Tài liệu Báo cáo khoa học: The role of antioxidants in the cytotoxicity of chemotherapeutic drugs pptx

Molecular Basis of Disease3.1 Oxidative Stress S3.1-1 The role of antioxidants in the cytotoxicity of chemotherapeutic drugs T.. S3.1-2 Oxidized protein degradation and repair in ageing

3 Molecular Basis of Disease

3.1 Oxidative Stress

S3.1-1

The role of antioxidants in the cytotoxicity of

chemotherapeutic drugs

T Ozben, H Akbas, I Akan, S Akan and M Timur

Department of Biochemistry, Faculty of Medicine, Akdeniz

University, Antalya, Turkey E-mail: ozben@akdeniz.edu.tr

A number of drugs used in cancer chemotherapy induce oxidative

stress by generation of oxygen free radicals (ROS) which might

be an alternative mechanism for their cytotoxic effect via

indu-cing apoptosis In order to clarify the roles of antioxidants in

chemotherapy, we investigated Quercetin

(3,3’,4’,5,7-pentahyd-roxyflavone) and N-acetylcysteine (NAC) in different cell types

treated with anticancer drugs We studied cytotoxic activity of

Topotecan alone and/or in combination with Quercetin in two

human breast cancer cell lines, MCF-7 and MDA-MB-231 We

also investigated the effect of NAC on MRP1-mediated

doxoru-bicin and vincristine cytotoxicity in Human Embryonic Kidney

(HEK293) and its MRP1 transfected (293MRP) cells The

viabil-ity of the cells was measured using the colorimetric MTT

(3-(4,5)-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide)

assay Intracellular ROS was measured using fluorometric

2’,7’-dichlorodihydrofluorescein diacetate (DCFH-DA) assay Our

data indicated increased oxidative status in MCF-7 and

MDA-MB-231 cells exposed to Topotecan Treatment with Quercetin

did not inhibit ROS generation, and enhanced cytotoxicity of

Topotecan in both cells In contrast, NAC enhanced resistance

against doxorubicine and vincristine in MRP1 overexpressing

cells We conclude that Quercetin and NAC may have diverse

effects in the cytotoxicity of chemotheurapeutic drugs depending

on their other pharmacological properties which may

predomin-ate their antioxidant effects

S3.1-2

Oxidized protein degradation and repair in

ageing and oxidative stress

B Friguet

Laboratoire de Biologie et Biochimie Cellulaire du Vieillissement,

Universite´ Denis Diderot – Paris 7, Paris, France

E-mail: bfriguet@paris7.jussieu.fr

Cellular ageing is characterized by the accumulation of oxidatively

modified proteins and oxidized protein buildup with age may be

due to increased protein damage and/or decreased elimination of

oxidized protein Since the proteasome is in charge of protein

turn-over and removal of oxidized protein, its fate during ageing has

received special attention, and evidence has been provided for an

age-related impairment of proteasome function In fact, depending

on the cellular system investigated, the loss in proteasome activity

observed during ageing and upon oxidative stress appears to be due to either or both: (i) decreased proteasome expression and con-tent, (ii) inactivation upon modification of proteasome subunits and (iii) formation of inhibitory proteins However oxidized pro-teins can be eliminated through degradation but also repair Oxid-ized protein repair is limited to the reversion of few modifications such as the reduction of methionine sulfoxide by the methionine sulfoxide reductase (Msr) system We have previously shown that Msr activity is impaired during ageing To analyse the relationship between oxidative stress, protein oxidative damage and Msr, MsrA has been overexpressed in immortalized WI-38 human fibroblasts After H202-induced oxidative stress, MsrA-overexpressing cells exhibit lower protein oxidative damage than control cells indica-ting that MsrA may play an important role in cellular defences against oxidative stress by limiting oxidative damage to proteins

S3.1-3 Role of oxidative stress in progressive kidney failure

A Tomasi1, S Uggeri2, S Beergamini3, L Della Casa3,

A Albertazzi2, L Lucchi2and A Iannone1

1Department Laboratory Medicine, Universita` di Modena e Reggio Emilia, Modena, Italy,2Division of Nephrology, University Hospital, Modena, Italy,3Department of Biomedical Sciences, Modena, Italy E-mail: tomasi@unimore.it

The leading cause of morbidity and mortality in patients with end stage renal disease (ESRD), who are maintained on regular dialysis treatment, is cardiovascular disease Increased free radical production and oxidative stress promote the atherosclerotic pro-cess The association between haemodialysis and activation of circulating monocytes, both spontaneous and endotoxin-induced release of TNF-alpha are well known In our research spanning many years, as well as in many other laboratories, there has been

a massive attempt to identify reliable biomarkers of oxidative stress Initially our attention was drawn on direct markers of oxi-dative stress such as malondialdehyde (MDA) and conjugated dienes More recently, high plasma level of homocysteine, which

is considered a putative cardiovascular risk factor by inducing endothelial dysfunction and serum C-reactive protein (CRP), which contributes to monocytes recruitment in the atherosclerotic lesion have been adopted as possible markers of atherosclerotic progression in ESRD patients It has been postulated that ESRD patients have also a decreased ability to withstand oxidative stress due to a reduced antioxidant capacity, which was also investigated as a putative biomarker Recently, we have tried to define novel markers of oxidative stress applying proteomic pro-filing technologies, employing both 2-D gel electrophoresis - mass spectrometry and high throughput SELDI technology

