Your search keyword '"Pangburn MK"' showing total 8 results

1. Identification of intermolecular bonds between human factor B and Cobra Venom Factor important for C3 convertase stability.

Author

Hew BE, Pangburn MK, Vogel CW, and Fritzinger DC

Subjects

Animals, Complement C3, Complement Factor H, Humans, Recombinant Fusion Proteins, Complement C3-C5 Convertases chemistry, Complement Factor B chemistry, Elapid Venoms chemistry

Abstract

Cobra venom factor (CVF) is the complement-activating protein in cobra venom. CVF is a structural and functional analog of complement component C3. CVF, like C3b, forms a convertase with factor B. This bimolecular complex CVF, Bb is an enzyme that cleaves C3 and C5. However, CVF, Bb exhibits significantly different functional properties from C3b,Bb. Whereas both, CVF, Bb and C3b, Bb exhibit spontaneous decay-dissociation into the respective subunits, thereby eliminating the enzymatic activity, the CVF, Bb convertase is physico-chemically far more stable, decaying with a half-life that is more than two orders of magnitude slower than that of C3b,Bb. In addition, CVF, Bb is completely resistant to inactivation by Factors H and I. These two properties of CVF, Bb allow continuous activation of C3 and C5, and complement depletion in serum. In order to understand the structural basis for the physico-chemical stability of CVF,Bb, we have created recombinant hybrid proteins of CVF and human C3, based on structural differences between CVF and human C3b in the C-terminal C345C domain. Here we describe three human C3/CVF hybrid proteins which differ in only one, two, or five amino acid residues from earlier described hybrid proteins. In all three cases, the hybrid proteins containing CVF residues form more stable convertases, and exhibit stronger complement-depletion activity than hybrid proteins with human C3 residues. Three bonds between CVF residues and Factor Bb residues could be identified by crystallographic modeling that contribute to the greater stability of the convertases., (Copyright © 2020 Elsevier Ltd. All rights reserved.)

Published

2020

2. Identification of functionally important amino acid sequences in cobra venom factor using human C3/Cobra venom factor hybrid proteins.

Author

Hew BE, Fritzinger DC, Pangburn MK, and Vogel CW

Subjects

Amino Acid Sequence, Humans, Recombinant Fusion Proteins chemistry, Sequence Analysis, Protein, Structure-Activity Relationship, Complement C3 chemistry, Elapid Venoms chemistry

Abstract

Cobra venom factor (CVF) is the complement-activating protein in cobra venom. CVF is a structural and functional analog of complement component C3. CVF, like C3b, forms a convertase with factor B. This bimolecular complex CVF,Bb is an enzyme that cleaves C3 and C5. However, CVF,Bb exhibits significantly different functional properties from C3b,Bb. The CVF,Bb convertase is physico-chemically very stable, and completely resistant to an activation by Factors H and I. These two properties, in contrast to C3b,Bb, allow continuous activation of C3 and C5, and complement depletion in serum. In order to understand the structural basis for the functional differences between CVF and C3, we have created several hybrid proteins of CVF and human C3. Here we report that replacing the C-terminal 168 amino acid residues of human C3 with the corresponding residues from CVF results in a hybrid protein (HC3-1496) which is essentially a human C3 derivative exhibiting the functional properties of CVF. This result demonstrates that the important structures for the CVF-specific functions reside within the C-terminal 168 amino acid residues of CVF. We further demonstrate that reverting the 46 C-terminal CVF residues of HC3-1496 to human C3 sequence results in a hybrid protein (HC3-1496/1617) that exhibits a physico-chemically unstable convertase with only residual complement depleting activity. This result demonstrates that most, but not all, structural requirements for CVF activity reside within the 46 C-terminal amino acid residues. We also investigated the potential role of position 1633, which is an acidic residue in human C3 (glutamic acid) but a basic amino acid residue (histidine) in CVF. However, the charge at position 1633 appears to be of no functional relevance. Exchanging the neutral amino acids present in CVF at positions 1499 and 1501 with the two charged amino acids at these positions in human C3 (aspartic acid and lysine) resulted in a hybrid protein that exhibited significantly slower convertase formation although both binding to Factor B and C3 cleavage was not affected, demonstrating that the charged amino acid residues at these two positions interfere with the formation of the convertase. In conclusion, our work demonstrates that hybrid proteins of human C3 and CVF present valuable tools to identify functionally important amino acid residues in CVF., (Copyright © 2019 Elsevier Ltd. All rights reserved.)

