Disulfide connectivity of recombinant C-terminal region of human thrombospondin 2

The thrombospondin (TSP) family of extracellular glycoproteins consists of five members in vertebrates, TSP1 to -4 and TSP5/cartilage oligomeric matrix protein, and a single member in Drosophila. TSPs are modular multimeric proteins. The C-terminal end of a monomer consists of 3-6 EGF-like modules; seven tandem 23-, 36-, or 38-residue aspartate-rich, Ca(2+)-binding repeats; and an approximately 230-residue C-terminal sequence. The Ca(2+)-binding repeats and C-terminal sequence are spaced almost exactly the same in different TSPs and share many blocks of identical residues. We studied the C-terminal portion of human TSP2 from the third EGF-like module through the end of the protein (E3CaG2). E3CaG2, CaG2 lacking the EGF module, and Ca2 composed of only the Ca(2+)-binding repeats were expressed using recombinant baculoviruses and purified from conditioned media of insect cells. As previously described for intact TSP1, E3CaG2 bound Ca(2+) in a cooperative manner as assessed by equilibrium dialysis, and its circular dichroism spectrum was sensitive to the presence of Ca(2+). Mass spectrometry of the recombinant proteins digested with endoproteinase Asp-N revealed that disulfide pairing of the 18 cysteines in the Ca(2+)-binding repeats and C-terminal sequence is sequential, i.e. a 1-2, 3-4, 5-6, etc., pattern.     

Binding of human complement C8 to C9: role of the N-terminal modules in the C8 alpha subunit

Human C8 is one of five components of the membrane attack complex of complement (MAC). It is composed of a disulfide-linked C8alpha-gamma heterodimer and a noncovalently associated C8beta chain. The C8alpha and C8beta subunits contain a pair of N-terminal modules [thrombospondin type 1 (TSP1) + low-density lipoprotein receptor class A (LDLRA)] and a pair of C-terminal modules [epidermal growth factor (EGF) + TSP1]. The middle segment of each protein is referred to as the membrane attack complex/perforin domain (MACPF). During MAC formation, C8alpha mediates binding and self-polymerization of C9 to form a pore-like structure on the membrane of target cells. In this study, the portion of C8alpha involved in binding C9 was identified using recombinant C8alpha constructs in which the N- and/or C-terminal modules were either exchanged with those from C8beta or deleted. Those constructs containing the C8alpha N-terminal TSP1 or LDLRA module together with the C8alpha MACPF domain retained the ability to bind C9 and express C8 hemolytic activity. By contrast, those containing the C8alpha MACPF domain alone or the C8alpha MACPF domain and C8alpha C-terminal modules lost this ability. These results indicate that both N-terminal modules in C8alpha have a role in forming the principal binding site for C9 and that binding may be dependent on a cooperative interaction between these modules and the C8alpha MACPF domain.     

Chimeric and truncated forms of human complement protein C8 alpha reveal binding sites for C8 beta and C8 gamma within the membrane attack complex/perforin region.

Human C8 is one of five components of the membrane attack complex of complement. It is an oligomeric protein composed of three subunits (C8 alpha, C8 beta, and C8 gamma) that are derived from different genes. C8 alpha and C8 beta are homologous and both contain a pair of tandemly arranged N-terminal modules [thrombospondin type 1 (TSP1) + low-density lipoprotein receptor class A (LDLRA)], an extended middle segment referred to as the membrane attack complex/perforin region (MACPF), and a pair of C-terminal modules [epidermal growth factor (EGF) + TSP1]. During biosynthetic processing, C8 alpha and C8 gamma associate to form a disulfide-linked dimer (C8 alpha-gamma) that binds to C8 beta through a site located on C8 alpha. In this study, the location of binding sites for C8 beta and C8 gamma and the importance of the modules in these interactions were investigated by use of chimeric and truncated forms of C8 alpha in which module pairs were either exchanged for those in C8 beta or deleted. Results show that exchange or deletion of one or both pairs of modules does not abrogate the ability of C8 alpha to form a disulfide-linked dimer when coexpressed with C8 gamma in COS cells. Furthermore, each chimeric and truncated form of C8 alpha-gamma retains the ability to bind C8 beta; however, only those containing the TSP1 + LDLRA modules from C8 alpha are hemolytically active. These results indicate that binding sites for C8 beta and C8 gamma reside within the MACPF region of C8 alpha and that interaction with either subunit is not dependent on the modules. They also suggest that the N-terminal modules in C8 alpha are important for C9 binding and/or expression of C8 activity.     

