Open quaternary structure of the hagfish proteinase inhibitor with similar properties to human alpha-2-macroglobulin

A recombinant bait region mutant of human alpha2-macroglobulin exhibiting an altered proteinase-inhibiting spectrum

Alpha 2-macroglobulin (alpha2M), a plasma glycoprotein produced in the liver, inhibits a variety of proteinases and thus considered to play important homeostatic roles in the body. This broad inhibitory spectrum has been explained by the trapping theory by which a proteinase recognizes a region of 25-30 amino acid peptide in alpha2M called bait region and cleaves it, leading to the conformational change of alpha2M, and to the subsequent entrapment and inhibition of the proteinase. We constructed alpha2M cDNAs with mutated DNA sequences in the bait region, and obtained recombinant CHO cell lines producing either wild type alpha2M, or mutant alpha2Ms, i.e., alpha2M/K692 and alpha2M/K696, each with substitution of Arg with Lys at codons 692 and 696, respectively. We tested if lysyl endopeptidase is not inhibited by wild type alpha2M, but could be inhibited by these engineered mutant alpha2Ms. Thus, recombinant alpha2M/K696 protein successfully inhibited lysyl endopeptidase activity, while recombinant alpha2M/K692 protein was not sensitive to lysyl endopeptidase, suggesting that not all bait region peptide bonds can equally be accessible and susceptible to proteinases. The present results not only provided the trapping theory with additional supportive evidence, but the first experimental evidence for the value of engineered alpha2M-derived proteinase inhibitor with an artificial proteinase inhibitory spectrum of potential industrial and/or therapeutic usefulness.

alpha2-Macroglobulin in the marine fish Sparus aurata

The alpha2-macroglobulin proteinase inhibitors (alpha2Ms) are a family of plasma proteins with the unique ability to inhibit a broad spectrum of proteinases, but are also known as binding proteins for many growth factors and cytokines, including growth hormone and members of the transforming growth factor-beta superfamily. A partial cDNA (475 amino acids) encoding the C-terminus of alpha2M was cloned from the liver of the marine teleostean fish Sparus aurata. The deduced amino acid sequence of the cloned fragment showed 58-60% similarity to carp alpha2Ms. Northern blot analysis of hepatic alpha2M revealed a transcript of about 5 kb. A transcript of a similar size was detected in 1-day larvae. Steady state levels of alpha2M in larvae increased gradually on subsequent days post-hatching. alpha2M expression in embryos was determined by RT-PCR and started in embryos aged 8 h post-fertilization, but not earlier. RT-PCR of muscle RNA detected alpha2M also in fish muscle, albeit with a lower expression than in the liver. Immunoreactive-alpha2M was found in yolk syncytial layer of 3-day larvae and in livers from larvae and adults. Immunoreactive-alpha2M was also identified in soluble total proteins from young larvae with a pattern resembling that of plasma. These data demonstrate that the alpha2M gene is expressed early in fish development. Moreover, in addition to its major expression in liver, alpha2M is expressed also in fish muscle.

Molecular cloning and structural characterization of the hagfish proteinase inhibitor of the alpha-2-macroglobulin family

The "most primitive" living vertebrate the hagfish has a dimeric proteinase inhibitor, a protein homologous to human alpha2-macroglobulin, in its plasma at high concentration. Although the hagfish proteinase inhibitor has been isolated and its function and quaternary structure studied, its primary structure, subunit composition and fragmentation process remain unclear. In this study, hagfish proteinase inhibitor cDNA was cloned, sequenced and cDNA-deduced amino acid sequence was analyzed. A large fraction of homosubunits in the dimeric structure of the protein has undergone a cleavage at a specific arginyl residue (Arg833) while the rest retained their chain integrity without being processed. Thus random combinations of processed and nonprocessed subunits in the dimeric structure of this protein result in different molecular conformers and generate a complicated multiband pattern in SDS-PAGE. It was further demonstrated by proteolytic analysis that the hagfish inhibitor has no susceptible arginyl residues within its bait region and thus incapable of trapping arginine specific proteinases. This implies that the specific subunit cleavage at Arg833 was caused by an unknown arginine specific proteinase which escaped from the entrapment by the hagfish inhibitor.

