Substrate Strain Mitigates Effects of β-Aminopropionitrile-Induced Reduction in Enzymatic Crosslinking

Enzymatic crosslinks stabilize type I collagen and are catalyzed by lysyl oxidase (LOX), a step interrupted through β-aminopropionitrile (BAPN) exposure. This study evaluated dose-dependent effects of BAPN on osteoblast gene expression of type I collagen, LOX, and genes associated with crosslink formation. The second objective was to characterize collagen produced in vitro after exposure to BAPN, and to explore changes to collagen properties under continuous cyclical substrate strain. To evaluate dose-dependent effects, osteoblasts were exposed to a range of BAPN dosages (0-10 mM) for gene expression analysis and cell proliferation. Results showed significant upregulation of BMP-1, POST, and COL1A1 and change in cell proliferation. Results also showed that while the gene encoding LOX was unaffected by BAPN treatment, other genes related to LOX activation and matrix production were upregulated. For the loading study, the combined effects of BAPN and mechanical loading were assessed. Gene expression was quantified, atomic force microscopy was used to extract elastic properties of the collagen matrix, and Fourier Transform infrared spectroscopy was used to assess collagen secondary structure for enzymatic crosslinking analysis. BAPN upregulated BMP-1 in static samples and BAPN combined with mechanical loading downregulated LOX when compared to control-static samples. Results showed a higher indentation modulus in BAPN-loaded samples compared to control-loaded samples. Loading increased the mature-to-immature crosslink ratios in control samples, and BAPN increased the height ratio in static samples. In summary, effects of BAPN (upregulation of genes involved in crosslinking, mature/immature crosslinking ratios, upward trend in collagen elasticity) were mitigated by mechanical loading.

High glucose increases lysyl oxidase expression and activity in retinal endothelial cells: mechanism for compromised extracellular matrix barrier function

OBJECTIVE

In diabetes, retinal vascular basement membrane (BM) undergoes significant thickening and compromises vessel function including increased vascular permeability, a prominent lesion of early diabetic retinopathy. In this study we determined whether altered expression and activity of lysyl oxidase (LOX), a cross-linking enzyme, may compromise vascular basement membrane functional integrity under high-glucose (HG) conditions.

RESEARCH DESIGN AND METHODS

Rat retinal endothelial cells (RRECs) grown in normal (5 mmol/l) or HG (30 mmol/l glucose) medium for 7 days were assessed for expression of LOX and proLOX by Western blot analysis and LOX enzyme activity. To determine whether HG alters cellular distribution patterns of LOX and proLOX, immunostaining with respective antibodies was performed. Similarly, cells grown in normal or HG medium were subjected to both LOX inhibition with β-aminopropionitrile (BAPN) and by small interfering RNA knockdown, and respectively examined for cell monolayer permeability. Additionally, retinas of streptozotocin (STZ)-induced diabetic rats were analyzed to determine if diabetes altered LOX expression.

RESULTS

Western blot analysis revealed significantly increased LOX and proLOX expression in cells grown in HG medium compared with those grown in normal medium. The increased LOX level was strikingly similar to LOX upegulation in the diabetic retinas. In cells grown in HG medium, LOX activity and cell monolayer permeability was significantly increased, as were LOX and proLOX immunostaining. Small interfering RNA- or BAPN-induced-specific blockage of LOX expression or activity, respectively, reduced cell monolayer permeability.

CONCLUSIONS

HG-induced increased LOX expression and activity compromises barrier functional integrity, a prominent lesion of diabetic retinopathy.

Developmental toxicity of cartap on zebrafish embryos

Cartap is a widely used insecticide which belongs to a member of nereistoxin derivatives and acts on nicotinic acetylcholine receptor site. Its effects on aquatic species are of grave concern. To explore the potential developmental toxicity of cartap, zebrafish embryos were continually exposed, from 0.5 to 144h post-fertilization, to a range of concentrations of 25-1000microg/l. Results of the experiment indicated that cartap concentrations of 100microg/l and above negatively affected embryo survival and hatching success. Morphological analysis uncovered a large suite of abnormalities such as less melanin pigmentation, wavy notochord, crooked trunk, fuzzy somites, neurogenesis defects and vasculature defects. The most sensitive organ was proved to be the notochord which displayed defects at concentrations as low as 25microg/l. Both sensitivity towards exposure and localization of the defect were stage specific. To elucidate mechanisms concerning notochord, pigmentation, and hatching defects, enzyme assay, RT Q-PCR, and different exposure strategies were performed. For embryos with hatching failure, chorion was verified not to be digested, while removing cartap from exposure at early pre-hatching stage could significantly increase the hatching success. However, cartap was proved, via vitro assay, to have no effect on proteolytic activity of hatching enzyme. These findings implied that the secretion of hatching enzyme might be blocked. We also revealed that cartap inhibited the activity of melanogenic enzyme tyrosinase and matrix enzyme lysyl oxidase and induced expression of their genes. These suggested that cartap could impaired melanin pigmentation of zebrafish embryos through inhibiting tyrosinase activity, while inhibition of lysyl oxidase activity was responsible for notochord undulation, which subsequently caused somite defect, and at least partially responsible for defects in vasculature and neurogenesis.