3.2 DNA Damage Processing

S3.2-1

The role of the human mismatch repair

system in the processing of modified

nucleotides

N Mojas, F Fischer, M Lopes, P Cejka and J Jiricny

Institute of Molecular Cancer Research, University of Zurich,

Zurich, Switzerland E-mail: jiricny@imcr.unizh.ch

The mismatch repair (MMR) system has evolved to correct

errors of DNA replication and to prevent illegitimate

recombina-tion events However, MMR is also involved in DNA damage

signalling In MMR-proficient cells, methylating agents such as

MNNG activate a cell cycle arrest in the second G2 phase after

treatment The signalling cascade, which is triggered by the ATR

and Chk1 kinases, is not activated in MMR-deficient cells We

show that the lesions triggering the cascade are not ‘mismatches’

arising through DNA modification by the methylating agents

Nor are these lesions generated during DNA replication Our

evi-dence suggests that the cell-cycle-arresting lesions are generated

through unsuccessful attempts by the MMR system to repair

mehylation damage, which leads to the generation of

recombino-genic intermediates DNA recombination enables the cells to

cross the mitotic boundary, but the damage that remains kills the

cells during the subsequent cell cycle Thus, in the absence of

recombination, the cells become hypersensitive to killing by

methylating agents and arrest already in the first G2 We are

currently searching for the structures of the recombination

inter-mediates that lead to cell death We are also investigating the

role of the MMR system in the cytotoxicity of 5-fluorouracil

(FU), which has been reported to kill MMR-proficient cells more

efficiently than MMR-deficient ones In our hands, isogenic

MMR-proficient and -deficient cells are equally sensitive to FU

S3.2-2

Base excision repair proteins in cancer

prevention and acquired immune responses

H E Krokan, M Akbari, J Pen˜ a Diaz, B Kavli, M Otterlei,

M Ericsson, H Aarset, S Andersen and G Slupphaug

Department of Cancer Research and Molecular Medicine,

Norwegian University of Science and Technology, Trondheim,

Norway E-mail: hans.krokan@ntnu.no

Base excision repair repairs DNA by removing damaged bases

and filling in the gap with correct nucleotides Uracil-DNA

gly-cosylase encoded by the UNG-gene is also required for somatic

hypermutation and class switch recombination Furthermore,

Ung-deficient mice have lymphatic hyperplasia and several-fold

increased risk of developing B-cell lymphomas Humans deficient

in UNG2 activity display the hyperIgM syndrome (HIGM) phe-notype, including B-cell hyperplasia We find that lymphomas in mice are of follicular (FL) and diffuse large B-cell type (DLBCL) type All FLs and 75% of the DLBCLs were monoclonal while 25% were biclonal Monoclonality was also observed in hyperpl-asia, and could represent an early stage of lymphoma develop-ment Lymphoid hyperplasia was observed as a significant increase of splenic B-cells Furthermore, loss of Ung also causes

a reduction of T-helper cells, and 50% of the young Ung–/– mice investigated have no detectable NK/NKT-cell population in their spleen In addition, production of the cytokines interferon c, interleukin-6 and interleukin-2 is clearly different in wild type and in Ung-deficient mice Thus, Ung-proteins have important functions in the immune system, not only in the process of anti-body maturation, but also for production and functions of immunologically important cell types The immunological imbal-ances in the Ung-deficient mice may be central in the develop-ment of lymphomas in a background of generalized lymphoid hyperplasia

S3.2-3 New complexities in base excision repair and relevance to human pathology

E Dogliotti Department of Environment and Primary Prevention, Istituto Superiore di Sanita`, Rome, Italy E-mail: dogliott@iss.it Base excision repair (BER) is the major mechanism for repair of oxidative DNA damage Xeroderma pigmentosum (XP) C is involved in the recognition of a variety of bulky DNA distorting lesions in NER of the genome overall We show that XPC plays

an unexpected and multifaceted role in cell protection from oxidative DNA damage We provide the first in vivo evidence that XPC is involved in the repair of 8,5’-cyclopurine 2’-deoxynu-cleosides and of the mutagenic oxidized DNA base 8-hydroxy-guanine (8-OH-Gua) By in vitro reconstitution experiments we uncover a new role of XPC as co-factor in 8-OHGua cleavage by the DNA glycosylase OGG1 XPC complex, by participating to BER of 8-OH-Gua, might contribute to cancer prevention A provokative hypothesis has recently emerged in which BER enzymes, more than controlling the integrity of the genome, may create unintended consequences Adaptive increases in BER enzymes have been shown to generate microsatellite instability in chronic inflammation We detect up-regulation of BER genes in association with microsatellite instability in an inflammation rela-ted cancer (i.e stomach cancer) Future research should address the mechanistic basis of this phenomenon that might be of great relevance in human pathology

