Paulette Robinson

Connective tissue growth factor and integrin αvβ6: A new pair of regulators critical for ductular reaction and biliary fibrosis in mice

Connective tissue growth factor (CTGF) is a matricellular protein that mediates cell‐matrix interaction through various subtypes of integrin receptors. This study investigated the role of CTGF and integrin αvβ6 in hepatic progenitor/oval cell activation, which often occurs in the form of ductular reactions (DRs) when hepatocyte proliferation is inhibited during severe liver injury. CTGF and integrin αvβ6 proteins were highly expressed in DRs of human cirrhotic livers and cholangiocarcinoma. Confocal microscopy analysis of livers from Ctgf promoter‐driven green fluorescent protein reporter mice suggested that oval cells and cholangiocytes were the main sources of CTGF and integrin αvβ6 during liver injury induced by 3,5‐diethoxycarbonyl‐1,4‐dihydrocollidine (DDC). Deletion of exon 4 of the Ctgf gene using tamoxifen‐inducible Cre‐loxP system down‐regulated integrin αvβ6 in DDC‐damaged livers of knockout mice. Ctgf deficiency or inhibition of integrin αvβ6, by administrating the neutralizing antibody, 6.3G9 (10 mg/kg body weight), caused low levels of epithelial cell adhesion molecule and cytokeratin 19 gene messenger RNAs. Also, there were smaller oval cell areas, fewer proliferating ductular epithelial cells, and lower cholestasis serum markers within 2 weeks after DDC treatment. Associated fibrosis was attenuated, as indicated by reduced expression of fibrosis‐related genes, smaller areas of alpha‐smooth muscle actin staining, and low collagen production based on hydroxyproline content and Sirius Red staining. Finally, integrin αvβ6 could bind to CTGF mediating oval cell adhesion to CTGF and fibronection substrata and promoting transforming growth factor (TGF)‐β1 activation in vitro. Conclusions: CTGF and integrin αvβ6 regulate oval cell activation and fibrosis, probably through interacting with their common matrix and signal partners, fibronectin and TGF‐β1. CTGF and integrin αvβ6 are potential therapeutic targets to control DRs and fibrosis in related liver disease. (Hepatology 2015;61:678‐691)

Effect of Connective Tissue Growth Factor on Protein Kinase Expression and Activity in Human Corneal Fibroblasts

PURPOSE To investigate signal transduction pathways for connective tissue growth factor (CTGF) in human corneal fibroblasts (HCF). METHODS Expression of 75 kinases in cultures of serum-starved (HCF) were investigated using protein kinase screens, and changes in levels of phosphorylation of 31 different phosphoproteins were determined at 0, 5, and 15 minutes after treatment with CTGF. Levels of phosphorylation of three signal transducing phosphoproteins (extracellular regulated kinase 1 [ERK1], extracellular regulated kinase 2 [ERK2] [MAPKs], and signal transducer and activator of transcription 3 [STAT3]) were measured at nine time points after exposure to CTGF using Western immunoblots. Inhibition of Ras, MEK1/2 (MAPKK), and ERK1/2, on CTGF-stimulated fibroblast proliferation and collagen gel contraction was assessed using selective inhibitors farnesylthiosalicylic acid, PD-98059, and SB203580, respectively. RESULTS Thirty two of the 75 kinases (43%) evaluated by the kinase screen were detected in extracts of quiescent HCF, suggesting these kinases are available to respond acutely to CTGF exposure. Addition of CTGF increased levels of phosphorylation of five phosphoproteins (ERK1 and 2, MEK1/2 [MAPKK], STAT3, and SAPK/JNK), and decreased levels of phosphorylation of 14 phosphoproteins (including protein kinases B and C) after 5 and 15 minutes. Further analysis of ERK1 and 2 and STAT3 phosphorylation showed rapid increases within 1 minute of CTGF exposure that peaked between 5 and 10 minutes then returned to pretreatment levels by 30 minutes. Treatment of HCF with selective inhibitors of Ras, MEK 1/2, and ERK1/2 individually blocked both CTGF induced cell proliferation, and collagen gel contraction. CONCLUSIONS Results from protein kinase screens and selective kinase inhibitors demonstrate Ras/MEK/ERK/STAT3 pathway is required for CTGF signaling in HCF.

