Amino acid sequence and immunological properties of chachalaca egg white lysozyme

Summary The amino acid sequence of lysozyme c from chachalaca egg white was determined. Like other bird lysozymes c, that of the chachalaca has 129 amino acid residues. It differs from other avian lysozymes c by 27 to 31 amino acid substitutions as well as by being devoid of phenylalanine. It contains substitutions at 9 positions which are invariant in the other 7 bird lysozymes of known sequence. Although the chachalaca is classified zoologically in the order Galliformes, which includes chickens and other pheasant-like birds, its lysozyme differs more from those of pheasant-like birds than do the lysozymes c of ducks. Phylogenetic analysis of the sequence comparisons confirms that the lineage leading to chachalaca lysozyme c separated from that leading to other galliform lysozymes c before the duck lysozyme c lineage did. This indicates a contrast between protein evolution and evolution at the organismal level. Immunological comparison of chachalacalysozyme c with other lysozymes of known sequence provides further support for the proposal that immunological cross-reactivity is strongly dependent on degree of sequence resemblance among bird lysozymes.103rd communication on lysozymes from the Laboratory of P. Jollès. Supported in part by grants from C.N.R.S. (ER 102), I.N.S.E.R.M. (Groupe de recherche U-116), N.S.F. (GB-42028X), and N.I.H. (GM-21509).     

Structure of the pigeon lysozyme and its relationship with other type c lysozymes

1. The secondary structure of the pigeon egg-white lysozyme shows important differences when compared to other type c lysozymes. These differences are mainly located at the region comprising residues 77-84. This segment contains one alpha-helix in the lysozymes c studied by means of an X-ray analysis, while the residues at such positions in pigeon lysozyme would form two beta-bends. 2. Analysis of the tertiary structure of the pigeon lysozyme by means of hydropathy profiles reveals that the above segment seems to be more hydrophilic in the pigeon enzyme than in other type c lysozymes. 3. Though a certain similarity to the calcium-binding loop of alpha-lactalbumins is detected in pigeon lysozyme, the circular dichroism spectra of the protein at neutral pH do not change in the presence of Ca2+ ions. 4. The presented structural analysis is discussed in terms of function-structure and antigenicity relationships between the type c lysozymes.     

Amino acid sequence around the cysteine residues of pigeon egg-white lysozyme: comparative study with other type c lysozymes

The cysteine-containing tryptic peptides of pigeon egg-white lysozyme have been purified by reverse-phase chromatography and thin-layer chromatography and electrophoresis on cellulose plates. They contain the eight cysteine residues of the protein. The amino acid sequence of these peptides reveals the existence of 24 differences in comparison to the homologous regions in hen egg-white lysozyme, among the 53 sequenced residues. The sequence data are compared to the corresponding ones in other type c lysozymes. According to this study, the pigeon lysozyme exhibits ten substitutions not observed in any other type c lysozyme. Pigeon lysozyme is the most different type c lysozyme from birds, according to the data on primary structure.     

Protein conformation wheels: cytochromes and lysozymes

Conformation wheels, directly relating to amino acid sequence to the local torsion angles in a protein molecule, are presented for cytochromes c, c2, c550, and c551 and for lysozymes from hen egg-white and T4 bacteriophage. The circular plots for the cytochrome molecules aid in visualizing the common three-dimensional folding ("cytochrome fold") observed in this family of proteins. Conformation wheels for lysozymes from two different species reveal the characteristic differences in their folding patterns. These novel plots are also useful in storing and comparing the several sets of crystallographic data reported for lysozyme.     

Relationship between hydropathic variability and functional properties of alpha-lactalbumins and type c lysozymes

Hydropathic profiles obtained from the amino acid sequences of 8 alpha-lactalbumins were averaged and compared to the average profile deduced from the primary structure of 21 type c lysozymes. This analysis was performed in order to detect differences between both types of molecules, since it could explain their different functional properties. The application of the method herein described reveals the existence of very significative differences (P less than 0.001) between the amino acid residues located at positions 31-32, 34-35, 37-45, 47-48, 80-85 and 108-113 of alpha-lactalbumins and their homologous in type c lysozymes. These differences are in agreement with the chemical data about the interaction sites of both galactosyltransferase and calcium ions with alpha-lactalbumin, which are not required for the lysozyme function.     

