Cornelis A.M. Jongenelen

Establishment of human adult astrocyte cultures derived from postmortem multiple sclerosis and control brain and spinal cord regions: immunophenotypical and functional characterization

We have successfully established highly enriched astrocyte cultures upon passaging of primary cultures derived from various regions of postmortem human adult brain and spinal cord. Tissues were collected at autopsies with relatively short postmortem times (3–9 hr) from multiple sclerosis (MS) and (normal) control cases. Immunocytochemical analysis showed that primary cultures were composed of colonies of oligoclonal cells that expressed the intermediate filament proteins glial fibrillary acidic protein (GFAP), vimentin, as well as glutamine synthetase (GS). Passaging the astrocytes did not affect their proliferating capacity as monitored by bromodeoxyuridine (BrdU) incorporation. Astrocyte‐specific markers were stably expressed for at least 12 passages per individual tissue sample. Large numbers of GFAP‐positive astrocytes were obtained from each sample and could be stored frozen and recultured. Very few macrophages/microglial cells (1–3%) were present in the human adult astrocyte cultures, using a panel of macrophage‐specific markers. However, the monoclonal antibodies (mAbs KP1, EBM11, 25F9) and lysozyme antiserum directed against lysosomal antigens strongly immunostained cultured astrocytes derived from MS and control cases, implicating that expression of these lysosomal antigens is not restricted to macrophages/microglial cells in human glial cell cultures. Interestingly, astrocytes derived from active demyelinated MS lesions showed an increased proliferating capacity compared to astrocytes derived from non‐lesioned and normal brain and spinal cord regions, as shown with a microculture tetrazolium assay (MTT assay). J. Neurosci. Res. 49:342–354, 1997.

Astrocyte-Derived Tissue Transglutaminase Interacts with Fibronectin: A Role in Astrocyte Adhesion and Migration?

An important neuropathological feature of neuroinflammatory processes that occur during e.g. Multiple Sclerosis (MS) is the formation of an astroglial scar. Astroglial scar formation is facilitated by the interaction between astrocytes and extracellular matrix proteins (ECM) such as fibronectin. Since there is evidence indicating that glial scars strongly inhibit both axon growth and (re)myelination in brain lesions, it is important to understand the factors that contribute to the interaction between astrocytes and ECM proteins. Tissue Transglutaminase (TG2) is a multifunctional enzyme with an ubiquitous tissue distribution, being clearly present within the brain. It has been shown that inflammatory cytokines can enhance TG2 activity. In addition, TG2 can mediate cell adhesion and migration and it binds fibronectin with high affinity. We therefore hypothesized that TG2 is involved in astrocyte-fibronectin interactions. Our studies using primary rat astrocytes show that intracellular and cell surface expression and activity of TG2 is increased after treatment with pro-inflammatory cytokines. Astrocyte-derived TG2 interacts with fibronectin and is involved in astrocyte adhesion onto and migration across fibronectin. TG2 is involved in stimulating focal adhesion formation which is necessary for the interaction of astrocytes with ECM proteins. We conclude that astrocyte-derived TG2 contributes to the interaction between astrocytes and fibronectin. It might thereby regulate ECM remodeling and possibly glial scarring.

Blockade of enzyme activity inhibits tissue transglutaminase-mediated transamidation of α-synuclein in a cellular model of Parkinson's disease

