use of trimethylation on histone H3K4 (H3K4me3) and
phosphorylation on H3T3, we demonstrated that this approach can be
successfully utilized for identification of the PTM crosstalk on the
same histone. By use of H3K4me3 and acetylation on H4K16, we showed
the potential application of the probe in the multivalent interactions
among PTMs on different histones. Thus, this new chemical proteomics
tool combined with mass spectrometry holds a promising potential in
profiling of the readers of combinatorial HPTMs and characterization
of crosstalk among multiple PTMs on histones and can be adapted for
broad biomedical applications
Probing the Binding Interfaces of Histone-Aptamer by Photo Cross-Linking Mass Spectrometry
Histone proteins,
which could interact with DNA, play important
roles in the regulation of chromatin structures, transcription, and
other DNA-based biological processes. Here, we developed a novel aptamer-based
probe for the analysis of histone H4-aptamer interfaces. This probe
contains a DNA sequence for specific recognition of histone H4, a
biotin tag for affinity enrichment, an aryl azide photoactive group
for cross-linking and a cleavable disulfide group to dissociate aptamer
from labeled histones. We successfully achieved specific enrichment
of histone H4 and further developed a new analysis strategy for histone-aptamer
interaction by photo cross-linking mass spectrometry. The binding
area of histone H4 to aptamer was investigated and discussed for the
first time. This strategy exhibits great potential and might further
contribute to the understanding of histone–DNA interaction
patterns
Maltose-Functionalized Hydrophilic Magnetic Nanoparticles with Polymer Brushes for Highly Selective Enrichment of N‑Linked Glycopeptides
Efficient enrichment glycoproteins/glycopeptides
from complex biological
solutions are very important in the biomedical sciences, in particular
biomarker research. In this work, the high hydrophilic polyethylenimine
conjugated polymaltose polymer brushes functionalized magnetic Fe<sub>3</sub>O<sub>4</sub> nanoparticles (NPs) denoted as Fe<sub>3</sub>O<sub>4</sub>–PEI–pMaltose were designed and synthesized
via a simple two-step modification. The obtained superhydrophilic
Fe<sub>3</sub>O<sub>4</sub>–PEI–pMaltose NPs displayed
outstanding advantages in the enrichment of N-linked glycopeptides,
including high selectivity (1:100, mass ratios of HRP and bovine serum
albumin (BSA) digest), low detection limit (10 fmol), large binding
capacity (200 mg/g), and high enrichment recovery (above 85%). The
above-mentioned excellent performance of novel Fe<sub>3</sub>O<sub>4</sub>–PEI–pMaltose NPs was attributed to graft of
maltose polymer brushes and efficient assembly strategy. Moreover,
Fe<sub>3</sub>O<sub>4</sub>–PEI–pMaltose NPs were further
utilized to selectively enrich glycopeptides from human renal mesangial
cell (HRMC, 200 μg) tryptic digest, and 449 N-linked glycopeptides,
representing 323 different glycoproteins and 476 glycosylation sites,
were identified. It was expected that the as-synthesized Fe<sub>3</sub>O<sub>4</sub>–PEI–pMaltose NPs, possessing excellent
performance (high binding capacity, good selectivity, low detection
limit, high enrichment recovery, and easy magnetic separation) coupled
to a facile preparation procedure, have a huge potential in N-glycosylation
proteome analysis of complex biological samples