The 'EF-hand' Ca2+-binding motif plays an essential role in eukaryotic cellular signalling, and the proteins containing this motif constitute a large and functionally diverse family. The EF-hand is defined by its helix-loop-helix secondary structure as well as the ligands presented by the loop to bind the Ca2+ ion. The identity of these ligands is semi-conserved in the most common (the 'canonical') EF-hand; however, several non-canonical EF-hands exist that bind Ca2+ by a different co-ordination mechanism. EF-hands tend to occur in pairs, which form a discrete domain so that most family members have two, four or six EF-hands. This pairing also enables communication, and many EF-hands display positive co-operativity, thereby minimizing the Ca2+ signal required to reach protein saturation. The conformational effects of Ca2+ binding are varied, function-dependent and, in some cases, minimal, but can lead to the creation of a protein target interaction site or structure formation from a molten-globule apo state. EF-hand proteins exhibit various sensitivities to Ca2+, reflecting the intrinsic binding ability of the EF-hand as well as the degree of co-operativity in Ca2+ binding to paired EF-hands. Two additional factors can influence the ability of an EF-hand to bind Ca2+: selectivity over Mg2+ (a cation with very similar chemical properties to Ca2+ and with a cytoplasmic concentration several orders of magnitude higher) and interaction with a protein target. A structural approach is used in this review to examine the diversity of family members, and a biophysical perspective provides insight into the ability of the EF-hand motif to bind Ca2+ with a wide range of affinities.
The peptide lactoferricin (Lfcin) can be released from the multifunctional protein lactoferrin (LF) through proteolysis by pepsin under acidic conditions, a reaction that occurs naturally in the stomach. Lfcin encompasses a large portion of the functional domain of the intact protein, and in many cases it not only retains the activities of LF but is more active. Lfcin possesses strong antimicrobial and weak antiviral activities, and it also has potent antitumor and immunological properties. This review covers the current state of research in this field, focusing on the many beneficial activities of this peptide. Throughout we will discuss the breadth of Lfcin activity as well as the mechanism of action. Many recent studies have drawn attention to the fact that the main site of action for the peptide may be intracellular. In addition the results of structural and dynamic studies of Lfcin are presented, and the relationship between structure and activity is explored.
Non-homologous end joining (NHEJ) is one of the primary pathways for the repair of ionizing radiation (IR)-induced DNA double-strand breaks (DSBs) in mammalian cells. Proteins required for NHEJ include the catalytic subunit of the DNA-dependent protein kinase (DNA-PKcs), Ku, XRCC4 and DNA ligase IV. Current models predict that DNA-PKcs, Ku, XRCC4 and DNA ligase IV assemble at DSBs and that the protein kinase activity of DNA-PKcs is essential for NHEJ-mediated repair of DSBs in vivo. We previously identified a cluster of autophosphorylation sites between amino acids 2609 and 2647 of DNA-PKcs. Cells expressing DNA-PKcs in which these autophosphorylation sites have been mutated to alanine are highly radiosensitive and defective in their ability to repair DSBs in the context of extrachromosomal assays. Here, we show that cells expressing DNA-PKcs with mutated autophosphorylation sites are also defective in the repair of IR-induced DSBs in the context of chromatin. Purified DNA-PKcs proteins containing serine/threonine to alanine or aspartate mutations at this cluster of autophosphorylation sites were indistinguishable from wild-type (wt) protein with respect to protein kinase activity. However, mutant DNA-PKcs proteins were defective relative to wt DNA-PKcs with respect to their ability to support T4 DNA ligase-mediated intermolecular ligation of DNA ends. We propose that autophosphorylation of DNA-PKcs at this cluster of sites is important for remodeling of DNA-PK complexes at DNA ends prior to DNA end joining.
Titin (connectin) based passive force regulation has been an important physiological mechanism to adjust to varying muscle stretch conditions. Upon stretch, titin behaves as a spring capable of modulating its elastic response in accordance with changes in muscle biochemistry. One such mechanism has been the calcium-dependent stiffening of titin domains that renders the spring inherently more resistant to stretch. This transient titin-calcium interaction may serve a protective function in muscle, which could preclude costly unfolding of select domains when muscles elongate to great lengths. To test this idea, fluorescence spectroscopy was performed revealing a change in the microenvironment of the investigated immunoglobulin domain 27 (I27) of titin with calcium. Additionally, an atomic force microscope was used to evaluate the calcium-dependent regulation of passive force by stretching eight linked titin I27 domains until they unfolded. When stretching in the presence of calcium, the I27 homopolymer chain became stabilized, displaying three novel properties: (1) higher stretching forces were needed to unfold the domains, (2) the stiffness, measured as a persistence length (PL), increased and (3) the peak-to-peak distance between adjacent I27 domains increased. Furthermore, a peak order dependence became apparent for both force and PL, reflecting the importance of characterizing the dynamic unfolding history of a polymer with this approach. Together, this novel titin Ig-calcium interaction may serve to stabilize the I27 domain permitting titin to tune passive force within stretched muscle in a calcium-dependent manner.
