Gene selection, alternative splicing, and post-translational processing regulate neuroligin selectivity for beta-neurexins

Neuroligins 1-4 are postsynaptic transmembrane proteins capable of initiating presynaptic maturation via interactions with beta-neurexin. Both neuroligins and beta-neurexins have alternatively spliced inserts in their extracellular domains. Using analytical ultracentrifugation, we determined that the extracellular domains of the neuroligins sediment as dimers, whereas the extracellular domains of the beta-neurexins appear monomeric. Sedimentation velocity experiments of titrated stoichiometry ratios of beta-neurexin and neuroligin suggested a 2:2 complex formation. The recognition properties of individual neuroligins toward beta-neurexin-1 (NX1beta), along with the influence of their splice inserts, were explored by surface plasmon resonance and affinity chromatography. Different neuroligins display a range of NX1beta affinities spanning more than 2 orders of magnitude. Whereas splice insert 4 in beta-neurexin appears to act only as a modulator of the neuroligin/beta-neurexin association, splice insert B in neuroligin-1 (NL1) is the key element regulating the NL1/NX1beta binding. Our data indicate that gene selection, mRNA splicing, and post-translational modifications combine to give rise to a controlled neuroligin recognition code with a rank ordering of affinities for particular neurexins that is conserved for the neuroligins across mammalian species.     

Quaternary structure of carbonmonoxyhemoglobins in solution: structural changes induced by the allosteric effector inositol hexaphosphate

We have applied the residual dipolar coupling (RDC) method to investigate the solution quaternary structures of (2)H- and (15)N-labeled human normal adult recombinant hemoglobin (rHb A) and a low-oxygen-affinity mutant recombinant hemoglobin, rHb(alpha96Val-->Trp), both in the carbonmonoxy form, in the absence and presence of an allosteric effector, inositol hexaphosphate (IHP), using a stretched polyacrylamide gel as the alignment medium. Our recent RDC results [Lukin, J. A., Kontaxis, G., Simplaceanu, V., Yuan, Y., Bax, A., and Ho, C. (2003) Proc. Natl. Acad. Sci. U.S.A. 100, 517-520] indicate that the quaternary structure of HbCO A in solution is a dynamic ensemble between two previously determined crystal structures, R (crystals grown under high-salt conditions) and R2 (crystals grown under low-salt conditions). On the basis of a comparison of the geometric coordinates of the T, R, and R2 structures, it has been suggested that the oxygenation of Hb A follows the transition pathway from T to R and then to R2, with R being the intermediate structure [Srinivasan, R., and Rose, G. D. (1994) Proc. Natl. Acad. Sci. U.S.A. 91, 11113-11117]. The results presented here suggest that IHP can shift the solution quaternary structure of HbCO A slightly toward the R structure. The solution quaternary structure of rHbCO(alpha96Val-->Trp) in the absence of IHP is similar to that of HbCO A in the presence of IHP, consistent with rHbCO(alpha96Val-->Trp) having an affinity for oxygen lower than that of Hb A. Moreover, IHP has a much stronger effect in shifting the solution quaternary structure of rHbCO(alpha96Val-->Trp) toward the R structure and toward the T structure, consistent with IHP causing a more pronounced decrease in its oxygen affinity. The results presented in this work, as well as other results recently reported in the literature, clearly indicate that there are multiple quaternary structures for the ligated form of hemoglobin. These results also provide new insights regarding the roles of allosteric effectors in regulating the structure and function of hemoglobin. The classical two-state/two-structure allosteric mechanism for the cooperative oxygenation of hemoglobin cannot account for the structural and functional properties of this protein and needs to be revised.     

