Growth-modulating tripeptide (glycylhistidyllysine): association with copper and iron in plasma, and stimulation of adhesiveness and growth of hepatoma cells in culture by tripeptide-metal ion complexes

The tripeptide H-Gly-His-Lys-OH (GHL) is a human plasma constituent which has been previously shown to modulate the growth and viability of a variety of cell types and organisms. Experimental observations presented herein indicate that GHL is complexed with the transition metal ions Cu++ and Fe++ in vivo and may exert its biological effects as a peptide-metal chelate. At physiological pH in vitro, GHL associates with ionic copper, cobalt, iron, molybdenum, manganese, nickel, and zinc, but has no affinity for calcium, manganese, potassium, and sodium. GHL acts synergistically with copper, iron, cobalt, and zinc to alter patterns of cell growth in monolayer cultures of a tumorigenic hepatoma cell line (HTC4). These transition metals induce cellular flattening and adhesion to support surfaces, and inhibit DNA synthesis and lactic acid production when growth is limited by reduction of serum concentrations in medium. These inhibitory effects are neutralized, and intercellular adhesion and growth are stimulated by GHL in medium at nanomolar concentrations. Cu and Fe are the most active metals when combined with GHL. The results suggest that the inability of HTC4 cultures to replicate without adequate concentrations of serum in medium may reflect deficiency of GHL and transition metals, which appear to form complexes prior to interaction with cells. Chelation of transition metals with GHL and, potentially, with other growth-modulating peptide factors in plasma or medium, may provide a mechanism for expression and regulation of biological activities influenced by transition metals and polypeptide growth factors. The observed effects of GHL-metal complexes, including stimulation of cellular adhesiveness to substratum (flattening) and intercellular attachment (monolayer formation), appear to satisfy requirements for growth of hepatoma cells in monolayer culture.     

Effects of glycyl-histidyl-lysine on Morris hepatoma 7777 cells

Glycyl-histidyl-lysine (GHL) has been shown to have growth stimulatory effects on a number of different cell types including hepatocytes and hepatoma cells. In this study, the effects of GHL on Morris hepatoma 7777 cells were investigated. The greatest stimulatory effects on 3H-thymidine and 3H-leucine incorporation were observed at a GHL concentration of 2 ng/ml. In randomly proliferating cells, the incorporation of 3H-thymidine into DNA increased by 50% and that of 3H-leucine into protein by 29%. In addition, synergistic effects were observed when insulin and glucagon were included with GHL in the incubation mixture. Experiments with cells rendered quiescent by serum starvation indicated that cells in the G1 phase of the cell cycle are more sensitive to GHL stimulation. In these experiments, 3H-thymidine incorporation increased earlier and peaked at a higher value than in the control cells. This finding suggests that GHL may play a role in stimulating quiescent cells to re-enter the cell cycle.     

NMR studies on binary and ternary Pd(II) complexes formed by the growth-modulating tripeptide glycylhistidyllysine and nucleotides

The mechanism of transport of Pt(II) and Pd(II) into tissues through blood and that of their elimination in kidney is incompletely known so far. In this respect, the binding of palladium by the tripeptide glycyl-L-histidyl-L-lysine (GHL), a constituent of the human plasma, as a binary complex, and by the nucleotides 5'-IMP and 5'-GMP, as ternary complexes, has been studied by 1H and 13C NMR spectroscopy. These studies have been conducted in aqueous media and at different ligand/metal ratios. At acidic pH, resonances were observed for binary and ternary kinetically stable complexes, and binding sites in these complexes were identified by the effect of binding on chemical shifts of protons and carbon resonances. From these data, stoichiometries and structures of these complexes were proposed.     

The complex formation of copper(II) with GHL and related peptides

The formation constants for complexes of Cu(II) with GHL and a series of related dipeptides were determined by means of potentiometric titration and ESR spectroscopy in aqueous solution. The complex formation of the related peptides AH, LH, HL, GL and VL is compared to that of GHL. The somewhat higher affinity of GHL to Cu(II) as compared to AH and LH seems to be a poor explanation for the biological functions of GHL. A dimeric Cu(II)HL complex is detected, which displays an ESR spectrum at room temperature. The ESR spectra of the different complexes and the influences of structures on the spectra are discussed.     

