Effect of temperature and the F27W mutation on the Ca2+ activated structural transition of trout cardiac troponin C

The Ca(2+) sensitivity of cardiac contractile element is reduced at lower temperatures, in contrast to that in fast skeletal muscle. Cardiac troponin C (cTnC) replacement in mammalian skinned fibers showed that TnC plays a critical role in this phenomenon (Harrison and Bers, (1990), Am. J. Physiol. 258, C282-8). Understanding the differences in affinity and structure between cTnCs from cold-adapted ectothermic species and mammals may bring new insights into how the different isoforms provide different resistances to cold. We followed the Ca(2+) titration to the regulatory domain of rainbow trout cTnC by NMR (wild type at 7 and 30 degrees C and F27W mutant at 30 degrees C) and fluorescence (F27W mutant, at 7 and 30 degrees C) spectroscopies. Using NMR spectroscopy, we detected Ca(2+) binding to site I of trout cTnC at high concentrations. This places trout cTnC between mammalian cTnC, in which site I is completely inactive, and skeletal TnC, in which site I binds Ca(2+) during muscle activation, and which is not as much affected by lower temperatures. This binding was seen both at 7 and at 30 degrees C. Despite the low Ca(2+) affinity, trout TnC site I may increase the likelihood of an opening of the regulatory domain, thus increasing the affinity for TnI. This way, it may be responsible for trout cTnC's capacity to function at lower temperatures.     

Nuclear magnetic resonance structure of the P395S mutant of the N-SH2 domain of the p85 subunit of PI3 kinase: an SH2 domain with altered specificity

Understanding the specificity of Src homology 2 (SH2) domains is important because of their critical role in cell signaling. Previous genetic analysis has characterized mutants of the N-terminal src homology 2 (SH2) domain of the p85 subunit of phosphoinositide 3-kinase (PI3K). The P395S mutant exhibits a specificity for phosphopeptide binding different from that of the wild-type SH2. The P395S mutant has an increased affinity for the platelet-derived growth factor receptor (PDGFr) compared to polyomavirus middle T antigen (MT). Solution structures of the P395S mutant of the p85 N-SH2 alone and complexed to a PDGFr phosphopeptide were determined to explain the change in specificity. Chemical shift perturbations caused by different peptides were compared for mutant and wild-type structures. The results show that the single P395S mutation has broad effects on the structure. Furthermore, they provide a rationale for the observed changes in binding preference.     

Correlating structure and affinity for PEX5:PTS1 complexes

Many proteins that are destined to reside within the lumen of the peroxisome contain the peroxisomal targeting signal-1 (PTS1), a C-terminal tripeptide approximating the consensus sequence -Ser-Lys-Leu-COO(-). The PTS1 is recognized by the tetratricopeptide repeat (TPR) domains of PEX5, a cytosolic receptor that cycles between the cytoplasm and the peroxisome. To gain insight into the energetics of PTS1 binding specificity and to correlate these with features from the recently determined structure of a PEX5:PTS1 complex, we used a fluorescence-based binding assay that enables the quantitation of the dissociation constants for PTS1-containing peptide complexes with the TPR region of human PEX5. Through application of this assay to a collection of pentapeptides containing different C-terminal tripeptide sequences, including both natural and unnatural amino acids, the thermodynamic effects of sequence variation were examined. PTS1 variants that correspond to known functional targeting signals bind to the PEX5 fragment with a change in the standard binding free energy within 1.8 kcal mol(-1) of that corresponding to the peptide ending with -Ser-Lys-Leu-COO(-). The results suggest that a binding energy threshold may determine the functionality of PTS1 sequences.     

Selective attenuation of the extrinsic limb of the tissue factor-driven coagulation protease cascade by occupancy of a novel peptidyl docking site on tissue factor

Tissue factor (TF), the receptor and cofactor for factor VIIa (VIIa) for cellular initiation of the coagulation protease cascade, drives thrombogenesis, inflammation, tumor cell metastasis, and the lethality of severe sepsis. To identify TF surface loci that can selectively inhibit substrate zymogen association and activation, TF(1-218), the extracellular domain, was used as the target for the phage display search. This resulted in selection of 59 clones from a phage gpVIII surface protein-expressed library of constrained combinatorial peptides. Of these, one encoding the peptide Glu-Cys-Leu-Arg-Ser-Val-Val-Thr-Cys on gpVIII most avidly bound TF(1-218), as did the synthetic peptide. Inhibition of binding was selective with an IC(50) of 30 nM for proteolytic activation of factor X by the TF(1-218)-VIIa complex. In contrast, there was no inhibition of factor IX activation. The selective inhibition of only factor X association with TF(1-218) will spare the intrinsic hemostatic pathway while attenuating the extrinsic thrombogenic pathway. This and related peptidyl structures provide the potential for the more precise identification of TF surface loci that mediate selective functional properties of the protein as well as a structural basis for the design of novel molecules for selectively attenuating initiation of the extrinsic limb of the coagulation protease cascade and other functions of TF.     

