Effects of interaction with calcineurin on the reactivities of calmodulin lysines

Microscale thermophoresis and fluorescence polarization assays of calcineurin-peptide interactions

Calcineurin is a Ca²⁺/calmodulin-dependent phosphatase. It is very important to study the affinity between calcineurin and its substrate or other interacting proteins. Two conserved motifs have been reported on the interactive proteins of calcineurin, namely, the PxIxIT motif and the LxVP motif. Here, we used 5(6)-carboxyfluorescein to fluorescently label the N-terminus of the short peptides derived from the two motifs and then determined the affinity between the protein and polypeptides. Microscale thermophoresis (MST) is very suitable for determining calcineurin with peptides containing the LxVP motif. The K_d values of the binding of calcineurin with NFATc1-YLAVP, NHE1-YLTVP, and A238L-FLCVK peptides were 6.72 ± 0.19 μM, 17.14 ± 0.35 μM, and 15.57 ± 0.10 μM, respectively. The GST pull-down results further confirmed the binding trend of the three peptides to calcineurin. However, fluorescently labeled PxIxIT polypeptides are not suitable for MST due to their own aggregation. We determined the binding affinity of the RCAN1-PSVVVH polypeptide to calcineurin by the fluorescence polarization (FP) method. MST and FP assays are fast and accurate in determining the affinity between protein-peptide interactions. Our research laid the foundation for screening the molecules that affect the binding between calcineurin and its substrates in the future.

A novel peptide exerts potent immunosuppression by blocking the two-site interaction of NFAT with calcineurin

The calcineurin/nuclear factor of activated T cell (CN/NFAT) signaling pathway plays a critical role in the immune response. Therefore, inhibition of the CN/NFAT pathway is an important target for inflammatory disease. The conserved PXIXIT and LXVP motifs of CN substrates and targeting proteins have been recognized. Based on the affinity ability and inhibitory effect of these docking sequences on CN, we designed a bioactive peptide (named pep3) against the CN/NFAT interaction, which has two binding sites derived from the RCAN1-PXIXIT motif and the NFATc1-LXVP motif. The shortest linker between the two binding sites in pep3 is derived from A238L, a physiological binding partner of CN. Microscale thermophoresis revealed that pep3 has two docking sites on CN. Pep3 also has the most potent inhibitory effect on CN. It is suggested that pep3 contains an NFATc1-LXVP-substrate recognition motif and RCAN1-PXIXIT-mediated anchoring to CN. Expression of this peptide significantly suppresses CN/NFAT signaling. Cell-permeable 11-arginine-modified pep3 (11R-pep3) blocks the NFAT downstream signaling pathway. Intranasal administration of the 11R-pep3 peptide inhibits airway inflammation in an ovalbumin-induced asthma model. Our results suggest that pep3 is promising as an immunosuppressive agent and can be used in topical remedies.

The interaction between calcineurin and α-synuclein is regulated by calcium and calmodulin

Calcineurin (CN) is a protein phosphatase and widely distributed in eukaryotes, with an extremely high level of expression in mammalian brain. Alpha-synuclein (α-syn) is a small soluble protein expressed primarily at presynaptic terminals in the central nervous system. In our present study, we explored the interactions between CN and α-syn in vitro. Based on the data from microscale thermophoresis, GST pull-down assays, and co-immunoprecipitation, we found that CN binds α-syn. Furthermore, this interaction is mediated by calcium/calmodulin (Ca²⁺/CaM) signaling. Additionally, thapsigargin (TG) triggered an increase in CN activity and α-syn aggregation in HEK293 cells stably transfected with α-syn. Our previous study in vivo suggest that overexpression of α-syn in transgenic mice significantly promoted CN activity and subsequent nuclear translocation of nuclear factor of activated T-cells (NFAT) in the midbrain dopaminergic (mDA) neurons. These in vivo and in vitro studies have been complementary with each other, representing the changes in the CN-dependent pathway affected by overexpression of α-syn.

Peptides derived from transcription factor EB bind to calcineurin at a similar region as the NFAT-type motif

Calcineurin (CN) is involved in many physiological processes and interacts with multiple substrates. Most of the substrates contain similar motifs recognized by CN. Recent studies revealed a new CN substrate, transcription factor EB (TFEB), which is involved in autophagy. We showed that a 15-mer QSYLENPTSYHLQQS peptide from TFEB (TFEB-YLENP) bound to CN. When the TFEB-YLENP peptide was changed to YLAVP, its affinity for CN increased and it had stronger CN inhibitory activity. Molecular dynamics simulations revealed that the TFEB-YLENP peptide has the same docking sites in CN as the 15-mer DQYLAVPQHPYQWAK motif of the nuclear factor of activated T cells, cytoplasmic 1 (NFATc1-YLAVP). Moreover expression of the NFATc1-YLAVP peptide suppressed the TFEB activation in starved Hela cells. Our studies first identified a CN binding site in TFEB and compared the inhibitory capability of various peptides derived from CN substrates. The data uncovered a diversity in recognition sequences that underlies the CN signaling within the cell. Studies of CN-substrate interactions should lay the groundwork for developing selective CN peptide inhibitors that target CN-substrate interaction in vitro experiments.