Pro-interleukin (IL)-1�� Shares a Core Region of Stability as Compared with Mature IL-1�� While Maintaining a Distinctly Different Configurational Landscape: A COMPARATIVE HYDROGEN/DEUTERIUM EXCHANGE MASS SPECTROMETRY STUDY*

Interleukin-1β (IL-1β) is a master cytokine involved in initiating the innate immune response in vertebrates (Dinarello, C. A. (1994) FASEB J. 8, 1314–1325). It is first synthesized as an inactive 269-residue precursor (pro-interleukin-1β or pro-IL-1β). Pro-IL-1β requires processing by caspase-1 to generate the active, mature 153-residue cytokine. In this study, we combined hydrogen/deuterium exchange mass spectrometry, circular dichroism spectroscopy, and enzymatic digestion comparative studies to investigate the configurational landscape of pro-IL-1β and the role the N terminus plays in modulating the landscape. We find that the N terminus keeps pro-IL-1β in a protease-labile state while maintaining a core region of stability in the C-terminal region, the eventual mature protein. In mature IL-1β, this highly protected region maps back to the area protected earliest in the NMR studies characterizing an on-route kinetic refolding intermediate. This protected region also encompasses two important functional loops that participate in the IL-1β/receptor binding interface required for biological activity. We propose that the purpose of the N-terminal precursor region in pro-IL-1β is to suppress the function of the eventual mature region while keeping a structurally and also functionally important core region primed for the final folding into the native, active state of the mature protein. The presence of the self-inhibiting precursor region provides yet another layer of regulation in the life cycle of this important cytokine.Nearly all cell types respond to interleukin (IL)-1β,⁴ in a very sensitive manner, via binding to the interleukin-1 receptor type 1 (IL-1RI) (2). Although essential in the immune response, overproduction of IL-1β can lead to both acute (sepsis) as well as chronic (rheumatoid arthritis, atherosclerosis, obesity, and diabetes) disease states (3). Thus, the expression, activation, and secretion of this cytokine are tightly controlled (4). Although many cell types express IL-1β, it is predominately produced and secreted by monocytes and macrophages (1). The protein is synthesized as a biologically inactive 269-residue precursor molecule, pro-interleukin-1β (pro-IL-1β), and the 153-residue active mature IL-1β is generated from the C-terminal domain. Processing of the proprotein involves the recently discovered NALP-1 and NALP-3 inflammasomes, which are responsible for activating procaspase-1 (5). The inflammasome function is integral in wound repair as well as for combating infection (6–9).In vivo, the 31-kDa pro-IL-1β precursor is processed to the active C-terminal 17-kDa form by the interleukin-1 converting enzyme, caspase-1 (10, 11). Caspase-1 is a cysteine protease that recognizes two cleavage sites in pro-IL-1β, the Asp²⁷↓Gly²⁸ and Asp¹¹⁶↓Ala¹¹⁷ peptide bonds (Fig. 1A). These cleavage sites are conserved across mammals (12–14). The activation pathway is believed to proceed with cleavage first at Asp²⁷↓Gly²⁸ (site 1) followed by Asp¹¹⁶↓Ala¹¹⁷ (site 2). These processing events lead to the generation of the mature, active IL-1β from the C-terminal domain of pro-IL-1β (15). After cleavage, the mature protein is exported via a cell-specific non-classical pathway (16). The events leading from caspase-1 activation to active IL-1β secretion are poorly understood and constitute an area of active research (16–20).Open in a separate windowFIGURE 1.A, a schematic of pro-interleukin-1β processing by caspase-1. The two caspase-1 cleavage sites are labeled by residue/number. The products for the cleavage scenario are represented as smaller blocks, and the final mature protein as the actual three-dimensional structure shown in blue (Protein Data Bank code 6I1B (74)). B, panel i, important features are highlighted on the structure of mature IL-1β. Residues Tyr⁶⁸ (residue 184 in pro-IL-1β) and Trp¹²⁰ (236 in pro-IL-1β) are indicated by red side chain stick representation. The two loops important for binding at the third Ig domain of the receptor are indicated by blue spheres (the basic/hydrophobic 90s loop, which encompasses residues 85–99 in mature and 201–216 in pro-IL-1β) and yellow spheres (the β-bulge, residues 46–53 and 162–169). The numbering corresponds to mature and pro-IL-1β, respectively. Panel ii, after rotating the structure 90°, the individual trefoils are labeled by color (trefoil 1 in orange, trefoil 2 in yellow, and trefoil 3 in blue). The structural features described in panel i maintain the same coloring. Panel iii, the two-dimensional splay diagram of the trefoils labeled by color as in panel ii showing the 3-fold symmetry of the secondary structure elements.The native structure of IL-1β is classified as a β-trefoil. The global protein-fold contains three pseudo-symmetric βββloopβ motifs that coalesce to form a six-stranded barrel with three hairpins that form a six-stranded cap closing one end of the barrel (see Fig. 1B) (21). Mature IL-1β refolds relatively slowly (22), accessing multiple routes including a major route with a detectable intermediate population (23, 24). Recently, this slow folding has been attributed to repacking of a functionally important loop (the β-bulge) in the mature protein (see Fig. 1B, i) (25–27). Although much information is known about the structure, folding, and function of mature IL-1β, there is little information available on pro-IL-1β, despite the central importance of this molecule in mediating critical inflammatory processes (28–30). What is known is that the presence of the N-terminal 116 amino acids results in a highly protease-sensitive protein with no biological activity (31). Folding of mature IL-1β is believed to occur after cleavage of pro-IL-1β in vivo. Therefore, structural analysis of the precursor is essential for a better understanding of the role the precursor region plays in regulating folding events leading to the generation of the eventual mature protein.The crystal structure of pro-IL-1β has not been determined, despite approximately 25 years of intensive efforts directed toward this goal, as a result of the dynamic nature of this molecule (32–34). Therefore, we used structure-sensitive methods to compare pro-IL-1β in reference to the mature protein. Optical methods in combination with hydrogen/deuterium exchange mass spectrometric analysis (DXMS) and enzymatic digestion were used to investigate how the N-terminal precursor region modulates the properties of the C-terminal mature domain. DXMS is a well established technique for characterizing proteins refractory to standard crystallographic or NMR structure determination techniques (35–37). Taken together, our results indicate that the N terminus inhibits folding to the fully active trefoil structure in the C-terminal region, but maintains the protein in a conformation that is primed for efficient folding upon release after caspase-1 cleavage.     