Interaction between the C8 alpha-gamma and C8 beta subunits of human complement C8: role of the C8 beta N-terminal thrombospondin type 1 module and membrane attack complex/perforin domain

Human C8 is one of five complement components (C5b, C6, C7, C8, and C9) that interact to form the cytolytic membrane attack complex (MAC). It is an oligomeric protein composed of a disulfide-linked C8alpha-gamma heterodimer and a noncovalently associated C8beta chain. C8alpha and C8beta are homologous; both contain an N-terminal thrombospondin type 1 (TSP1) module, a low-density lipoprotein receptor class A (LDLRA) module, an extended central segment referred to as the membrane attack/perforin (MACPF) domain, an epidermal growth factor (EGF) module, and a second TSP1 module at the C-terminus. In this study, the segment of C8beta that confers binding specificity toward C8alpha-gamma was identified using recombinant C8beta constructs in which the N- and/or C-terminal modules were deleted or exchanged with those from C8alpha. Constructs were tested for their ability to bind C8alpha-gamma in solution and express C8 hemolytic activity. Binding to C8alpha-gamma was found to be dependent on the TSP1 + LDLRA + MACPF segment of C8beta. Within this segment, the TSP1 module and MACPF domain are principally involved and act cooperatively to mediate binding. Results from activity assays suggest that residues within this segment also mediate binding and incorporation of C8 into the MAC.     

Solution structure and dynamics of a prototypical chordin-like cysteine-rich repeat (von Willebrand Factor type C module) from collagen IIA

Chordin-like cysteine-rich (CR) repeats (also referred to as von Willebrand factor type C (VWC) modules) have been identified in approximately 200 extracellular matrix proteins. These repeats, named on the basis of amino acid conservation of 10 cysteine residues, have been shown to bind members of the transforming growth factor-beta (TGF-beta) superfamily and are proposed to regulate growth factor signaling. Here we describe the intramolecular disulfide bonding, solution structure, and dynamics of a prototypical chordin-like CR repeat from procollagen IIA (CR(ColIIA)), which has been previously shown to bind TGF-beta1 and bone morphogenetic protein-2. The CR(ColIIA) structure manifests a two sub-domain architecture tethered by a flexible linkage. Initial structures were calculated using RosettaNMR, a de novo prediction method, and final structure calculations were performed using CANDID within CYANA. The N-terminal region contains mainly beta-sheet and the C-terminal region is more irregular with the fold constrained by disulfide bonds. Mobility between the N- and C-terminal sub-domains on a fast timescale was confirmed using NMR relaxation measurements. We speculate that the mobility between the two sub-domains may decrease upon ligand binding. Structure and sequence comparisons have revealed an evolutionary relationship between the N-terminal sub-domain of the CR module and the fibronectin type 1 domain, suggesting that these domains share a common ancestry. Based on the previously reported mapping of fibronectin binding sites for vascular endothelial growth factor to regions containing fibronectin type 1 domains, we discuss the possibility that this structural homology might also have functional relevance.     

The NTR module: domains of netrins, secreted frizzled related proteins, and type I procollagen C-proteinase enhancer protein are homologous with tissue inhibitors of metalloproteases.

