Digital Comprehensive Summaries of Uppsala Dissertations
from the Faculty of Medicine
Modeling glioblastoma
heterogeneity to decipher its
biology
YUAN XIE
ACTA
UNIVERSITATIS
UPSALIENSIS
UPPSALA
2016
ISSN 1651-6206
urn:nbn:se:uu:diva-278529
Dissertation presented at Uppsala University to be publicly examined in Rudbecksalen, Dag
Hammarskjold v 20, Uppsala, Friday, 15 April 2016 at 09:15 for the degree of Doctor of
Philosophy (Faculty of Medicine). The examination will be conducted in English. Faculty
examiner: PhD, head of the Seve Ballesteros Foundation Brain Tumor group Massimo
Squatrito (BBVA Foundation – CNIO Cancer Cell Biology Programme).
Abstract
Xie, Y. 2016. Modeling glioblastoma heterogeneity to decipher its biology. Digital
Comprehensive Summaries of Uppsala Dissertations from the Faculty of Medicine 49 pp.
Uppsala: Acta Universitatis Upsaliensis.
Glioblastoma multiforme (GBM) is the most common and lethal form of primary brain tumor
that mainly affects adults. GBM displays remarkable intra- and inter-tumoral heterogeneity and
contains a subpopulation of cells named glioma stem cells that is believed to be responsible for
tumor maintenance, progression and recurrence.
We have established and characterized a biobank of 48 cell lines derived from GBM patients.
The cells were explanted and maintained as adherent cultures in serum-free, defined neural
stem cell medium. These GBM cells (GCs) displayed NSC marker expression in vitro, had
orthotopic tumor initiating capability in vivo, harboured genomic alterations characteristic of
GBM and represented all four TCGA molecular subtypes. Our newly established biobank is
also connected with a database (www.hgcc.se) that provides all molecular and clinical data.
This resource provides a valuable platform of valid in vitro and in vivo models for basic GBM
research and drug discovery.
By using RCAS/tv-a mouse models for glioma, we found that GBMs originating from a
putative NSC origin caused more tumorigenic GCs that had higher self-renewal abilities than
those originating from putative glial precursor cell origin. By transcriptome analysis a mouse
cell origin (MCO) gene signature was generated to cluster human GCs and GBM tissue samples
and a functional relationship between the differentiation state of the initially transformed cell
and the phenotype of GCs was discovered, which provides the basis for a new predictive MCObased patient classification.
LGR5 was found to be highly expressed in the most malignant mouse GC lines of putative
NSC origin and also enriched in proneural GBMs characterized by PDGFRA alterations and
OLIG2 up-regulation. By overexpressing or depleting LGR5 we discovered that high LGR5
expression in proneural GC lines increased the tumorigenicity, self-renewal and invasive
capacities of the cells and could potentiate WNT signalling through its ligand RSPO1. Through
transcriptome analysis we identified the candidate genes CCND2, PDGFRA, OLIG2, DKK1 that
were found to be regulated by LGR5.
In the last study, we found that mouse OPCs could initiate both astrocytic and oligdendroglial
gliomas, which indicated that oncogenic signalling is dominant to cell of origin in affecting the
histology of gliomas.
Keywords: Glioblastoma multiforme, biobank, GBM cells, cell of origin, LGR5, OPCs
Yuan Xie, Department of Immunology, Genetics and Pathology, Rudbecklaboratoriet, Uppsala
University, SE-751 85 Uppsala, Sweden.
© Yuan Xie 2016
ISSN 1651-6206
urn:nbn:se:uu:diva-278529 (http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-278529)
To my family
”A will finds a way”
-Orison Swett Marden
List of Papers
This thesis is based on the following papers, which are referred to in the text
by their Roman numerals.
I
Xie, Y.*, Bergström, T.*, Jiang, Y.*, Johansson, P.*, Marinescu, V.
D., Lindberg, N., Segerman, A., Wicher, G., Niklasson, M.,
Baskaran, S., Sreedharan, S., Everlien, I., Kastemar, M.,
Hermansson, A., Elfineh, L., Libard, S., Holland, E.C., Hesselager,
G., Alafuzoff, I., Westermark, B.#, Nelander, S.#, Forsberg-Nilsson,
K.#, and Uhrbom, L.# (2015). The Human Glioblastoma Cell Culture
Resource: Validated Cell Models Representing All Molecular
Subtypes. EBioMedicine, 2 (10):1351-1363.
II
Jiang, Y.*, Marinescu, V.D.*, Xie, Y., Jarvius, M., Haglund, C., Pendekanti, P., Olofsson, S., Lindberg, N., Olofsson, T., Hesselager, G.,
Alafuzoff, I., Fryknäs, M., Larsson, R., Nelander, S.#, and Uhrbom,
L.# (2016). Malignancy and drug sensitivity of glioblastoma cells are
affected by the cell of origin. Submitted.
III Xie, Y., Sundström, A., Marinescu, V.D., Tan, E-J., Pendekanti, P.,
Tirfing, M., Blokzijl, A., Jin, C., Chen, L., Essand M., Swartling,
F.J., Nelander S., Jiang Y., and Uhrbom L. (2016). High LGR5
expression in proneural glioblastoma cells contributes to increased
self-renewal and invasiveness. Manuscript.
IV Lindberg, N., Jiang, Y.*, Xie, Y.*, Bolouri, H., Kastemar, M.,
Olofsson, T., Holland, E.C., and Uhrbom, L. (2014). Oncogenic
signaling is dominant to cell of origin and dictates astrocytic or
oligodendroglial tumor development from oligodendrocyte precursor
cells. The Journal of Neuroscience, 34 (44): 14644-14651.
*, # These authors contributed equally to this work.
Reprints were made with permission from the respective publishers.
Other papers by the author:
•
Segerman, A., Niklasson, M., Haglund C.*, Bergström, T.*, Jarvius,
M.*, Xie, Y., Caglayan, D., Westermark, A., Hermansson, A.,
Kastemar, M., Ali, Z.N., Berglund, M., Sundström, M., Hesselager,
G., Uhrbom, L., Gustafsson, M., Larsson, R., Fryknäs, M., Segerman, B.#, and Westermark, B.# (2016). Glioblastoma exhibits phenotypic microheterogeneity and harbors pre-existing multiresistant
clones with a mesenchymal transition signature. Submitted.
•
Sreedharan, S.*, Xie, Y.*, Pendekanti, P.*, Sundström, A., Jarvius,
M., Libard, S., Fryknäs, M., Larsson, R., Alafuzoff, I., Swartling,
F.J., and Uhrbom L. (2016). Molecular and phenotypic influences of
cell of origin on pediatric high-grade glioma. Manuscript.
*, # These authors contributed equally to this work.