The importance of Loop 7 for the activity of calcineurin

Calcineurin (CN) is a heterodimer composed of a catalytic subunit (CNA) and a regulatory subunit (CNB). Loop 7 lies within the CNA catalytic domain. To investigate the role of Loop 7 in enzyme activity, we systematically examined all its residues by site-directed deletion mutation. Our results show that the Loop 7 residues are important for enzyme activity. Besides deleting residues V314, Y315 or N316, enzyme activity also increased dramatically when residues D313 or K318 were deleted. In contrast, almost all activity was lost when L312 or N317 were deleted. Ni2+ and Mn2+ were effective activators for all active mutants. However, whereas the wild-type enzyme was more efficiently activated by Ni2+ than by Mn2+ with 32P-labeled R(II) peptide as substrate, the reverse was true in all the mutants. We also found that the effect of Loop 7 on enzyme activity was substrate dependent, and involved interactions between Loop 7 residues and the unresolved part of the CN crystal structure near the auto-inhibitory domain and catalytic site.

Preparation and characterization of a single-chain calcineurin–calmodulin complex

Calcineurin (CN), a Ca(2+)/calmodulin (CaM)-dependent serine/threonine protein phosphatase, is a heterodimer composed of a catalytic subunit (CNA) and a regulatory subunit (CNB). The activity of CNA is under the control of two functionally distinct, but structurally similar Ca(2+)-regulated proteins, CaM and CNB. The crystal structure of the holoenzyme reveals that the N-terminus and C-terminus of CNB and the N-terminus of CNA each have a long arm not involved in the active site. We constructed a fusion of the genes of CaM, CNB and CNA in that order using linker primers containing six and ten codons of glycine. A single-chain CaM-CNB-CNA (CBA) complex was expressed and purified to near homogeneity. The single-chain complex was fully soluble, and had biochemical properties and kinetic parameters similar to single-chain CNB-CNA (BA) activated by CaM. It was not regulated by CaM and CNB, but was strongly stimulated by Mn2+, Ni2+ and Mg2+. Intrinsic fluorescence spectroscopy of the complex showed a change in the environment of tryptophan in the presence of Ca2+ and circular dichroism (CD) spectropolarimetry revealed an increase in alpha-helical content. Our findings suggest that fusion of CaM, CNB and CNA does not prevent the structural changes required for their functioning; in particular, CaM within the complex could still interact correctly with CN in the presence of Ca2+.

Function and structure of recombinant single chain calcineurin

Calcineurin (CN) is a Ca(2+)/calmodulin(CaM)-dependent serine/threonine protein phosphatase which is a heterodimer composed of a 61 kDa catalytic subunit (CNA) and a 19 kDa regulatory subunit (CNB). The enzyme is critical for several important intracellular signal-transducing pathways, including T-cell activation. Its crystal structure reveals that the C-terminal of CNB lies in close vicinity of the N-terminal of CNA and each end has a long arm not involved in the active site. After fusing two subunits, it was determined that folding and function of the protein were not affected by the fusion. We amplified a fused gene of A and B subunits using a pair of linker primers including six codons of glycine. A single chain calcineurin was constructed and purified to near-homogeneity. The recombinant enzyme was fully soluble, displayed high specific activity with substrate, and exhibited biochemical properties and kinetic parameters similar to those of the native enzyme from the bovine brain. It was still activated by Ca(2+)/calmodulin but was not regulated by extra CNB and was still strongly stimulated by Mn(2+) and Ni(2+) divalent metal ions. The solution conformations of both recombinant enzyme and bovine calcineurin were assayed under the same conditions using intrinsic fluorescence spectroscopy and circular dichroism spectropolarimetry, and results showed their graphs are approximately identical. Our findings suggested that the fusion of A and B subunits of calcineurin does not affect their folding pathways and structural changes involved in their function, furthermore, they are bound to the correct binding site.

Converting troponin C into calmodulin: effects of mutations in the central helix and of changes in temperature