3.3 DNA Repair in Health, Disease and Aging

S3.3-1

DNA repair deficiencies in human premature

aging

A Bohr

Laboratory of Molecular Gerontology, National Institute on Aging,

NIH, Baltimore, Maryland, USA E-mail: vbohr@nih.gov

There are a number of human syndromes where the patients

appear much older than their actual chronological age These

conditions are interesting model systems for the study of aging For many of these conditions, the responsible gene has been cloned, identified, and characterized, thus enabling studies of its molecular function We are interested in the category of human premature aging conditions that are defective in recQ helicases and associated with genomic instability These conditions include Werner syndrome, Rothmund–Thompsons syndrome and others The molecular function of the recQ helicases will be discussed and evidence presented that these proteins participate in an intergral

manner in the DNA repair process Another premature aging

condition, also associated with DNA repair defects, Cockayne

syndrome, will also be discussed These studies lend credibility to

the notion that aging is associated with defects in DNA repair

that then lead to genomic instability

S3.3-2

DNA damage repair and the connection with

cancer and aging

J Hoeijimakers1, J.-O Andressoo1, L Niedernhofer2,

I van der Pluijm1, K Diderich1, A Lalai1, H de Waard1,

G Garinis1, J Mitchell1, R.B Beems3, H van Steeg3and

G.T.J van der Horst1

1MGC, CBG, Department of Cell Biology and Genetics, Erasmus

University, Rotterdam, The Netherlands,2University of Pittsburgh

Cancer Institute, Hillman Cancer Center, Pittsburgh, PA, USA,

3RIVM, Bilthoven, The Netherlands

The physico-chemical constitution of our genes does not

guaran-tee life-long stability and proper function A perplexing diversity

of lesions is continuously induced in our genes ranging from

sin-gle and double strand breaks, to chemical alterations of

nucleo-tides including adducts, as well as inter- and intrastrand DNA

crosslinks They arise from ubiquitous, noxious exogenous agents

(UV- and X-radiation, chemicals), natural metabolites produced

by respiration (notably reactive oxygen species) and from

intrin-sic chemical instability of DNA To protect the vital genetic

information from the deleterious effects of DNA injury a

net-work of genome care-taking mechanisms has evolved of which a

set of DNA repair systems constitute a key component The

clinical impact of the DNA damage problem is still strongly

underestimated Nucleotide excision repair (NER) removes a

wide range of helix-distorting lesions in a complex ‘cut and

patch’ reaction There are two sub-pathways: global genome

NER critical for preventing mutations and transcription-coupled

repair (TCR) counteracting the cytotoxic effects of DNA injury

Inherited NER defects are associated with sun (UV)

hypersensi-tive syndromes, including xeroderma pigmentosum (XP, highly

cancer-prone), and the severe neuro-developmental conditions

Cockayne syndrome (CS) and trichothiodystrophy (TTD)

Muta-tions in the multifunctional NER/TCR XPB and XPD helicases

are associated with an extreme clinical heterogeneity, ranging

from XP to XP combined with CS and TTD Defects in the

NER and crosslink repair endonuclease, ERCC1/XPF, cause XP

or XP with multi-system dysfunction Mouse models have

provi-ded important insights into the impact of the NER sub-pathways

on human health and the complex genotype-phenotype

relation-ship XPDTTD mice, with a partial defect in both global and

TCR are only moderately cancer-prone, but exhibit wide spread

premature ageing XPDXP/CSmutant mice are highly predisposed

to cancer, with a milder ageing phenotype Complete repair defi-ciency in TTDxXPA mice aggravates many premature ageing symptoms, reducing life span to ~3 weeks Mutations in the ERCC1 gene induce a distinct set of accelerated ageing features, with a rate of onset depending on the severity of the mutation The correlation between repair defect severity and clinical mani-festation provides strong evidence for the DNA damage theory

of ageing We propose that endogenous oxidative lesions com-promise transcription, inactivate genes, and trigger apoptosis/sen-escence inducing aging Very cytotoxic interstrand cross-links may also cause cell death, senescence and features of ageing In contrast, lesions or defects in genetic stability mechanisms caus-ing enhanced levels of DNA damage-induced mutagenesis corre-late with increased carcinogenesis Various single and double mutant mouse models including conditional mutants have been generated and microarray analysis performed to study these pro-cesses in a controlled, systematic manner

