Michael T. Ivy

A unique covalent bond in basement membrane is a primordial innovation for tissue evolution

Significance The evolution of multicellular animals from single-celled ancestors was one of the most significant transitions of life on earth. The emergence of larger, more complex animals able to resist predation and colonize new environments was enabled, in part, by a collagen scaffold, which anchors cells together to form tissues and organs. Here, we show that a unique chemical bond, a link between sulfur and nitrogen atoms called a sulfilimine bond, arose over 500 Mya, binding this scaffold together and enabling tissues to withstand mechanical forces. Peroxidasin forms the bond by generating hypohalous acids as strong oxidants, a form of bleach, which normally function as antimicrobial agents. These understandings may lead to approaches for targeting tumors and treatment of other diseases. Basement membrane, a specialized ECM that underlies polarized epithelium of eumetazoans, provides signaling cues that regulate cell behavior and function in tissue genesis and homeostasis. A collagen IV scaffold, a major component, is essential for tissues and dysfunctional in several diseases. Studies of bovine and Drosophila tissues reveal that the scaffold is stabilized by sulfilimine chemical bonds (S = N) that covalently cross-link methionine and hydroxylysine residues at the interface of adjoining triple helical protomers. Peroxidasin, a heme peroxidase embedded in the basement membrane, produces hypohalous acid intermediates that oxidize methionine, forming the sulfilimine cross-link. We explored whether the sulfilimine cross-link is a fundamental requirement in the genesis and evolution of epithelial tissues by determining its occurrence and evolutionary origin in Eumetazoa and its essentiality in zebrafish development; 31 species, spanning 11 major phyla, were investigated for the occurrence of the sulfilimine cross-link by electrophoresis, MS, and multiple sequence alignment of de novo transcriptome and available genomic data for collagen IV and peroxidasin. The results show that the cross-link is conserved throughout Eumetazoa and arose at the divergence of Porifera and Cnidaria over 500 Mya. Also, peroxidasin, the enzyme that forms the bond, is evolutionarily conserved throughout Metazoa. Morpholino knockdown of peroxidasin in zebrafish revealed that the cross-link is essential for organogenesis. Collectively, our findings establish that the triad—a collagen IV scaffold with sulfilimine cross-links, peroxidasin, and hypohalous acids—is a primordial innovation of the ECM essential for organogenesis and tissue evolution.

Synergistic effect of pro-inflammatory TNFα and IL-17 in periostin mediated collagen deposition: Potential role in liver fibrosis

BACKGROUND The pro-inflammatory cytokines, tumor necrosis factor (TNF)-α, and interleukin (IL)-17, have been implicated in the pathogenesis of liver fibrosis. In this study, we investigated the role of TNFα and IL-17 toward induction of profibrotic factor, periostin. METHODS HepG2 cells were cultured and treated with inflammatory cytokines, TNFα and IL-17. Computational promoter sequence analysis of the periostin promoter was performed to define the putative binding sites for transcription factors. Transcription factors were analyzed by Western blot and Chromatin Immunoprecipitation. Periostin and transcription factor expression analysis was performed by RT-PCR, Western blot, and fluorescence microscopy. Type I collagen expression from fibroblast cultures was analyzed by Western blot and Sircol soluble collagen assay. RESULTS Activation of HepG2 Cells with TNFα and IL-17 enhanced the expression of periostin (3.5 and 4.4 fold, respectively p<0.05) compared to untreated cells. However, combined treatment with both TNFα and IL-17 at similar concentration demonstrated a 13.3 fold increase in periostin (p<0.01), thus suggesting a synergistic role of these cytokines. Periostin promoter analysis and specific siRNA knock-down revealed that TNFα induces periostin through cJun, while IL-17 induced periostin via STAT-3 signaling mechanisms. Treatment of the supernatant from the cytokine activated HepG2 cells on fibroblast cultures induced enhanced expression of type I collagen (>9.1 fold, p<0.01), indicative of a direct fibrogenic effect of TNFα and IL-17. CONCLUSION TNFα and IL-17 induced fibrogenesis through cJun and STAT-3 mediated expression of profibrotic biomarker, periostin. Therefore, periostin might serve as a novel biomarker in early diagnosis of liver fibrosis.

The involvement of protein kinase C in the regulation of choline cotransport in Limulus.