Histidine-114 at subsites E and F can explain the characteristic enzymatic activity of guinea hen egg-white lysozyme

The courses of the reaction catalyzed by guinea hen egg-white lysozyme (GHL), in which Asn113 and Arg114 at subsites E and F in hen egg-white lysozyme (HEL) are replaced by Lys and His, respectively, was studied with the substrate N-acetylglucosamine pentamer, (GlcNAc)5. Although GHL was found to retain the main-chain folding similar to HEL as judged from CD spectroscopy, the courses of GHL showed increased production of (GlcNAc)4 and reduced production of (GlcNAc)2 when compared with HEL. To identify critical residue(s) involved in the alteration in the courses of GHL, two mutant enzymes as to subsites E and F in HEL, N113K and R114H, were prepared by site-directed mutagenesis. Kinetic analysis of these mutants revealed that the mutation of Asn113 to Lys had little effect on the courses of HEL, while the Arg114 to His mutation completely reproduced the courses of GHL, demonstrating that His114 in GHL is the key residue responsible for the characteristic courses of GHL. Computer simulation of the reaction courses of the R114H mutant revealed that this substitution decreased not only the binding free energies for subsites E and F, but also the rate constant of transglycosylation. The Arg residue at position 114 may play an important role in the transglycosylation activity of HEL.     

The complex formation of copper(II) with GHL and HSA

The formation constants for complexes of copper(II) with GHL have been determined by means of pH titrations and ESR spectroscopy in aqueous solutions. GHL has an extremely high affinity for copper(II) and forms very stable 1:1 complexes and a comparatively weak 1:2 complex. The ? amino group of GHL seems not to be involved in complex formation as can be deducted from both equilibrium constants and ESR spectroscopy. The ternary system copper(II)-GHL-HSA was investigated by ESR spectroscopy and optical absorption spectroscopy in aqueous solution at physiological pH (7.4). At equimolar concentrations, copper(II), HSA and GHL form a ternary complex.     

Specificity of clinical examinations for testing glenohumeral ligament integrity: a computational study

An accurate diagnosis of glenohumeral joint (GHJ) instability is essential for an effective surgical intervention. There is presently no known comprehensive algorithm of clinical tests for the confirmation of the functional integrity of glenohumeral ligaments (GHLs). A validated computational GHL strain analyser was applied to a set of GHJ kinematics data from the literature to simulate 57 different physiological clinical examination manoeuvres. An algorithm that integrates the GHL pre-straining activities at the toe region of the stress–strain curve was developed for the quantification of ligament loading from prevailing strains. This was used to upgrade the strain analyser and applied to produce a matrix of the various GHL loadings and sensitivities during the manoeuvres. The investigation magnified the likely impact of anatomical variations of GHL attachments as possible causes of misdiagnoses during clinical examinations of GHJ dysfunction. This can serve as an assistive guide to ascertain the functional condition of a specific GHL during symptomatic clinical examinations.     

A new GTP-binding protein in differentiated human leukemic (HL-60) cells serving as the specific substrate of islet-activating protein, pertussis toxin

A GTP-binding protein serving as the specific substrate of islet-activating protein (IAP), pertussis toxin, was partially purified from human leukemic (HL-60) cells that had been differentiated into neutrophil type. The partially purified protein, referred to as GHL, predominantly consisted of at least two polypeptides with molecular masses of 40,000 daltons (alpha) and 36,000 or 35,000 daltons (beta). The structure was similar to Gi or Go previously purified from rat brain as an alpha beta gamma-heterotrimeric IAP substrate (Katada, T., Oinuma, M., and Ui, M. (1986) J. Biol. Chem. 261, 8182-8191), although the existence of the gamma of GHL was unclear. The 40,000-dalton polypeptide contained the site for IAP-catalyzed ADP-ribosylation and the binding site for guanine nucleotide with a high affinity. The 36,000- and 35,000-dalton polypeptides were cross-reacted with the affinity-purified antibody raised against the beta of brain Gi and Go. Limited proteolysis with trypsin and immunoblot analyses with the use of the affinity-purified antibodies raised against the alpha of brain Gi or Go indicated that the alpha of GHL was different from the alpha of Gi or Go. Kinetics of guanosine 5'-(3-O-thio)triphosphate (GTP gamma S) binding to GHL was also quite different from that to brain Gi or Go. Incubation of GHL with GTP gamma S resulted in a resolution into GTP gamma S-bound alpha and beta(gamma) thus purified had abilities to inhibit a membrane-bound adenylate cyclase activity and to associate with the alpha of brain IAP substrate in a fashion similar to the beta gamma of brain IAP substrates, suggesting that there were no significant differences in the biological activities between the beta(gamma) of GHL and those of Gi or Go. Physiological roles of the new GTP-binding protein, GHL, purified from the neutrophil-like cells in receptor-mediated signal transduction are discussed.     