Contents
Classification of glioma ................................................................................ 11 Histological classification......................................................................... 11 Transcriptome-based molecular classification ......................................... 12 Epigenetic-based molecular classification................................................ 14 Core pathways in human GBM ..................................................................... 15 RTK signalling pathways ......................................................................... 15 p53 and RB pathways ............................................................................... 18 Mouse models of glioma ............................................................................... 19 Chemical mutagen-induced models.......................................................... 19 Xeno- or allograft transplantation models ................................................ 19 Germline modification models ................................................................. 20 Somatic cell genetic modification models ................................................ 20 RCAS/tv-a glioma model ..................................................................... 21 Cellular origin of glioma ............................................................................... 23 Neural stem cells ...................................................................................... 23 Glial precursor cells .................................................................................. 23 Oligodendrocyte precursor cells ............................................................... 24 Sources of Heterogeneity within Cancer ....................................................... 25 Intrinsic Genetic/Epigenetic Clonal Evolution ......................................... 25 Extrinsic Environmental Effects ............................................................... 25 Cancer Stem Cell Model........................................................................... 26 Glioma Stem Cells ............................................................................... 26 Combined Model ...................................................................................... 27 LGR5 ............................................................................................................. 28 LGR5 and Wnt signalling ......................................................................... 28 LGR5 in cancer ......................................................................................... 29 LGR5 in GBM .......................................................................................... 30 Present investigations .................................................................................... 31 Paper I. ...................................................................................................... 31 The Human Glioblastoma Cell Culture Resource: Validated Cell
Models Representing All Molecular Subtypes .................................... 31 Paper II. .................................................................................................... 32 Malignancy and drug sensitivity of glioblastoma cells are affected
by the cell of origin .............................................................................. 32 Paper III. ................................................................................................... 34 High LGR5 expression in proneural glioblastoma cells contributes
to increased self-renewal and invasiveness.......................................... 34 Paper IV. ................................................................................................... 36 Oncogenic signalling is dominant to cell of origin and dictates
astrocytic or oligodendroglial tumor development from
oligodendrocyte precursor cells ........................................................... 36 Future perspective ......................................................................................... 38 Acknowledgements ....................................................................................... 40 References ..................................................................................................... 43 Abbreviations
ALV
APC
APCs
ARF
BMP4
BTSC
CDKN2
CNAs
CNP
CNS
COO
CRC
CSC
eGFP
EGF
EGFR
eNOS
FGF
G-CIMP
GBM
GC
GEF
GFAP
GPR
GSC
HGCC
HMG
IDH1
INK
LGR5
LOH
avian leucosis virus
adenomatous polyposis coli
astrocytic precursor cells
p14/p19 Arf
bone morphogenetic protein 4
brain tumor stem cell
cyclin-dependent kinase inhibitor 2A
copy-number aberrations
2’, 3’-cyclic nucleotide 3’-phosphodiesterase
central nervous system
cell of origin
colorectal cancer
cancer stem cell
enhanced green fluorescent protein
epidermal growth factor
epidermal growth factor receptor
endothelial nitric oxide synthase
fibroblast growth factor
glioma-CpG island methylator phenotype
glioblastoma multiforme
GBM cells
guanine exchange factor
glial fibrillary acidic protein
G-protein coupled receptor
glioma stem cell
Human Glioblastoma Cell Culture
high mobility group
isocitrate dehydrogenase 1
inhibitor of CDK4
leucine-rich repeat-containing G-protein coupled receptor 5
loss of heterozygosity
LRP
MAPK
MADM
MCO
MDM2
Mes
MLL5
MMLV
NF1
NO
NSCs
O2A
Olig2
OPCs
PDGF
PDGFR
PDGFRA
PI3K
PIP2
PN
Prolif
PTEN
PVN
RB
RCAS
RSPO
RTK
SVZ
TCGA
TMA
TP53
tv-a
VEGF
WHO
low density-lipoprotein receptor related protein
mitogen-activated protein kinase
mosaic analysis with double markers
mouse cell origin
murine double minute 2
mesenchymal
mixed lineage leukemia 5
moloney murine leukemia virus
neurofibromin 1
nitric oxide
neural stem cells
oligodendrocyte/ type-2 astrocyte
oligodendrocyte transcription factor
oligodendrocyte progenitor/precursor cells
platelet-derived growth factor
platelet-derived growth factor receptor
platelet-derived growth factor receptor alpha
phosphoinositide 3-kinase
phosphatidylinositol-4, 5-biosphosphate
proneural
proliferative
phosphatase and tensin homolog
perivascular niche
retinoblastoma 1
replication competent ALV splice acceptor
R-Spondin proteins
receptor tyrosine kinase
subventricular zone
The Cancer Genome Atlas Research Work
tissue microarray
tumor suppressor protein 53
receptor for subgroup A avian sarcoma and leukosis virus
vascular endothelial growth factor
World Health Organization
Classification of glioma
Malignant gliomas are the most common and aggressive primary intracranial
brain tumor mainly affecting adults. The most frequent and malignant glioma is called glioblastoma multiforme (GBM). Approximately 5% of the
GBM patients will survive five years after diagnosis despite implementation
of intensive therapeutic strategies and medical care1. The incidence of GBM
is much higher in older people with the highest in 75 to 84 years old patients1. Due to its features of diffuse infiltration, resistance to radio/chemotherapy, and remarkable intra- and inter-tumoral heterogeneity,
the prognosis is very poor and currently there is no cure for GBM patients2.
Histological classification
Gliomas are categorized morphologically as ependymomas, astrocytomas
and oligodendrogliomas. Tumors are further histologically classified into
four (I-IV) grades according to the World Health Organization (WHO) malignancy scale3. Grade I tumors are biological benign with a low proliferation index, and can often be cured by surgical resection alone. These gliomas
usually occur in children or young adults. Grade II tumors begin to infiltrate
into surrounding brain tissues, but with a relatively low proliferation potential. Several grade II tumors tend to transform to higher grades of malignancy. For instance, diffuse astrocytomas with a low-grade can progress to highgrade anaplastic astrocytomas and GBMs.
Grade III tumors exhibit nuclear atypia, increased anaplasia and mitotic
activity. In most cases, patients with grade III tumors are treated by radio/chemotherapy. Grade IV tumors are the most malignant and most frequent and account for 45.6% of all gliomas1. These tumors are also termed
GBM and often display pseudopalisading necrosis and extensive vascular
proliferation, considered to be hallmarks of GBM. Approximately 74,000
GBMs are diagnosed worldwide per year4. The median survival for GBM
patients ranges from 12 to 15 months despite intensive treatment5. GBMs are
further subdivided into primary and secondary GBM subtypes. Primary
GBMs account for approximately 90% of all GBMs, and usually occur in
older patients, while secondary GBMs typically occur in younger patients (<
45 years). Primary GBMs are diagnosed de novo while secondary GBMs are
derived from a prior diagnosis of a lower grade glioma. Primary and second11
ary GBMs have indistinguishable histopathological, but their genomes and
transcriptomes are remarkably different.
Figure 1. Histological classification of astrocytic tumors based on WHO malignancy
scale. Modified from1,3,5-7.
Transcriptome-based molecular classification
Human malignant gliomas exhibit a great level of inter- and intra-tumoral
molecular heterogeneity that is histopathologically indistinguishable. Based
on large-scale analysis of genomes, transcriptomes, and proteomes of tumor
samples, the first molecular classification of high-grade gliomas (HGGs =
grade III-IV gliomas) displayed three molecular subtypes: proneural (PN),
proliferative (Prolif), and mesenchymal (Mes)8. These subtypes displayed a
association with histological tumor grade. PN included almost all the WHO
grade III tumors and a part of grade IV tumors. In contrast, Prolif and Mes
are exclusively grade IV tumor with necrosis. Patients classified into PN
were around 40 years old with relatively longer survival. However, patients
from Prolif and Mes were about 50 years old with shorter survival. Loss of
PTEN and EGFR amplification could be found in both Prolif and Mes subtypes, but not in PN.
12
Subsequently, The Cancer Genome Atlas research network (TCGA) provided a robust gene-expression based molecular classification of adult
GBMs that is currently widely used. In this classification, GBMs are divided
into four molecular subtypes: classical, mesenchymal, neural, and proneural9. The classical group harbours high-level EGFR amplification, homozygous CDKN2A deletions, and a distinct lack of TP53 mutations. Chromosome 7 gain paired with chromosome 10 loss is also one main feature in
classical samples. The mesenchymal subtype is characterized with predominantly hemizygous NF1 deletion and lower level of NF1 mRNA expression.
This subtype also exhibited expression of mesenchymal markers
(CHI3L1/YKL40 and MET) and astrocytic markers (CD44 and MERTK). The
neural samples have no defining mutations and an expression of markers that
is quite similar to normal brain. The proneural class harbours PDGFRA alterations or point mutation in IDH1, and frequent TP53 mutations. This
group displayed high expression of oligodendrocytic lineage genes, such as
PDGFRA and OLIG2. Moreover, a subset of the proneural group was found
display global hypermethylation, a feature termed glioma-CpG island methylator phenotype (G-CIMP), often overlapping with the IDH1 mutated samples, and these patients were younger at diagnosis and had improved survival10,11.
Accumulating evidence also indicate the remarkable intratumor heterogeneity of GBM which can be an underlying cause for the treatment failure.
Different samples from the same GBM patient can be classified as different
TCGA subtypes12. Individual cells13 or single cell-derived clones14 from the
same GBM patients can also be grouped as different subtypes by transcriptome analysis.
Table 1. Molecular classification of GBM based on large-scale analysis of genomes
and transcriptomes by TCGA.