Using homology search, structure prediction, and structural characterization methods we show that the C-terminal domains of (1) netrins, (2) complement proteins C3, C4, C5, (3) secreted frizzled-related proteins, and (4) type I procollagen C-proteinase enhancer proteins (PCOLCEs) are homologous with the N-terminal domains of (5) tissue inhibitors of metalloproteinases (TIMPs). The proteins harboring this netrin module (NTR module) fulfill diverse biological roles ranging from axon guidance, regulation of Wnt signaling, to the control of the activity of metalloproteases. With the exception of TIMPs, it is not known at present what role the NTR modules play in these processes. In view of the fact that the NTR modules of TIMPs are involved in the inhibition of matrixin-type metalloproteases and that the NTR module of PCOLCEs is involved in the control of the activity of the astacin-type metalloprotease BMP1, it seems possible that interaction with metzincins could be a shared property of NTR modules and could be critical for the biological roles of the host proteins.     

Grafting an RGD motif onto an epidermal growth factor-like module: chemical synthesis and functional characterization of the chimeric molecule.

A novel protein was engineered by inserting the GRGDS motif of fibronectin within the 14-residue loop of the EGF-like module from human complement protease C1r. The resulting chimeric EGF-RGD module (52 residues, three disulfide bridges) was assembled by automated solid-phase synthesis using the t-Boc strategy. Using reduced/oxidized glutathione, the EGF-RGD module was folded as efficiently as the natural C1r-EGF module, resulting in formation of the appropriate disulfide bridge pattern as shown by mass spectrometry and N-terminal sequence analyses of thermolytic fragments. Circular dichroism and NMR measurements provided further indication that introduction of the GRGDS motif had no significant effect on the folding. Using Chinese Hamster Ovary (CHO) cells bearing the integrin receptors specific for fibronectin and vitronectin, EGF-RGD was shown to induce cell adhesion via the introduced GRGDS motif. Cell binding was inhibited specifically and efficiently by the synthetic peptide GRGDSP and by fibronectin, and to a much lesser extent by vitronectin, whereas the monoclonal antibody PB1 directed to the alpha5 subunit of alpha5beta1 integrin had no effect. The ability of EGF-RGD to trigger significant cell spreading and intracellular signaling was also demonstrated using immunofluorescence and confocal microscopy.     

The different energetic state of the intra A-chain/domain disulfide of insulin and insulin-like growth factor 1 is mainly controlled by their B-chain/domain

Insulin and insulin-like growth factor 1 (IGF-1) share homologous sequence, similar three-dimensional structure, and weakly overlapping biological activity, but different folding information is stored in their homologous sequences: the sequence of insulin encodes one unique thermodynamically stable three-dimensional structure while that of IGF-1 encodes two disulfide isomers with different three-dimensional structure but similar thermodynamic stability. Their different folding behavior probably resulted from the different energetic state of the intra A-chain/domain disulfide: the intra A-chain disulfide of insulin is a stable bond while that of IGF-1 is a strained bond with high energy. To find out the sequence determinant of the different energetic state of their intra A-chain/domain disulfide, the following experiments were carried out. First, a local chimeric single-chain insulin (PIP) with the A8-A10 residues replaced by the corresponding residues of IGF-1 was prepared. Second, the disulfide stability of two global hybrids of insulin and IGF-1, Ins(A)/IGF-1(B) and Ins(B)/IGF-1(A), was investigated. The local segment swap had no effect on the fidelity of disulfide pairing and the disulfide stability of PIP molecule although the swapped segment is close to the intra A-chain/domain disulfide. In redox buffer which favors the disulfide formation for most proteins, Ins(A)/IGF-1(B) cannot form and maintain its native disulfides just like that of IGF-1, while the disulfides of Ins(B)/IGF-1(A) are stable in the same condition. One major equilibrium intermediate with two disulfides of Ins(A)/IGF-1(B) was purified and characterized. V8 endoproteinase cleavage and circular dichroism analysis suggested that the intra A-chain/domain disulfide was reduced in the intermediate. Our present results suggested that the energetic state of the intra A-chain/domain disulfide of insulin and IGF-1 was not controlled by the A-chain/domain sequence close to this disulfide but was mainly controlled by the sequence of the B-chain/domain.     

