138,698 research outputs found
A Systemic Receptor Network Triggered by Human cytomegalovirus Entry
Virus entry is a multistep process that triggers a variety of cellular
pathways interconnecting into a complex network, yet the molecular complexity
of this network remains largely unsolved. Here, by employing systems biology
approach, we reveal a systemic virus-entry network initiated by human
cytomegalovirus (HCMV), a widespread opportunistic pathogen. This network
contains all known interactions and functional modules (i.e. groups of
proteins) coordinately responding to HCMV entry. The number of both genes and
functional modules activated in this network dramatically declines shortly,
within 25 min post-infection. While modules annotated as receptor system, ion
transport, and immune response are continuously activated during the entire
process of HCMV entry, those for cell adhesion and skeletal movement are
specifically activated during viral early attachment, and those for immune
response during virus entry. HCMV entry requires a complex receptor network
involving different cellular components, comprising not only cell surface
receptors, but also pathway components in signal transduction, skeletal
development, immune response, endocytosis, ion transport, macromolecule
metabolism and chromatin remodeling. Interestingly, genes that function in
chromatin remodeling are the most abundant in this receptor system, suggesting
that global modulation of transcriptions is one of the most important events in
HCMV entry. Results of in silico knock out further reveal that this entire
receptor network is primarily controlled by multiple elements, such as EGFR
(Epidermal Growth Factor) and SLC10A1 (sodium/bile acid cotransporter family,
member 1). Thus, our results demonstrate that a complex systemic network, in
which components coordinating efficiently in time and space contributes to
virus entry.Comment: 26 page
Recycling of solvent used in a solvent extraction of petroleum hydrocarbons contaminated soil.
The application of water washing technology for recycling an organic composite
solvent consisting of hexane and pentane (4:1; TU-A solvent) was investigated
for extracting total petroleum hydrocarbons (TPH) from contaminated soil. The
effects of water volume, water temperature, washing time and initial
concentration of solvent were evaluated using orthogonal experiments followed by
single factor experiments. Our results showed that the water volume was a
statistically significant factor influencing greatly the water washing
efficiency. Although less important, the other three factors have all increased
the efficacy of water washing treatment. Based on a treatment of 20g of
contaminated soil with a TPH concentration of 140mgg(-1), optimal conditions
were found to be at 40°C, 100mL water, 5min washing time and 660mgg(-1) solvent.
Semi-continuous water extraction method showed that the concentration of the
composite solvent TU-A was reduced below 15mgg(-1) d.w. soil with a recovery
extraction efficiency >97%. This finding suggests that water washing is a
promising technology for recycling solvent used in TPH extraction from
contaminated soil
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