Congruency of phylogenies derived from different proteins

Summary This communication examines the question of phylogenetic congruency- i.e., whether or not the branching order of evolutionary trees is independent of the protein studied. It was found that trees constructed for birds on the basis of immunological comparison of their transferrins, albumins, and ovalbumins agree approximately with a published tree based on the amino acid sequences of their lysozymesc. This congruency is especially noteworthy with respect to the phylogenetic position of the chachalaca, a Mexican bird classified on morphological grounds in the family Cracidae of the order Galliformes. At the protein level, this species differs as much from non-cracid galliform birds as does the duck, which belongs to another order. Despite the organismal similarity between cracid and non-cracid galliform birds, the molecular relationship is remote. If this contrast between organismal and molecular results had been based on comparative studies with only lysozyme, one could have ascribed the contrast to the possibility that chachalaca lysozyme was paralogous, rather than orthologous, to the other bird lysozymesc. Examination of several proteins is thus desirable in cases of possible paralogy.This work was supported in part by grants GB-42028X from NSF and GM-21509 from NIH     

Thermal stability and enzymatic activity of a smaller lysozyme from silk moth (Bombyx mori)

Bombyx mori lysozyme is 10 amino acids shorter than hen egg-white lysozyme, which is a typical c-type lysozyme. It was expressed by using the methylotrophic yeast Pichia pastoris. The thermal stability and the enzymatic activity of the Bombyx mori lysozyme were estimated and compared with those of human and hen egg-white lysozymes. The denaturation temperature was 17-26°C lower than those of human and hen egg-white lysozymes. Further, the enthalpy change and the heat capacity change for unfolding were smaller than those of human lysozyme. It was also confirmed that the stability against guanidine hydrochloride was lower than those of the other two lysozymes. The enzymatic activity toward a simple synthetic substrate was measured and compared with those of human and hen egg-white lysozymes. The B-F binding mode was obviously dominant, although the A-E binding mode was preferred in human and hen egg-white lysozymes.     

Mapping the antigenic epitope for a monoclonal antibody against lysozyme

A monoclonal antibody (HyHEL-5), prepared to chicken lysozyme c by the method of K?hler and Milstein, identified an antigenic site (epitope) that was shared by the lysozymes of seven different species of galliform birds. The lysozymes of two galliform species, bobwhite quail and chachalaca, shared only partial antigenic identity with the epitope defined by this antibody. Duck lysozyme did not react with the antibody at all. Amino acids that determined the epitope structure were tentatively identified by comparing the amino acid sequences of these lysozymes and assuming the antigenic changes produced by evolutionary substitutions are not due to long-range conformational changes. Arg 68 was identified as a determining amino acid. Arg 68 is hydrogen-bonded to Arg 45, and together these two amino acids form a basic cluster that may be a subsite of the epitope. The antibody inhibited lysis of Micrococcus lysodeikticus by chicken lysozyme. Additionally, Biebrich Scarlet, a dye that binds to the catalytic site, inhibited antibody binding to this lysozyme, which indicates that the epitope extends into the cleft region between Arg 45 and Arg 114. The epitope was hypothesized to involve a region measuring at least 13 x 6 x 15 A including the Arg 68-Arg 45 complex that borders the enzymatic catalytic site. Four other monoclonal antibodies to lysozyme have been partially characterized; each had a distinct pattern of binding specificity for various species of bird lysozymes.     

Calcium-binding and structural stability of echidna and canine milk lysozymes.