Folding and binding integrity of variants of a prototype ligand-binding module from the LDL receptor possessing multiple alanine substitutions

The LA repeats that comprise the ligand-binding domain of the LDL receptor are among the most common autonomously structured extracellular modules found in the nonredundant protein sequence database. Here, we investigate the information content of the amino acid sequence of a typical LA module by constructing sequences with alanine residues at nonconserved positions in the module. Starting with the sequence of the fifth ligand-binding repeat of the LDL receptor (LA5), we created generic LA modules with alanine substitutions of nonconserved residues in only the N-terminal lobe, only the C-terminal lobe, and throughout both lobes of the module. LA variants with alanine residues at as many as 18 of 37 positions fold to a preferred disulfide isomer in the presence of calcium. Indeed, the six cysteines, the C-terminal calcium coordinating residues, two hydrophobic residues involved in packing, two glycines, and five other residues that form side chain-intramodule hydrogen bonds are alone sufficient to specify the fold of an LA module when alanine residues are present at all other positions. The LA variants with multiple alanines in either the N- or C-terminal lobe were then exploited to identify residues of LA5 that contribute to the binding of apoE-containing ligands in LDL receptor-derived "minireceptors", implicating nonconserved residues of the N-terminal lobe of LA5 in recognition of apoE-DMPC. Our library of LA modules with multiple alanine substitutions should be generally useful for probing the roles of nonconserved side chains in ligand recognition by proteins of the LDL receptor family.     

Independently melting modules and highly structured intermodular junctions within complement receptor type 1.

A segment of complement receptor type 1 (CR1) corresponding to modules 15-17 was overexpressed as a functionally active recombinant protein with N-glycosylation sites ablated by mutagenesis (referred to as CR1 approximately 15-17(-)). A protein consisting of modules 15 and 16 and another corresponding to module 16 were also overexpressed. Comparison of heteronuclear nuclear magnetic resonance (NMR) spectra for the single, double, and triple module fragments indicated that module 16 makes more extensive contacts with module 15 than with module 17. A combination of NMR, differential scanning calorimetry, circular dichroism, and tryptophan-derived fluorescence indicated a complex unfolding pathway for CR1 approximately 15-17(-). As temperature or denaturant concentration was increased, the 16-17 junction appeared to melt first, followed by the 15-16 junction, and module 17 itself; finally, modules 15 and 16 became denatured. Modules 15 and 16 adopted an intermediate state prior to total denaturation. These results are compared with a previously published study [Clark, N. S., Dodd, I, Mossakowska, D. E., Smith, R. A. G., and Gore, M. G. (1996) Protein Eng. 9, 877-884] on a fragment consisting of the N-terminal three CR1 modules which appeared to melt as a single unit.     

Biophysical characterization,including disulfide bond assignments,of the anti-angiogenic type 1 domains of human thrombospondin-1

Thrombospondin-1 (TSP1), a modular secreted glycoprotein, possesses anti-angiogenic activity both in vitro and in vivo. This activity has been localized to the thrombospondin type 1 repeats/domains (TSR). A TSP1 monomer contains three TSRs, each with a hydrophobic cluster with three conserved tryptophans (WxxWxxW), a basic cluster with two conserved arginines (RxR), and six conserved cysteines. Using the baculovirus system, we expressed TSRs of human TSP1 as either the three domains in tandem (P123) or the third domain alone (P3) and demonstrated that both P123 and P3 at nanomolar concentrations inhibit either basic fibroblast-growth-factor or sphingosine-1-phosphate induced endothelial cell migration. Far-UV circular dichroism (CD) indicated that P123 and P3 have a common global fold that is very similar to properdin, a protein with six TSRs. Near-UV CD and fluorescence quenching studies indicated the conserved tryptophans are in a structured, partially solvent-accessible, positively charged environment. N-terminal sequence and mass spectrometry analysis of trypsin-digested TSRs indicated that the RFK linker sequence between P1 and P2 is readily proteolyzed and the conserved arginines are solvent accessible. By a combination of proteolysis and mass spectrometry, the recombinant TSRs were determined to be fully disulfide bonded with a connectivity of 1-5, 2-6, and 3-4 (cysteines are numbered sequentially from N- to C-terminus). TSRs are found in numerous extracellular proteins. These TSRs share the hydrophobic and basic clusters of the TSP TSRs but some have quite different placement of cysteine residues. We propose a sorting of TSRs into six groups that reconciles our results with information about other TSRs.     