Endo-alpha-1-4-polygalactosaminidases and their homologues: structure and evolution

Endo-alpha-1,4-polygalactosaminidase is a rare enzyme. Its catalytic domain belongs to the GH114 family of glycoside hydrolases. Phylogenetic analysis of the family proteins allowed us to show an important role of duplications, eliminations, and horizontal transfer in the evolution of their genes. Domain structure, the secondary structure, and proposed structure of the active center of the endo-alpha-1,4-polygalactosaminidases are discussed. Evolutionary connections of the GH114 family with GH13, GH18, GH20, GH27, GH29, GH31, GH35, GH36, and GH66 families of glycoside hydrolases, as well as, with COG1306, COG1649, COG2342, GHL3, and GHL4 families of enzymatically uncharacterized proteins have been revealed by iterative screening of the protein database. The unclassified homologues have been grouped into 13 new families of hypothetical glycoside hydrolases: GHL5 - GHL15, GH36J, and GH36K.     

The Hsp90 inhibitor radicicol interacts with the ATP-binding pocket of bacterial sensor kinase PhoQ

Sensor kinases in the bacterial two-component system share a unique ATP-binding Bergerat fold with the GHL (gyrase, Hsp90, and MutL) family of proteins. We demonstrated that selected GHL inhibitors bind to the catalytic domain of sensor kinase PhoQ (PhoQcat) using NMR chemical shift perturbation experiments. Using crystallographic approaches, we show that radicicol (an Hsp90 inhibitor) binds and interacts specifically with residues in the ATP-binding pocket of PhoQ. The interaction between radicicol and PhoQcat demonstrates significant similarities as well as differences compared to AMPPNP (a non-hydrolyzable ATP analog) bound to PhoQcat and radicicol bound to Hsp90. Our results suggest that GHL inhibitors may be useful lead compounds for developing sensor kinase inhibitors.     

Structural dissection of ATP turnover in the prototypical GHL ATPase TopoVI

GHL proteins are functionally diverse enzymes defined by the presence of a conserved ATPase domain that self-associates to trap substrate upon nucleotide binding. The structural states adopted by these enzymes during nucleotide hydrolysis and product release, and their consequences for enzyme catalysis, have remained unclear. Here, we have determined a complete structural map of the ATP turnover cycle for topoVI-B, the ATPase subunit of the archaeal GHL enzyme topoisomerase VI. With this ensemble of structures, we show that significant conformational changes in the subunit occur first upon ATP binding, and subsequently upon release of hydrolyzed P(i). Together, these data provide a structural framework for understanding the role of ATP hydrolysis in the type II topoisomerase reaction. Our results also suggest that the GHL ATPase module is a molecular switch in which ATP hydrolysis serves as a prerequisite but not a driving force for substrate-dependent structural transitions in the enzyme.     

The complex formation of zinc(II) with GHL and related peptides

The formation constants for complexes of Zn(II) with GHL and related peptides have been determined by means of potentiometric titration and ¹H NMR spectroscopy in aqueous solution. GHL has a high affinity for Zn(II) but this somewhat higher affinity compared to the related peptides AH, LH and HL is not a sufficient explanation for its biological role.¹H NMR spectroscopy allows structural assignment of the relative chemical shifts to complex structures and the method, therefore, is a powerful tool for the determination of complex structures when the metal ion is diamagnetic and the ESR method previously applied to the GHLCu(II) system (see ref. 4) cannot be used.     

The effect of a collagen tripeptide fragment (GER) on fibroblast adhesion and spreading depends on properties of an adhesive surface

The effect of collagen tripeptide fragment GER on the adhesion and spreading of mouse embryonic fibroblasts STO to different substrates (polystyrene plastic, poly-L-lysine, fibronectin, gelatin) has been studied. It was found that tripeptide GER was involved in fibroblast adhesion and spreading. The cell response depended both on the mode of tripeptide addition to culture medium and the substrate type. Coincubation of fibroblasts with tripeptide stimulated the cell attachment and spreading to untreated plastic and plastic coated with fibronectin or gelatin but did not change cell adhesion to immobilized poly-L-lysine. Preincubation of cells with tripeptide resulted in partial inhibition of fibroblast adhesion and spreading on fibronectin- and gelatin-coated substrata. It was shown that activation and inhibition of adhesive processes after tripeptide treating was higher on fibronectin than gelatin. The data obtained support the assumption about concerted action of tripeptide GER (activity was dependent both on the used concentration of the tripeptide and the mode of tripeptide addition to culture medium) and chemical characteristics of substrate (polymers of styrene and L-lysine, ECM proteins in native (fibronectin) or partly denatured (gelatin) form) on the cell adhesion and spreading. The main targets that GER peptide may affect during the formation of cell-substrate interactions are discussed.     