13
Epigenetic-based molecular classification
Furthermore, an epigenetic-based GBM classification that also included
pediatric GBMs has revealed six distinct DNA methylation clusters15.
Hotspot H3F3A mutations affecting two amino acids (K27 and G34) have
been identified almost exclusively in GBMs from children, that were mutually exclusive with IDH1 mutations. Based on correlation with mutations,
gene expression profile and DNA copy-number aberrations (CNAs), six
distinct DNA methylation clusters are identified, “IDH”, “K27”, “G34”,
“RTK I (PDGFRA)”, “mesenchymal” and “RTK II (Classic)”. “IDH1”
group contains a majority of IDH1 mutated tumors and exhibits concerted
hypermethylation, which is clearly mapped to G-CIMP+ cluster10. “proneural” signature is found in all the tumors from “IDH1” cluster9. “K27” group
is also clearly enriched in “proneural” expression. Nevertheless, for ”G34”
cluster, it displays widespread hypomethylation especially in nonpromoter
regions.
In all the three clusters of IDH1, K27 and G34, frequent TP53 mutations
and lack of detected CNAs (amplification of EGFR, deletion of CDKN2A,
chromosome 7 gain paired with chromosome 10 loss) were observed. In
addition, “RTK I (PDGFRA)”, “mesenchymal” and “RTK II (classical) clusters are respectively highly enriched for proneural, mesenchymal, and classical gene expression signatures described by TCGA9.
It is known that dysregulation of H3.3 is through mutations in pediatric
GBM. Adult GBMs also display the dysregulation of H3.3 but through epigenetic repression. It has been revealed that mixed lineage leukemia 5
(MLL5) and H3.3 together play a role in maintaining cell self-renewal, a key
character of cancer cell contributing to GBM recurrence16.
14
Core pathways in human GBM
Multi-dimensional molecular analysis has identified three core pathways in
human GBM pathogenesis, including RTK signalling, and the p53 and RB
tumor suppressor pathways. TCGA has found 74% of 206 human GBM
samples carried aberrations in all three pathways, suggesting that cooperation among three pathways is a core requirement in controlling glioma cell
proliferation, apoptosis, necrosis, angiogenesis and metastasis17.
RTK signalling pathways
Based on the latest study of GBM by TCGA, genetic aberrations have been
found in up to 90% of the RTK/PI3K/RAS pathway11.
Receptor tyrosine kinase (RTK) signalling pathways are critical targets
for glioma initiation and progression. Several mechanisms are involved in
activating the RTK pathways, such as receptor amplification, abnormal activity through autocrine stimulation or receptor mutations causing constitutive activity. In nomal cells RTKs are activated upon ligand binding (e.g.
EGFs, FGFs, PDGFs or VEGFs) to their specific RTK that induces dimerization of RTKs and autophosphorylation of intracellular domains. The phosphorylated RTKs then activate corresponding downstream effector pathways, including Ras/MAPK, PI3-K, PLC-γ, and JAK-STAT, which can
regulate cellular responses such as proliferation, survival and migration18.
15
Ligand (EGF,FGF,VEGF or PDGF)
Dimerization
RTK
RTK
Cell membrane
RAS
NF-1
Raf
SOS
Grb-2
p
p
p
p
PI3K
MEK
PIP2
PIP3
PIP2
Akt
PTEN
ERK
Proliferation
Survival
Cell cycle progression
Migration
Nuclear Membrane
CDKN2A
Mutant Arf
p16INK4a
p14/p19ARF
S
G2
MDM2
MDM2
Cell cycle
restriction
Arf
p53
M
G1
p
p53
p
p
Proteasome
p21
p
pRb p
p
E2F
pRb p
p
CDK4
Cyclin
CDK6
Figure 2. Major signalling pathways in human GBM. Modified from19. Red prints
indicate oncogenes, and green prints indicate tumor suppressor genes.
16
PDGFR signalling is an essential regulator of gliomagenesis. There are
four PDGF ligands PDGF-A, -B, -C, -D, that form of homo- or heterodimers, which may bind to the receptors PDGFR-αα, PDGFR-αβ or
PDGF-ββ20. PDGF is secreted by type-1 astrocytes and promotes the division and development of bipotential oligodendrocyte/ type-2 astrocyte
(O2A) progenitor cells21-23. In the normal brain PDGFR signalling is considered to play a predominant role in oligodendrocyte development22. It has
been found that PDGFR-α is downregulated in glial progenitors that differentiate into oligodendrocytes, and PDGF-AA deficient mice have a great
decrease in the number of glial progenitors and oligodendrocytes24. In the
adult mouse brain, PDGFR-α is restricted to the ventricular and subventricular zones (SVZ) of the lateral ventricles, which is deemed as the biggest
niche of adult neurogenesis and the most likely source of gliomas25. PDGFRα+ cells have also been found scattered throughout the white matter and
cerebral cortex of adult rodents26. An important role for PDGFR signalling in
human GBM was implied for the first time several decades ago when coexpression PDGF ligands and receptors were described in glioma cells27, that
was shown to result in increased cell proliferation due to an autocrine loop2830
. Unsupervised analysis of 251 GBMs, PDGFRA was found altered in 13%
of all the samples.
The majority of alterations in GBM involve EGFR signalling11,17. EGF
mRNA expression could be detected in all regions examined including cerebellum, cerebral cortex, brain stem, olfactory bulb, hippocampus, basal hypothalamus, striatum and thalamus during central nervous system (CNS)
development in rat31. On embryonic day 14, EGF expression could be detected and continued to be detected to the postnatal period in the whole
brain31. Cellular localization and finding of EGFR support the notion of the
roles of EGF in CNS development. EGFR is also found to be expressed in
various region of the CNS32. In primary GBM, EGFR is frequently activated.
The most common EGFR VIII mutant is the deletion of extracellular domain
(exon 2-7), which result in a constitutively active receptor33,34. According to
the latest study by TCGA, up to 57% of the GBMs displayed EGFR alterations, including mutation, rearrangement, altered splicing, and /or focal amplification11.
Ras/MAPK and PI3-K are two major effector pathways activated by
RTKs. Ras are part of the monomeric GTPase superfamily of proteins. Ras
are located in the inner surface of the plasma membrane and transmit extracellular signals to promote the activities of cells, such as cell growth, proliferation and differentiation. Autophosphorylation of intracellular receptor
domains allows guanine exchange factor (GEF) to attach to the receptor by
the adaptor proteins SOS and Grb-2. GEF induces the exchange of GDP to
GTP, which result in activation of Ras. Furthermore, Ras-GTP can be inactivated by Ras-GAP proteins (e.g. NF1). NF1 is a tumor suppressor in glioma,
inactivating mutations or homozygous deletions of NF1 can be found in 10%
17
of GBMs11. The major downstream target of Ras-GTP is mitogen-activated
protein kinase (MAPK), which is involved in the regulation of cell proliferation.
The other important effector of RTK activation, PI3K (phosphinositide 3kinase), acts by phosphorylating PIP2 to PIP3 that in turn activates its downstream target Akt, which plays a vital role in cell survival and cell proliferation. Akt mutations are very rare but the high activity has been seen in most
GBM samples17. However, tumor suppressor protein PTEN catalyses
dephosphorylation of PIP3 to PIP2 and counteracts the PI3K activity. Mutations or homozygous deletions of PTEN can be detected in 41% of GBMs11.
p53 and RB pathways
According to TCGA, at least one genetic alteration has been identified in
85% and 79% of p53 and RB pathways respectively11, that is most GBMs
have mutations of both these pathways. The essential components of the RB
pathway are CDKN2A, CDK4/6 and RB and in the p53 pathway CDKN2A,
MDM2/4 and p53. The CDKN2A locus is thus shared by both p53 and RB
signalling and encodes two tumor suppressor proteins, p16INK4a and p14ARF.
p16INK4a inhibits CDK4 and CDK6 that promote activation of RB. Activation
of Rb proteins bind E2F family proteins, which in turn inhibit the cell cycle
to move on to the S phase. The other tumor suppressor encoded by
CDKN2A, p14ARF, can bind to and inactivate MDM2, an E3 ubiquitin ligase
that cause degradation of p53. Furthermore, p53 can bind to promoters of
many downstream genes that regulate cell cycle arrest, DNA repair and programmed cell death.