Transamidation of α-synuclein by the Ca(2+)-dependent enzyme tissue transglutaminase (tTG, EC 2.3.2.13) is implicated in Parkinsons disease (PD). tTG may therefore offer a novel therapeutic target to intervene in PD. Here we first evaluated the potency and efficacy of three recently developed irreversible active-site inhibitors of tTG (B003, Z006 and KCC009) to inhibit tTG activity in vitro and in living cells. In vitro, all compounds were found to be full inhibitors of tTG activity showing a rank order of potency (defined by IC-50 values) of Z006>B003>KCC009. Upon Ca(2+) ionophore (A23187) induced activation of cellular tTG (measured by incorporation of the tTG-specific amine substrate 5-(biotinamido)pentylamine (BAP) into cellular proteins) in neuroblastoma SH-SY5Y cells, only Z006 (0.3-30 μM) retained the capacity to completely inhibit tTG activity. Under these conditions B003 (3-300 μM) only partially blocked tTG activity whereas KCC009 (3-100 μM) failed to affect tTG activity at any of the concentrations used. Z006 (30 μM) also blocked the tTG mediated incorporation of BAP into α-synuclein monomers and SDS-resistant multimers in vitro and in α-synuclein overexpressing SHSY5Y cells exposed to A23187 or the PD mimetic 1-methyl-4-phenylpyridine (MPP(+)). Moreover, Z006 (30 μM) substantially reduced formation of SDS-resistant α-synuclein multimers in SH-SY5Y cells exposed to A23187 or MPP(+) in the absence of BAP. We conclude that α-synuclein is a cellular substrate for tTG under conditions mimicking PD and blockade of tTG activity counteracts α-synuclein transamidation and aggregation in vitro and in living cells. Moreover, our cell model appears an excellent readout to identify candidate inhibitors of intracellular tTG.

Increase in endoplasmic reticulum-associated tissue transglutaminase and enzymatic activation in a cellular model of Parkinson's disease

Parkinsons disease (PD) is characterized by accumulation of α-synuclein aggregates and degeneration of melanized, catecholaminergic neurons. The tissue transglutaminase (tTG) enzyme catalyzes molecular protein cross-linking. In PD, tTG levels are increased and cross-linking has been identified as an important factor in α-synuclein aggregation. In our quest to link tTGs distribution in the human brain to the hallmarks of PD pathology, we recently reported that catecholaminergic neurons in PD disease-affected brain areas display typical endoplasmic reticulum (ER) granules showing tTG immunoreactivity. In the present study, we set out to elucidate the nature of the interaction between tTG and the ER in PD pathogenesis, using retinoic-acid differentiated SH-SY5Y cells exposed to the PD-mimetic 1-methyl-4-phenylpyridinium (MPP(+)). Alike our observations in PD brain, MPP(+)-treated cells displayed typical TG-positive granules, that were also induced by other PD mimetics and by ER-stress inducing toxins. Additional immunocytochemical and biochemical investigation revealed that tTG is indeed associated to the ER, in particular at the cytoplasmic face of the ER. Upon MPP(+) exposure, additional recruitment of tTG toward the ER was found. In addition, we observed that MPP(+)-induced tTG activity results in transamidation of ER membrane proteins, like calnexin. Our data provide strong evidence for a, so far unrecognized, localization of tTG at the ER, at least in catecholaminergic neurons, and suggests that in PD activation of tTG may have a direct impact on ER function, in particular via post-translational modification of ER membrane proteins.

Development of carbon-11 labeled acryl amides for selective PET imaging of active tissue transglutaminase

INTRODUCTION Tissue transglutaminase (TG2) is a ubiquitously expressed enzyme capable of forming metabolically and mechanically stable crosslinks between the γ-carboxamide of a glutamine acyl-acceptor substrate and the ε-amino functionality of a lysine acyl-donor substrate resulting in protein oligomers. High TG2 crosslinking activity has been implicated in the pathogenesis of various diseases including celiac disease, cancer and fibrotic and neurodegenerative diseases. Development of a PET tracer specific for active TG2 provides a novel tool to further investigate TG2 biology in vivo in disease states. Recently, potent irreversible active site TG2 inhibitors carrying an acrylamide warhead were synthesized and pharmacologically characterized. METHODS Three of these inhibitors, compound 1, 2 and 3, were successfully radiolabeled with carbon-11 on the acrylamide carbonyl position using a palladium mediated [(11)C]CO aminocarbonylation reaction. Ex vivo biodistribution and plasma stability were evaluated in healthy Wistar rats. Autoradiography was performed on MDA-MB-231 tumor sections. RESULTS [(11)C]1, -2 and -3 were obtained in decay corrected radiochemical yields of 38-55%. Biodistribution showed low uptake in peripheral tissues, with the exception of liver and kidney. Low brain uptake of <0.05% ID/g was observed. Blood plasma analysis demonstrated that [(11)C]1 and [(11)C]2 were rapidly metabolized, whereas [(11)C]3 was metabolized at a more moderate rate (63.2 ± 6.8 and 28.7 ± 10.8% intact tracer after 15 and 45 min, respectively). Autoradiography with [(11)C]3 on MDA-MB-231 tumor sections showed selective and specific binding of the radiotracer to the active state of TG2. CONCLUSIONS Taken together, these results identify [(11)C]3 as the most promising of the three compounds tested for development as PET radiotracer for the in vivo investigation of TG2 activity.