S3.3-3 DNA double strand repair and its relationship

to human disease

A Jeggo Genome Damage and Stability Centre, University of Sussex, UK E-mail: p.a.jeggo@sussex.ac.uk

DNA is constantly subject to damage Cells utilise multiple DNA damage response pathways to maintain genomic stability A DNA double strand break (DSB) represents a particularly critical DNA lesion that can lead to cell death or carcinogenesis DSBs are introduced during immune development to generate genetic diver-sity Curiously, cells exploit the mechanism normally used to maintain genomic stability after exposure to DNA damaging agents to create diversity during immune development This path-way is DNA non-homologous end-joining (NHEJ), a process of DSB repair To date, three genetic diseases with defects in NHEJ have been identified As expected from the role of NHEJ in immune development, such patients display immunodeficiency Additionally, since a DSB is induced following exposure to ion-izing radiation, such patients and cell lines derived from them dis-play marked radiosensitivity LIG4 syndrome is a disorder conferred by mutations in DNA ligase IV, the enzyme that effects rejoining during NHEJ LIG4 patients display pancytopaenia, microcephaly and developmental delay RS-SCID1 patients have mutations in Artemis, a protein that processes DNA ends prior to rejoining More recently, a further disorder has been described, which is associated with marked immunodeficiency and mild developmental delay The protein defective in this disorder is also

a NHEJ protein The distinct clinical features of the patients will

be discussed in the context of the protein function

3.4 Diabetes, Obesity and Metabolic Syndrome

S3.4-1

Integration of inflammatory and metabolic

signals in obesity and diabetes

G Hotamisligil

Department of Genetics and Complex Diseases, Harvard School of

Public Health, Boston, MA, USA

E-mail: ghotamis@hsph.harvard.edu

Obesity is associated with chronic, low grade, inflammatory

responses in metabolically active sites This hightened

inflamma-tory status is among the key links between obesity and other associated pathologies, i.e type 2 diabetes Recent studies in our group demonstrated the involvement of the inflammatory kinase JNK and endoplasmic reticulum (ER) stress as events involved in both sensing and relaying stress signals and disturb-ing metabolic homeostasis Obesity generates conditions that increase the demand on the ER and leads to strong activation

of JNK in insulin sensitive sites We have shown that, in both cultured cells and whole animals, experimentally induced ER stress leads to IRE1±-dependent activation of JNK, serine

phosphorylation of insulin receptor substrate 1 (IRS1), and

inhibition of insulin action Hence, we conclude that JNK

acti-vation and ER stress, integrates inflammatory and metabolic

responses, plays a crucial role in development of insulin

resist-ance and diabetes in obesity and present new targets for the

treatment of these disorders Recently, we developed JNK- or

XBP-1 genetic gain- or loss-of function mouse models as well

as chemical tools to alter the functional capacity of ER and

JNK activity in whole animals to demonstrate the causal link

between these pathways and metabolic disease Recent activities

in these areas and identification of cellular and molecular

tar-gets and development of new genetic models are underway and

will be discussed here

S3.4-2

The metabolic syndrome and adipocytokines

Y Matzuzawa

Department of Internal Medicine and Molecular Science, Graduate

School of Medicine Osaka University, Osaka, Japan

Visceral fat accumulation plays crucial roles in the development

of cardiovascular disease as well as diabetes mellitus,

hyperlipide-mia and hypertension and so-called metabolic syndrome

Adipo-cyte functions has been intensively investigated in the past

10 years, and adipocytes have been revealed to act as endocrine

cells which secrete various bioactive substances.(adipocytokine)

Among adipocytokines, tumour necrosis factor-a, plasminogen

activator inhibitor type 1, heparin binding epidermal growth

fac-tor-like growth factor and visfatin (newly found in visceral fat)

are produced in adipocytes as well as other organs, and may

con-tribute to the development of vascular diseases On the contrary

to these adipocytokines, adiponectin, an adipose-tissue-specific,

collagen-like protein, has been noted as an important

antiathero-genic and antidiabetic protein, or as an anti-inflammatory

pro-tein The functions of adipocytokine secretion might be regulated

dynamically by nutritional state Visceral fat accumulation causes

dysregulation of adipocyte functions, including oversecretion of TNF-a, PAI-1 and heparin HBEGF and hyposecretion of adipo-nectin, which results in the development of a variety of metabolic and circulatory diseases In this review, the importance of adipo-cytokines, especially focusing on adiponectin is discussed with respect to cardiovascular diseases

S3.4-3 Nuclear receptors as therapeutic targets to modulate the metabolic syndrome