Evolution of effectors and receptors of innate immunity

The bony fishes are derived from one of the earliest divergent vertebrate lineages to have both innate and acquired immune systems. They are considered by some to be an ideal model to study the underpinnings of immune systems precisely because of their phylogenetic position and the fact that their adaptive immune systems have not been elaborated to the extent seen in mammals. By the same token, examination of innate immune systems in invertebrates and early chordates can provide insight into how homologous systems operate in fish and higher vertebrates. Herein, we provide an overview of the molecular evidence that we hope helps clarify the evolutionary relationships of innate immune molecules identified in bony fishes. The innate immune systems being considered include select chemokines (CC and CXC chemokines and their receptors), cytokines (IL-1, IL-8, interferons, TGF-beta, TNF-alpha), acute phase proteins (SAA, SAP, CRP, alpha2M, and the complement components--C3-C9, MASP, MBL, Bf), NK cell receptors, and molecules upstream and downstream of the Toll signaling pathways.

Purification and characterization of a tetrameric alpha-macroglobulin proteinase inhibitor from the gastropod mollusc Biomphalaria glabrata

The alpha-macroglobulin proteinase inhibitors (alpha Ms) are a family of proteins with the unique ability to inhibit a broad spectrum of proteinases. Whereas monomeric, dimeric and tetrameric alpha Ms have been identified in vertebrates, all invertebrate alpha Ms characterized so far have been dimeric. This paper reports the isolation and characterization of a tetrameric alpha M from the tropical planorbid snail Biomphalaria glabrata. The sequence of 18 amino acids at the N-terminus indicates homology with other alpha Ms. The subunit mass of approx. 200 kDa was determined by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry and SDS/PAGE. The quaternary structure was determined by sedimentation equilibrium centrifugation and native pore-limit electrophoresis. Evidence for a thioester is provided by the fact that methylamine treatment prevents the autolytic cleavage of the snail alpha M subunit and results in the release of 4 mol of thiols per mol of snail alpha M. The snail alpha M inhibited the serine proteinase trypsin, the cysteine proteinase bromelain and the metalloproteinase thermolysin. The spectrum of proteinases inhibited, together with the demonstration of steric protection of the proteinase active site and a "slow to fast' conformational change after reacting with trypsin, all suggest that the inhibitory mechanism of the snail alpha M is similar to the "trap mechanism' of human alpha 2-macroglobulin.

Identification and partial characterization of alpha 2-macroglobulin from the tuatara (Sphenodon punctatus)

alpha 2-Macroglobulin (alpha 2-M), a large molecular mass proteinase-binding protein, was identified in plasma from tuatara (Sphenodon), a rare reptile endemic to New Zealand. In this genus, alpha 2-M constitutes 11-13% of total plasma protein (approximately 2.2-3.9 mg/mL). Analysis of blood samples collected at approximately monthly intervals from individual tuatara indicated that the plasma level of alpha 2-M remains fairly constant. The subunits of tuatara alpha 2-M have an apparent molecular mass of approximately 160 kDa as determined by SDS-polyacrylamide gel electrophoresis and the intact protein is an oligomer that contains inter-chain disulfide bonds. N-terminal sequence analyses of tuatara alpha 2-M revealed a distinct similarity to alpha-macroglobulins of other vertebrates and that at least two types of alpha 2-M subunits are present in plasma of tuatara.

Ultrastructure of alpha 2-macroglobulins

New results concerning the ultrastructure of human alpha 2-macroglobulin (alpha 2M) molecules are presented in connection and comparison with the historical, the current and our own most recent, even unpublished results on the structure and function of alpha 2M and related proteins. The electron microscopic approach uses classical negative staining, combined with the new imaging mode "Electron Energy Loss Spectroscopy", which provides unusual contrast, resolution and readability of the electron micrographs. Immuno- and cryoelectron microscopy, as well as image processing has provided new data necessary to the building of tentative 3D models of the molecule. A model for the native tetrameric alpha 2M is described for the first time, and tries to explain and gather the various observations, sometimes contradictory, taken from different laboratories. A revised version for a model of the methylamine- and proteinase-transformed forms of alpha 2M is also shown. The probable positions of the bait regions and the thiol esters are given on both models. We confirm that alpha 2M is a twin trap capable of inactivating one or two proteinases by partial immobilization. Preliminary results on the production of crystals of alpha 2M-chymotrypsin complexes are also presented. A critical analysis of our models is presented in comparison with others. The technical limitations reached with some techniques and some possible extensions of future research in the field are also presented.