18
Mouse models of glioma
Mouse models are the favorite animal models to study human cancers due to
their genomic similarity and short generation period. Mouse models can be
used to study complex tumor characteristics including malignancy, invasion,
and metastasis, which cannot be modeled in cell culture systems. Moreover,
mice are essential tools as preclinical models for identifying potential therapeutic targets for tumorigenesis. To date, there are four predominant strategies employed that mimic human gliomagenesis: chemical mutagen-induced
models, xeno- or allograft transplantation models, germline genetic modification models and somatic cell genetic modification models35.
Chemical mutagen-induced models
DNA alkylating agents are commonly used to generate point mutations to
induce glioma36-38. Although the histology of induced tumors show similarity
to equivalent tumors in human, the initiating mutation responsible for tumor
induction and the cell of origin are not known in this model.
Xeno- or allograft transplantation models
This strategy has been widely used in preclinical trials39,40 and to examine
the tumor initiating capacity of brain tumor stem cells (BTSCs). Human or
mouse glioma cell lines are injected subcutaneously or orthotopically into
immunocompromised mice. These cells usually grow fast and tumor incidence is high. These models have several good characteristics including
defined and reproducible tumor formation and time to death41. However,
genetic alterations and immunological interaction between tumor and host
are not known in these models, which is not ideal for investigating early
stages of tumor development but good tools for drug test and preclinical
studies.
19
Germline modification models
The formation of glioma is a multistep process that involve altered growthfactor signalling and altered cell-cycle arrest. More genetically accurate rodent model is developed by gain of function transgenic approaches and loss
of function targeted deletion strategies. By applying the promoter that drives
a construct’s expression, knock-in mice can express a gene of interest, or
called oncogene in all the cells. On the contrary, transgenic mice can lose
expression of tumor suppressor genes. By applying the Cre/Lox technology,
inducible conditional knock-out or knock-in models can be made through
recombining a pair of target DNA sequences (named lox sequence) by Cre
recombinase42. This technology is widely used in germline modification
models. However generation of germline modification models is a timeconsuming process.
Somatic cell genetic modification models
By injecting retroviral vectors, genes of interest are delivered into cells postnatally. Unlike germline modification, somatic cell genetic modifications are
not inheritable. To date, two common systems are available including
MMLV (moloney murine leukemia virus) and ALV (avian leucosis virus)
single–stranded RNA virus based approaches43. MMLV has the ability to
infect any dividing cell types. Obviously, the cell of origin of gliomagenesis
cannot be specified by using this system. However, ALV has a limited infection capacity restricted to avian cells because their expression of the tv-a
receptor. Mammalian cells can be made susceptible to ALV infection
through transgenic expression of tv-a. RCAS (replication competent ALV
splice acceptor) is an ALV retrovirus that is used as vehicle to transfer genes
of interest into transgenic mice that express tv-a, the avian cell surface receptor for RCAS. Nowadays, the RCAS/tv-a system is widely used in transferring oncogenes into selected somatic cell types, which may allow for spatiotemporal control of tumorgenesis. It is an excellent model for addressing the
cell of origin of glioma43. Recently, an efficient and promising targeting
method CRISPR/Cas9 has emerged to model gliomagenesis44. By applying
this technology to delete multiple genes (Trp53, Pten, Nf1) in the mouse
brain, GBM-like tumor will develop45.
20
RCAS/tv-a glioma model
To obtain cell type-specific gene transfer by RCAS tv-a transgenic mice are
needed.
Figure 3. The RCAS/tv-a mouse model. Three different transgenic tv-a mouse lines
N/tv-a46, G/tv-a47 and C/tv-a48 were used in our glioma studies.
There are many tv-a transgenic mouse lines available46-52, but in our glioma studies we have used three different tv-a transgenic mouse lines, Nestin/tv-a, GFAP/tv-a and CNP/tv-a. The Nestin promoter is used to control the
expression of tv-a in N/tv-a mice, which direct infection to CNS stem and
progenitor cells47. In G/tv-a mice the glial fibrillary acidic protein (GFAP)
promoter is used that direct infection to mature astrocytes and NSCs46, and
in the C/tv-a mice recently established in our lab, the CNP (2',3'-cyclic nucleotide 3'-phosphodiesterase) promoter is used to drive infection in late
oligodendrocyte progenitor cells (OPCs) and mature oligodendrocytes48. All
21
tv-a mouse lines have been crossed with mice deficient for the tumor suppressor genes of Cdkn2a locus, Ink4a, Arf or combined loss of both.
With these mouse lines we and others have modeled many types and
grades of gliomas. For instance, with RCAS-PDGF-B oligodendrogliomalike tumors could be induced in all three tv-a lines48,53-55. Combined K-ras
and Akt infection generated malignant gliomas in N/tv-a but not G/tv-a
mice55. The additional loss of Ink4a or Arf in both N/tv-a and G/tv-a mice
lead to higher tumor incidence and malignancy55,56.
22
Cellular origin of glioma
The cell of origin in human GBM is unknown. Investigations from mouse
models imply that many cell types of the CNS can be the origin. Development of cells in CNS occurs in a hierarchical way, from NSCs to committed
precursor cells that in turn differentiate into neurons, ependymal cells, astrocytes and oligodendrocytes. Based on results from animal models many of
these cell types have the potential to serve as a cellular origin of glioma.
Neural stem cells
NSCs mainly reside in the SVZ and hippocampus. Human brain tumors are
frequently located in this germinal region, SVZ57. By evaluation of MRI
scans in 100 glioma patients, up to 93% cases the lesion connected to SVZ58.
NSCs have self-renewal capacity, and can differentiate into neurons and
macroglia (astrocytes and oligodendrocytes). Several surface markers are
available to characterize both normal NSCs and GSCs, like Sox259, Nestin60,
CD13361, GFAP57, and GFAP delta57,62. Nevertheless, none of them is universal stem cell marker. Combination of p53 loss and activation of Ras signalling via Nf1 inactivation is demonstrated to initiate malignant astrocytoma
with 100% penetrance. Histopathology analysis of all these tumors reveals
that all the early pre-symptomatic lesions reside within SVZ of lateral ventricle, indicating that NSCs in SVZ region may serve as a cell-of-origin63.
Inactivation of tumor suppresors p53, Nf1 and Pten in neural stem cells is
certified to be necessary and sufficient to develop malignant astrocytoma64.
Putatively NSC derived glioma stem cells are demonstrated to sustain GBM
growth and recurrence after chemotherapy65.
Glial precursor cells
GFAP is expressed in both radial glia cells66 and NSCs of the SVZ67, which
has been widely used as a promoter to control many different oncogenic
mutations. Somatic delivery of PDGFB into GFAP+ cells results in oligodendrogliomas or oligo-astrocytomas in 40% mice by applying RCAS/tv-a
mouse model, and loss of Ink4a-Arf shortens latency and increases malignancy of glioma53. Inactivation of pRb, p107 and p130 in GFAP+ cells in23
duced high-grade astrocytoma, and the tumor development was accelerated
by heterozygous deletion of PTEN but not P5368. Lentiviral transduction of
shNF1-shp53 in GFAP+ cells can give rise to malignant glioma69.
Oligodendrocyte precursor cells
CNP is a highly specific marker in the CNS for late development of OPCs or
in mature oligodendrocytes. It is applied as a promoter to control oncogenic
mutations in C/tv-a mice that is developed in our lab48. RCAS-PDGFB transfer to CNP+ cells can induce WHO grade II glioma with a penetrance of
33%. Although infected cells are CNP+, the tumor cells start to express earlier OPCs markers, like SOX2, SOX10, OLIG2, NG2, and PDGFR, indicating
a process of dedifferentiation occur in target OPCs. NG2+ oligodendroglioma cells show sensitivity to chemotherapy and have limited self-renewal
capacity, which indicate a progenitor origin for these cells70. Additionally, a
new mouse model “MADM” (mosaic analysis with double markers) allows
to trace entire tumorigenic process when initial mutation p53/Nf1 sporadically in NSCs. Interestingly, aberrant proliferation prior to tumor lesion can
only be discovered in OPCs. Transcriptome analysis of these tumors also
reveals obvious OPC feature71. Recently, two phenotypically and molecularly distinct subtypes of GBM has been discovered, which arise from functionally different CNS progenitors. This finding point to that the cell of
origin plays an essential role in determining GBM subtype diversity72.
