Different conformational switches underlie the calmodulin-dependent modulation of calcium pumps and channels

We have used fluorescence spectroscopy to investigate the structure of calmodulin (CaM) bound with CaM-binding sequences of either the plasma membrane Ca-ATPase or the skeletal muscle ryanodine receptor (RyR1) calcium release channel. Following derivatization with N-(1-pyrene)maleimide at engineered sites (T34C and T110C) within the N- and C-domains of CaM, contact interactions between these opposing domains of CaM resulted in excimer fluorescence that permits us to monitor conformational states of bound CaM. Complementary measurements take advantage of the unique conserved Trp within CaM-binding sequences that functions as a hydrophobic anchor in CaM binding and permits measurements of both a local and global peptide structure. We find that CaM binds with high affinity in a collapsed structure to the CaM-binding sequences of both the Ca-ATPase and RyR1, resulting in excimer formation that is indicative of contact interactions between the N- and the C-domains of CaM in complex with these CaM-binding peptides. There is a 4-fold larger amount of excimer formation for CaM bound to the CaM-binding sequence of the Ca-ATPase in comparison to RyR1, indicating a closer structural coupling between CaM domains in this complex. Prior to CaM association, the CaM-binding sequences of the Ca-ATPase and RyR1 are conformationally disordered. Upon CaM association, the CaM-binding sequence of the Ca-ATPase assumes a highly ordered structure. In comparison, the CaM-binding sequence of RyR1 remains conformationally disordered irrespective of CaM binding. These results suggest an important role for interdomain contact interactions between the opposing domains of CaM in stabilizing the structure of the peptide complex. The substantially different structural responses associated with CaM binding to Ca-ATPase and RyR1 indicates a plasticity in their respective binding mechanisms that accomplishes different physical mechanisms of allosteric regulation, involving either the dissociation of a C-terminal regulatory domain necessary for pump activation or the modulation of intersubunit interactions to diminish RyR1 channel activity.     

Calpain and cell death

Neither the early nor the late steps in apoptosis have been defined biochemically. Several different signalling pathways have been implicated, and these are familiar from other signalling paradigms. In what way could they lead to cell death, when under the usual conditions they are involved in reversible activation events? A possible role for proteolysis is suggested, because the cleavage of a peptide bond is one of the few irreversible processes in cellular metabolism, and death, after all, is an irreversible outcome. In this review we discuss the calcium-dependent neutral protease calpain, a member of the papain family of cysteine proteases quite distinct from the ICE family. Calpain has been shown to play an essential role in several important examples of physiologic apoptosis. It seems to play its part after the various 'private' pathways have been invoked, but before the final common pathway.     

Resolution of phospholipid conformational heterogeneity in model membranes by spin-label EPR and frequency-domain fluorescence spectroscopy.

We have utilized both fluorescent and nitroxide derivatives of stearic acid as probes of membrane structural heterogeneity in phospholipid vesicles under physiological conditions, as well as conditions of varying ionic strengths and temperatures where spectral heterogeneity has been previously observed and attributed to multiple ionization states of the probes. To identify the source of this spectral heterogeneity, we have utilized complimentary measurements of the relaxation properties (lifetimes) and motion of both (a) spin labeled and anthroyloxy derivatives of stearic acid (i.e., SASL and AS) and (b) a diphenylhexatriene derivative of phosphatidylcholine (DPH-PC) in single component membranes containing dimyristoylphosphatidylcholine (DMPC). We use an 15N stearic-acid spin label for optimal sensitivity to membrane heterogeneity. The lifetime and dynamics of the fluorescent phospholipid analogue DPH-PC (with no ionizable groups over this pH range) were compared with those of AS, allowing us to discriminate between changes in membrane structure and the ionization of the label. The quantum yield and rotational dynamics of DPH-PC are independent of pH, indicating that changes in pH do not affect the conformation of the host phospholipids. However, both EPR spectra of SASL and the lifetime or dynamics of AS are affected profoundly by changes in solution pH. The apparent pKa's of these two probes in DMPC membranes were determined to be near pH 6.3, implying that at physiological pH and ionic strength these stearic-acid labels exist predominantly as a single ionized population in membranes. Therefore, the observed temperature- and ionic-strength-dependent alterations in the spectra of SASL as well as the lifetime or dynamics of AS in DMPC membranes at neutral pH are due to changes in membrane structure rather than the ionization of the probes. The possibility that ionic gradients across biological membranes induce alterations in phospholipid structures, thereby modulating lipid-protein interactions is discussed.     