B Staels UR545, Dpt d’Athe´roscle´rose, Institut Pasteur de Lille and Faculte´

de Pharmacie, Universite´ de Lille II, Lille, France

E-mail: bart.staels@pasteur-lille.fr Cardiovascular disease is significantly increased in patients with the metabolic syndrome and type 2 diabetes A clustering of risk factors, including dyslipidaemia, insulin resistance, hypertension, inflammation and coagulation disorders result in an increased risk for cardiovascular events in these patients The Farnesoid X Receptor (FXR) and peroxisome proliferator-activated receptor (PPAR) alpha are members of the nuclear receptor superfamily Whereas PPARalpha is activated by fatty acids, FXR has recently been identified as a bile acid-activated nuclear receptor FXR not only controls bile acid synthesis, conjugation and trans-port, but also lipid and glucose metabolism Activation of PPAR-alpha represents one important pathway that influences vascular function both directly and indirectly PPARalpha activation induces beneficial effects not only on lipid metabolism, but also influences glucose homeostasis, endothelial function and vessel wall inflammation PPARalpha agonists in clinical use, such as fibrates, may alter the process of atherosclerosis, especially in subjects with the metabolic syndrome and type 2 diabetes This presentation will highlight the molecular mechanisms of FXR and PPARalpha action in the prevention and treatment of the metabolic syndrome and atherosclerosis

3.5 Lipid Related Disorders and Atherosclerosis

S3.5-1

Treatment of the metabolic syndrome by

targeting hepatocyte nuclear factor-4a by

MEDICA

R Hertz and J Bar-Tana

Department of Human Nutrition and Metabolism, Hebrew

University Medical School, Jerusalem, Israel

E-mail: bartanaj@cc.huji.ac.il

Dyslipoproteinemia, NIDDM and essential hypertension often

coexist, and synergistically promote ASCVD The Metabolic

Syn-drome that comprises these diseases is driven by nutritional

sat-urated fat Transcriptional modulation of liver genes involved in

lipoprotein production and their plasma clearance (apoB, apoC

III,MTP), hepatic glucose production (G6Pase, PEPCK), blood

coagulation and others is dominated by hepatocyte nuclear

fac-tor-4a (HNF4) Activation/suppression of HNF4 transcriptional

activity by its acyl-CoA ligands as function of their chain length,

unsaturation or extent of substitution, correlates with the

repor-ted effects of long chain fatty acid nutrients in the Metabolic

Syndrome context Hence, HNF4 serves as cellular sensor for

long chain fatty acids, and targeting HNF4 may offer means for

targeting the Syndrome Long chain methyl-substituted

a,x-dicarboxylic acids (MEDICA compounds) are incapable of being

esterified into lipids or b-oxidized MEDICA-CoA specifically binds to HNF4 with Kdvalues in the nM range, and blocks its

transcriptional activity MEDICA compounds induce hypolipide-mia accounted for by a pronounced activation of plasma chylo-microns and VLDL clearance complemented by robust inhibition

of liver VLDL production, transcriptional suppression of hepatic glucose production, abrogation of non-alcoholic steatohepatitis, activation of glucose uptake during hyperinsulinemic–euglycemic clamp, and amelioration of ASCVD in animal models of the Metabolic Syndrome

S3.5-2 Why a metabolic syndrome?

P G Kopelman Institute of Health, University of East Anglia, Norwich, UK E-mail: p.g.kopelman@qmul.ac.uk

The global prevalence of obesity confirms that it has become a major threat to public health One in five children in Europe are overweight The rise in obesity in young people is paralleled in adults – obesity rates in men vary from 10% to 27%, in women

up to 38%: at least 25% of adults in US have the metabolic syn-drome The patho-physiological consequence of increased body

fatness is predictable from an understanding of the relationship

between insulin resistance, systemic hyperinsulinaemia and

even-tual pancreatic islet cell decompensation There is a close

associ-ation between increasing weight, intra-abdominal fat, impaired

glucose tolerance and deleterious alterations in lipid profile that

are associated with alterations in pro-inflammatory markers

CRP, interleukin-6 and TNF-a Unsurprisingly these changes are

clinically characterised by type 2 diabetes, hypertension and

accelerated coronary artery disease The INTERHEART trial

from 52 countries confirms the detrimental impact of abdominal

obesity on rates and outcome from myocardial infarction Of

particular worry is that these chronic diseases begin in young

people The great expectation of new therapies to effectively treat

obesity has not been fulfilled Thus a major challenge for 21st

century is the prevention of obesity, and the metabolic

syn-drome, through populations adopting healthier lifestyles with

health-promoting social marketing becoming an important

prevention tool

S3.5-3 Transcriptional regulatory networks in the ABCA1/AP3-pathway determine lipid trafficking in macrophages

G Schmitz, M Grandl, G Liebisch, A Boettcher, E Orso and

T Langmann Institute of Clinical Chemistry and Laboratory Medicine, University Hospital Regensburg, Regensburg, Germany