Background: Calmodulin inhibits the proteolysis of L-selectin's extracellular domains through an unknown mechanism. Results: Calmodulin binds the juxtamembrane and predicted membrane-spanning regions of L-selectin in a calcium-dependent manner. Conclusion: Binding of calmodulin to the cytoplasmic/transmembrane domain of L-selectin enacts a conformational change in the extracellular domains preventing cleavage. Significance: Elucidating the mechanisms of L-selectin shedding is critical to understanding leukocyte trafficking.
Here we present a novel NMR method for the structure determination of calcium-calmodulin (Ca(2+)-CaM)-peptide complexes from a limited set of experimental restraints. A comparison of solved CaM-peptide structures reveals invariability in CaM's backbone conformation and a structural plasticity in CaM's domain orientation enabled by a flexible linker. Knowing this, the collection and analysis of an extensive set of NOESY spectra is redundant. Although RDCs can define CaM domain orientation in the complex, they lack the translational information required to position the domains on the bound peptide and highlight the necessity of intermolecular NOEs. Here we employ a specific isotope labeling strategy in which the role of methionine in CaM-peptide interactions is exploited to collect these critical NOEs. By (1)H, (13)C-labeling the methyl groups of deuterated methionine against a (2)H, (12)C background, we can acquire a (13)C-edited NOESY characterized by simplified, easily analyzable spectra. Together with measured CaM backbone H(N)-N RDCs and intrapeptide NOE-based distances, these intermolecular NOEs provide restraints for a low temperature torsion-angle dynamics and simulated annealing protocol used to calculate the complex structure. We have applied our method to a CaM complex previously solved through X-ray crystallography: Ca(2+)-CaM bound to the CaM kinase I peptide (PDB code: 1MXE). The resulting structure has a backbone RMSD of 1.6 Å to that previously published. We have also used this test complex to investigate the importance of homologous model selection on the calculated outcome. In addition to having application for fast complex structure determination, this method can be used to determine the structures of difficult complexes characterized by chemical shift overlap and broad signals for which the traditional method based on the use of fully (13)C, (15)N-labeled CaM fails.
Calcium- and integrin-binding protein 1 (CIB1) is a ubiquitous, multifunctional regulatory protein consisting of four helix-loop-helix EF-hand motifs. Neither EF-I nor EF-II binds divalent metal ions; however, EF-III is a mixed Mg2+/Ca2+-binding site, and EF-IV is a higher-affinity Ca2+-specific site. Through the generation of several CIB1 mutant proteins, we have investigated the importance of the last (-Z) metal-coordinating position of EF-III (D127) and EF-IV (E172) with respect to the binding of CIB1 to Mg2+, Ca2+, and its biological target, the cytoplasmic domain of the platelet alphaIIb integrin. A D127N mutant had reduced Mg2+ and Ca2+ affinity at EF-III but retained affinity for the alphaIIb domain. A D127E mutant had increased Mg2+ and Ca2+ affinity at EF-III, but unexpectedly, the affinity for the alphaIIb domain was too low for binding to be observed. E172Q and E172D mutants showed no and weak Mg2+ binding at EF-IV, respectively, and each mutant had reduced Ca2+ affinity at EF-IV and showed moderate metal-dependent differences in affinity for the alphaIIb domain. Finally, a D127Q mutant bound Mg2+ and Ca2+ in a manner similar to that of D127N, but like that of D127E, the affinity for the alphaIIb domain was reduced below the detection limit. These data, combined with a NMR-based structural comparison of the Mg2+- and Ca2+-loaded CIB1-alphaIIb peptide complexes, suggest that the D127E and D127Q mutations have a disruptive effect on alphaIIb binding since they expand the metal-binding loop and change the alpha-helix positions in EF-III. Conversely, upon replacement of the ancestral Glu with Asp at the -Z position of EF-III, CIB1 gained affinity for alphaIIb, and the Ca2+ affinity of CIB1 shifted into a range where the protein is able to act as an intracellular Ca2+ sensor.
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