Hammerhead ribozyme-mediated knockdown of mRNA for fibrotic growth factors: transforming growth factor-beta 1 and connective tissue growth factor.

Excessive scarring (fibrosis) is a major cause of pathologies in multiple tissues, including lung, liver, kidney, heart, cornea, and skin. The transforming growth factor-β (TGF-β) system has been shown to play a key role in regulating the formation of scar tissue throughout the body. Furthermore, connective tissue growth factor (CTGF) has been shown to mediate most of the fibrotic actions of TGF-β, including stimulation of synthesis of extracellular matrix and differentiation of fibroblasts into myofibroblasts. Currently, no approved drugs selectively and specifically regulate scar formation. Thus, there is a need for a drug that selectively targets the TGF-β cascade at the molecular level and has minimal off-target side effects. This chapter focuses on the design of hammerhead ribozymes, measurement of kinetic activity, and assessment of knockdown mRNAs of TGF-β and CTGF in cell cultures.

A disintegrin and metalloprotease with thrombospondin type I motif 7: a new protease for connective tissue growth factor in hepatic progenitor/oval cell niche.

Hepatic progenitor/oval cell (OC) activation occurs when hepatocyte proliferation is inhibited and is tightly associated with the fibrogenic response during severe liver damage. Connective tissue growth factor (CTGF) is important for OC activation and contributes to the pathogenesis of liver fibrosis. By using the Yeast Two-Hybrid approach, we identified a disintegrin and metalloproteinase with thrombospondin repeat 7 (ADAMTS7) as a CTGF binding protein. In vitro characterization demonstrated CTGF binding and processing by ADAMTS7. Moreover, Adamts7 mRNA was induced during OC activation, after the implantation of 2-acetylaminofluorene with partial hepatectomy in rats or on feeding a 3,5-diethoxycarbonyl-1,4-dihydrocollidine (DDC) diet in mice. X-Gal staining showed Adamts7 expression in hepatocyte nuclear factor 4α(+) hepatocytes and desmin(+) myofibroblasts surrounding reactive ducts in DDC-treated Adamts7(-/-) mice carrying a knocked-in LacZ gene. Adamts7 deficiency was associated with higher transcriptional levels of Ctgf and OC markers and enhanced OC proliferation compared to Adamts7(+/+) controls during DDC-induced liver injury. We also observed increased α-smooth muscle actin and procollagen type I mRNAs, large fibrotic areas in α-smooth muscle actin and Sirius red staining, and increased production of hepatic collagen by hydroxyproline measurement. These results suggest that ADAMTS7 is a new protease for CTGF protein and a novel regulator in the OC compartment, where its absence causes CTGF accumulation, leading to increased OC activation and biliary fibrosis.

Toxicology and Pharmacology of an AAV Vector Expressing Codon-optimized RPGR in RPGR-deficient Rd9 Mice

Applied Genetic Technologies Corporation (AGTC) is developing a recombinant adeno-associated virus (rAAV) vector AGTC-501, also designated AAV2tYF-GRK1-RPGRco, to treat retinitis pigmentosa (RP) in patients with mutations in the retinitis pigmentosa GTPase regulator (RPGR) gene. The vector contains a codon-optimized human RPGR cDNA (RPGRco) driven by a photoreceptor-specific promoter (G protein-coupled receptor kinase 1, GRK1) and is packaged in an AAV2 capsid with three surface tyrosine residues changed to phenylalanine (AAV2tYF). We conducted a safety and potency study of this vector administered by subretinal a injection in the naturally occurring RPGR-deficient Rd9 mouse model. Sixty Rd9 mice (20 per group) received a subretinal injection in the right eye of vehicle (control) or AAV2tYF-GRK1-RPGRco at one of two dose levels (4 × 108 or 4 × 109 vg/eye) and were followed for 12 weeks after injection. Vector injections were well tolerated, with no systemic toxicity. There was a trend towards reduced electroretinography b-wave amplitudes in the high vector dose group that was not statistically significant. There were no clinically important changes in hematology or clinical chemistry parameters and no vector-related ocular changes in life or by histological examination. Dose-dependent RPGR protein expression, mainly in the inner segment of photoreceptors and the adjacent connecting cilium region, was observed in all vector-treated eyes examined. Sequence integrity of the codon-optimized RPGR was confirmed by sequencing of PCR-amplified DNA, or cDNA reverse transcribed from total RNA extracted from vector-treated retinal tissues, and by sequencing of RPGR protein obtained from transfected HEK 293 cells. These results support the use of rAAV2tYF-GRK1-RPGRco in clinical studies in patients with XLRP caused by RPGR mutations.

