Structural insights into calmodulin/adenylyl cyclase 8 interaction.

Calmodulin (CaM) is a highly conserved intracellular Ca(2+)-binding protein that exerts important functions in many cellular processes. Prominent examples of CaM-regulated proteins are adenylyl cyclases (ACs), which synthesize cAMP as a central second messenger. The interaction of ACs with CaM represents the link between Ca(2+)-signaling and cAMP-signaling pathways. Thereby, different AC isoforms stimulated by CaM, comprise diverse mechanisms of regulation by the Ca(2+) sensor. To extend the structural information about the detailed mechanisms underlying the regulation of AC8 by CaM, we employed an integrated approach combining chemical cross-linking and mass spectrometry with two peptides representing the CaM-binding regions of AC8. These experiments reveal that the structures of CaM/AC8 peptide complexes are similar to that of the CaM/skeletal muscle myosin light chain kinase peptide complex where CaM is collapsed around the target peptide that binds to CaM in an antiparallel orientation. Cross-linking experiments were complemented by investigating the binding of AC8 peptides to CaM thermodynamically with isothermal titration calorimetry. There were no hints on a complex, in which both AC8 peptides bind simultaneously to CaM, refining our current understanding of the interaction between CaM and AC8.

Remodeling and Repositioning of Nucleosomes in Nucleosomal Arrays.

ATP-dependent nucleosome remodeling factors sculpt the nucleosomal landscape of eukaryotic chromatin. They deposit or evict nucleosomes or reposition them along DNA in a process termed nucleosome sliding. Remodeling has traditionally been analyzed using mononucleosomes as a model substrate. In vivo, however, nucleosomes form extended arrays with regular spacing. Here, we describe how regularly spaced nucleosome arrays can be reconstituted in vitro and how these arrays can be used to dissect remodeling in the test tube. We outline two assays. The first assay senses various structural changes to a specific nucleosome within the nucleosomal array whereas the second assay is specific toward detecting repositioning of nucleosomes within the array. Both assays exploit changes to the accessibility of DNA to restriction enzymes during the remodeling reaction.

Concerted regulation of ISWI by an autoinhibitory domain and the H4 N-terminal tail.

ISWI-family nucleosome remodeling enzymes need the histone H4 N-terminal tail to mobilize nucleosomes. Here we mapped the H4-tail binding pocket of ISWI. Surprisingly the binding site was adjacent to but not overlapping with the docking site of an auto-regulatory motif, AutoN, in the N-terminal region (NTR) of ISWI, indicating that AutoN does not act as a simple pseudosubstrate as suggested previously. Rather, AutoN cooperated with a hitherto uncharacterized motif, termed AcidicN, to confer H4-tail sensitivity and discriminate between DNA and nucleosomes. A third motif in the NTR, ppHSA, was functionally required in vivo and provided structural stability by clamping the NTR to Lobe 2 of the ATPase domain. This configuration is reminiscent of Chd1 even though Chd1 contains an unrelated NTR. Our results shed light on the intricate structural and functional regulation of ISWI by the NTR and uncover surprising parallels with Chd1.

One-step purification and porin transport activity of the major outer membrane proteins P2 from Haemophilus influenzae, FomA from Fusobacterium nucleatum and PorB from Neisseria meningitidis.

Bacterial porins are major outer membrane proteins that function as essential solute transporters between the bacteria and the extracellular environment. Structural features of porins are also recognized by eukaryotic cell receptors involved in innate and adaptive immunity. To better investigate the function of porins, proper refolding is necessary following purification from inclusion bodies [1, 2]. Using a single-step size exclusion chromatographic method, we have purified three major porins from pathogenic bacteria, the OmpP2 (P2) from Haemophilus influenzae, FomA from Fusobacterium nucleatum and PorB from Neisseria meningitidis, at high yield and report their unique solute transport activity with size exclusion limit. Furthermore, we have optimized their purification method and achieved improvement of their thermostability for facilitating functional and structural analyses.

High-resolution structures of the D-alanyl carrier protein (Dcp) DltC from Bacillus subtilis reveal equivalent conformations of apo- and holo-forms.

D-Alanylation of lipoteichoic acids plays an important role in modulating the properties of Gram-positive bacteria cell walls. The D-alanyl carrier protein DltC from Bacillus subtilis has been solved in apo- and two cofactor-modified holo-forms, whereby the entire phosphopantetheine moiety is defined in one. The atomic resolution of the apo-structure allows delineation of alternative conformations within the hydrophobic core of the 78 residue four helix bundle. In contrast to previous reports for a peptidyl carrier protein from a non-ribosomal peptide synthetase, no obvious structural differences between apo- and holo-DltC forms are observed. Solution NMR spectroscopy confirms these findings and demonstrates in addition that the two forms exhibit similar backbone dynamics on the ps-ns and ms timescales.

Flexing and stretching in nonribosomal Peptide synthetases.

Re-engineering of nonribosomal peptide synthetase molecular assembly lines has been hampered by a lack of detailed knowledge concerning inter-domain substrate transfer. Recent structural studies of catalytically relevant domain-domain interactions provide valuable insights into this problem (Liu et al., 2011; Sundlov et al., 2012 [in this issue of Chemistry & Biology]).