The involvement of protein kinase C (PKC) in the regulation of [3H]choline cotransport was studied in Limulus brain hemi-slice preparations. The PKC activators, phorbol 12-myristate 13-acetate (PMA) or phorbol 12,13-dibutyrate (PDBu), significantly decreased [3H]choline cotransport. Conversely, the PKC inhibitors, staurosporine (STAURO) and polymyxin B (PMB), each increased [3H]choline cotransport. These PKC inhibitors prevented the phorbol ester-induced reduction of transport. Both the PMA induced decrease and the STAURO induced increase in [3H]choline cotransport were paralleled by respective and comparable changes in [3H]hemicholinium-3 (HC-3) specific binding. Pre-exposure of brain hemi-slices to elevated potassium chloride (120 mM KCl) resulted in a doubling of [3H]choline cotransport and [3H]HC-3 binding. The enhancement of [3H]choline cotransport by STAURO and antecedent 120 mM KCl treatment were additive. PMA did not significantly alter elevated potassium stimulated transport. Moreover, arachidonyltrifluoromethyl ketone (AACOCF3) and quinacrine (QUIN), both phospholipase A2 (PLA2) inhibitors, markedly decreased enhanced [3H]choline transport and [3H]HC-3 binding induced by antecedent exposure to depolarizing concentrations of potassium. These results suggest that PKC and PLA2 are involved in the regulation of [3H]choline cotransport but at different regulatory sites.

Effect of 2-(4-phenylpiperidino)cyclohexanol (AH 5183) on the veratridine-induced increase in acetylcholine synthesis by rat hippocampal tissue.

Abstract: The intent of this study was to determine whether the drug 2‐(4‐phenylpiperidino)cyclohexanol (AH 5183 or vesamicol) might inhibit the veratridine‐induced increase in acetylcholine (ACh) synthesis by reducing the veratridine‐induced activation of a detergent‐soluble choline‐O‐acetyltransferase (EC 2.3.1.6; ChAT) fraction associated with a vesicle‐bound store of ACh. When minces of rat hippocampal tissue were loaded with [14C]choline and subsequently depolarized with veratridine, an increase in the synthesis of [14C]ACh occurred that could be abolished by l‐AH 5183 (75 nM). When minces were depolarized with veratridine in the presence of l‐AH 5183 (75 nM), the depolarization‐induced activation of a detergent‐soluble ChAT fraction associated with a vesicle‐bound store of ACh was blocked. Conversely, the veratridine‐induced activation of a water‐soluble ChAT fraction believed to be cytosolic was not. AH 5183 also blocked the repletion of the vesicle‐bound store with newly synthesized ACh following veratridine‐induced depletion of ACh, a result that appeared to be mediated by an effect on the synthesis of ACh at the vesicular surface. These results suggest that veratridine depolarization of rat hippocampal nerve terminals stimulates the synthesis of ACh by activating a detergentsoluble fraction of ChAT closely associated with synaptic vesicle release sites. ACh synthesis and transport at the vesicular surface may be influenced by a common AH 5183‐sensitive regulatory protein.

The distribution of cholinergic components in a marine arthropod

Abstract 1. The distribution of several cholinergic components generally accepted as being associated with cholinergic transmission was studied in Limulus nerve and muscle tissue. 2. Acetylcholine (ACh) and choline were distributed among all the tissues assayed, with abdominal ganglia showing the highest concentration of both. 3. Corpora pedunculata showed the greatest enrichment of choline acetyltransferase (ChAT) and the brain nerve roots had the highest levels of acetylcholinesterase (AChE) activity. No direct correlation was found between levels of ChAT and the amount of measurable ACh in a tissue. 4. Tissue/medium (T/M) ratios indicative of high affinity [ 3 H]choline uptake were selectively distributed, ranging from 13.22 to 4.62 in corpora pedunculata, circumoesophageal ring, abdominal ganglia and cardiac ganglion. All these tissues, with the exception of cardiac ganglion, released [ 3 H]ACh in a Ca 2+ dependent fashion in response to treatment with elevated potassium (90 mM). 5. Cardiac ganglion was found not to synthesize [ 3 H]ACh and had no detectable levels of ChAT activity. 6. These results suggest that high affinity [ 3 H]choline uptake is not exclusively associated with the synthesis of [ 3 H]ACh and hence is not a unique property of cholinergic neurons and/or terminals.

Sodium channel γENaC mediates IL-17 synergized high salt induced inflammatory stress in breast cancer cells.

Chronic inflammation is known to play a critical role in the development of cancer. Recent evidence suggests that high salt in the tissue microenvironment induces chronic inflammatory milieu. In this report, using three breast cancer-related cell lines, we determined the molecular basis of the potential synergistic inflammatory effect of sodium chloride (NaCl) with interleukin-17 (IL-17). Combined treatment of high NaCl (0.15M) with sub-effective IL-17 (0.1 nM) induced enhanced growth in breast cancer cells along with activation of reactive nitrogen and oxygen (RNS/ROS) species known to promote cancer. Similar effect was not observed with equi-molar mannitol. This enhanced of ROS/RNS activity correlates with upregulation of γENaC an inflammatory sodium channel. The similar culture conditions have also induced expression of pro-inflammatory cytokines such as IL-6, TNFα etc. Taken together, these data suggest that high NaCl in the cellular microenvironment induces a γENaC mediated chronic inflammatory response with a potential pro-carcinogenic effect.