Endo-α-1,4-polygalactosaminidases and their homologs: Structure and evolution

Endo-α-1,4-polygalactosaminidase is a rare enzyme. Its catalytic domain belongs to the GH114 family of glycoside hydrolases. It is shown by phylogenetic analysis that the evolution of the corresponding genes involved duplications, elimination, and horizontal transfer. The domain and secondary structures of endo-α-1,4-polygalactosaminidases are discussed. A hypothesis is put forward as to the structure of the active center of the enzyme. Iterative screening of a protein database reveals evolutionary relationships of the GH114 family with the GH13, GH18, GH20, GH27, GH29, GH31, GH35, GH36, and GH66 families of glycoside hydrolases and with the COG1306, COG1649, COG2342, GHL3, and GHL4 families of proteins with unknown enzymatic functions. Unclassified homologs are grouped into 13 new families of hypothetical glycoside hydrolases: GHL5-GHL15, GH36J, and GH36K.     

Algorithm and validation of a computer method for quantifying attachment locus of glenohumeral ligament in vivo

The aim of this work is to validate an algorithm that quantifies the locus of glenohumeral ligament (GHL) attachments on glenohumeral joint (GHJ) bones. A computed tomography scan of a GHJ was segmented to reconstruct the humerus, scapula, anatomical neck (AN) and glenoid rim (GR) into 3D meshes of interconnecting nodal vectors. These were applied to construct a 'clock face' coordinate system in which 3 o'clock points anteriorly. Based on the assigned clock face coordinate frame and the fitted plane, the error between the fitted plane and the actual bony node was quantified through manual data extraction. This was tested on 50 specimens. Mean algorithm quantification errors for GHL attachments were 4.8 (SD 2.2?mm) and 4.5?mm (1.7?mm) for the humerus and glenoid, respectively. Further studies would apply this to investigate GHL length changes during function and may suggest how these structures should be handled during surgical repairs.     

Efficient biostimulation of native and introduced quorum-quenching Rhodococcus erythropolis populations is revealed by a combination of analytical chemistry, microbiology, and pyrosequencing

Degradation of the quorum-sensing (QS) signals known as N-acylhomoserine lactones (AHL) by soil bacteria may be useful as a beneficial trait for protecting crops, such as potato plants, against the worldwide pathogen Pectobacterium. In this work, analytical chemistry and microbial and molecular approaches were combined to explore and compare biostimulation of native and introduced AHL-degrading Rhodococcus erythropolis populations in the rhizosphere of potato plants cultivated in farm greenhouses under hydroponic conditions. We first identified gamma-heptalactone (GHL) as a novel biostimulating agent that efficiently promotes plant root colonization by AHL-degrading R. erythropolis population. We also characterized an AHL-degrading biocontrol R. erythropolis isolate, R138, which was introduced in the potato rhizosphere. Moreover, root colonization by AHL-degrading bacteria receiving different combinations of GHL and R138 treatments was compared by using a cultivation-based approach (percentage of AHL-degrading bacteria), pyrosequencing of PCR-amplified rrs loci (total bacterial community), and quantitative PCR (qPCR) of the qsdA gene, which encodes an AHL lactonase in R. erythropolis. Higher densities of the AHL-degrading R. erythropolis population in the rhizosphere were observed when GHL treatment was associated with biocontrol strain R138. Under this condition, the introduced R. erythropolis population displaced the native R. erythropolis population. Finally, chemical analyses revealed that GHL, gamma-caprolactone (GCL), and their by-products, gamma-hydroxyheptanoic acid and gamma-hydroxycaproic acid, rapidly disappeared from the rhizosphere and did not accumulate in plant tissues. This integrative study highlights biostimulation as a potential innovative approach for improving root colonization by beneficial bacteria.     

Algorithm and validation of a computer method for quantifying attachment locus of glenohumeral ligament in vivo

The aim of this work is to validate an algorithm that quantifies the locus of glenohumeral ligament (GHL) attachments on glenohumeral joint (GHJ) bones.