Calmodulin (CaM) and troponin C (TnC) are the most similar members of EF-hand family and show few differences in the primary structure. Here, we use mutants of troponin that mimic calmodulin and changes in temperature to investigate the factors that determine their specificity as regulatory proteins. Using a double mutant of troponin that resembles calmodulin in lacking both the N-terminal helix and KGK(91-93) we observe a small difference from troponin in binding to the erythrocyte Ca(2+)-ATPase, and an improvement in enzyme activation. A triple mutant, where in addition, the residues 88-90 are replaced with the corresponding sequence from calmodulin is equivalent to calmodulin in maximal activation, and it restores protein ability to increase Ca(2+) affinity for the enzyme. However, this mutant also binds less tightly (1/100) than calmodulin. Remarkably, a decrease in temperature has a more marked effect in protein binding than either mutation, reducing the difference in affinities to 18-fold, but without any improvement in their ability to increase Ca(2+) affinity for the enzyme. Spectroscopic analysis of hydrophobic domain exposure in EF-hand proteins was carried out using 8-anilino-1-naphthalenesulfonic acid (ANS). The probe shows a much higher fluorescence when bound to the complex Ca(4)-calmodulin than to Ca(4)-troponin. Decreasing the temperature exposes additional hydrophobic regions of troponin. Changing the Mg(2+) concentration does not affect their bindings to the enzyme. It is suggested that the requirements for troponin to mimic calmodulin in binding to the target enzyme, and those for activating it, are met by different regions of the protein.

Ferredoxin binding site on ferredoxin: NADP+ reductase. Differential chemical modification of free and ferredoxin-bound enzyme

The chloroplast enzyme ferredoxin: NADP+ reductase (FNR) catalyzes the reduction of NADP+ by ferredoxin (Fd). FNR and Fd form a 1:1 complex that is stabilized by electrostatic interactions between acidic residues of Fd and basic residues of FNR. To localize lysine residues at the Fd binding site of FNR, the FNR:Fd complex (both proteins from spinach) was studied by differential chemical modification. In a first set of experiments, free FNR and the FNR:Fd complex were reacted with the N-hydroxysuccinimidyl ester of biotin. Biotinylated peptides and non-biotinylated peptides were separated on monovalent avidin-Sepharose and purified by high-performance liquid chromatography. Two peptides containing Lys18 and Lys153, respectively, were less biotinylated in complexed FNR than in free FNR. In a second set of experiments, free and complexed FNR were treated with 4-N,N-dimethylaminoazobenzene-4'-isothiocyano-2'-sulfonic acid (S-DABITC) to obtain coloured lysine-modified FNR. Protection of Lys153 was again found by modification with S-DABITC. In addition, Lys33 and Lys35 were less labelled in the S-DABITC-modified. Fd-bound enzyme. FNR modified in the presence, but not in the absence, of Fd was still able to bind Fd, indicating that the Fd-protected residues are involved in the formation of the Fd:FNR complex. The lysine residues disclosed by differential modification surround the positive end of the molecular dipole moment (558 Debye approximately 1.85 x 10(-27) Cm) and are located in a domain of strong positive potential on the surface of the FNR molecule. This domain we had proposed to belong to the binding site of FNR for Fd [De Pascalis, A. R., Jelesarov, I., Ackermann, F., Koppenol, W. H., Hirasawa, M., Knaff, D. B. & Bosshard, H. R. (1993) Protein Science 2. 1126-1135]. The prediction was based on the complementarity of shape between positive and negative potential domains of FNR and Fd, respectively.

Binding of ferredoxin to ferredoxin:NADP+ oxidoreductase: the role of carboxyl groups, electrostatic surface potential, and molecular dipole moment

The small, soluble, (2Fe-2S)-containing protein ferredoxin (Fd) mediates electron transfer from the chloroplast photosystem I to ferredoxin: NADP+ oxidoreductase (FNR), a flavoenzyme located on the stromal side of the thylakoid membrane. Ferredoxin and FNR form a 1:1 complex, which is stabilized by electrostatic interactions between acidic residues of Fd and basic residues of FNR. We have used differential chemical modification of Fd to locate aspartic and glutamic acid residues at the intermolecular interface of the Fd:FNR complex (both proteins from spinach). Carboxyl groups of free and FNR-bound Fd were amidated with carbodiimide/2-aminoethane sulfonic acid (taurine). The differential reactivity of carboxyl groups was assessed by double isotope labeling. Residues protected in the Fd:FNR complex were D-26, E-29, E-30, D-34, D-65, and D-66. The protected residues belong to two domains of negative electrostatic surface potential on either side of the iron-sulfur cluster. The negative end of the molecular dipole moment vector of Fd (377 Debye) is close to the iron-sulfur cluster, in the center of the area demarcated by the protected carboxyl groups. The molecular dipole moment and the asymmetric surface potential may help to orient Fd in the reaction with FNR. In support, we find complementary domains of positive electrostatic potential on either side of the FAD redox center of FNR. The results allow a binding model for the Fd:FNR complex to be constructed.

Tertiary structure of calcineurin B by homology modeling

The crystal structure of the calcium-binding protein calmodulin is used to model the immunologically important calcineurin subunit B. The rough structure is produced by computer-aided homology modeling. Refinement of this using molecular dynamics leads to a suggested structure which appears to satisfy reasonable hydrophilicity and hydrogen-bonding criteria. In the absence of a crystal structure, the model may prove useful in modeling of its interactions with the phosphatase catalytic subunit calcineurin A, and help to explain the calcium modulation of this protein.