E-mail: gerd.schmitz@klinik.uni-regensburg.de ABCA1 controls cellular cholesterol and choline-phospholipid release and is required for the generation of pre-b-HDL Our goal was to characterize gene regulatory networks and ABCA1 associated lipid pathways in human macrophages in cardiovascu-lar disease and under atherogenic and nutritional stimulation Macrophages from healthy apoE3 donors and patients with monogenetic lipid disorders (ABCA1 deficiency, Niemann–Pick C disease) were incubated with modified lipoproteins, enzymatically modified LDL (E-LDL) and mildly oxidized LDL (Ox-LDL), lipid deloaded with apoA-I and HDL3 and stimulated with reti-noids We applied Affymetrix DNA-microarrays, TaqMan RT-PCR and computational biology approaches and determined the cellular lipid content and composition using ESI-MS/MS (i) 9-cis retinoic acid (9-cis RA) and all-trans retinoic acid (ATRA) induce a nuclear receptor network strongly upregulating apolipoproteins, scavenger receptors, steroid-27-hydroxylase, ABCA1 and ABCG1 resulting in a potent induction of lipid efflux (ii) E-LDL increases cellular free cholesterol and forma-tion of cholesterol/sphingomyelin-rich rafts in macrophages, whereas Ox-LDL causes accumulation and cell surface expression

of ceramide and a stronger binding of apoE (iii) ABCA1, syntaxin-13 and flotillin-1 operate in both loading conditions with different response rates and downstream signalling involving

an inward rectifying K+-channel along the ABCA1/AP-3 secretory pathway

3.6 Oncogenes and Tumor Suppressors

S3.6-1

Molecular pathogenesis of liver cancer

M Ozturk

Department of Molecular Biology and Genetics, Bilkent University,

Ankara, Turkey E-mail: ozturk@fen.bilkent.edu.tr

Liver cancer (hepatocellular carcinoma; HCC) is one of the 10

most common cancers worldwide The major etiology of liver

cancer is cirrhosis that is observed mostly in old people with a

chronic history of viral (HBV and HCV) and/or non-viral

hepa-titis Liver cancer appears as a heterogeneous disease at the

molecular level, probably because of the fact that different

etio-logical factors contribute to the development of these cancers,

depending on geographical locations The most shared genetic

alterations of liver cancers are mutations affecting p53, b-catenin

and Axin1 genes together with the epigenetic or mutational

inac-tivation of the p16INK4a gene Most liver cancers also display

hTERT telomerase induction whose mechanisms remain elusive

Gene expression profiling data show deregulated expression of

genes involved in proliferation, apoptosis, DNA repair, protein

synthesis and liver-specific functions Taken together these

observations provide evidence for critical involvement of

senes-cence- and differentiation-regulating events, in addition to well

established cell cycle and apoptosis regulatory changes in liver

cancer Among others, ‘p53-retinoblastoma tumor suppressing

network’ and ‘canonical Wnt-b-catenin signaling’ appear to play

a central role in hepatocellular carcinogenesis New experimental data incriminating senescence- and differentiation-related molecular changes in the pathogenesis of liver cancer will also

be presented

S3.6-2 AP-1 (Fos/Jun) and cancer

E F Wagner IMP, Research Institute of Molecular Pathology, Vienna, Austria E-mail: wagner@imp.univie.ac.at

AP-1(Fos/Jun) proteins are prototypic oncogenes regulating cell proliferation, differentiation and cell transformation in various organs We are investigating the specific functions of Fos pro-teins, e.g Fos, Fra-1 and Fra-2 in development and disease Transgenic mice expressing Fos develop osteosarcomas (OS), whereas mice lacking Fos are osteopetrotic It is well established that Fos is phosphorylated in the C-terminus by kinases such as RSK-2 in vitro We have been studying the role of Fos phos-phorylation in OS development and found that tumors do not progress in the absence of RSK-2 We speculate that the effect

on tumor development is due to increased stability of phosphor-ylated Fos protein When the Fos–/– osteopetrotic mutant was crossed into the p53 background, double mutant mice specifically develop rhabdomyosarcomas (RMS) Re-expressing Fos in

mutant muscle tumor cell lines induced apoptosis implying a

novel function of the oncogene Fos as a potential tumor

suppres-sor Recent data regarding the target genes of Fos in OS and

RMS cells obtained by microarray analyses will be presented

The functions of the Jun family members c-Jun and JunB have

been analyzed by conditional mutagenesis Whereas c-Jun was

found to function as an oncogene in liver cancer, JunB acts as a

tumor suppressor gene in a mouse model of myeloid leukemias

The combined inducible deletion of c-Jun and JunB in the skin

of adult mice causes a psoriasis-like phenotype strongly

resem-bling the human disease

S3.6-3

Chromatin modifications and their function

C Neilson, H Santos-Rosa, A Bannister and T Kouzarides

Gurdon Institute, Tennis Court Road, Cambridge, UK

Covalent modifications of histones regulate many biological pro-cesses, the most characterized of which is transcription We are interested in the molecular mechanisms by which these modifica-tions function Our focus recently has been the analysis of his-tone methylation at lysines and arginines We now find that one site of lysine methylation on histone H3 is under the control of proline isomerization Prolines can exist in a -cis or -trans confor-mation Enzymes exist (peptidyl prolyl isomerases), which can convert prolines from one conformation to the other We have found that a yeast protein FPR4 is an enzyme that can isomerize specific prolines in histone H3 and that this isomerization affects lysine methylation of H3 The cross-talk between proline isomeri-zation and lysine methylation has a consequence in the regulation

of transcription of certain genes in yeast These data define a novel non-covalent histone modification that regulates gene expression