Enthalpic and entropic contributions mediate the role of disulfide bonds on the conformational stability of interleukin-4

The role of disulfide bridges in the structure, stability, and folding pathways of proteins has been the subject of wide interest in the fields of protein design and engineering. However, the relative importance of entropic and enthalpic contributions for the stabilization of proteins provided by disulfides is not always clear. Here, we perform a detailed analysis of the role of disulfides in the conformational stability of human Interleukin-4 (IL4), a four-helix bundle protein. In order to evaluate the contribution of two out of the three disulfides to the structure and stability of IL4, two IL4 mutants, C3T-IL4 and C24T-IL4, were used. NMR and ANS binding experiments were compatible with altered dynamics and an increase of the nonpolar solvent-accessible surface area of the folded state of the mutant proteins. Chemical and thermal unfolding experiments followed by fluorescence and circular dichroism revealed that both mutant proteins have lower conformational stability than the wild-type protein. Transition temperatures of unfolding decreased 14 degrees C for C3T-IL4 and 10 degrees C for C24T-IL4, when compared to WT-IL4, and the conformational stability, at 25 degrees C, decreased 4.9 kcal/mol for C3T-IL4 and 3.2 kcal/mol for C24T-IL4. Interestingly, both the enthalpy and the entropy of unfolding, at the transition temperature, decreased in the mutant proteins. Moreover, a smaller change in heat capacity of unfolding was also observed for the mutants. Thus, disulfide bridges in IL4 play a critical role in maintaining the thermodynamic stability and core packing of the helix bundle.     

Complex of pregnancy-associated plasma protein-A and the proform of eosinophil major basic protein. Disulfide structure and carbohydrate attachment

Pregnancy-associated plasma protein-A (PAPP-A) is a metzincin superfamily metalloproteinase responsible for cleavage of insulin-like growth factor-binding protein-4, thus causing release of bound insulin-like growth factor. PAPP-A is secreted as a dimer of 400 kDa but circulates in pregnancy as a disulfide-bound 500-kDa 2:2 complex with the proform of eosinophil major basic protein (pro-MBP), recently shown to function as a proteinase inhibitor of PAPP-A. Except for PAPP-A2, PAPP-A does not share global similarity with other proteins. Three lin-notch (LNR or LIN-12) modules and five complement control protein modules (also known as SCR modules) have been identified in PAPP-A by sequence similarity with other proteins, but no data are available that allow unambiguous prediction of disulfide bonds of these modules. To establish the connectivities of cysteine residues of the PAPP-A.pro-MBP complex, biochemical analyses of peptides derived from purified protein were performed. The PAPP-A subunit contains a total of 82 cysteine residues, of which 81 have been accounted for. The pro-MBP subunit contains 12 cysteine residues, of which 10 have been accounted for. Within the 2:2 complex, PAPP-A is dimerized by a single disulfide bond; pro-MBP is dimerized by two disulfides, and each PAPP-A subunit is connected to a pro-MBP subunit by two disulfide bonds. All other disulfides are intrachain bridges. We also show that of 13 potential sites for N-linked carbohydrate substitution of the PAPP-A subunit, 11 are occupied. The large number of disulfide bonds of the PAPP-A.pro-MBP complex imposes many restraints on polypeptide folding, and knowledge of the disulfide pattern of PAPP-A will facilitate structural studies based on recombinant expression of individual, putative PAPP-A domains. Furthermore, it will allow rational experimental design of functional studies aimed at understanding the formation of the PAPP-A.pro-MBP complex, as well as the inhibitory mechanism of pro-MBP.     

Chemical and physical properties of the disulfides of bovine neurophysin-II.