An investigation of the distal histidyl hydrogen bonds in oxyhemoglobin: effects of temperature, pH, and inositol hexaphosphate

On the basis of X-ray crystal structures and electron paramagnetic resonance (EPR) measurements, it has been inferred that the O(2) binding to hemoglobin is stabilized by the hydrogen bonds between the oxygen ligands and the distal histidines. Our previous study by multinuclear nuclear magnetic resonance (NMR) spectroscopy has provided the first direct evidence of such H-bonds in human normal adult oxyhemoglobin (HbO(2) A) in solution. Here, the NMR spectra of uniformly (15)N-labeled recombinant human Hb A (rHb A) and five mutant rHbs in the oxy form have been studied under various experimental conditions of pH and temperature and also in the presence of an organic phosphate, inositol hexaphosphate (IHP). We have found significant effects of pH and temperature on the strength of the H-bond markers, i.e., the cross-peaks for the side chains of the two distal histidyl residues, α58His and β63His, which form H-bonds with the O(2) ligands. At lower pH and/or higher temperature, the side chains of the distal histidines appear to be more mobile, and the exchange with water molecules in the distal heme pockets is faster. These changes in the stability of the H-bonds with pH and temperature are consistent with the changes in the O(2) affinity of Hb as a function of pH and temperature and are clearly illustrated by our NMR experiments. Our NMR results have also confirmed that this H-bond in the β-chain is weaker than that in the α-chain and is more sensitive to changes in pH and temperature. IHP has only a minor effect on these H-bond markers compared to the effects of pH and temperature. These H-bonds are sensitive to mutations in the distal heme pockets but not affected directly by the mutations in the quaternary interfaces, i.e., α(1)β(1) and/or α(1)β(2) subunit interface. These findings provide new insights regarding the roles of temperature, hydrogen ion, and organic phosphate in modulating the structure and function of hemoglobin in solution.     