3.7 Intracellular Trafficking in Health and Disease

S3.7-1

The yeast vacuolar protein sorting pathway

as an experimental model for lysosomal

trafficking

J Rytka

Department of Genetics, Institute of Biochemistry and Biophysics,

Warsaw, Poland E-mail: rytka@psd.ibb.waw.pl

Compartmental organization of eucaryotic cells requires

mecha-nisms for precise sorting and distribution of proteins and

metab-olites to their target organelles Due to impressive conservation

of intracellular traffic across phyla, a great deal of the current

knowledge on the mechanisms of integration of these processes

into the cellular interaction network has been acquired from

studies on Saccharomyces cerevisiae A good example is vacuolar/

lysosomal transport, as the yeast vacuole is analogous to the

mammalian lysosome, and trafficking to both organelles is

remarkably conserved Defects in vacuolar function lead to

pro-tein mislocalization, disturbances in ion homeostasis, affect such

complicated processes as osmoregulation and sporulation

Isola-tion and characterizaIsola-tion of yeast mutants blocked at various

sta-ges of transport pathways are an invaluable method for

unravelling the molecular details of vacuolar and lysosomal

traf-fic The activities of lysosomes are critical to many essential

cellu-lar processes Such diseases as Huntington’s, Alzheimer’s,

Parkinson’s, tumor invasion and metastasis are all associated

with altered lysosomal trafficking Our research concentrates on

Ccz1p, the yeast homolog of mammalian HPS4 The mutated

HPS4 protein is responsible for Hermansky–Pudlak syndrome

type 4

S3.7-2

Sorting, targeting and delivery in mammalian

post-golgi pathways

P Luzio

Cambridge Institute for Medical Research, University of

Cambridge, Cambridge, UK E-mail: jpl10@cam.ac.uk

The targeting and localization of proteins to the correct

intracel-lular organelle or cell surface domain is essential for their

physio-logical function In the post-Golgi secretory and endocytic

pathways proteins are targeted to many locations, with vesicular

traffic being the major mechanism of transport between donor

and acceptor compartments Disruption of membrane traffic events is the molecular basis for many hereditary, autoimmune and other diseases In addition, several microbial pathogens sub-vert normal membrane traffic and some viruses are able to hijack membrane traffic machinery to avoid recognition by the immune system and/or for the purposes of viral budding In general, membrane traffic defects in hereditary disease can be subdivided into abnormalities of cargo or of traffic machinery The former are by far the most common Mutations in cargo or machinery proteins can result in inappropriate targeting and consequent cel-lular malfunction This will be illustrated by reference to muta-tions in protein targeting motifs in cargo trafficking to/from the plasma membrane and to lysosomes An example of traffic machinery in which abnormalities of function can result in dis-ease is that for formation of multivesicular bodies on the endocy-tic pathway Components of this machinery have been implicated

in viral disease, cancer and interacting with spastin, a protein encoded by a hereditary spastic paraplegia gene

S3.7-3 How vesicular stomatitis virus hijacks the endocytic pathway to infect cells

P P Luyet, I Le Blanc and J Gruenberg Biochemistry Department, University of Geneva, Geneva, Switzerland E-mail: pierre.luyet@biochem.unige.ch Like other enveloped viruses, vesicular stomatitis virus (VSV) infects cells through the endocytic pathway VSV infection requires transport beyond early endosomes, hence to multivesicu-lar endosomes (MVBs), and then the transcriptionally active nucleocapsid is delivered to the cytoplasm after low pH-mediated fusion of the viral envelope with endosomal membranes We observed that VSV envelope fusion and nucleocapsid release into the cytosol occur sequentially at two successive steps of the endo-cytic pathway – and not concomitantly as it was thought Our results indicate that VSV envelope undergoes fusion with the membrane of intra-endosomal vesicles contained within MVBs, thereby releasing the nucleocapsid into the lumen of these vesi-cles Then, the capsid uses these intra-endosomal vesicles as a Trojan horse to reach late endosomes, from where the nucleocap-sid is delivered to the cytoplasm This latest step occurs presuma-bly via the back-fusion of the internal vesicles with the endosome limiting membrane, in a process regulated by the endosomal lipid

lysobisphosphatidic acid under the control of Alix/Vps31p and

by the phosphatidylinositol-3-phosphate via Snx16 We propose

that proteins and lipids, which are transported from within late

endosomes to other cellular destinations, also use this intra-endo-somal trafficking pathway The functions of other effectors in this pathway will be discussed