A computed tomography scan of a GHJ was segmented to reconstruct the humerus, scapula, anatomical neck (AN) and glenoid rim (GR) into 3D meshes of interconnecting nodal vectors. These were applied to construct a ‘clock face’ coordinate system in which 3 o'clock points anteriorly.

Based on the assigned clock face coordinate frame and the fitted plane, the error between the fitted plane and the actual bony node was quantified through manual data extraction. This was tested on 50 specimens.

Mean algorithm quantification errors for GHL attachments were 4.8 (SD 2.2 mm) and 4.5 mm (1.7 mm) for the humerus and glenoid, respectively. Further studies would apply this to investigate GHL length changes during function and may suggest how these structures should be handled during surgical repairs.     

Further studies on the biological characteristics of an endogenous colon mitosis inhibitor: Comparison with some structurally related peptides

Previous work indicates that the colonic epithelial cell proliferation in mice is reversibly inhibited by the tripeptide pGlu-His-GlyOH found in aqueous extracts of the intestine. In the present study we examined the possible tissue specificity of the colon mitosis inhibitor. The mitotic rate in the small intestine, epidermis and forestomach in mice was registered after a single i.p. injection of the tripeptide. A significantly reduced rate of cell renewal was found at 18 h in the epidermis whereas no inhibition was observed in the forestomach or ileal epithelium. To investigate whether the amino acid sequence of the tripeptide is essential for the inhibitory effect, three structurally related bioactive peptides were tested and compared to the effect of CMI. CMI showed a bell-shaped dose-response relationship as previously shown, whereas the mitotic rate was not reduced in the colonie epithelium after treatment with either an epidermal mitosis inhibitory pentapeptide, or the dipeptide pGlu-GlyOH, or an analogue of luteinizing hormone-releasing hormone. The efficacy of the tripeptide was dependent on the basal rate of cell renewal in the colonie epithelium. When the tripeptide was given at the circadian nadir of cell proliferation a delayed reduction of the proliferative activity was observed at 6 h after treatment, whereas treatment when the rate of cell proliferation was at its circadian zenith gave an immediate mitotic inhibition.     

Further studies on the biological characteristics of an endogenous colon mitosis inhibitor: comparison with some structurally related peptides

Previous work indicates that the colonic epithelial cell proliferation in mice is reversibly inhibited by the tripeptide pGlu-His-GlyOH found in aqueous extracts of the intestine. In the present study we examined the possible tissue specificity of the colon mitosis inhibitor. The mitotic rate in the small intestine, epidermis and forestomach in mice was registered after a single i.p. injection of the tripeptide. A significantly reduced rate of cell renewal was found at 18 h in the epidermis whereas no inhibition was observed in the forestomach or ileal epithelium. To investigate whether the amino acid sequence of the tripeptide is essential for the inhibitory effect, three structurally related bioactive peptides were tested and compared to the effect of CMI. CMI showed a bell-shaped dose-response relationship as previously shown, whereas the mitotic rate was not reduced in the colonic epithelium after treatment with either an epidermal mitosis inhibitory pentapeptide, or the dipeptide pGlu-GlyOH, or an analogue of luteinizing hormone-releasing hormone. The efficacy of the tripeptide was dependent on the basal rate of cell renewal in the colonic epithelium. When the tripeptide was given at the circadian nadir of cell proliferation a delayed reduction of proliferative activity was observed at 6 h after treatment, whereas treatment when the rate of cell proliferation was at its circadian zenith gave an immediate mitotic inhibition.     

GHL1-GHL15: new families of hypothetical glycoside hydrolases

Domains of fifteen recently found families of hypothetical glycoside hydrolases (GHL1-GHL15) have been used for iterative screening of the protein database. Evolutionary connections between representatives of these families were revealed. Also, their relationship with members of the following known families of protein domains were found: GH5, GH13, GH13_33, GH17, GH18, GH20, GH27, GH29, GH31, GH35, GH36A, GH36B, GH36C, GH36D, GH36E, GH36F, GH36G, GH36H, GH36J, GH36K, GH39, GH42, GH53, GH66, GH97, GH101, GH107, GH112, GH114, COG1082, COG1306, COG1649, COG2342, DUF3111, and PF00962. The unclassified homologues were grouped into 35 new families of hypothetical glycoside hydrolases: GHL16-GHL50. Position of GHL1-GHL15 families in the hierarchical classification of glycoside hydrolases and their homologues is discussed. Several new superfamilies of protein domains are suggested.