Bovine neurophysin-II is shown to be very susceptible to partial reduction in the absence of urea. Reduction of an average of one disulfide leads to major changes in conformation and disulfide optical activity, manifest in part by pronounced far-uv ellipticity changes, complete loss of the 248-nm ellipticity band, and a shift of the 278-nm ellipticity band to shorter wavelengths with loss of half its intensity; the reduction process generates a mixture of products and appears to be accompanied by disulfide interchange. The circular dichroism data indicate that the disulfide(s) most susceptible to reduction or interchange are either the principal contributors to the 248- and 278-nm ellipticity bands or that the optical activity of other disulfides is dependent on their integrity. Peptides that bind to the hormone-binding site of neurophysin-II protect against reduction. On reoxidation of partially reduced neurophysin-II there is only a partial return of the native circular dichroism spectrum and electrophoretic behavior. The percentage of native protein in samples reoxidized following different degrees of reduction was estimated by comparison of the circular dichroism spectra of these samples with those of the fractionated native and denatured components of monoreduced-reoxidized neurophysin. Under our reoxidation conditions, less than 50% native protein was found in monoreduced-reoxidized neurophysin and less than 10% native protein was found in completely reduced-reoxidized neurophysin. The results are interpreted with qualified reference to a model in which one or more disulfides are "strained" in the native state and in which the native protein is unstable relative to species in which the disulfides are differently paired.     

Interactions among Stalk Modules of Thrombospondin-1

Thrombospondin-1 is a trimeric, modular calcium-binding glycoprotein. The subunit is composed of an N-terminal module; oligomerization domain; stalk modules including a von Willebrand factor type C module, three properdin or thrombospondin type 1 repeat (TSR) modules, and two thrombospondin-type EGF-like modules; and a C-terminal signature domain comprising single copies of the epidermal growth factor (EGF)-like, wire, and lectin-like modules. Conformational changes in the signature domain influence ligand binding to the N-terminal modules. Interactions have been demonstrated among the modules of the signature domain and the thrombospondin-type EGF-like modules. We have extended this analysis to the rest of the stalk modules. Differential scanning calorimetry revealed interactions between the most C-terminal TSR module and the EGF-like modules. Calorimetry and differences in expression levels of single versus tandem modules indicated that the three TSRs interact with each other as well. No evidence of interactions between the von Willebrand factor type C and TSR modules were detected by differential scanning calorimetry, circular dichroism, or intrinsic fluorescence. These results indicate that the TSR and thrombospondin-type EGF-like stalk modules act as a unit that may relay conformational information between the N-terminal and C-terminal parts of the protein.Thrombospondin-1 (TSP-1)² is a major secreted protein of platelets that plays multiple roles after vascular injury (1, 2). TSPs are a family of multimodular, calcium-binding, extracellular glycoproteins. There are five family members in tetropods, each of which has a specific pattern of expression in embryonic and adult tissues (3). TSPs have two unique features, a signature domain comprising single copies of EGF-like, Ca²⁺-binding wire, and lectin-like modules and the TSP-type EGF-like module in which Cys⁴ and Cys⁵ are separated by two rather than one residue (3, 4). The family falls into two groups: A or trimeric TSPs, TSP-1 and TSP-2; and B or pentameric TSPs, TSP-3, TSP-4, and TSP-5. As depicted in Fig. 1, a subunit of the group A TSPs is composed of an N-terminal module tethered to an oligomerization domain, a von Willebrand Factor type C (vWF-C) module, three properdin or TSP type 1 repeat (TSR) modules, two TSP-type EGF-like modules, and the signature domain (3, 4). Subunits of group B TSPs lack vWF-C and TSR modules and have an extra TSP-type EGF-like module (4). Multiple interactions have been demonstrated among the modules of the signature domain of Ca²⁺-replete TSP-2 and TSP-5 (5, 6) and between the signature domain wire and second TSP-type EGF-like module of Ca²⁺-replete TSP-2 (5, 7).Open in a separate windowFIGURE 1.Schematics of (A) TSP-1 stalk modules studied in this paper, (B) TSP-1 in its Ca²⁺-depleted conformation, and (C) TSP-1 in its Ca²⁺-replete formation. Parts of TSP-1 in panels A and B are labeled as follows: N, N-terminal module; T, tether; C, vWF-C module; P, properdin or TSR module, E, EGF-like module; wire, Ca²⁺-binding repeats with 26 Ca²⁺-binding sites; and L, lectin-like module. The TSP-type EGF-like modules, E1 and E2, contain central shading. Sites of binding to heparin sulfate proteoglycan (HSPG), latent transforming growth factor-β (TGF), and CD36 are indicated in panel C. The schematics have been drawn based on structures described in the text. Sites of fucosylation of TSRs are indicated by open diamonds, and inter-module CPIXG sequences between P2 and P3 and between P3 and E1 are indicated with dots. As per the “Discussion,” changes in conformation and charge density of the signature domain due to gain or loss of Ca²⁺ are proposed to be propagated throughout trimeric TSP-1 by the stalk modules.TSP-1 has a distinctive appearance when examined by rotary shadowing electron microscopy: three bunched globules, which are thought to be the N-terminal modules, are connected by three stalks to three larger globules thought to be the C-terminal signature domains (4). Rotary shadowing electron microscopy demonstrates a striking conformational change upon removal of Ca²⁺ from the C-terminal signature domain with apparent lengthening of the stalk and loss of size of the C-terminal globules (8–10). Considerations of structures of the parts of TSP-1 indicate that the vWF-C, TSR, and TSP-type EGF-like modules form the stalk in Ca²⁺-replete TSP-1 (4), as depicted in Fig. 1. Immunochemical studies suggest that lengthening of the stalk is due, at least in part, to unraveling of two of the 13 Ca²⁺-binding repeats of the wire module (11).Removal of Ca²⁺ from binding sites on the C-terminal signature domain impacts binding of ligands or antibodies to the N-terminal modules of TSP-1 (12). The N700S polymorphism in TSP-1 that alters coordination of Ca²⁺ by the first Ca²⁺-binding wire repeat (13) also impacts interactions of the N-terminal modules with ligands (14). These observations indicate that TSP-1 possesses an allosteric mechanism whereby changes in the C-terminal signature domain are transmitted to the N-terminal modules. We have reported that the two TSP-type EGF-like modules and the signature domain EGF-like module interact with each other, suggesting a mechanism by which conformational changes in the signature domain can be propagated N-terminal as far as the first TSP-type EGF-like module (15). We have now explored the potential of EGF-like modules to work with TSR and vWF-C modules to transmit conformational information between the two ends of TSP-1.     