Spectroscopic determination of the binding affinity of zinc to the DNA-binding domains of nuclear hormone receptors

Zinc binding to the two Cys(4) sites present in the DNA-binding domain (DBD) of nuclear hormone receptor proteins is required for proper folding of the domain and for protein activity. By utilizing Co(2+) as a spectroscopic probe, we have characterized the metal-binding properties of the two Cys(4) structural zinc-binding sites found in the DBD of human estrogen receptor alpha (hERalpha-DBD) and rat glucocorticoid receptor (GR-DBD). The binding affinity of Co(2+) to the two proteins was determined relative to the binding affinity of Co(2+) to the zinc finger consensus peptide, CP-1. Using the known dissociation constant of Co(2+) from CP-1, the dissociation constants of cobalt from hERalpha-DBD were calculated: K(d1)(Co) = 2.2 (+/- 1.0) x 10(-7) M and K(d2)(Co) = 6.1 (+/- 1.5) x 10(-7) M. Similarly, the dissociation constants of Co(2+) from GR-DBD were calculated: K(d1)(Co) = 4.1 (+/- 0.6) x 10(-7) M and K(d2)(Co) = 1.7 (+/- 0.3) x 10(-7) M. Metal-binding studies conducted in which Zn(2+) displaces Co(2+) from the metal-binding sites of hERalpha-DBD and GR-DBD indicate that Zn(2+) binds to each of the Cys(4) metal-binding sites approximately 3 orders of magnitude more tightly than Co(2+) does: the stoichiometric dissociation constants are K(d1)(Zn) = 1 (+/- 1) x 10(-10) M and K(d2)(Zn) = 5 (+/- 1) x 10(-10) M for hERalpha-DBD and K(d1)(Zn) = 2 (+/- 1) x 10(-10) M and K(d2)(Zn) = 3 (+/- 1) x 10(-10) M for GR-DBD. These affinities are comparable to those observed for most other naturally occurring structural zinc-binding sites. In contrast to the recent prediction by Low et. al. that zinc binding in these systems should be cooperative [Low, L. Y., Hernández, H., Robinson, C. V., O'Brien, R., Grossmann, J. G., Ladbury, J. E., and Luisi, B. (2002) J. Mol. Biol. 319, 87-106], these data suggest that the zincs that bind to the two sites in the DBDs of hERalpha-DBD and GR-DBD do not interact.     

A family of leukemia inhibitory factor-binding peptides that can act as antagonists when conjugated to poly(ethylene glycol)

A panel of six na?ve 14-residue random peptide libraries displayed polyvalently on M13 phage was pooled and sorted against human leukemia inhibitory factor (LIF). After four rounds of selection, a single large family of peptides with the consensus sequence XCXXXXG(A/S)(D/E)(W/F)WXCF was found to bind specifically to LIF. Peptides within this family did not bind related members of the interleukin-6 family of cytokines, nor to murine LIF that has 80% sequence identity with human LIF. A representative peptide from this family was synthesized and found to bind to LIF with an affinity of approximately 300 nM. The phage-displayed form of this peptide was able to compete with the LIF receptor alpha chain (LIFR) for binding to LIF; however, the free synthetic peptide was unable to inhibit LIF-LIFR binding or inhibit LIF bioactivity in vitro. Using a panel of human/murine chimeric LIF molecules, the peptide-binding site on LIF was mapped to a groove located between the B and the C helices of the LIF structure, which is distinct from the surfaces involved in binding to receptor. To mimic the effect of the phage particle and convert the free peptide into an antagonist of LIFR binding, a 40 kDa poly(ethylene glycol) (PEG) moiety was conjugated to the synthetic LIF-binding peptide. This PEG-peptide conjugate was found to be both an antagonist of LIF-LIFR binding and of LIF signaling in engineered Ba/F3 cells expressing LIFR and the gp130 coreceptor.     