Biochemical evidence for cholinergic involvement in the Limulus brain

The transport of [3H]choline by the corpora pedunculata of the circumoesophageal ring gland (brain) of Limulus polyphemus was studied. Corpora pedunculata slices were incubated individually in Chaos solution containing 0.01 microM [3H]choline at room temperature (25 +/- 2 degrees C) and readily accumulated the radiolabel from the extracellular environment. The corpora pedunculata uptake of [3H]choline was linear over 60 min. The kinetic analysis indicated the existence of dual uptake systems for choline within the corpora pedunculata, a high affinity choline uptake process (Km = 0.54 microM and Vmax = 0.037 pmoles/mg/min) and a low affinity process (Km = 137 microM and Vmax = 6.3 pmoles/mg/min). The high affinity choline transport system was dependent on sodium ions and was inhibited by micromolar concentrations of hemicholinium-3. The pre-exposure of the corpora pedunculata to Chaos solution containing 90 mM potassium for 15 min resulted in a 24% increase in the velocity of the high affinity choline uptake process (Vmax = 0.046 pmoles/mg/min). The 90 mM potassium Chaos pretreatment stimulated a substantial increase in the synthesis of [3H]acetylcholine by the corpora pedunculata. The results suggest that the high affinity choline uptake process within the Limulus corpora pedunculata is associated with the synthesis of the transmitter acetylcholine, presumably within cholinergic terminals in this tissue.

A novel choline cotransporter sequestration compartment in cholinergic neurons revealed by selective endosomal ablation.

J. Neurochem. (2010) 112, 1295–1304.

The use of competitive PCR mimic to evaluate a Limulus lambda phage genomic DNA library.

Abstract1. A λ phage genomic DNA library for Limulus (L.) polyphemus brain was constructed using the λGEM-12 vector and the host strain KW251.2. The primary library contained approximately 1.275 × 106 independent clones, increasing upon amplfication to 6.66 × 109 pfu/ml in a total volume of 58 ml.3. A total of 28 clones was randomly chosen for a determination of the average size of inserts in the library. All clones contained inserts and the average size was 14.9 kb, ranging from 11.7 to 28.0 kb. The library provides a 10-fold equivalent of the L. polyphemus genome.4. A new approach for evaluating a genomic DNA library was developed, in which competitive PCR MIMIC was employed to determine the target gene copy number in both constructed library and brain genomic DNA. The putative protein kinase C ε (PKCε) was selected as the target gene because its partial sequence of cDNA was recently cloned from L. polyphemus brain in our laboratory (Cao et al., 1998). A 419-bp fragment of nonhomologous sequence derived from putative PKCε and a 306-bp fragment from plasmid pUC 18 were generated for use as target and competitor in PCR MIMIC, respectively.5. Within the genomic library DNA, a 0.8 value was obtained for the copy number of the putative PKCε gene that was detected in 0.1 amol of one equivalent L. polyphemus genome in terms of the average recombinant molecular weight. In the genomic DNA, a single copy of putative PKCε was found in 0.1 amol of one coverage for the L. polyphemus genome. Thus, it was implied that nearly 80% genetic resource was incorporated into the library. This percentage was termed the incorporation rate.6. Based on these findings, we suggest that the incorporation rate is an essential factor for evaluating genomic libraries, particularly, when using partial digestion with restriction enzymes for library construction.

A comparative study of high affinity choline uptake and choline utilization in cholinergic and non-cholinergic tissues

Comparative studies of [3H]choline accumulation were done in the Limulus corpora pedunculata, abdominal ganglia and cardiac ganglion. Dual uptake processes for choline were found in all three tissues. In acute experiments, the corpora pedunculata high affinity choline uptake system showed exclusive sensitivity to ouabain. Prolonged exposure to ouabain revealed that the HAChUS of all three tissues were significantly inhibited. The metabolism of [3H]choline transported via the high affinity process in the three tissues was studied. [3H]Acetylcholine was a major product of the [3H]choline taken up by the corpora pedunculata and the abdominal ganglia. Phosphorylcholine was the major product seen in cardiac ganglion extracts and occurred in significant proportions in abdominal ganglia extracts. [3H]Acetylcholine was not detected in cardiac ganglion extracts. Treatment with either lithium chloride or hemicholinium-3 markedly inhibited high affinity uptake of [3H]choline in all three tissues.