Lysyl oxidase activity in the cells of flexor retinaculum of individuals with carpal tunnel syndrome

Lysyl oxidase (LO) is produced by myofibroblast cells in some tissues and can be influenced by transforming growth factor beta 1 (TGF beta 1). Myofibroblast-like cells are present in the flexor reticulum of patients with carpal tunnel syndrome (CTS). The goal of the current study was to determine LO activity and the effects of TGF beta 1 on LO expression in the cells from patients with CTS. Tissues from both hands of five individuals with CTS were used for this study. LO activity with and without TGF beta 1 stimulation was assayed in 7-day cell culture specimens. A significant difference in LO activity among individual patients, but not between right and left hands of the same patient, was observed. There was no correlation between the severity of CTS determined by nerve conduction studies and LO activity. Addition of TGF beta 1 significantly increased LO in all cell lines.

Activation of chick tendon lysyl oxidase in response to dietary copper

Lysyl oxidase (EC 1.4.3.13), a cuproenzyme, can account for 10-30% of the copper present in connective tissue. Herein, we assess the extent to which tissue copper concentrations and lysyl oxidase activity are related because the functional activity of lysyl oxidase and the copper content of chick tendon are both related to dietary copper intake. Chicks (1-d old) were fed diets (basal copper concentration, 0.4 microg/g diet) to which copper was added from 0 to 16 microg/g diet. Liver and plasma copper levels tended to normalize in chickens that consumed from 1 to 4 microg copper/g of diet, whereas tendon copper concentrations suggested an unusual accumulation of copper in chickens that consumed 16 microg copper/g diet. The molecular weight of lysyl oxidase was also estimated using matrix-assisted laser desorption ionization/time-of-flight/mass spectrometry (MALDI/TOF/MS). A novel aspect of these measurements was estimation of protein mass directly from the surface of chick tendons and aortae. Whether copper deficiency (0 added copper) or copper supplementation (16 microg copper/g of diet) caused changes in the molecular weight of protein(s) in tendon corresponding to lysyl oxidase was addressed. The average molecular weight of the peak corresponding to lysyl oxidase in tendon and aorta from copper-deficient birds was 28,386 Da +/- 86, whereas the average molecular weight of corresponding protein in tendon from copper-supplemented birds was 28,639 Da +/- 122. We propose that the shift in molecular weight is due in part to copper binding and the formation of lysyl tyrosyl quinone, the cofactor at the active site of lysyl oxidase.

Regulation of lysyl oxidase and cyclooxygenase expression in human lung fibroblasts: interactions among TGF-beta, IL-1 beta, and prostaglandin E

Prostaglandin E2, transforming growth factor-beta, and interleukin-1 beta variably regulate the expression of cyclooxygenase 1, cyclooxygenase 2, and lysyl oxidase in IMR90, human embryo lung fibroblasts. Prostaglandin E2 at 100 nM upregulates cyclooxygenase 1 mRNA by approximately three-fold while it downregulates lysyl oxidase mRNA levels. Notably, prostaglandin E2 suppresses the enhancing effect of TGF-beta on basal levels of lysyl oxidase mRNA. These changes in steady state mRNA levels reflect transcriptional level control, at least in part. Corresponding changes are seen in the protein levels of lysyl oxidase, cyclooxygenase 1 and cyclooxygenase 2 and catalytic activities of these enzymes, including net prostaglandin E2 synthesis. Cyclooxygenase 2 mRNA(t1/2, 30 min) is considerably less stable than that of cyclooxygenase 1 (t1/2, 4 h) while lysyl oxidase mRNA is unusually stable (t1/2 > 14 h). Taken together with the differing kinetics with which these genes respond to perturbation by these cytokines, the present results suggest a coordinated, autocrine-like mechanism of regulation of cyclooxygenase 1 and cyclooxygenase 2 and further point to the potential of their metabolic product, prostaglandin E2, to suppress the expression of lysyl oxidase in the inflammatory response to injury.