The interaction of recombinant subdomains of the procollagen C-proteinase with procollagen I provides a quantitative explanation for functional differences between the two splice variants, mammalian tolloid and bone morphogenetic protein 1

The procollagen C-proteinase (PCP) is a zinc peptidase of the astacin family and the metzincin superfamily. The enzyme removes the C-terminal propeptides of fibrillar procollagens and activates other matrix proteins. Besides its catalytic protease domain, the procollagen C-proteinase contains several C-terminal CUB modules (named after complement factors C1r and C1s, the sea urchin UEGF protein, and BMP-1) and EGF-like domains. The two major splice forms of the C-proteinase differ in their overall domain composition. The longer variant, termed mammalian tolloid (mTld, i.e., PCP-2), has the protease-CUB1-CUB2-EGF1-CUB3-EGF2-CUB4-CUB5 composition, whereas the shorter form termed bone morphogenetic protein 1 (BMP-1, i.e., PCP-1) ends after the CUB3 domain. Two related genes encode proteases similar to mTld in humans and have been termed mammalian tolloid like-1 and -2 (mTll-1 and mTll-2, respectively). For mTll-1, it has been shown that it has C-proteinase activity. We demonstrate that recombinant EGF1-CUB3, CUB3, CUB3-EGF2, EGF2-CUB4, and CUB4-CUB5 modules of the procollagen C-proteinase can be expressed in bacteria and adopt a functional antiparallel beta-sheet conformation. As shown by surface plasmon resonance analysis, the modules bind to procollagen I in a 1:1 stoichiometry with dissociation constants (K(D)) ranging from 622.0 to 1.0 nM. Their binding to mature collagen I is weaker by at least 1 order of magnitude. Constructs containing EGF domains bind more strongly than those consisting of CUB domains only. This suggests that a combination of CUB and EGF domains serves as the minimal functional unit. The binding affinities of the EGF-containing modules for procollagen increase in the order EGF1-CUB3 < CUB3-EGF2 < EGF2-CUB4. In the context of the full length PCP, this implies that a given module has an affinity that continues to increase the more C-terminally the module is located within the PCP. The tightest binding module, EGF2-CUB4 (K(D) = 1.0 nM), is only present in mTld, which might provide a quantitative explanation for the different efficiencies of BMP-1 and mTld in procollagen C-proteinase activity.     