Site mutations disrupt inter-helical H-bonds (alpha14W-alpha67T and beta15W-beta72S) involved in kinetic steps in the hemoglobin R-->T transition without altering the free energies of oxygenation

Three recombinant mutant hemoglobins (rHbs) of human normal adult hemoglobin (Hb A), rHb (alphaT67V), rHb (betaS72A), and rHb (alphaT67V, betaS72A), have been constructed to test the role of the tertiary intra-subunit H-bonds between alpha67T and alpha14W and between beta72S and beta15W in the cooperative oxygenation of Hb A. Oxygen-binding studies in 0.1 M sodium phosphate buffer at 29 degrees C show that rHb (alphaT67V), rHb (betaS72A), and rHb (alphaT67V, betaS72A) exhibit oxygen-binding properties similar to those of Hb A. The binding of oxygen to these rHbs is highly cooperative, with a Hill coefficient of approximately 2.8, compared to approximately 3.1 for Hb A. Proton nuclear magnetic resonance (NMR) studies show that rHb (alphaT67V), rHb (betaS72A), rHb (alphaT67V, betaS72A), and Hb A have similar quaternary structures in the alpha(1)beta(2) subunit interfaces. In particular, the inter-subunit H-bonds between alpha42Tyr and beta99Asp and between beta37Trp and alpha94Asp are maintained in the mutants in the deoxy form. There are slight perturbations in the distal heme pocket region of the alpha- and beta-chains in the mutants. A comparison of the exchangeable 1H resonances of Hb A with those of these three rHbs suggests that alpha67T and beta72S are H-bonded to alpha14W and beta15W, respectively, in the CO and deoxy forms of Hb A. The absence of significant free energy changes for the oxygenation process of these three rHbs compared to those of Hb A, even though the inter-helical H-bonds are abolished, indicates that these two sets of H-bonds are of comparable strength in the ligated and unligated forms of Hb A. Thus, the mutations at alphaT67V and betaS72A do not affect the overall energetics of the oxygenation process. The preserved cooperativity in the binding of oxygen to these three mutants also implies that there are multiple interactions involved in the oxygenation process of Hb A.     

Dynamics of cAPK type IIbeta activation revealed by enhanced amide H/2H exchange mass spectrometry (DXMS)

cAMP-dependent protein kinase (cAPK) is a key component in numerous cell signaling pathways. The cAPK regulatory (R) subunit maintains the kinase in an inactive state until cAMP saturation of the R-subunit leads to activation of the enzyme. To delineate the conformational changes associated with cAPK activation, the amide hydrogen/deuterium exchange in the cAPK type IIbeta R-subunit was probed by electrospray mass spectrometry. Three states of the R-subunit, cAMP-bound, catalytic (C)-subunit bound, and apo, were incubated in deuterated water for various lengths of time and then, prior to mass spectrometry analysis, subjected to digestion by pepsin to localize the deuterium incorporation. High sequence coverage (>99%) by the pepsin-digested fragments enables us to monitor the dynamics of the whole protein. The effects of cAMP binding on RIIbeta amide hydrogen exchange are restricted to the cAMP-binding pockets, while the effects of C-subunit binding are evident across both cAMP-binding domains and the linker region. The decreased amide hydrogen exchange for residues 253-268 within cAMP binding domain A and for residues 102-115, which include the pseudosubstrate inhibitory site, support the prediction that these two regions represent the conserved primary and peripheral C-subunit binding sites. An increase in amide hydrogen exchange for a broad area within cAMP-binding domain B and a narrow area within cAMP-binding domain A (residues 222-232) suggest that C-subunit binding transmits long-distance conformational changes throughout the protein.     

Ligand binding properties and structural studies of recombinant and chemically modified hemoglobins altered at beta 93 cysteine