Published

2019

3. Complement nomenclature 2014.

Author

Kemper C, Pangburn MK, and Fishelson Z

Subjects

Animals, Humans, Complement System Proteins classification, Terminology as Topic

Abstract

The first update since 1981 of the nomenclature used in the field of complement has been completed by the Complement Nomenclature Committee established under the auspices of the International Complement Society (ICS) and by the boards of the ICS and the European Complement Network (ECN). Recommended names of complement pathways, proteins, protein complexes, protein fragments and receptors are listed. Authors are urged to use these names in their published and presented works., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2014

4. Complement control protein factor H: the good, the bad, and the inadequate.

Author

Ferreira VP, Pangburn MK, and Cortés C

Subjects

Animals, Complement C3b immunology, Complement C3b metabolism, Complement C3d immunology, Complement C3d metabolism, Complement Factor H genetics, Complement Factor H metabolism, Humans, Models, Immunological, Protein Binding, Complement Factor H immunology, Complement Pathway, Alternative immunology, Immune Evasion immunology

Abstract

The complement system is an essential component of the innate immune system that participates in elimination of pathogens and altered host cells and comprises an essential link between the innate and adaptive immune system. Soluble and membrane-bound complement regulators protect cells and tissues from unintended complement-mediated injury. Complement factor H is a soluble complement regulator essential for controlling the alternative pathway in blood and on cell surfaces. Normal recognition of self-cell markers (i.e. polyanions) and C3b/C3d fragments is necessary for factor H function. Inadequate recognition of host cell surfaces by factor H due to mutations and polymorphisms have been associated with complement-mediated tissue damage and disease. On the other hand, unwanted recognition of pathogens and altered self-cells (i.e. cancer) by factor H is used as an immune evasion strategy. This review will focus on the current knowledge related to these versatile recognition properties of factor H., (Copyright 2010 Elsevier Ltd. All rights reserved.)

Published

2010

5. Role of the C3b-binding site on C4b-binding protein in regulating classical pathway C5 convertase.

Author

Rawal N and Pangburn MK

Subjects

Animals, Binding Sites immunology, Chickens, Complement C3b physiology, Complement C4b-Binding Protein physiology, Humans, Protein Binding immunology, Complement C3b metabolism, Complement C4b-Binding Protein metabolism, Complement C5 Convertase, Classical Pathway metabolism

Abstract

A high affinity C5 convertase is generated when a C3 convertase deposits additional C3b molecules on and around itself thereby switching the substrate specificity of C3 convertase from C3 to C5. In the present study the role of the additional C3b molecules in influencing the regulation of classical pathway C5 convertase by C4b-binding protein (C4BP) was examined and compared to its precursor, the C3 convertase. Determination of IC(50) for inhibiting formation of the high affinity C5 convertase and for enhancing its decay (72 and 20 nM) were found to be similar to those obtained for the surface-bound C3 convertase (35 and 11 nM). No difference was observed in the cofactor activity of C4BP for surface-bound C4b alone or when in complex with C3b. Analysis of binding interactions between C4BP and EAC1,C4b cells revealed an average apparent dissociation constant (12 nM) similar to that obtained with EAC1,C4b cells with C3b on them (11 nM). Increasing the C4b or C3b density on the cell surface did not alter the affinity of C4BP. The data suggest that C4BP regulates the C5 convertase by mechanisms similar to those observed for the C3 convertase. Since the IC(50) for inhibiting formation of the soluble C3 convertase (5 nM) is 50-80-fold below the normal serum concentration of C4BP (250-400 nM), C4BP in blood effectively prevents formation of classical pathway C3 convertase in the fluid phase. Although deposition of additional C3b molecules is necessary to convert a C3 convertase to a high affinity C5 convertase, the additional C3b molecules play no role in the regulation of C5 convertase by C4BP.

Published

2007

6. The contrasting mechanisms of serum resistance of Neisseria gonorrhoeae and group B Neisseria meningitidis.

Author

Ram S, Mackinnon FG, Gulati S, McQuillen DP, Vogel U, Frosch M, Elkins C, Guttormsen HK, Wetzler LM, Oppermann M, Pangburn MK, and Rice PA

Subjects

Complement System Proteins metabolism, Humans, In Vitro Techniques, Lipopolysaccharides chemistry, Lipopolysaccharides immunology, Neisseria gonorrhoeae pathogenicity, Neisseria meningitidis classification, Neisseria meningitidis pathogenicity, Porins immunology, Species Specificity, Blood Bactericidal Activity immunology, Neisseria gonorrhoeae immunology, Neisseria meningitidis immunology

