Paulius Vaitiekunas scite author profile

Microcalorimetric studies of DNA duplexes and their component single strands showed that association enthalpies of unfolded complementary strands into completely folded duplexes increase linearly with temperature and do not depend on salt concentration, i.e. duplex formation results in a constant heat capacity decrement, identical for CG and AT pairs. Although duplex thermostability increases with CG content, the enthalpic and entropic contributions of an AT pair to duplex formation exceed that of a CG pair when compared at the same temperature. The reduced contribution of AT pairs to duplex stabilization comes not from their lower enthalpy, as previously supposed, but from their larger entropy contribution. This larger enthalpy and particularly the greater entropy results from water fixed by the AT pair in the minor groove. As the increased entropy of an AT pair exceeds that of melting ice, the water molecule fixed by this pair must affect those of its neighbors. Water in the minor groove is, thus, orchestrated by the arrangement of AT groups, i.e. is context dependent. In contrast, water hydrating exposed nonpolar surfaces of bases is responsible for the heat capacity increment on dissociation and, therefore, for the temperature dependence of all thermodynamic characteristics of the double helix.

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Advances in membrane proteomics and cancer biomarker discovery: Current status and future perspective

Shukla

Vaitiekunas

Cotter

2012

Proteomics

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Membrane proteomic analysis has been proven to be a promising tool for identifying new and specific biomarkers that can be used for prognosis and monitoring of various cancers. Membrane proteins are of great interest particularly those with functional domains exposed to the extracellular environment. Integral membrane proteins represent about one-third of the proteins encoded by the human genome and assume a variety of key biological functions, such as cell-to-cell communication, receptor-mediated signal transduction, selective transport, and pharmacological actions. More than two-thirds of membrane proteins are drug targets, highlighting their immensely important pharmaceutical significance. Most plasma membrane proteins and proteins from other cellular membranes have several PTMs; for example, glycosylation, phosphorylation, and nitrosylation, and moreover, PTMs of proteins are known to play a key role in tumor biology. These modifications often cause change in stoichiometry and microheterogeneity in a protein molecule, which is apparent during electrophoretic separation. Furthermore, the analysis of glyco- and phosphoproteome of cell membrane presents a number of challenges mainly due to their low abundance, their large dynamic range, and the inherent hydrophobicity of membrane proteins. Under pathological conditions, PTMs, such as phosphorylation and glycosylation are frequently altered and have been recognized as a potential source for disease biomarkers. Thus, their accurate differential expression analysis, along with differential PTM analysis is of paramount importance. Here we summarize the current status of membrane-based biomarkers in various cancers, and future perspective of membrane biomarker research.

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The Linker of the Interferon Response Factor 3 Transcription Factor Is Not Unfolded

et al. 2012

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Interferon response factor 3 (IRF-3) is a transcription factor that plays an essential role in controlling the synthesis of interferon-β (IFN-β) and is a protein consisting of two well-defined domains, the N-terminal DNA-binding and the C-terminal dimerization domains, connected by a 75-residue linker, supposedly unfolded. However, it was not clear whether in intact IRF-3 this linker segment of the chain, which carries the nuclear export signal and includes a region of high helical propensity, remains unfolded. This has been investigated using nuclear magnetic resonance by ligating the (15)N-labeled linker to the unlabeled N-terminal and C-terminal domains. It was found that, while the linker alone is indeed in a completely unfolded state, when ligated to the C-terminal domain it shows some ordering, and this ordering becomes much more pronounced when the linker is also ligated to the N-terminal domain. Thus, in intact IRF-3, the linker represents a folded structural domain; i.e., IRF-3 is a three-domain globular protein. Light scattering studies of wild-type IRF-3 showed that these three domains are tightly packed, and therefore, the dimer of IRF-3, which is formed upon phosphorylation of its C-terminal domains following virus invasion, must be a rather rigid and compact construction. One would then expect that binding of such a dimer to its tandem recognition sites PRDIII and PRDI, which are located on opposing faces of the IFN-β enhancer DNA, should result in deformation of the DNA. Analysis of the characteristics of binding of the monomeric and dimeric IRF-3 to the enhancer DNA indeed showed that formation of this complex requires considerable work for deformation of its components, most likely bending of the DNA. Such bending was confirmed by atomic force microscopy of dimeric IRF-3 bound to the PRDII-PRDI tandem recognition sites placed at the middle of a 300 bp DNA probe. Bending of DNA by IRF-3 must be significant in the assembly and function of the IFN-β enhancer.

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On the Viscoelastic Property Measurement of Filled Polymers by Dynamic Mechanical Analyzer (DMA)

Phansalkar

Han

Akbari

et al. 2022

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Dynamic mechanical analyzers (DMA) are routinely practiced in the semiconductor industry to measure the viscoelastic behavior of highly filled thermosetting polymers. The highly filled polymers possess unique challenges in viscoelastic property measurements where set-and-forget style of DMA operation do not always produce the most accurate data due to a large change in modulus over operating and/or manufacturing temperature excursions. This paper discusses the unique challenges associated with the highly filled polymers first and proposes a procedure to determine a proper set of testing parameters.

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