Tissue transglutaminase-catalysed cross-linking induces Apolipoprotein E multimers inhibiting Apolipoprotein E's protective effects towards amyloid-beta-induced toxicity.

Cerebral amyloid angiopathy (CAA) is a pathological hallmark of Alzheimers disease (AD) and characterized by deposition of amyloid‐β (Aβ) protein and smooth muscle cell (SMC) death in cerebral vessel walls. Apolipoprotein E (ApoE) is of importance in both Aβ accumulation and Aβ‐mediated toxicity towards SMCs in the cerebral vessel wall, although its exact role in CAA pathogenesis remains unclear. Tissue transglutaminase (tTG) is an enzyme capable of inducing both protein complexes and altered protein bioactivity via post‐translational cross‐linking. In CAA, tTG and its catalytic activity are associated with deposited Aβ. Furthermore, several apolipoproteins are known substrates of tTG. We therefore investigated whether ApoE is a substrate for tTG and if this affects ApoEs bioactivity. We found strong binding of different ApoE isoforms with tTG and demonstrated tTG‐catalysed ApoE multimers. In post‐mortem human AD cases, ApoE colocalized with in situ active tTG in CAA. Moreover, human brain SMCs treated with Aβ demonstrated enhanced secretion of both ApoE and tTG, and of TG cross‐links in the extracellular matrix. Interestingly, tTG‐catalysed cross‐linked ApoE failed to protect SMCs against Aβ‐mediated cytotoxicity. Together, our data demonstrate a novel tTG‐driven post‐translational modification of ApoE that might play an important role in CAA.

Tissue transglutaminase cross-links beclin 1 and regulates autophagy in MPP+-treated human SH-SY5Y cells

Tissue transglutaminase (tTG) is a cross-linking enzyme involved in protein aggregation during Parkinsons disease (PD) pathogenesis. Autophagy is inhibited by tTG activation via a mechanism in which cross-linking of beclin 1, an autophagy initiator at the level of the endoplasmic reticulum (ER), has been implicated. We reported increased tTG protein levels and activity at the ER in both PD brain and in a PD-mimicking cell system. Here we characterized the interaction between tTG and beclin 1 at the ER membrane and the role of tTG in reduced autophagy in an in vitro model of PD, using differentiated SH-SY5Y neurons treated with the PD-mimic MPP(+). We found that under PD-mimicking conditions, beclin 1 and tTG partially colocalized at the ER, beclin 1 levels increased at the ER, and tTG readily cross-linked beclin 1 which was prevented by enzymatic blockade of tTG. Under these conditions, accumulation of beclin 1 at the ER was enhanced by inhibition of tTG activity. In line with these observations and the role of beclin 1 in autophagy, levels of the autophagy marker protein LC3II in MPP(+)-treated cells, were significantly increased by inhibition of tTG activity. Our data provide first evidence for a role of tTG-mediated regulation of beclin 1 and autophagy in MPP(+)-treated human SH-SY5Y cells.

The blood clotting Factor XIIIa forms unique complexes with amyloid‐beta (Aβ) and colocalizes with deposited Aβ in cerebral amyloid angiopathy

Cerebral amyloid angiopathy (CAA) is a key pathological hallmark of Alzheimers disease (AD) characterized by accumulation of amyloid‐beta (Aβ) protein in blood vessel walls. CAA impairs vessel functioning, affects blood brain barrier integrity and accelerates cognitive decline of AD patients. Unfortunately, mechanisms underlying Aβ deposition in the vessel wall remain largely unknown. Factor XIIIa (FXIIIa) is a blood‐derived transglutaminase crucial in blood coagulation by cross‐linking fibrin molecules. Evidence is mounting that blood‐derived factors are present in CAA and may play a role in protein deposition in the vessel wall. We therefore investigated whether FXIIIa is present in CAA and if FXIIIa cross‐link activity affects Aβ aggregation.