Mediating molecular recognition by methionine oxidation: conformational switching by oxidation of methionine in the carboxyl-terminal domain of calmodulin

The C-terminus of calmodulin (CaM) functions as a sensor of oxidative stress, with oxidation of methionine 144 and 145 inducing a nonproductive association of the oxidized CaM with the plasma membrane Ca(2+)-ATPase (PMCA) and other target proteins to downregulate cellular metabolism. To better understand the structural underpinnings and mechanism of this switch, we have engineered a CaM mutant (CaM-L7) that permits the site-specific oxidation of M144 and M145, and we have used NMR spectroscopy to identify structural changes in CaM and CaM-L7 and changes in the interactions between CaM-L7 and the CaM-binding sequence of the PMCA (C28W) due to methionine oxidation. In CaM and CaM-L7, methionine oxidation results in nominal secondary structural changes, but chemical shift changes and line broadening in NMR spectra indicate significant tertiary structural changes. For CaM-L7 bound to C28W, main chain and side chain chemical shift perturbations indicate that oxidation of M144 and M145 leads to large tertiary structural changes in the C-terminal hydrophobic pocket involving residues that comprise the interface with C28W. Smaller changes in the N-terminal domain also involving residues that interact with C28W are observed, as are changes in the central linker region. At the C-terminal helix, (1)H(alpha), (13)C(alpha), and (13)CO chemical shift changes indicate decreased helical character, with a complete loss of helicity for M144 and M145. Using (13)C-filtered, (13)C-edited NMR experiments, dramatic changes in intermolecular contacts between residues in the C-terminal domain of CaM-L7 and C28W accompany oxidation of M144 and M145, with an essentially complete loss of contacts between C28W and M144 and M145. We propose that the inability of CaM to fully activate the PMCA after methionine oxidation originates in a reduced helical propensity for M144 and M145, and results primarily from a global rearrangement of the tertiary structure of the C-terminal globular domain that substantially alters the interaction of this domain with the PMCA.     

Redox modulation of cellular signaling and metabolism through reversible oxidation of methionine sensors in calcium regulatory proteins

Adaptive responses associated with environmental stressors are critical to cell survival. Under conditions when cellular redox and antioxidant defenses are overwhelmed, the selective oxidation of critical methionines within selected protein sensors functions to down-regulate energy metabolism and the further generation of reactive oxygen species (ROS). Mechanistically, these functional changes within protein sensors take advantage of the helix-breaking character of methionine sulfoxide. The sensitivity of several calcium regulatory proteins to oxidative modification provides cellular sensors that link oxidative stress to cellular response and recovery. Calmodulin (CaM) is one such critical calcium regulatory protein, which is functionally sensitive to methionine oxidation. Helix destabilization resulting from the oxidation of either Met(144) or Met(145) results in the nonproductive association between CaM and target proteins. The ability of oxidized CaM to stabilize its target proteins in an inhibited state with an affinity similar to that of native (unoxidized) CaM permits this central regulatory protein to function as a cellular rheostat that down-regulates energy metabolism in response to oxidative stress. Likewise, oxidation of a methionine within a critical switch region of the regulatory protein phospholamban is expected to destabilize the phosphorylation-dependent helix formation necessary for the release of enzyme inhibition, resulting in a down-regulation of the Ca-ATPase in response to beta-adrenergic signaling in the heart. We suggest that under acute conditions, such as inflammation or ischemia, these types of mechanisms ensure minimal nonspecific cellular damage, allowing for rapid restoration of cellular function through repair of oxidized methionines by methionine sulfoxide reductases and degradation pathways after restoration of normal cellular redox conditions.     

Differences in the capacity of reovirus strains to induce apoptosis are determined by the viral attachment protein sigma 1.