For echidna and canine milk lysozymes, which were presumed to be the calcium-binding lysozymes by their amino acid sequences, we have quantitated their calcium-binding strength and examined their guanidine unfolding profiles. The calcium-binding constants of echidna and canine lysozymes were determined to be 8.6 x 10(6) M(-1) and 8.9 x 10(6) M(-1) in 0.1 M KCl at pH 7.1 and 20 C, respectively. The unfolding of decalcified canine lysozyme proceeds in the same manner as that of alpha-lactalbumin, through a stable molten globule intermediate. However, neither calcium-bound nor decalcified echidna lysozyme shows a stable molten globule intermediate. This unfolding profile of echidna lysozyme is identical to that of conventional lysozymes and pigeon egg-white lysozyme, avian calcium-binding lysozyme. This result supports the suggestion of Prager and Jolles (Prager EM, Jolles P. 1996. Animal lysozymes c and g: An overview. In: Jolles P, ed. Lysozymes: Model enzymes in biochemistry and biology. Basel-Boston-Berlin: Birkhauzer Verlag. pp 9-31) that the lineage of avian and echidna calcium-binding lysozymes and that of eutherian calcium-binding lysozymes diverged separately from that of conventional lysozymes.     

Amino acid sequence of a lysozyme (B-enzyme) from Bacillus subtilis YT-25

The amino acid sequence of a lysozyme, (B-enzyme), from Bacillus subtilis YT-25 was determined by conventional methods. B-Enzyme comprised 117 amino acid residues and had a heterogeneous sequence in the amino-terminal region. The amino acid sequence of B-enzyme was different from those of all other lysozymes the sequences of which are known. However, the partial amino acid sequence of Ser(74) to Ser(97) of B-enzyme was homologous with that of the active-site region of hen egg-white lysozyme (Ser(36) to Ser(60], which includes one of the catalytic amino acids, Asp(52). It is interesting that B-enzyme has an amino acid sequence homologous with that of the gag protein p25 of the AIDS virus ARV-2.     

Structure of the induced antibacterial protein from tasar silkworm, Antheraea mylitta. Implications to molecular evolution

The crystal structure of an antibacterial protein of immune origin (TSWAB), purified from tasar silkworm (Antheraea mylitta) larvae after induction by Escherichia coli infection, has been determined. This is the first insect lysozyme structure and represents induced lysozymes of innate immunity. The core structure of TSWAB is similar to c-type lysozymes and alpha-lactalbumins. However, TSWAB shows significant differences with respect to the other two proteins in the exposed loop regions. The catalytic residues in TSWAB are conserved with respect to the chicken lysozyme, indicating a common mechanism of action. However, differences in the noncatalytic residues in the substrate binding groove imply subtle differences in the specificity and the level of activity. Thus, conformational differences between TSWAB and chicken lysozyme exist, whereas functional mechanisms appear to be similar. On the other hand, alpha-lactalbumins and c-type lysozymes exhibit drastically different functions with conserved molecular conformation. It is evident that a common molecular scaffold is exploited in the three enzymes for apparently different physiological roles. It can be inferred on the basis of the structure-function comparison of these three proteins having common phylogenetic origin that the conformational changes in a protein are minimal during rapid evolution as compared with those in the normal course of evolution.     

Characterization and conformational analysis by Raman spectroscopy of human airway lysozyme

Human airway lysozyme, purified from pathological bronchial secretions, is characterized by a specific activity 3-fold higher than that of hen egg-white lysozyme. The amino acid composition of human airway lysozyme is identical to that of other human lysozymes. The laser Raman spectra of human airway lysozyme and hen egg-white lysozyme in phosphate buffer solution (pH 7.2) are recorded in the range 300-1900 cm-1 at 488 nm. Drastic intensity differences are observed between the spectra analyzed in the ranges characteristic of the peptide backbone (e.g., beta-sheet; C alpha-C, C alpha-N), and of the aromatic side-chain vibrations (tyrosine, tryptophan). The deconvolution of the Raman amide I band gives secondary structures of 38% and 39% alpha-helix, 25% and 20% beta-sheet, and 37% and 41% undefined structure for the human and hen lysozymes, respectively.     