Development of fluorine-18 labeled peptidic PET tracers for imaging active tissue transglutaminase

INTRODUCTION The protein-protein crosslinking activity of the enzyme tissue transglutaminase (TG2; EC 2.3.2.13) is associated with the pathogenesis of various diseases, including celiac disease, lung-, liver- and kidney fibrosis, cancer and neurodegenerative diseases. This study aims at developing a TG2 PET tracer based on the peptidic irreversible TG2 inhibitor Z006. METHODS Initially, the carbon-11 labeling of Z006 at the diazoketone position was explored. Subsequently, a set of analogues that allow for fluorine-18 labeling was synthesized. Two potent analogues, 6f and 6g, were radiolabeled with fluorine-18 and biodistribution and metabolite analysis in Wistar rats was performed. The identity of the main metabolite of [18F]6g was elucidated using LC-MS/MS. In vitro binding to isolated TG2 and in vitro autoradiography on MDA-MB-231 breast cancer tissue using [18F]6g was performed. RESULTS [18F]6f and [18F]6g were obtained in 20 and 9% yields, respectively. Following administration to healthy Wistar rats, rapid metabolism of both tracers was observed. Remarkably, full conversion to just one single metabolite was observed for one of the tracers, [18F]6g. By LC-MS/MS analysis this metabolite was identified as C-terminally saponified [18F]6g. This metabolite was also found to be a potent TG2 inhibitor in vitro. In vitro binding to isolated TG2 and in vitro autoradiography on MDA-MB-231 tumor sections using [18F]6g demonstrated high specific and selective binding of [18F]6g to active TG2. CONCLUSIONS Whereas based on the intensive metabolism [18F]6f seems unsuitable as a TG2 PET tracer, the results warrant further evaluation of [18F]6gin vivo.

Characterization of Transglutaminase 2 activity inhibitors in monocytes in vitro and their effect in a mouse model for multiple sclerosis

The neurodegenerative disease multiple sclerosis (MS) is pathologically characterized by the massive influx of immune cells into the central nervous system. This contributes to demyelination and axonal damage which causes symptoms such as motor and cognitive dysfunctions. The migration of leukocytes from the blood vessel is orchestrated by a multitude of factors whose determination is essential in reducing cellular influx in MS patients and the experimental autoimmune encephalomyelitis (EAE) animal model. The here studied enzyme tissue Transglutaminase (TG2) is present intracellularly, on the cell surface and extracellularly. There it contributes to cellular adhesion and migration via its transamidation activity and possibly by facilitating cellular interaction with the extracellular matrix. Previous data from our group showed reduced motor symptoms and cellular infiltration after using a pharmacological TG2 transamidation activity inhibitor in a rat EAE model. However, it remained elusive if the cross-linking activity of the enzyme resulted in the observed effects. To follow-up, we now characterized two new small molecule TG2 activity inhibitors, BJJF078 and ERW1041E. Both compounds are potent inhibitor of recombinant human and mouse Transglutaminase enzyme activity, mainly TG2 and the close related enzyme TG1. In addition they did not affect the binding of TG2 to the extracellular matrix substrate fibronectin, a process via which TG2 promotes cellular adhesion and migration. We found, that ERW1041E but not BJJF078 resulted in reduced EAE disease motor-symptoms while neither caused apparent changes in pathology (cellular influx), Transglutaminase activity or expression of inflammation related markers in the spinal cord, compared to vehicle treated controls. Although we cannot exclude issues on bioavailability and in vivo efficacy of the used compounds, we hypothesize that extracellular TG1/TG2 activity is of greater importance than (intra-)cellular activity in mouse EAE pathology.