X-ray scattering study of hagfish protease inhibitor, a protein structurally related to complement and alpha 2-macroglobulin

A protease inhibitor from hagfish blood plasma, homologous to human alpha 2-macroglobulin, has been studied in solution using small-angle X-ray scattering; the radius of gyration, R, was found to be 7.0 nm, the molecular weight 340,000 +/- 20,000, and the largest distance within the molecule, Dmax, 22 nm. When the inhibitor reacts with chymotrypsin, its 1:1 chymotrypsin complex is found to be more compact than the native molecule, R = 6.1 nm. A very similar conformational change is observed after the protein is reacted with methylamine. The data are consistent with models consisting of two equal elliptic cylinders with the same size as the one used as a model for the complement proteins C3 and C4 [cf. Osterberg et al. (1989) Eur. J. Biochem. 183, 507-511]. In the model for the native protein, these cylinders are arranged in an extended form, and in the one for the methylamine derivative (or chymotrypsin complex), they are closer together so that the projection of their elliptic surfaces forms an angle of about 70 degrees. These models for the hagfish protease inhibitor were expanded to models for the twice as large human alpha 2-macroglobulin using symmetry operations, and the resulting alpha 2-macroglobulin models were found to agree with those emerged from earlier studies involving electron microscopy and X-ray scattering methods.

Structural studies of human alpha 2-macroglobulin: concordance between projected views obtained by negative-stain and cryoelectron microscopy

Two views of native alpha 2-macroglobulin are revealed by electron microscopy of negatively stained samples; in one view the molecule resembles a padlock and in the other, a pair of lips. Interconversion of the two views upon tilting establishes that these are two different projected views of the same structure. Furthermore, the two views are related by a 45 degrees rotation about their major axis because they interconvert when the specimens are titled +/- 22.5 degrees. Negatively stained molecules on Butvar films present a nearly equal distribution of the two views, whereas in frozen-hydrated samples the molecules almost exclusively are oriented in the lip view. Measurements from both views indicate that the alpha 2-macroglobulin molecule is approximately 200 A long and approximately 140 A wide. Our results suggest that alpha 2-macroglobulin is composed of two protomeric units, each in the shape of a twisted letter S. These units are joined together at their ends to form a complex with point group symmetry 222. The 45 degrees interconversion angle between the lip and padlock views support this arrangement. Average images of unstained and stained lips are quite similar, indicating that the native structure is consistently preserved by the two electron microscopy procedures used in this investigation. This is substantiated by the interconversion between the lip and padlock views that occurs when the molecule is rotated 45 degrees [corrected] about its major twofold axis.

Polymerization of turtle alpha-macroglobulin through newly exposed sulfhydryls reveals the location of ex-thiolester bonds

Green turtle alpha-macroglobulin, which has previously been shown to contain thiolester bonds, formed linear polymers after being treated with proteinases. Biochemical analyses showed that the polymerization proceeded through disulfide-bond formation between monomers. The only sulfhydryl groups available for such polymerization after proteinase treatment were those created as the product of thiolester hydrolysis. Electron micrographs of polymers revealed H-shaped monomeric units aligned lengthwise in linear polymers. The average length per monomeric unit in the polymer estimated from the discrete distribution of polymer lengths was approximately 80% of the average length of free monomers, indicating that monomers overlapped each other within a region of about 4 nm. From such observations we concluded that the newly produced sulfhydryl groups were located on the four arms of the H-shaped molecule. The location of sulfhydryls can be taken as the site of the exposure of thiolesters which were originally sequestered in the hydrophobic interior of the molecule. Since the structure of turtle alpha-macroglobulin is very similar to that of human serum alpha 2-macroglobulin the results predict a similar location of sulfhydryls in human alpha 2-macroglobulin after proteinase treatment. The observed polymerization property is unique to sea turtle alpha-macroglobulin and has not been observed with human alpha 2-macroglobulin or other homologous proteins.

Calculation and experimental verification of the frictional ratio of hagfish proteinase inhibitor

A major structural feature of the alpha-2-macroglobulin-like inhibitor of hagfish described in Osada, Nishigai, and Ikai [(1987) J. Ultrastruct. Mol. Struct. Res. 96, 00-00] was its highly open quaternary structure observed under an electron microscope. We drew a qualitative conclusion that the high frictional ratio obtained from the result of sedimentation study and the large Stokes radius obtained in gel chromatographic experiment were the reflection of such an open quaternary structure. In this paper I present several structural models of hagfish inhibitor based on its electron micrographs and calculate expected frictional ratios for such models according to the method developed by Bloomfield and his co-workers. Their method allows the calculation of frictional coefficient of a body of an arbitrary shape by approximating it with a collection of small spheres. To test the validity of such a method, macroscopic models were built from plastic spheres or cylindrical capsules and their translational frictional coefficients were measured by the free-falling method under experimental conditions where the Reynolds number was between 10(-3) and 10(-4).