VL-VH expression by monoclonal antibodies recognizing avian lysozyme

Seven BALB/c hybridoma antibodies directed against the protein antigen, hen egg-white lysozyme c (HEL), were characterized on the basis of their ability to bind lysozymes from 10 species of birds, and their ability to bind HEL competitively. The hybridomas were separable into three complementation groups based upon competitive interactions. The fine specificities of all antibodies were distinct, but two, HyHEL-8 and HyHEL-10, had very similar and overlapping reactivity patterns. To test the hypothesis that VL-VH pairing correlates with binding specificity, the N-terminal amino acid sequences were determined to identify the VL and VH isotopes (subgroups) of the anti-HEL antibodies. HyHEL-8 and -10 shared the VK23 light chain isotype and nearly identical heavy chains in Kabat subgroup I, whereas the heavy and light chain isotypes of all other antibodies differed from HyHEL-8 and -10 and from each other. The heavy and light chain isotypes expressed by HyHEL-8 and -10 are also expressed by XRPC-25, a DNP-binding myeloma protein that does not bind lysozyme. These results are discussed with respect to the contributions of various genetic sources of structural diversity to antibody functional diversity.     

Crystallization and preliminary X-ray structure analysis of pigeon egg-white lysozyme.

Calcium binding lysozyme from pigeon egg-white was crystallized by the hanging drop vapor diffusion technique using ammonium sulphate as a precipitant. The crystals belong to the orthorhombic system, space group P2(1)2(1)2(1), and have unit cell dimensions of a = 34.2 A, b = 34.8 A, and c = 99.4 A. One asymmetric unit contains one molecule of the pigeon lysozyme. The crystals diffract X-rays at least to 2.0 A resolution and are suitable for high resolution structure analysis. The diffraction data up to 3.0 A resolution were collected with a diffraction image processor, DIP100, using a Fuji imaging plate as an area detector. The structure was solved by the molecular replacement technique and refined to an R factor of 0.216. Least-squares fitting of the main-chains of pigeon egg-white lysozyme with those of chicken egg-white lysozyme and baboon alpha-lactalbumin showed that the main-chain folding of pigeon lysozyme is more similar to that of chicken lysozyme than that of alpha-lactalbumin. The largest differences between the pigeon and chicken lysozymes are in the surface loop regions.     

Hydrophobic Regions in Myelin Proteins Characterized Through Analysis of "Hydropathic"Profiles

Computer-generated "hydropathic" profiles were constructed for graphic comparison of the amino acid sequences for P2 protein, 18.5 kilodalton (kDa) myelin basic protein (BP), and myelin proteolipid protein (PLP). Profiles were also obtained for cytochrome b5, a membrane protein known to be capable of reversible association with lipid bilayers and of a size comparable to that of the myelin BPs. Analysis of the PLP sequence produced profiles generally compatible with the suggestions that PLP has three transbilayer and two bilayer intercalating segments. Profiles for P2 and 18.5 kDa BP were found to contain hydrophilic segments separated by relatively short hydrophobic regions. Whereas hydropathic indices in hydrophobic regions of P2, 18.5 kDa BP, and PLP fall in the value ranges recently reported for cores of globular proteins and intrabilayer domains of membrane proteins, hydrophobic sections of P2 and 18.5 kDa BP have hydropathic indices similar to those in the hydrophobic core (transprotein) regions of globular proteins. None of them are comparable to the region of cytochrome b5 known to anchor that protein in its membrane or to the segments of PLP sequence proposed as intrabilayer domains. This comparison suggests that neither BP has structural characteristics compatible with insertion into the hydrocarbon core of the myelin lipid bilayer, a conclusion that is consistent with a recently published study that identified the bilayer penetrating proteins of myelin with a hydrophobic probe. The above findings suggest an enhancement for some details of myelin architecture and a cautious approach to interpreting data for BP intercalation into bilayers.     

Effects of p-benzoquinone and melatonin on amyloid fibrillogenesis of hen egg-white lysozyme

More than 20 different human proteins can fold abnormally resulting in the formation of pathological deposits and several lethal degenerative diseases. Despite extensive investigations on amyloid fibril formation, the detailed molecular mechanism remained far from complete. In this work, utilizing hen egg-white lysozymes as a model system, two objectives were pursued: (1) to search for suitable conditions for producing amyloid fibrils and (2) to investigate inhibitory activities of two potential molecules against lysozyme fibril formation. Via numerous spectroscopic analyses and electron microscopy, our results showed that the formation of lysozyme amyloid fibrils at pH 2.0 was considerably increased by the addition of salt. Moreover, the inhibition of lysozyme amyloid formation by either p-benzoquinone or melatonin followed a concentration-dependent fashion. Furthermore, p-benzoquinone, in comparison with melatonin, served as a more effective inhibitor against amyloid fibril formation of lysozyme. We believe that a better understanding of how hen egg-white lysozymes aggregate will not only aid in deciphering the molecular mechanism of amyloid fibrillogenesis, but also shed light on a rational design of effective therapeutics for amyloidogenic diseases.     