Reoviruses are important models for studies of viral pathogenesis; however, the mechanisms by which these viruses produce cytopathic effects in infected cells have not been defined. In this report, we show that murine L929 (L) cells infected with prototype reovirus strains type 1 Lang (TIL) and type 3 Dearing (T3D) undergo apoptosis and that T3D induces apoptosis to a substantially greater extent than T1L. Using T1L x T3D reassortant viruses, we found that differences in the capacity of T1L and T3D to induce apoptosis are determined by the viral S1 gene segment, which encodes the viral attachment protein sigma 1 and the non-virion-associated protein sigma 1s. Apoptosis was induced by UV-inactivated, replication-incompetent reovirus virions, which do not contain sigma 1s and do not mediate its synthesis in infected cells. Additionally, T3D-induced apoptosis was inhibited by anti-reovirus monoclonal antibodies that inhibit T3D cell attachment and disassembly. These results indicate that sigma 1, rather than sigma 1s, is required for induction of apoptosis by the reovirus and suggest that interaction of virions with cell surface receptors is an essential step in this mechanism of cell killing.     

Temperature dependence of rotational dynamics of protein and lipid in sarcoplasmic reticulum membranes

We have investigated the relationship between function and molecular dynamics of both the lipid and the Ca-ATPase protein in sarcoplasmic reticulum (SR), using temperature as a means of altering both activity and rotational dynamics. Conventional and saturation-transfer electron paramagnetic resonance (EPR) was used to probe rotational motions of spin-labels attached either to fatty acid hydrocarbon chains or to the Ca-ATPase sulfhydryl groups in SR. EPR studies were also performed on aqueous dispersions of extracted SR lipids, in order to study intrinsic lipid properties independent of the protein. While an Arrhenius plot of the Ca-ATPase activity exhibits a clear change in slope at 20 degrees C, Arrhenius plots of lipid hydrocarbon chain mobility are linear, indicating that an abrupt thermotropic change in the lipid hydrocarbon phase is not responsible for the Arrhenius break in enzymatic activity. The presence of protein was found to decrease the average hydrocarbon chain mobility, but linear Arrhenius plots were observed both in the intact SR and in extracted lipids. Lipid EPR spectra were analyzed by procedures that prevent the production of artifactual breaks in the Arrhenius plots. Similarly, using sample preparations and spectral analysis methods that minimize the temperature-dependent contribution of local probe mobility to the spectra of spin-labeled Ca-ATPase, we find that Arrhenius plots of overall protein rotational mobility also exhibit no change in slope. The activation energy for protein mobility is the same as that of ATPase activity above 20 degrees C; we discuss the possibility that overall protein mobility may be essential to the rate-limiting step above 20 degrees C.     

Lipid fluidity directly modulates the overall protein rotational mobility of the Ca-ATPase in sarcoplasmic reticulum

We have developed a quantitative and relatively model-independent measure of lipid fluidity using EPR and have applied this method to compare the temperature dependence of lipid hydrocarbon chain fluidity, overall protein rotational mobility, and the calcium-dependent enzymatic activity of the Ca-ATPase in sarcoplasmic reticulum. We define membrane lipid fluidity to be T/eta, where eta is the viscosity of a long chain hydrocarbon reference solvent in which a fatty acid spin label gives the same EPR spectrum (quantitated by the order parameter S) as observed for the same probe in the membrane. This measure is independent of the reference solvent used as long as the spectral line shapes in the membrane and the solvent match precisely, indicating that the same type of anisotropic probe motion occurs in the two systems. We argue that this empirical measurement of fluidity, defined in analogy to the macroscopic fluidity (T/eta) of a bulk solvent, should be more directly related to protein rotational mobility (and thus to protein function) than are more conventional measures of fluidity, such as the rate or amplitude of rotational motion of the lipid hydrocarbon chains themselves. This new definition thus offers a fluidity measure that is more directly relevant to the protein's behavior. The direct relationship between this measure of membrane fluidity and protein rotational mobility is supported by measurements in sarcoplasmic reticulum. The overall rotational motion of the spin-labeled Ca-ATPase protein was measured by saturation-transfer EPR. The Arrhenius activation energy for protein rotational mobility (11-12 kcal/mol/degree) agrees well with the activation energy for lipid fluidity, if defined as in this study, but not if more conventional definitions of lipid fluidity are used. This agreement, which extends over the entire temperature range from 0 to 40 degrees C, suggests that protein mobility depends directly on lipid fluidity in this system, as predicted from hydrodynamic theory. The same activation energy is observed for the calcium-dependent ATPase activity under physiological conditions, suggesting that protein rotational mobility (dependent on lipid fluidity) is involved in the rate-limiting step of active calcium transport.