24
Sources of Heterogeneity within Cancer
Intrinsic Genetic/Epigenetic Clonal Evolution
The concept of genetic clonal evolution was presented in 1970. It suggests
that a tumor is initiated from one mutated single cell that acquires a selective
growth advantage over the adjacent cells. After a latency period, neoplastic
proliferation eventually leads to genetic instability in the expansion of a tumor cell population73. Also, a central role of epigenetic processes in cancer
development have been frequently studied in the past decades74. Upon intrinsic genetic/epigenetic clonal evolution, heterogeneity arises within tumors in
a stochastic manner and through a selection process.
Extrinsic Environmental Effects
Heterogeneity can also arise in response to extrinsic environmental factors.
Cancer cells adjacent to the perivascular niche (PVN) show differences from
the cells located further away from the PVN. One study shows that endothelial nitric oxide synthase (eNOS) is significantly increased in tumor vascular
endothelium that is adjacent to glioma cells. Only the perivascular glioma
cells show expression of Nestin, Notch and the nitric oxide (NO) receptor,
but not the cells further from blood vessels75. This indicates that only a population of glioma cells adjacent to blood vessels can respond to NO signalling.
25
Figure 4. Sources of heterogeneity within cancer. Modified from76.
Cancer Stem Cell Model
The cancer stem cell (CSC) model suggests that tumors are mainly initiated
by a rare fraction of self-renewing, multipotent cells with stem cell capabilities77-79. There is now compelling evidence that various cancers, both leukemias and solid tumors are organized in a hierarchical manner and sustained
by the so-called CSCs (or tumor initiation cells) which can generate full
repertoire of tumor cells80.
Glioma Stem Cells
GSCs are a subpopulation of cells suggested to be responsible for glioma
maintenance, therapeutic resistance and recurrence. To date, three functional
criteria are used to characterize GSCs: (1) They are tumorigenic after intracranial orthotropic transplantation into NOD-SCID mice. (2) GSCs can give
rise to both tumorigenic and non-tumorigenic cells, establishing a cellular
hierarchy. (3) They have increased self-renewal capacity and multi-lineage
differentiation potentials81.
As GSCs can be a potential therapeutic target, there is a great interest in
finding a reliable cell-surface marker to identify and isolate them. CD133
(prominin-1) was the first marker used to isolate GSCs. These CD133+ cells
held the capacity to proliferate and self-renewal in vitro and lacked expression of neural differentiation markers. As few as 100 CD133+ were proved to
be sufficient for initiation of human brain tumors in NOD-SCID mice, while
as much as 50,000 to 100,000 CD133- cells could not form tumors in the
same mice. It suggested that CD133+ human brain tumor cell fraction contain GSCs that exclusively induced tumor formation82. Furthermore, CD133+
26
cells exhibit the ability to activate DNA damage checkpoint in response to
radiation, which is deemed as the source of tumor recurrence after radiation83. However, increasing controversy argues that CD133- cells also have
the capability to initiate tumor in nude mice and give rise to CD133+ cells84.
Approximately 40% of freshly isolated GBM biopsies do not contain
CD133+ cells. It seems that the ability of self-renewing and proliferation in
human brain tumor might not be restricted to an exclusive subset of CD133+
stem-like cells.
Over the last decade, several additional markers have emerged to enrich
GSCs, like CD4485, L1CAM86, A2B587,88, SSEA-181 and integrin alpha 689.
Some GSCs markers are also embryonic stem cell marker for normal brain
development, like Sox290-92, Nestin93,94, Nanog91 and Oct491,95,96. As GBM
displays remarkable intra- and intertumoral heterogeneity, it seems unlikely
to discover a universal marker for GSCs. Instead, trying to identify GSC
markers coupled to subgroups of GBMs, such as the molecular subtype or as
yet novel subgroups, will probably be a more successful strategy.
Combined Model
The above three sources of heterogeneity are not mutually exclusive and
may apply to variable extents depending on the type of cancer. Cancer that
depend on the CSC model could also follow genetic/epigenetic clone evolution and in response to extrinsic environmental effects.
In addition, since many cell types in the mouse can develop glioma it is
not unrealistic to hypothesize that so is the case also in human glioma. In
line with such reasoning it may also be hypothesized that different cellular
origin may contribute to the inter-tumoral heterogeneity found in GBM.
27
LGR5
Leucine-rich repeat-containing G-protein coupled receptor 5 (LGR5) is also
known as G-protein coupled receptor 49 (GPR49) or G-protein coupled receptor 67 (GPR67). It is a 7-transmembrane receptor that has gained prominence as a stem cell marker in the intestine, stomach and hair follicle, however its expression can be found across a diverse range of tissues such as
muscle, placenta, spinal cord and brain.
LGR5 and Wnt signalling
LGR5 is a member of wnt signalling pathway that controls stem cell selfrenewal and differentiation. Wnt receptor complex that activates canonical
pathway contains two components: a member of the Frizzled family and a
member of the low density-lipoprotein receptor related protein (LRP5 or
LRP6). R-Spondin (RSPO) proteins belong to a family of secreted Wnt signalling agonists that binds LGR5 and form a complex with Frizzled and LRP
to potentiate Wnt signalling97,98. The central player of the wnt pathway is
beta-catenin, whose stability is controlled by the “destruction complex”.
In absence of wnt receptor activation, Axin and the tumor suppressors adenomatous polyposis coli (APC) proteins form a scaffold that facilitates newly synthesized beta-catenin phosphorylation by two kinases, CK1α and
GSK3β. The phosphorylated beta-catenin is subsequently ubiquitinylated,
and undergoes proteasomal degradation. In the absence of wnt signalling, the
levels of beta-catenin will decrease which allows the DNA binding protein
Tcf/Lef to repress target gene expression by associating with co-repressors.
However, when wnt receptors are engaged, the destruction complex is inactivated through relocation of Axin to the membrane. Beta-catenins can accumulate and enter into the nucleus, which transiently converts Tcf/Lef factors into transcription factors. LGR5 activation by R-spondins has been
shown to enhance the WNT/beta-catenin signalling pathway leading to transcription of Tcf/Lef target genes98.
Wnt/beta-catenin signalling also plays a key role in the development of
glioma99. Persistent activation of beta-catenin has been found in the most
malignant form of glioma GBM100. In addition, Wnt2 and Wnt5a are also
overexpressed in human glioma. Knockdown of Wnt2 by siRNA in
U251MG could inhibit cell proliferation101 whereas overexpression of Wnt5a
28
increases glioma cell proliferation in vitro102. However, the molecular mechanisms behind Wnt-LGR5 signalling in GBM development are not well understood.
Figure 5. LGR5 and wnt signalling pathway. LGR5 activation by R-spondins has
been shown to enhance the WNT/beta-catenin signalling pathway. Modified from103.
LGR5 in cancer
LGR5 expression is not only enriched in healthy human intestinal stem cells
but also in tumor-initiation cells in human colorectal cancer. LGR5+ intestinal stem cells combined with loss of APC resulted in a progressively growing neoplasia104. LGR5 has further been validated as a bona-fide CSC marker identifying a fraction of colorectal cancer (CRC) cells with clonogenic
and tumorigenic capacities. In stomach cancer, LGR5+ pyloric stem cells
combined with loss of APC also lead to initiation of adenoma growth in the
pylorus105. LGR5+ pyloric stem cells are suggested as the cell of origin of
wnt-driven stomach cancer. In hair follicles, hundreds of regeneration cycles
occur in a lifetime. In the resting phase of this cycle, LGR5+ cells are
demonstrated to reside exclusive in secondary germ of telogen hair follicles
29
and the lower bulge that is/are believed to be the major stem cell reservoir
for hair follicles106. Further, LGR5+ hair follicle stem cells are identified as a
potential cell of origin for basal cell carcinoma107. Similar with intestine and
stomach, these LGR5+ stem cells are potential targets for oncogenic mutations as a route to skin cancer. Recently, LGR5+ stem cells are shown to be
radiosensitive and suggested to have the ability to overtime give rise to a
radioresistant stem cell population in colorectal cancer108.