Reduced concentrations of collagen cross-links are associated with reduced strength of bone

The known cross-links of bone collagen are derived from lysine and hydroxylysine. The first step in the enzymatic cross-linking process is a deamination by lysyl oxidase producing an aldehyde which then may condense with a lysyl or hydroxylysyl residue of a neighbouring collagen molecule. Some of the resulting divalent aldimine and oxo-imine cross-links may later on be incorporated in trivalent hydroxylysyl-pyridinoline and lysyl-pyridinoline cross-links. In bone collagen prepared from the cancellous bone of vertebral bodies of osteoporotic individuals we found a reduced stability towards acetic acid and pepsin, and a substantial reduction in the concentration of the divalent collagen cross-links compared with sex- and age-matched controls. To what extent do the collagen cross-links influence the mechanical properties of bone? beta-amino-propionitrile (BAPN) irreversibly inhibits the enzyme lysyl oxidase and therefore, the formation of cross-links between the collagen molecules. In the present study female rats, 70 days old, injected subcutaneously two times daily with BAPN (333 mg/kg/day) for 1 month and saline injected control rats were studied. The concentration of the hydroxypyridinium cross-links of femoral mid-diaphyseal cortical bone was determined by HPLC with fluorescence detection and the mechanical properties of the rat femoral diaphyses were analyzed by a materials testing machine. The BAPN injections resulted in a 45% reduction in the concentration of the hydroxypyridinium cross-links and a 31% decrease in the stability of the bone collagen towards acetic acid and pepsin compared with the control rats. No changes were found in ash or collagen concentrations of the cortical bone.(ABSTRACT TRUNCATED AT 250 WORDS)

Inhibition of aortic aneurysm development in blotchy mice by beta adrenergic blockade independent of altered lysyl oxidase activity

PURPOSE

This study was designed to define the effects of beta-adrenergic blockade on aortic lysyl oxidase (LO), an enzyme responsible for elastin and collagen cross-linking, and aneurysm formation in the blotchy mouse. It was hypothesized that beta-blockade would inhibit the development of aneurysms because of its hemodynamic effect rather than a direct effect on LO activity.

METHODS

Three groups of mice were studied: group I--normal littermates of blotchy mice; group II--untreated blotchy mice; group III--blotchy mice given either propranolol, atenolol, or nadolol. Data from the three different beta blocker-treated animals, group III, were statistically identical and were combined for analysis. The study was concluded when the mice were 4 months of age. At that time systolic blood pressure, heart rate, and aortic diameters were measured, and the entire aorta from each mouse was subjected to a bioassay for LO activity.

RESULTS

Group I normal mice had an aortic arch diameter of 0.10 +/- 0.02 cm. Group II blotchy mice developed aortic arch aneurysms with a diameter of 0.21 +/- 0.03 cm. In Group III, beta blockade reduced the aortic arch diameter in blotchy mice to 0.11 +/- 0.03 cm. Mean heart rate in group III beta-blocked mice was reduced 25% compared with group I normal mice, and 18% compared with group II untreated blotchy mice. Blood pressures were similar in all three groups. Group II blotchy mice exhibited approximately half of the aortic LO activity (2.43 +/- 0.57 cpm/micrograms protein) noted in group I normal mice (5.82 +/- 1.06 cpm/micrograms protein). Aortic LO activity in group III blotchy mice remained low (2.09 +/- 0.85 cpm/micrograms protein) despite administration of beta-blockers.

CONCLUSIONS

This is the first study to document an actual decrease in the level of aortic LO activity in blotchy mouse. beta-Blockade inhibits development of aortic aneurysms in blotchy mice. This is associated with a reduction in heart rate, but not by alterations in LO activity.

Osteolathyrogenic effects of malathion in Xenopus embryos

Malathion, an organophosphorus insecticide, has been found previously to cause developmental defects such as enlargement of the atria and aorta and bent notochord in Xenopus laevis. Since these defects are similar to those caused by known lathyrogens, the effects of malathion on collagen biochemistry and structure were studied. Embyros were exposed to malathion or its metabolite malaoxon during the first 4 days of development. Notochords of malathion- and malaoxon-treated embryos were bent ventrally between the third and sixth somites and were enlarged. Ultrastructural examination of the postanal tail notochord showed that the elastic externa was disorganized and less dense and the sheath had fewer, more disorganized fibers. Embryos exposed in culture displayed a concentration-dependent reduction in ascorbate and hydroxyproline. Malathion and malaoxon inhibited the activities of lysyl oxidase (I50s of 0.7 and 8.7 nM, respectively) and proline hydroxylase (I50s of 58 microM and 49.9 nM, respectively) in homogenates of Xenopus embryos. These data suggest that malathion and malaoxon alter posttranslational modification of collagen, with resultant morphological defects in connective tissue.