Avian air sac and plasma proteins that bind surface polysaccharides of Escherichia coli O2.

Some serovars of Escherichia coli, mainly O2 and O78, are responsible for air sac and systemic infections in farm-raised turkeys (Meleagris gallopavo) and chickens (Gallus gallus). We looked in air sac surface fluid from young turkeys to identify proteins that bind surface polysaccharides of pathogenic respiratory E. coli O2. Turkey air sac surface fluid was subjected to affinity chromatography on Toyopearl AF-Epoxy-650M, coupled with either lipopolysaccharide (LPS) or lipid-free polysaccharide (LFP) purified from an avian pathogenic E. coli O2 isolate. A multimeric protein termed lipid-free polysaccharide binding protein-40 (LFPBP-40) composed of six covalently associated subunits of approximately 40 kDa was isolated by elution from LFP by EDTA or L-rhamnose. An analogous protein in air sac fluid proteins bound to intact E. coli O2 and eluted with L-rhamnose or N-acetylglucosamine (GlcNAc). The N-terminal amino acid sequence of LFPBP-40 DINGGGATLPQHLYLTPDV was related to the N-terminus of fragment 3 of a partially characterized human protein possessing T cell stimulation activity in synovial membrane of rheumatoid arthritis patients. However, endogenous amino acid sequences were unrelated to other known proteins. LFPBP-40 was immunoreactively distinct from pulmonary collectins and ficolins. These studies demonstrate a novel avian respiratory soluble lectin that can bind surface polysaccharides of pathogenic E. coli responsible for respiratory disease.

Plasma proteins of rainbow trout (Oncorhynchus mykiss) isolated by binding to lipopolysaccharide from Aeromonas salmonicida.

In an attempt to find plasma proteins that might be involved in the constitutive resistance of rainbow trout to furunculosis, a disease caused by Aeromonas salmonicida (AS), we purified serum and plasma proteins based on their calcium- and carbohydrate-dependent affinity for A. salmonicida lipopolysaccharide (LPS) coupled to an epoxy-activated synthetic matrix (Toyopearl AF Epoxy 650M). A multimeric family of high molecular weight (96 to 200-kDa) LPS-binding proteins exhibiting both calcium and mannose dependent binding was isolated. Upon reduction the multimers collapsed to subunits of approximately 16-kDa as estimated by 1D-PAGE and exhibited pI values of 5.30 and 5.75 as estimated from 2D-PAGE. Their N-terminal sequences were related to rainbow trout ladderlectin (RT-LL), a Sepharose-binding protein. Polyclonal antibodies to the LPS-purified 16-kDa subunits recognized both the reduced 16-kDa subunits and the non-reduced multimeric forms. A calcium- and N-acetylglucosamine (GlcNAc)-dependent LPS-binding multimeric protein (approximately 207-kDa) composed of 34.5-kDa subunits was purified and found to be identical to trout serum amyloid P (SAP) by N-terminal sequence (DLQDLSGKVFV). A protein of 24-kDa, in reduced and non-reduced conditions, was isolated and had N-terminal sequence identity with a known C-reactive protein (CRP) homologue, C-polysaccharide-binding protein 2 (TCBP2) of rainbow trout. A novel calcium-dependent LPS-binding protein was purified and termed rainbow trout lectin 37 (RT-L37). This protein, composed of dimers, tetramers and pentamers of 37 kDa subunits (pI 5.50-6.10) with N-terminal sequence (IQE(D/N)GHAEAPGATTVLNEILR) showed no close homology to proteins known or predicted from cDNA sequences. These findings demonstrate that rainbow trout have several blood proteins with lectin properties for the LPS of A. salmonicida; the biological functions of these proteins in resistance to furunculosis are still unknown.

Roles of individual kringle domains in the functioning of positive and negative effectors of human plasminogen activation.

In order to identify the individual contributions of the kringle (K) domains of human plasminogen (Pg) to the epsilon-aminocaproic acid (EACA) induced stimulation of Pg activation by low-molecular-weight urokinase-type plasminogen activator (LMW-uPA) and inhibition of this same activation by Cl-, we constructed the most conservative recombinant- (r-) Pg mutants possible that would greatly reduce the strength of the EACA binding site in the omega-amino acid binding kringles, [K1Pg] ([D139-->N]r-Pg), [K4Pg] ([D413-->N]r-Pg), and [K5Pg] ([D515--N]r-Pg). In each case, this involved mutation of a critical Asp (to Asn) within these three kringle domains in intact Pg. The three r-mutants were expressed in r-baculovirus-infected lepidopteran insect (Trichoplusia ni) cells. In the presence of Cl-, the positive activation effector, EACA, first stimulated and then inhibited the LMW-uPA-catalyzed initial activation of wild-type (wt) r-[Glu1]Pg and, to a lesser extent, the [K5Pg] mutant, [D518-->N/Glu1]r-Pg. The concentration of EACA that produced 50% stimulation of activation (C50) occurred at 3.3 mM for wtr-[Glu1]Pg and at 0.7 mM for [D518-->N/Glu1]r-Pg. Subsequent inhibition by EACA occurred with a C50 of approximately 15 mM and is likely due to inhibition of the amidolytic activity of plasmin generated during the activation. Similar initial activation rates of both [D139-->N]r-Pg and [D413N]r-Pg did not display this initial EACA-mediated stimulatory phase but did undergo ultimate inhibition with a C50 for this process that was similar to wtr-[Glu1]Pg and [D518-->N/Glu1]r-Pg.(ABSTRACT TRUNCATED AT 250 WORDS)

Amino acids of the recombinant kringle 1 domain of human plasminogen that stabilize its interaction with omega-amino acids.

A series of strategically designed recombinant (r) mutants of the kringle 1 region of human plasminogen ([K1HPg]) have been constructed and the resulting gene products employed to reveal the identities of the residues that contribute to stabilization of the binding of omega-amino acid ligands to this domain. On the basis of determinations of the binding constants of the ligands, 6-aminohexanoic acid and trans-4-(aminomethyl)cyclohexane-1-carboxylic acid, to a variety of these mutants, we find that the anionic site of the polypeptide responsible for stabilization of the amino group of the ligands consists of both D54 and D56 and the cationic site of the polypeptide that interacts with the carboxylate group of the ligand is composed solely of R70. The main hydrophobic interactions that stabilize binding of these ligands, likely by interactions with the ligand hydrophobic regions, are principally due to W61, Y63, and Y71. The results obtained are consistent with conclusions that could be made from analysis of the X-ray crystal structure of r-[K1HPg] and from previous studies from this laboratory regarding the binding of ligands of this type to the kringle 2 region of tissue-type plasminogen activator ([K2tPA]). It thus appears as though a common ligand binding site has evolved in different kringles with ligand specificity differences between r-[K2tPA] and r-[K1HPg] perhaps explainable by the different nature of the cationic sites on these polypeptides that are involved in coordination to the ligand carboxylate groups.