Abstract

Neisseria gonorrhoeae and Neisseria meningitidis have evolved intricate mechanisms to evade complement-mediated killing. Sialylation of gonococcal lipooligosaccharide (LOS) results in conversion of previously serum sensitive strains to unstable serum resistance, which is mediated by factor H binding. Porin (Por) is also instrumental in mediating stable serum resistance in gonococci. The 5th loop of certain gonococcal PorlAs binds factor H, which efficiently inactivates C3b to iC3b. Factor H glycan residues may be essential for factor H binding to certain Por1A strains. Por1A strains can also regulate the classical pathway by binding to C4b-binding protein (C4bp) probably via the 1st loop of the Por molecule. Certain serum resistant Por1 B strains can also regulate complement by binding C4bp through a loop other than loop 1. Purified C4b can inhibit binding of C4bp to Por 1B, but not Por1A, suggesting different binding sites on C4bp for the two Por types. Unlike serum resistant gonococci, resistant meningococci have abundant C3b on their surface, which is only partially processed to iC3b. The main mechanism of complement evasion by group B meningococci is inhibition of membrane attack complex (MAC) insertion by their polysaccharide capsule. LOS structure may act in concert with capsule to prevent MAC insertion. Meningococcal strains with Class 3 Por preferentially bind factor H, suggesting Class 3 Por acts as a receptor for factor H.

Published

1999

7. Tyrosine is a potential site for covalent attachment of activated complement component C3.

Author

Sahu A and Pangburn MK

Subjects

Amino Acid Sequence, Binding Sites, Complement C3b chemistry, Molecular Sequence Data, Peptide Mapping, Peptides chemical synthesis, Peptides chemistry, Complement Activation, Complement C3 chemistry, Tyrosine chemistry

Abstract

Activation of C3 results in the generation of metastable C3b, which has been shown to preferentially react with the hydroxyl groups of carbohydrates and with specific serine and threonine residues in proteins. In this study we have examined the reactivity of metastable C3b with the third type of hydroxyl group present in proteins, tyrosine (Tyr). The results demonstrated that Tyr reacts with the thioester of metastable C3b and that this reactivity was 11-fold better than that of threonine, 47-fold better than serine and 50-fold better than the reactivity of carbohydrates. Model peptides containing Tyr showed even higher reactivity than free Tyr, demonstrating that incorporation into peptide structures does not block C3b attachment. The site of attachment was found to be in the alpha'-chain of C3b and the bond was hydroxylamine sensitive, indicating an ester linkage. The stability of the C3b-Tyr complex was measured under physiological conditions (pH 7.4, 37 degrees C) and compared to the stability of other C3b complexes. C3b-Tyr decayed 50% in 19 hr at 37 degrees C, but C3b bound to a Tyr-containing peptide was more stable, exhibiting a t1/2 of 53 hr. The ester linked complexes C3b-IgG and C3b-glycerol were less stable each exhibiting a t1/2 of approximately 8 hr. As yet, only two specific C3b attachment sites on proteins have been identified, Ser1217 in C4b and Thr144 in IgG1. The present evidence demonstrates that Tyr residues are highly reactive and that the C3b-Tyr linkage is stable. The findings suggest that complexes involving tyrosine residues as the site of attachment will also be found.

Published

1995

8. Identification of multiple sites of interaction between heparin and the complement system.

Author

Sahu A and Pangburn MK

Subjects

Chromatography, Affinity, Complement Factor D metabolism, Complement Factor H metabolism, Humans, In Vitro Techniques, Protein Binding, Complement System Proteins metabolism, Heparin metabolism

Abstract

Many diverse effects of heparin on the complement system have been reported. In only a few cases have the sites or the mechanisms of these effects been identified. In order to understand these results we sought to comprehensively analyze which complement proteins interact with heparin and which do not. Purified components of the classical, alternative and terminal pathways of complement were radiolabeled and their affinity for heparin determined. Affinity chromatography of normal human serum on heparin-agarose allowed a complete analysis of complement proteins and confirmed the results obtained with radiolabeled purified components. Of the 22 complement proteins examined, 13 bound heparin (C1q, C2, C4, C4bp, C1INH, B, D, H, P, C6, C8, C9, and vitronectin) while 9 did not bind heparin (C1r, C1s, C3, Factor I, C5, C7, C3b, Ba and Bb). These observations help explain the many effects heparin has on the complement system and they identify the proteins which need to be examined in order to explain these effects.

Published

1993