Refolding of amphioxus insulin-like peptide: implications of a bifurcating evolution of the different folding behavior of insulin and insulin-like growth factor 1

Insulin and insulin-like growth factor 1 (IGF-1) share high sequence homology, but their folding behaviors are significantly different: insulin folds into one unique thermodynamically controlled structure, while IGF-1 folds into two thermodynamically controlled disulfide isomers. However, the origin of their different folding behaviors is still elusive. The amphioxus insulin-like peptide (ILP) is thought to be the common ancestor of insulin and IGF-1. A recombinant single-chain ILP has been expressed previously, and now its folding behavior is investigated. The folding behavior of ILP shows the characteristics of both insulin and IGF-1. On one hand, two thermodynamically controlled disulfide isomers of ILP have been identified; on the other hand, the content of isomer 1 (its disulfides are deduced identical to those of swap IGF-1) is much less than that of isomer 2 (its disulfides are deduced identical to those of native IGF-1); that is, more than 96% of ILP folds into the native structure. The present results suggest that the different folding behaviors of insulin and IGF-1 are acquired through a bifurcating evolution: the tendency of forming the thermodynamically controlled non-native disulfide isomer is diminished during evolution from ILP to insulin, while this tendency is amplified during evolution from ILP to IGF-1. Moreover, the N-terminal Gln residue of ILP can spontaneously form a pyroglutamate residue, and its cyclization has a significant effect on the folding behavior of ILP: the percentage of isomer 1 is approximately 2-fold that of isomer 1 of the noncyclized ILP; that is, isomer 1 becomes more favored when the N-terminal residue of ILP is cyclized. So, we deduce that the N-terminal residues have a significant effect on the folding properties of insulin, IGF-1, and ILP.     

The Cytoplasm-Entry Domain of Antibacterial CdiA Is a Dynamic α-Helical Bundle with Disulfide-Dependent Structural Features

Many Gram‐negative bacterial species use contact-dependent growth inhibition (CDI) systems to compete with neighboring cells. CDI⁺ strains express cell-surface CdiA effector proteins, which carry a toxic C-terminal region (CdiA-CT) that is cleaved from the effector upon transfer into the periplasm of target bacteria. The released CdiA-CT consists of two domains. The C-terminal domain is typically a nuclease that inhibits cell growth, and the N-terminal “cytoplasm-entry” domain mediates toxin translocation into the target-cell cytosol. Here, we use NMR and circular dichroism spectroscopic approaches to probe the structure, stability, and dynamics of the cytoplasm-entry domain from Escherichia coli STEC_MHI813. Chemical shift analysis reveals that the CdiA-CT^MHI813 entry domain is composed of a C-terminal helical bundle and a dynamic N-terminal region containing two disulfide linkages. Disruption of the disulfides by mutagenesis or chemical reduction destabilizes secondary structure over the N-terminus, but has no effect on the C-terminal helices. Although critical for N-terminal structure, the disulfides have only modest effects on global thermodynamic stability, and the entry domain exhibits characteristics of a molten globule. We find that the disulfides form in vivo as the entry domain dwells in the periplasm of inhibitor cells prior to target-cell recognition. CdiA-CT^MHI813 variants lacking either disulfide still kill target bacteria, but disruption of both bonds abrogates growth inhibition activity. We propose that the entry domain's dynamic structural features are critical for function. In its molten globule-like state, the domain resists degradation after delivery, yet remains pliable enough to unfold for membrane translocation.