299. Safety and Biodistribution Study of rAAV2tYF-PR1.7-hCNGB3 in CNGB3-Deficient Mice

Background: AGTC is developing a recombinant adeno-associated virus (rAAV) vector expressing the human CNGB3 gene, for treatment of achromatopsia, an inherited retinal disorder characterized by markedly reduced visual acuity, extreme light sensitivity and absence of color discrimination. Here we report results of a toxicology and biodistribution study of this vector administered by subretinal injection in CNGB3-deficient mice. Methods: Three groups of CNGB3-deficient mice (n= 35 per sex per group) received a subretinal injection in one eye of 1 µL of vehicle (balanced salt solution with 0.014% Tween 20) or rAAV2tYF-PR1.7-hCNGB3 vector at a concentration of 1 × 1012 vg/mL (1 × 109 vg/eye) or 4 × 1012 vg/mL (4 × 109 vg/eye). The other eye was untreated. Ten animals/sex/group were used for toxicology evaluation with ophthalmic examinations and pathological evaluations, 10 animals/sex/group were used for biodistribution evaluation, and 15 animals/sex/group were used for efficacy evaluation. Half the animals in the biodistribution and toxicology groups were euthanized 4 weeks after vector administration and the remaining animals were euthanized 12 weeks after vector administration. For animals in the biodistribution groups, blood for qPCR analysis was obtained on Study Days 3, 8 and at euthanasia. At necropsy, samples of eyes, brain, heart, liver, gall bladder, kidneys, spleen, thymus, lungs, adrenals, ovaries, epididymides and testes were obtained for histopathology (for animals in the toxicology groups) or DNA PCR (for animals in the biodistribution groups). For animals scheduled for efficacy evaluations, electroretinography (ERG) testing included scotopic and photopic tests performed at Week 4, 8, and 12 on each eye and serum was collected at euthanasia for measurement of antibodies to AAV and hCNGB3. Results: There were no test article-related changes in clinical observations, body weights, food consumption, ocular examinations, clinical pathology parameters, organ weights, or macroscopic observations at necropsy. Cone-mediated ERG responses were detected after vector administration in the treated eyes in 90% of animals in the higher dose group, 31% of animals in the lower dose group, and none of the untreated or vehicle-treated eyes. Microscopic pathology results demonstrated minimal mononuclear cell infiltrates in the retina and vitreous of some animals at the interim euthanasia, and in the vitreous of some animals at the terminal euthanasia. Serum anti-AAV antibodies developed in most vector-injected animals. No animals developed antibodies to hCNGB3. Biodistribution studies demonstrated high levels of vector DNA in vector-injected eyes but little or no vector DNA in non-ocular tissue. Conclusions: Subretinal injection of rAAV2tYF-PR1.7-hCNGB3 in CNGB3-deficient mice was associated with no clinically important toxicology findings, rescue of cone-mediated ERG responses in vector-treated eyes, and vector DNA detection limited primarily to vector-injected eyes. These results support the use of rAAV2tYF-PR1.7-hCNGB3 in clinical studies in patients with achromatopsia caused by CNGB3 mutations. A Phase 1/2 clinical trial evaluating rAAV2tYF-PR1.7-hCNGB3 is scheduled to begin in 2016.