LGR5 in GBM
Regarding the role of LGR5 in gliomagenesis, this is poorly investigated
with few reports so far. In 2013, Susumu et al. first demonstrated LGR5 as a
marker of poor prognosis in GBM based on immunochemistry staining of a
glioma tissue microarray (TMA) containing 283 different astrocytic tumors.
LGR5 knockdown in one glioblastoma cell line leads to loss of sphere formation and increased apoptosis109. LGR5 was then revealed to be preferentially expressed in GBMs of the proneural subtype and could be regulated by
the proneural factor OLIG2 through investigating two glioma cells lines with
siRNA-mediated OLIG2 depletion110. LGR5 depletion in U87MG cells that
cultured in serum containing medium, suspended sphere formation in vitro
and tumor growth in vivo111.Recently, SOX9 is found to directly upregulate
LGR5 mRNA expression by studying two glioblastoma cell lines112. And
trichosanthin (a bioactive protein purified form tuberous root of a Chinese
medical plant called Trichosanthes kirilowii) is discovered to induce apoptosis in U87 and U251 by targeting LGR5 and inhibiting the Wnt/beta-catenin
signalling pathway113.
30
Present investigations
Paper I.
The Human Glioblastoma Cell Culture Resource: Validated Cell
Models Representing All Molecular Subtypes
Background
Glioblastomas (GBMs) are highly heterogeneous and have recently have
been classified into distinct molecular subtypes. For relevant in vitro and in
vivo modeling of glioblastoma it is essential that the intra- and inter-tumor
heterogeneity can be maintained. There is a general agreement that classical
serum-derived cancer cell lines do not well represent the patients' tumors,
and that defined serum-free stem cell culture conditions is an efficient method to enrich for glioma-initiating cells in culture.
Aim
To establish a large collection of relevant and well-characterized cell lines
derived from GBM patients, maintained under serum-free stem cell culture
conditions.
Results and discussion
In this study, 94 GBM surgical specimens were explanted in defined serumfree media and 53 GC lines were established. The dissociated tumors cells
were first cultured as spheres and after 5-7 days transferred to laminincoated dish for adherent monolayer culture. Successful establishment of a
GC line from a patient’s tumor is positively correlated with a short patient
survival. To evaluate the proliferative capacity of these GC lines, we measured the cell density on day 1, day 4 and day 7. Patients whose tumors generated low proliferative cells exhibited better survival. However, a Cox multivariate analysis of several parameters (ability to propagated in culture, proliferative capacity and age) revealed that only age was a significant predictor
of survival.
Global gene expression followed by TCGA subtype classification was
applied on 48 of the GC lines. In a subset of tumor samples, we analysed the
molecular subtype of both primary tumors and their corresponding GC lines
employing Nanostring technology. Due to intratumor heterogeneity and
clonal selection during culturing, 10 of 22 cases the primary tissues and their
31
corresponding GC lines were assigned to the same molecular subtype. As GCIMP+ and IDH1 mutant proneural GBM patients showed better survival11,
we also analysed if there was IDH1 mutations in our GC lines by exsome
sequencing. We did not find the most frequent mutated site codon R132 in
IDH1 in any of the analysed GC lines, and in support with a previous report
showed that G-CIMP+ and IDH1 mutant GCs survival poorly in vitro114. The
above findings indicated that all our GCs are G-CIMP-. When transplanting a
majority of the GC lines to NOD-SCID mice, proneural GC lines displayed
the shortest survival compared to the other subtypes. This goes well in line
with a reduced survival of G-CIMP- proneural patients11.
To investigate the genomic similarity to TCGA GBM cohort, analysis of
copy number aberration was performed on 48 GC lines. Chromosome 7 gain
and chromosome 10 loss were presented in more than 70% of the GC lines
which was very similar to that of the tumors in TCGA cohort.
To summarize, we have established a large collection of human GBM
cells and these cells lines are tumorigenic, harbour genomic alterations characteristic of GBMs and represent all four TCGA molecular subtypes. This
collection we refer to as the Human Glioblastoma Cell Culture (HGCC)
resource, enable accurate cell-based modelling GBM and is connected with a
database (www.hgcc.se) that provides high-resolution molecular data and
clinical data. The HGCC resource provides an open-source repository for in
vitro and in vivo modelling of GBM heterogeneity that will enable stratified
studies of GBM mechanisms and facilitate the development of new therapies.
Paper II.
Malignancy and drug sensitivity of glioblastoma cells are
affected by the cell of origin
Background
GBMs harbours highly intra-and inter-tumor heterogeneity and can be divided into molecular subtypes but these have to date no clinical relevance. The
cell of origin for GBM is undefined but assumed to be a glial stem or progenitor cell. GBMs contain a subpopulation of cells called GSCs that has
increased resistance to therapy and is believed to be responsible for tumor
maintenance, progression and recurrence.
Aim
To investigate and cross-compare the consequences of the differentiation
state of the cell of origin for GBM development and GBM cell properties in
mouse and human cells. To identify a mouse cell origin (MCO) signature
32
and explore if that could be used to stratify GBM patients and find novel
targets and pathways of importance for GBM development.
Results and discussion
In this paper, we used RCAS/tv-a mouse models of glioma to investigate
how different states of differentiation of the initially transformed cell would
affect GBM development. To induce glioma, three different tv-a expressing
mouse strains (G/tv-a, N/tv-a and C/tv-a) were used to direct RCAS containing oncogene PDGF-B to infect GFAP, NES or CNP positive cells. All tv-a
mouse lines were used in a homozygous Arf deficient background.
To define the target cells in CNS, we initially injected DF-1 cells producing RCAS-eGFP in three tv-a lines at different locations in the brain. To
target NSCs and OPCs, we injected adult G/tv-a;Arf-/- and C/tv-a;Arf-/mice in the SVZ. To increase the likelihood to target other types of glial
precursor cells, we also inject N/tv-a;Arf-/- mice in the retrosplenial cortex
(CTX). By co-immunofluorescence staining for neural/glial markers and
GFP, we found RCAS infected CNS cells in G/tv-a SVZ brains displayed a
more immature phenotype (GFAP+/NES+/CNP-/OLIG2-/SOX2+), a putatively NSC; in N/tv-a CTX brains displayed a glial precursor cell-like phenotype (GFAP+/NES+/CNP-/OLIG2+/SOX2+) and in C/tv-a SVZ brains the
infected cells were similar to an OPC (GFAP-/NES-/CNP+/OLIG2+/
SOX2+).
Regarding the mouse survival, G/tv-a SVZ and N/tv-a CTX tended to be
more malignant than C/tv-a SVZ mice when DF-1 cells producing RCASPDGF-B were injected. Further, G/tv-a SVZ and N/tv-a CTX gave rise to a
glioma incidence of 100%, while tumors generated in C/tv-a SVZ mice had
an incidence of 82.6%.
Subsequently, we cultured GBM cells (GCs) in serum-free defined NSC
medium. The GC lines were named mGC1GFAP, mGC2NES and mGC3CNP for
mouse GCs originating from G/tv-a SVZ, N/tv-a CTX and C/tv-a SVZ. We
found mGC1GFAP cells of putative NSC origin were more tumorigenic and
had higher self-renewal abilities than mGC2NES or mGC3CNP cells, i.e. of
putative glial precursor cell origin. GCs of more immature origin are also
remarkably more resistant to proliferative arrest in response to seruminduced differentiation and were more sensitive to drugs compared to a glial
precursor cell origin.
By transcriptome analysis we have generated a MCO gene signature that
by cross-species bioinformatics could be used to stratify 64 human GCs and
529 GBM tissue samples. Human GCs in the mGC1GFAP group (=hGC1)
showed higher self-renewal and tumorigenic capacities while being more
sensitive to drugs compared to those assigned to the mGC2NES group
(=hGC2).
Here we show a functional relationship between the differentiation state
of the initially transformed cell and the phenotype of GBM cells generated
33
thereof that could be applied on human GBMs, which could have important
implications for therapy development and provide the basis for a new predictive MCO-based patient classification.
Paper III.