3.8 Neurodegenerative Disorders

S3.8-1

Tau and tauopathies: tau phosphorylation and

tau assembly

J Avila

Centro de Biologı´a Molecular ‘Severo Ochoa’, Facultad de

Ciencias, Campus de Cantoblanco, Universidad Auto´noma de

Madrid, Madrid, Spain E-mail: javila@cbm.uam.es

The role of tau protein in different tauopathies, mainly in

Alzhei-mer’s disease, will be commented Tau, a microtubule associated

protein, can aberrantly polymerize, in phosphorylated form,

yielding the paired helical filaments found in the brain of

Alzhei-mer’s disease patients Tau assembly can be reproduced in vitro

by mixing tau protein with polymerization-inducers like heparin

or Coenzyme Q0, being the assembly of phosphotau facilitated in

the presence of Co.Q0 Polymerization of tau has been also

mimified in vivo by using transgenic mouse models In these

models, human tau, bearing some of the mutations found in

patients with a tauopathy, FTDP-17, was expressed

Addition-ally, mutations on APP and/or PS-1 proteins will facilitate tau

phosphorylation by kinases like GSK3 in mouse models Thus, a

transgenic mouse model overexpressing GSK3 was also

charac-terized In some of these mouse models, a link between tau

phos-phorylation and tau assembly has been established Finally, the

possible toxic effect of phosphotau or tau aggregates will be

dis-cussed

S3.8-2

Alpha-synucleinopathies

M G Spillantini

Department of Clinical Neurosciences, Brain Repair Centre,

University of Cambridge, Cambridge, UK

E-mail: mgs11@cam.ac.uk

Parkinson’s disease (PD) and dementia with Lewy bodies (DLB)

are characterized neuropathologically by the presence of Lewy

bodies (LBs) which are intracytoplasmic filamentous inclusions

Alpha-synuclein (alpha-syn) has been implicated in the

pathogen-esis of PD based on the presence of missense mutations and

abnormal copy number of its gene in familial cases as well as for

its presence in LBs Alpha-syn constitutes also the major

compo-nent of the glial cytoplasmic inclusions found in multiple system

atrophy These diseases are therefore grouped under the name of

‘alpha-synucleinopathies’ The mechanism of alpha-syn

aggrega-tion in PD and DLB is not yet clear The presence of ubiquitin

in LBs and the association of mutations in the ubiquitin-protea-some pathway with early-onset Parkinsonism, has led to the sug-gestion that abnormalities in ubiquitin-dependent degradation and alpha-synuclein aggregation may be related processes in inclusion formation However, alpha-syn can be degraded by the proteasome in a ubiquitin independent manner and not all LBs contain ubiquitin These results suggest that alpha-syn ubiquityla-tion is not a primary event for alpha-syn fibrillizaubiquityla-tion This is in agreement with the observation that transgenic mouse models of alpha-syn accumulation show very little ubiquitin staining At present is clear that alpha-synuclein is linked to neurodegenera-tion in PD but the mechanisms and significance of its aggreganeurodegenera-tion remain to be determined

S3.8-3 Friedriech ataxia and other recessive ataxias

M Koenig IGBMC (CNRS-INSERM-ULP), Illkirch, Strasbourg, France Progressive recessive ataxias are severe disabling neurodegenera-tive diseases that affect the cerebellum and/or the spinocerebellar and sensory tracts of the spinal cord Thirteen genes causing non-metabolic degenerative ataxias have been identified in the recent years The majority of them encodes for either mitochond-rial or nuclear proteins The nuclear proteins are ATM, MRE11, tyrosyl-DNA phosphodiesterase 1 (TDP1), aprataxin and sena-taxin, respectively While the functions of ATM and MRE11 in DNA double strand break repair and of TDP1 immediately upstream of nucleotide excision repair are now well established, the precise function of aprataxin and senataxin remain elusive The mitochondrial proteins are frataxin, ABC7, twinkle and DNA polymerase gamma (POLGA) Twinkle and POLGA are involved mitochondrial DNA maintenance and frataxin and ABC7 are involved in Fe-S cluster biogenesis Complete loss of function of only ATM, aprataxin and senataxin results in reces-sive ataxia Ataxia mutations in the other genes are hypomor-phic, as their complete loss function would not be viable Friedreich ataxia is caused by intronic trinucleotide expansions which cause severely reduced expression of frataxin and subse-quent mitochondrial and cytosolic Fe-S protein deficiency We have used conditional and inducible knock-out strategies to artifi-cially recreate the partial frataxin deficiency in mouse models that present with several features of the human disease