Molecular genetics and evolution of stomach and nonstomach lysozymes in the hoatzin

Multiple genes of the hoatzin encoding stomach lysozyme c and closely related members of this calcium-binding lysozyme c group were cloned from a genomic DNA library and sequenced. There are a minimum of five genes represented among these sequences that encode two distinct groups of protein sequences. One group of three genes corresponds to the stomach lysozyme amino acid sequences, and the remaining genes encode predicted proteins that are more basic in character and share several sequence identities with the pigeon egg-white lysozyme rather than with the hoatzin stomach lysozymes. Despite these structural similarities between some of the hoatzin gene products and the pigeon lysozyme, phylogenetic analyses indicate that all of the hoatzin sequences are closely related to one another. This is borne out by the relatively small genetic distances even in the intronic regions, which are not subject to the selective pressures operating on the coding regions of the stomach lysozymes. These results suggest that multiple gene duplication events have occurred during the evolution of hoatzin lysozymes.     

Isolation of Protein Inhibitors of Papain,Trypsin, and α-Amylase in the Grain of Foxtail Millet

The amino acid sequence of Indian peafowl egg-white lysozyme has been identified. The reduced and carboxymethylated lysozyme was digested with trypsin followed by purification of the resulting peptides by reverse-phase HPLC. The tryptic peptides obtained were sequenced using the DABITC/PITC double coupling manual sequencing method. The alignment of the tryptic peptides were deduced by comparison with corresponding peptides of hen egg-white lysozyme. This protein proved to consist of 129 amino acid residues, and a relative molecular mass of 14423 Da was calculated. Amino acid sequence comparison of peafowl lysozyme and other phasianoid bird lysozymes revealed a maximum homology ratio of 98% with turkey lysozyme.     

Is the bacteriophage lambda lysozyme an evolutionary link or a hybrid between the C and V-type lysozymes? Homology analysis and detection of the catalytic amino acid residues.

The relationship between the bacteriophage lambda lysozyme (lambda L) and the C and V-type lysozymes has been investigated by sequence alignment, secondary structure prediction and pattern recognition methods. The alignment of the amino terminal part of lambda L with that of V-type lysozymes suggests that Glu19 is a residue essential for catalysis. Its mutation to Gln leads to a completely inactive enzyme. In the alignment of the sequence of lambda L with those of the C-type lysozymes a strongly homologous fragment of about 30 amino acid residues is detected. Taking into consideration this observation and the published structural alignments between C and V-type lysozymes, a repetition of the beta-sheet motif in lambda L is proposed. The multiple alignment draws the attention to a possible catalytic role for Asp34 that would be positioned in the middle of the second strand of the beta-sheet as in the C-type lysozymes. This role is confirmed by mutagenesis. The implications of these observations in terms of the evolutionary relationship between lambda L and the other lysozymes is discussed.     

Phylogenetic Analysis of Invertebrate Lysozymes and the Evolution of Lysozyme Function

We isolated and sequenced the cDNAs coding for lysozymes of six bivalve species. Alignment and phylogenetic analysis showed that, together with recently described bivalve lysozymes, the leech destabilase, and a number of putative proteins from extensive genomic and cDNA analyses, they belong to the invertebrate type of lysozymes (i type), first described by Jollès and Jollès (1975). We determined the genomic structure of the gene encoding the lysozyme of Mytilus edulis, the common mussel. We provide evidence that the central exon of this gene is homologous to the second exon of the chicken lysozyme gene, belonging to the c type. We propose that the origin of this domain can be traced back in evolution to the origin of bilaterian animals. Phylogenetic analysis suggests that i-type proteins form a monophyletic family. Received: 21 May 2001 / Accepted: 22 October 2001