Deacylated pulmonary surfactant protein SP-C transforms from alpha-helical to amyloid fibril structure via a pH-dependent mechanism: an infrared structural investigation

Bovine pulmonary surfactant protein C (SP-C) is a hydrophobic, alpha-helical membrane-associated lipoprotein in which cysteines C4 and C5 are acylated with palmitoyl chains. Recently, it has been found that the alpha-helix form of SP-C is metastable, and under certain circumstances may transform from an alpha-helix to a beta-strand conformation that resembles amyloid fibrils. This transformation is accelerated when the protein is in its deacylated form (dSP-C). We have used infrared spectroscopy to study the structure of dSP-C in solution and at membrane interfaces. Our results show that dSP-C transforms from an alpha-helical to a beta-type amyloid fibril structure via a pH-dependent mechanism. In solution at low pH, dSP-C is alpha-helical in nature, but converts to an amyloid fibril structure composed of short beta-strands or beta-hairpins at neutral pH. The alpha-helix structure of dSP-C is fully recoverable from the amyloid beta-structure when the pH is once again lowered. Attenuated total reflectance infrared spectroscopy of lipid-protein monomolecular films showed that the fibril beta-form of dSP-C is not surface-associated at the air-water interface. In addition, the lipid-associated alpha-helix form of dSP-C is only retained at the surface at low surface pressures and dissociates from the membrane at higher surface pressures. In situ polarization modulation infrared spectroscopy of protein and lipid-protein monolayers at the air-water interface confirmed that the residual dSP-C helix conformation observed in the attenuated total reflectance infrared spectra of transferred films is randomly or isotropically oriented before exclusion from the membrane interface. This work identifies pH as one of the mechanistic causes of amyloid fibril formation for dSP-C, and a possible contributor to the pathogenesis of pulmonary alveolar proteinosis.     

Freezing of a fish antifreeze protein results in amyloid fibril formation

Amyloid is associated with a number of diseases including Alzheimer's, Huntington's, Parkinson's, and the spongiform encephalopathies. Amyloid fibrils have been formed in vitro from both disease and nondisease related proteins, but the latter requires extremes of pH, heat, or the presence of a chaotropic agent. We show, using fluorescence spectroscopy, electron microscopy, and solid-state NMR spectroscopy, that the alpha-helical type I antifreeze protein from the winter flounder forms amyloid fibrils at pH 4 and 7 upon freezing and thawing. Our results demonstrate that the freezing of some proteins may accelerate the formation of amyloid fibrils.     

Elevated temperature effects on the oxidant/antioxidant balance in submerged batch cultures of the filamentous fungus Aspergillus niger B1-D

In the present study the relationship between oxidative stress and elevated culture temperature was examined in an industrially relevant fungal culture, Aspergillus niger B1-D. For the first time, both the intracellular levels of the main stressor species (superoxide radical [O(2) (.-)]) and activities of cellular defensive enzymes (superoxide dismutase [SOD], catalase [CAT], and glutathione peroxide [GPx]) were quantified at varying temperature (25, 30, 35, 40 degrees C) to more fully characterize culture response in different growth phases. Elevated culture temperature led to increased O(2) (.-) levels in various culture phases. In the exponential phase this was due to an enhanced generation of O(2) (.-), whereas in stationary phase a decreased dismutation rate may also have contributed. CAT activities generally increased with culture temperature, whereas GPx activity changed little as temperature rose, indicating that GPx played only a minor role in destroying H(2)O(2) in this A. niger. The combination of elevated temperature (35 degrees C) and increased O(2) supply (50% enrichment) led to decreased levels of O(2) (.-) compared to the cultivation at 35 degrees C gassed with air, probably due to enhanced activity of the alternative fungal respiratory pathway. Our findings indicate that while elevated cultivation temperature does clearly induce oxidative stress events, mechanistically, it does so by a rather more complex route than previous studies indicate. Elevated temperature caused a marked disparity in the activities of SOD and CAT, very distinct from the integrated increase in activity of these enzymes in response to oxidative stress.     

In-situ near infrared spectroscopy to monitor key analytes in mammalian cell cultivation

The use of in-situ near infrared spectroscopy (NIRS) as a tool for monitoring four key analytes in a CHO-K1 animal cell culture was investigated. Previous work using on-line NIRS to monitor bioprocesses has involved its application ex-situ where the analyzer is physically outside the fermentor, or to microbial bioprocesses. This novel application of NIRS to monitor analytes within an animal cell culture using a steam sterilizable in-situ fiber optic probe is very important for furthering the use of NIRS within the bioprocessing industry. The method of calibration used to develop the models involved the use of large data sets so that all likely variation in stoichiometry was incorporated within the models. Successful models for glucose, lactate, glutamine, and ammonia were built with Standard Error of Predictions (SEP's) of 0.072 (g/L), 0.0144 (g/L), 0.308 (mM), and 0.036 (mM), respectively of the total concentration range.