To investigate the roles of beta93 cysteine in human normal adult hemoglobin (Hb A), we have constructed four recombinant mutant hemoglobins (rHbs), rHb (betaC93G), rHb (betaC93A), rHb (betaC93M), and rHb (betaC93L), and have prepared two chemically modified Hb As, Hb A-IAA and Hb A-NEM, in which the sulfhydryl group at beta93Cys is modified by sulfhydryl reagents, iodoacetamide (IAA) and N-ethylmaleimide (NEM), respectively. These variants at the beta93 position show higher oxygen affinity, lower cooperativity, and reduced Bohr effect relative to Hb A. The response of some of these Hb variants to allosteric effectors, 2,3-bisphosphoglycerate (2,3-BPG) and inositol hexaphosphate (IHP), is decreased relative to that of Hb A. The proton nuclear magnetic resonance (NMR) spectra of these Hb variants show that there is a marked influence on the proximal heme pocket of the beta-chain, whereas the environment of the proximal heme pocket of the alpha-chain remains unchanged as compared to Hb A, suggesting that higher oxygen affinity is likely to be determined by the heme pocket of the beta-chain rather than by that of the alpha-chain. This is further supported by NO titration of these Hbs in the deoxy form. For Hb A, NO binds preferentially to the heme of the alpha-chain relative to that of the beta-chain. In contrast, the feature of preferential binding to the heme of the alpha-chain becomes weaker and even disappears for Hb variants with modifications at beta93Cys. The effects of IHP on these Hbs in the NO form are different from those on HbNO A, as characterized by (1)H NMR spectra of the T-state markers, the exchangeable resonances at 14 and 11 ppm, reflecting that these Hb variants have more stability in the R-state relative to Hb A, especially rHb (betaC93L) and Hb A-NEM in the NO form. The changes of the C2 proton resonances of the surface histidyl residues in these Hb variants in both the deoxy and CO forms, compared with those of Hb A, indicate that a mutation or chemical modification at beta93Cys can result in conformational changes involving several surface histidyl residues, e.g., beta146His and beta2His. The results obtained here offer strong evidence to show that the salt bridge between beta146His and beta94Asp and the binding pocket of allosteric effectors can be affected as the result of modifications at beta93Cys, which result in the destabilization of the T-state and a reduced response of these Hbs to allosteric effectors. We further propose that the impaired alkaline Bohr effect can be attributed to the effect on the contributions of several surface histidyl residues which are altered because of the environmental changes caused by mutations and chemical modifications at beta93Cys.     

Human monocytes in culture synthesize and secrete lipoprotein lipase

Within the first day in culture, human monocytes begin to synthesize and secrete a triglyceride lipase. The designation of this activity as lipoprotein lipase is based upon: 1) a requirement of serum or apolipoprotein C-II for full activity; 2) inhibition by 1M NaCl or apolipoprotein C-III₂; 3) a pH optimum of 8; and 4) binding to endothelial cells that is releasable by heparin. The enzyme also exhibits immunological cross reactivity with antibody to purified bovine milk lipoprotein lipase as does human postheparin plasma lipoprotein lipase. Lymphocytes and polymorphonuclear leukocytes do not appear to contain this enzyme.     

Dynamic coupling between the SH2 domain and active site of the COOH terminal Src kinase, Csk

The SH2 domain is required for high catalytic activity in the COOH-terminal Src kinase (Csk). Previous solution studies suggest that a short peptide sequence, the SH2-kinase linker, provides a functional connection between the active site and the distal SH2 domain that could underlie this catalytic phenomenon. Substitutions in Phe183 (tyrosine, alanine, and glycine), a critical hydrophobic residue in the linker, result in large decreases in substrate turnover and large increases in the K(m) for ATP. Indeed, F183G possesses kinetic parameters that are similar to that for a truncated form of Csk lacking the SH2 domain, suggesting that a single mutation disrupts communication between this domain and the active site. Based on equilibrium and stopped-flow fluorescence experiments, the elevated K(m) values for the mutants are due to changes in the rates of phosphoryl transfer and not to reduced ATP-binding affinities. Based on hydrogen-deuterium exchange experiments, glycine substitution reduces flexibility in several polypeptide regions in Csk, tyrosine substitution increases flexibility, and alanine substitution leads to mixed effects compared to wild-type. Normal mode analysis indicates that Phe183 and its environment are under strain, a theoretical finding that supports the results of mutations. Overall, the data indicate that domain-domain interactions, controlled through the SH2-kinase linker, provide a dynamic balance within the Csk framework that is ideal for efficient phosphoryl transfer in the active site.