High LGR5 expression in proneural glioblastoma cells
contributes to increased self-renewal and invasiveness
Background
Glioblastoma (GBM) maintenance, progression and recurrence are believed
to be driven by GSCs that have unique/enhanced tumorigenic capacities and
are more resistant to therapy. GSCs are characterized by increased selfrenewal capacity and have the ability to generate the full repertoire of tumor
cells. LGR5 was discovered as a stem cell marker in several normal tissues
and has been shown to both enhance and be induced by WNT signalling.
Expression of LGR5 has also been found in various forms of cancer and has
been validated as a cancer stem cell marker. In paper II, we identified LGR5
to be significantly upregulated in GBM cells (GCs) derived from tumors
induced in GFAP-promoter active cells in the SVZ of adult mice, i.e. of putative NSC origin.
Aim
To analyse the role of LGR5 in GBM and its mechanism of action in GCs.
Results and discussion
By microarray analysis and subsequent qPCR validation LGR5 was found to
be highly expressed in the most malignant mouse GC lines of putative NSC
origin. Investigating our HGCC database we found that the expression of
LGR5 was also significantly higher in the proneural subtype of human
GBM, which is characterized by PDGFRA amplification/overexpression.
When exploring LGR5 expression in TCGA database, LGR5 was also found
to be enriched in the proneural subtype and a significant correlation between
LGR5 and PDGFRA mRNA expression was discovered in both all GBMs
(n=206) and in proneural GBM tumors (n=56). However, this positive correlation could not be detected when proneural samples were removed from the
data set. To investigate the relation between LGR5 and PDGFRA, we made
lentiviral vectors to be able to overexpress LGR5 in our GC lines. We found
overexpression of LGR5 caused an upregulation of PDGFRA in LGR5high
proneural GCs but not in LGR5low GCs by immunofluorescence staining.
Co-expression of PDGFRA and LGR5 was observed in one of the LGR5high
proneural GC lines. To study if PDGFRA expression would affect LGR5
expression, we treated LGR5high proneural GC lines with siPDGFRA, and
34
found that depletion of PDGFRA caused a significant decrease of LGR5
expression in two out of three GC lines. These findings suggest that LGR5
may play an important role in proneural GCs/GBM and there may be a functional connection between LGR5 and PDGFRA.
By applying limiting dilution assay, we found LGR5high proneural GCs
showed higher self-renewal capacity and generated larger spheres than
LGR5high mesenchymal and LGR5low GCs. To investigate the functional
consequence of high LGR5 expression in GCs, we made lentiviral constructs
containing short hairpin-LGR5 (shLGR5) or a nonsense control shRNA
(shNS). Depletion of LGR5 in LGR5high proneural GC lines had a hampering
effect on self-renewal capacity.
From our previous studies in mouse GCs we knew that self-renewal capacity is strongly correlated with tumorigenicity. By intracranially transplanting GC lines to NOD-SCID mice, we found LGR5high GC lines accelerated tumor development compared to LGR5low GC lines. As LGR5high proneural GCs had higher self-renewal ability than LGR5high mesenchymal GCs,
we also transplanted these GCs into NOD-SCID mice and found that
LGR5high proneural GCs were more tumorigenic than LGR5high mesenchymal
GCs.
To investigate if overexpression of LGR5 would affect the in vivo tumorigenic phenotype of GCs, we transplanted LGR5 overexpression GCs and
corresponding controls into NOD-SCID mice. Overexpression of LGR5 in
LGR5high proneural GCs caused both larger and invasive tumors compared to
their controls. However, we did not observe this effect in LGR5low GC lines.
Continually, we investigated the role of LGR5 in migration and invasion in
vitro. We found depletion of LGR5 in LGR5high proneural cells caused decreased migration by applying scratch assay and decreased invasion capacity
by applying 3-D invasion assay in collagen gels. In lines with in vivo studies,
overexpression of LGR5 in LGR5low GCs did not increase their invasion
capacity in vitro.
Several studies in CSCs have indicated a role of LGR5 in WNT signalling
and RSPOs have been shown to bind LGR5 to potentiate WNT signalling.
We found knock-down of LGR5 affected beta-catenin nuclear localization
upon WNT3a treatment. RSPO1 was found to potentiate WNT signalling in
a subset of GCs. Differential mRNA expression analyses of a large set of
glioma relevant genes in relation to LGR5 high and low expression generated many candidates that may be further investigated in order to identify the
underlying mechanism of LGR5 signalling. Three of the genes, CCND2,
OLIG2 and DKK1, were further investigated and all were found to be regulated by LGR5. Our findings point to an important role for LGR5 in sustaining stemness, invasiveness and tumorigenicity in proneural GCs, which
makes it a putative predictive biomarker and a potential target for future
drug development.
35
Paper IV.
Oncogenic signalling is dominant to cell of origin and dictates
astrocytic or oligodendroglial tumor development from
oligodendrocyte precursor cells
Background
The majority of gliomas of grades II-IV is composed of astrocytic and oligodendroglial tumors, which are the two most common types of glioma that
mainly affect adult. Astrocytic and oligodendroglial gliomas have been considered as separate disease groups with different diagnosis and putatively
different origins. Oligodendrocyte precursor cells (OPCs) have been demonstrated as the cell of origin for experimental oligodendroglial tumors. While,
if OPCs could be the cell of origin for experimental astrocytic gliomas remains largely unknown.
Aim
To investigate the potential and circumstance of OPCs to develop both astrocytic and oligodendroglial gliomas.
Results and discussion
In our lab, the Ctv-a mouse model was developed to study the role of OPCs
in glioma development48. Thus it is the evidence that OPCs can be the cell
origin for oligodendroglial-like tumor in mice. We wondered if OPCs also
held the potential to develop astrocytomas. We then injected K-RAS+AKT
into neonatal Ctv-a mice deficient for ink4a, Arf or ink4a-Arf. Both Ctv-a
wild-type and ink4a-/- mice were not susceptible to K-RAS+AKT-induced
glioma development. While Arf -/- and ink4a-Arf -/- mice could give rise to
tumor development from OPCs with an incidence of 30% and 19% respectively. Quite interestingly, K-RAS+AKT-induced glioma from OPCs displayed an astrocytoma-like histopathology.
To investigate if Cdkn2a loss was responsible for the astrocytic histopathology, we injected RCAS-PDGF-B into neonatal Ctv-a mice deficient
for Arf or ink4a-Arf. Loss of Arf or ink4a-Arf also accelerated PDGF-B induced glioma development and increased tumor incidence. However, the
histopathology of these tumors was analogous to human oligodendroglioma,
which was in concordance with PDGF-B induced glioma in Ctv-a wild-type
mice. These findings indicate that OPCs can give rise to both astrocytic and
oligodendroglial tumors, depending on the activated oncogenes and loss of
Cdkn2a.
Subsequently, we compared expression of various glial proteins in KRAS+AKT and PDGF-B-induced tumors. Nestin and GFAP displayed homogenous expression in all K-RAS+AKT induced gliomas, while GFAP
only detected in reactive astrocytes in PDGF-B induced tumors. Further,
36
several astrocytic markers like vimentin, CD44 and YKL40 were all displayed higher expression in K-RAS+AKT induced gliomas. OPC makers
like PDGFRα and OLIG2 were shown to give a higher, more homogenous
expression in PDGF-B induced tumors.
By analyzing the transcriptome data from TCGA database, there was a
clear overlap between human astrocytic and oligodendroglial tumors that
supported our mouse data. Our findings indicate that oncogenic signalling is
dominant to cell of origin (COO) in affecting the histologic classification of
gliomas. This may have implications for future therapy development since
we have data (in paper II) that shows that COO affects therapy response of
GCs.
37
Future perspective
Glioblastoma (GBM) is the most common and lethal form of primary brain
tumor, which displays remarkable intra-and inter-tumor heterogeneity. These
histologically inseparable adult GBMs can be classified into at least four
different TCGA molecular subtype: proneural. neural, classical and mesenchymal 9.