88. Safety and Biodistribution Study of rAAV2tYF-PR1.7-hCNGB3 in Nonhuman Primates

Background: AGTC is developing a recombinant AAV vector expressing the human CNGB3 gene for treatment of achromatopsia, an inherited retinal disorder characterized by markedly reduced visual acuity, extreme light sensitivity and absence of color discrimination. Here we report results of a toxicology and biodistribution study of this vector administered by subretinal injection in cynomolgus macaques. Methods: Three groups of animals (n=2 males and 2 females per group) received a subretinal injection in one eye of 300 µL containing either vehicle or rAAV2tYF-PR1.7-hCNGB3 at one of two concentrations (4 × 1011 or 4 × 1012 vg/mL) and were evaluated for safety and biodistribution over a 3-month period prior to euthanasia. Toxicity assessment was based on mortality, clinical observations, body weights, ophthalmic examinations, intraocular pressure (IOP) measurements, electroretinography (ERG), visual evoked potentials (VEP), and clinical and anatomic pathology. Vector shedding and biodistribution was assessed by qPCR analyses. Immune responses to AAV and hCNGB3 were measured by ELISA, Elispot, or neutralization antibody assay for AAV2tYF. Results: There was no evidence of local or systemic toxicity and no changes in IOP, VEP responses, or hematology, coagulation or clinical chemistry parameters and no clinically important changes in ERG responses. Aqueous cells, sometimes with aqueous flare, were observed at the Day 3 evaluation in all groups and generally resolved or were at the mild (1+) levels by Week 4 and absent on Week 8 and thereafter except in one high dose animal. Posterior segment findings consisted of varying degrees of dose-related white vitreous cell, vitreous haze, white retinal perivascular sheathing, and white to grey-white subretinal infiltrates within and outside of the injection site. Vitreous haze resolved by Day 8 in eyes given vehicle control, by Week 4 in the low dose group and by Week 13 in the high dose group. Vitreous cells were observed at the mild (trace or 1+) level in the vehicle control group and resolved by Study Weeks 9 or 13 but persisted through Week 13 in a dose-related fashion in the low and high dose groups. Serum neutralizing antibodies against AAV2tYF were detected in all animals given vector. There were no T cell responses to AAV capsid peptides and no antibody or T cell responses to hCNGB3. Mononuclear cell infiltrates in the vitreous body/optic disc, of minimal intensity, in the vector-injected eye of all animals at both dose levels. All other tissues collected for histopathological examination showed no abnormalities. Results of biodistribution studies demonstrated that the vector did not spread widely or consistently outside the injected eye. High levels of vector DNA were found in vector-injected eyes but minimal or no vector DNA was found in any other tissue. Conclusions: Subretinal injection of rAAV2tYF-PR1.7-hCNGB3 at concentrations of 4 × 1011 or 4 × 1012 vg/mL was associated with a dose-related anterior and posterior segment inflammatory response that improved over time. There was no evidence of systemic toxicity and no changes in IOP, VEP responses, or hematology, coagulation or clinical chemistry parameters and no clinically important changes in ERG responses. These results support the use of rAAV2tYF-PR1.7-hCNGB3 in clinical studies in patients with achromatopsia. A Phase 1/2 clinical trial evaluating rAAV2tYF-PR1.7-hCNGB3 in patients with achromatopsia is scheduled to begin in 2016.

Chapter 17 – Introduction to Hepatic Progenitor Cells

Normal healthy livers have highly regenerative capabilities, but diseased livers have reduced (or lack the) ability to regenerate. When hepatocytes are prevented from initiating the regenerative response due to chronic or overwhelming injury then the liver stem cell compartment is activated and gives rise to the liver progenitor cell (oval cell) population. Oval cells are bipotential cells that are capable of differentiating into either hepatocyte or biliary lineages. In this chapter, we will review several aspects of liver progenitor cells in liver regeneration including cell markers, animal models, molecular regulation, their role in fibrosis, and possible therapeutic targets.