Highly specific interaction of monomeric S100P protein with interferon beta.

S100 proteins are EF-hand calcium-binding proteins of vertebrates exerting numerous intra- and extracellular actions and involved into multiple diseases. Some of S100 proteins serve as extracellular damage signals via interaction with receptors. Although several S100 proteins directly bind specific cytokines, this phenomenon remains underexplored.

Monomeric state of S100P protein: Experimental and molecular dynamics study.

S100 proteins constitute a large subfamily of the EF-hand superfamily of calcium binding proteins. They possess one classical EF-hand Ca-binding domain and an atypical EF-hand domain. Most of the S100 proteins form stable symmetric homodimers.

Interleukin-11 binds specific EF-hand proteins via their conserved structural motifs.

Interleukin-11 (IL-11) is a hematopoietic cytokine engaged in numerous biological processes and validated as a target for treatment of various cancers. IL-11 contains intrinsically disordered regions that might recognize multiple targets. Recently we found that aside from IL-11RA and gp130 receptors, IL-11 interacts with calcium sensor protein S100P.

Negative modulation of signal transduction via interleukin splice variation.

Interleukin 6 (IL-6) belongs to a large group of secreted proteins called cytokines functioning to mediate and regulate immunity, inflammation, and hematopoiesis with direct effects on cell proliferation, apoptosis, and differentiation. Along with the IL-6 protein, two of its splice variants, IL-6delta2 and IL-6delta4, were reported to be transcribed or expressed in vivo in human, and the mRNAs of IL-6delta3 and IL-6delta5 had been observed in mouse. While the existence of different splice variants of IL-6 has been shown, very little is known on how the structural modifications of IL-6 resulting from the formation of the different splice variants may alter cytokine functions.

Novel CalphaNN structural motif for protein recognition of phosphate ions.

Phosphate is one of the most frequently exploited chemical moieties in nature, present in a wide range of naturally occurring and critically important small molecules. Several phosphate group recognition motifs have been found for a few narrow groups of proteins, but for many protein families and folds the mode of phosphate recognition remains unclear. Here, we have analyzed the structures of all fold-representative protein-ligand complexes listed in the FSSP database, regardless of whether the bound ligand included a phosphate group.

"Acceptor-donor-acceptor" motifs recognize the Watson-Crick, Hoogsteen and Sugar "donor-acceptor-donor" edges of adenine and adenosine-containing ligands.

Nucleotides are among the most extensively exploited chemical moieties in nature and, as a part of a handful of different protein ligands, nucleotides play key roles in energy transduction, enzymatic catalysis and regulation of protein function. We have previously reported that in many proteins with different folds and functions a distinctive adenine-binding motif is involved in the recognition of the Watson-Crick edge of adenine. Here, we show that many proteins do have clear structural motifs that recognize adenosine (and some other nucleotides and nucleotide analogs) not only through the Watson-Crick edge, but also through the sugar and Hoogsteen edges.

Phosphate group binding "cup" of PLP-dependent and non-PLP-dependent enzymes: leitmotif and variations.

Pyridoxal-5'-phosphate (PLP) is widely used by many enzymes in reactions where amino acids are interconverted. Whereas the role of the pyridoxal ring in catalysis is well understood, the functional role of the single phosphate group in PLP has been less studied. Here we construct unambiguous connection diagrams that describe the interactions among the three non-ester phosphate oxygen atoms of PLP and surrounding atoms from the protein binding site and from water molecules, the so-called phosphate group binding "cup".

Functional attributes of the phosphate group binding cup of pyridoxal phosphate-dependent enzymes.

Twenty-four structures of pyridoxal-5'-phosphate (PLP)-dependent enzymes that represent five different folds are shown to share a common recognition pattern for the phosphate group of their PLP-ligands. All atoms that interact with the phosphate group of PLP in these proteins are organized within a two-layer structure so that the first interacting layer contains from five to seven atoms and parallel with this is a second layer containing from three to seven interacting atoms. In order to identify features of the phosphate-binding site common to PLP-dependent enzymes, a simple procedure is described that assigns relative positions to all interacting atoms unambiguously, such that the networks of interactions for different proteins can be compared.