In paper I, we have described the establishment and characterization of a
biobank of 48 cell lines derived from GBM patients using stem cell culture
conditions and these GC lines represent all four subtypes. As different samples or even individual cells from the same GBM patients can give different
molecular subtypes12,13, similarly only 45% of GC lines showed identical
transcriptome subtype as the tumor of origin. Besides the sample heterogeneity, the existence of non-neoplastic cells, like inflammatory cells, reactive
astrocytes and vascular cells can also contribute to the subtype shift. It would
be very valuable to develop a new cell culture method to also maintain nonneoplastic cells. Additionally, most mesenchymal GC lines did not generate
macroscopic tumors within 20 weeks, however diffusely spread human GCs
could be detected in most of the mouse brain. It would be interesting to further investigate these mesenchymal lines, whether they represent a phenotypically distinct subgroups and if those seemingly quiescent but clearly
alive human GCs can initiate GBM in mice by giving enough time.
In paper II, we have analyzed the GBM development and essential GC
properties by comparing tumors induced by three putative originating cell
types. We have found that a more immature, NSC-like origin significantly
accelerated GBM development, increased the number of GCs in the primary
tumor and enhanced their malignant properties compared to a glial precursor
cell origin. By transcriptome analysis we generated 196 mouse cell origin
(MCO) gene signature to stratify human GBM cells and then performed drug
test on the stratified groups. Interesting, both mouse and human GCs with
higher self-renewal and tumorigenic capacity also displayed a greater drug
sensitivity. To develop more effective drug treatment, we need to further
investigate the mechanism of interplay between stemness and drug sensitivity. To further explore the MCO gene signature is also a way to reveal more
candidate genes or pathways to contribute to GBM therapy. Additionally,
when related our mouse GBM models to TCGA subtypes, it is clearly
showed that the three mouse models could not cover the whole human GBM
38
diversity, which encourage both us and others to add more relevant mouse
models and oncogenes to investigate cell of origin.
In paper III, we investigated the role of LGR5 in sustaining stemness and
invasive properties in proneural GCs. We found that LGR5 is highly enriched in the proneural subtype and correlated with proneural markers, like
PDGFRA and OLIG2. It would be interesting to further explore the role of
LGR5 in PDGFRA and p53 signalling. LGR5 did not affect proliferation but
both self-renewal and invasive capacity of proneural GCs, which suggests it
could serve as a potential therapeutic GBM target. By relating the expression
of 758 glioma-relevant genes to high versus low LGR5 expression, we found
LPAR4, CCND2, PDGFRA and OLIG2 were most up-regulated expressed
in LGR5high GCs and DKK1 was significantly down-regulated in LGR5low
GCs. Next, we will investigate more on these downstream genes of LGR5
and study their function connections with LGR5 and how they affect LGR5
signalling.
In paper IV, we showed that human astrocytic and oligodendroglial tumors could have the same cell of origin and genetic alterations is dominant
to cell of origin in determining glioma histopathology. Cell of origin can also
affect the molecular subtype of GBMs, which is supported by us (Paper II)
and others72. We also found that OPCs of neonatal mice were easier to generate PDGF-B induced glioma compared to OPCs in adult mice. This suggests that development age plays an essential role in glioma development. It
would be interesting to further explore how a more immature origin influent
glioma development in neonatal mice compared to adult mice. Gene expression profiles of neonatal and adult glioma will add values to further investigate the development age in gliomagenesis.
In all, high-grade glioma is a very complex, heterogeneous and lethal disease that currently has no cure. It is imperative to stratify glioma patients
into clinical relevant groups and identify effective drug targets for each subgroup of patients. By establishing a biobank of glioma patients derived GCs
to model GBM and investigating cell of origin, genetic alterations and role
of a cancer stem cell marker LGR5 in gliomagenesis, hopefully these investigations will contribute to the new therapy development and benefit glioma
patients.
39
Acknowledgements
This work has been carried out at the Department of Immunology, Genetics
and Pathology, Uppsala University, Uppsala, Sweden. Financial support was
provided by grants from the Swedish Cancer Society, the Swedish Research
Council, the Swedish Childhood Cancer Foundation, Ragnar Söderberg's
Foundation, Knut and Alice Wallenberg's Foundation, the Swedish Society
of Medicine, the Faculty of Medicine and the Department of IGP at Uppsala
University.
I would like to take this opportunity to express my gratitude to the people
who have supported and helped me during my work.
My supervisor Lene Uhrbom, for accepting me as a PhD student in your
research group, for guiding me in the scientific journey with patience, for
supporting me in my life with your affection, for smiling and sharing happiness within our group, for always being there whenever I turned to you.
My co-supervisor Bengt Westermark, for your profound knowledge and
humorous way of expression. I am always impressed by your speaking either
in conferences or in discussions, which encourages me to think more and
deeper!
My co-supervisor Anna Segerman, for motivating me with your enthusiasm
in science, for sharing valuable ideas with me.
All my co-authors and collaborators, especially, Yiwen, you are another cosupervisor for me. Your support throughout my life in Rudbeck at both scientific and personal level has been very helpful. E-Jean, you taught me how
to make a fancy presentation and it is always joyful to talk and work with
you. Usha, you are such a nice girl and thanks for all your helps and supports in the lab. Anders, for all the bioinformatics analysis you have done
and I am very impressed by your quick response, efficient work and also
your chocolate with 100% COCO. Tobias, for the nice collaboration on both
HGCC and KAW projects. You are also a genius in fixing computer problem. Patrik, for establishing a searchable database for our HGCC resource
and it is very glad to collaborate with you. Sven and Voichita, I am so lucky
that you are here, my studies could not have moved into a further level without your invaluable advice and great contributions. Fredrik, there always a
40
smile on your face; always a brilliant idea from your mouth. Thanks for your
invaluable advices and sharing the materials for molecular cloning. Karin,
for all your encouragement and great supports. Chuan, for the knowledge
and resources of lentivirus production. You are always there when I need
you. Andries and Lei, for help me to detect endogenous protein level of
LGR5 in GCs using in situ PLA. Marianne, you are the sunshine in our lab.
You make the working environment so nice and warm. You are the best
technician that I have ever seen. Smitha, you taught me how to do molecular
cloning and how to lead a happy lifeJ. Sathish, for many helps in both cell
lab and our benches. Malin T., for your hard working and you are one of the
best students that I have ever supervised. Mia, for your sweet smile and
many helps. Demet, for teaching me how to do stereotactic injections for
newborn mice, and happiness we were sharing together. Nanna, still remember the time we spent together in New York. You are such a nice person. I will never forget you, a lovely pink girl.
My past and present office mates: E-Jean, Vasil, Gabriela, Sara, Usha,
Antonia, Lucy, Anna Sjösten, Demet, Anqi, Sanna, Vikki, Sathish,
Ludmila, Smitha and Yiwen. Thank you for the innumerable laughs, biscuits, and sharing interesting experience. You make my life colorful.
The past and present members of the rest of the neuro-oncology group:
Elena, Jelena, Sanaz, Ananya, Annika, Soumi, Andreas, Lulu, Argyris,
Grzegorz, Elin, Evgenia, Lukasz, Cecilia, Ingrid, Linnea, Anna Borgenvik, Matko, Sanna, Sonjia, Holger, Lisa, Hanna, Ida, Maria Ferletta,
Erika, Malin Berglund, Malin Jarvius, Jacob, Ann Westermark, Anna
Dimberg, Maria Georanaki, Luuk, Hua, Lei Zhang, Kalyani and Roberta for all the care and great moment in the lab.
To the students that I have supervised: Malin Engvall, Lilian Kempe, Malin Tirfling, Augusta Broome and Tina Saren, for your contributions to
the progress of LGR5 project.
Special thank goes to Di, for many helps in molecular cloning, lentivirus
production, computer problems and personal matters. I would not come to
Sweden without your beautiful presentation of an introduction to Uppsala
University.
Lei Zhang, for the helps in qPT-PCR, IVIS machine and a very warm welcome when the first time I arrived in Uppsala.
Pacholsky and Sara Petersson, for the helps in cell sorting. Matyas, for the
helps in bioimaging.
41
Chirstina Magnusson, you always try your best to help me.
The past and present guys and girls from the “Chinese lunch-table”:
Xiujuan, Yiwen, Anqi, Dan, Hua, Lei Zhang, Hanqian, Liqun, Yan
Zhang, Lei Chen, Kun Wang, Junhong, Di Wu, Jin Zhao and Yunyuan
for the relaxing and delightful lunch time.
To my buddies in Sweden, Kun Wei, Rui Miao, Henrik, Yinghua, Anders
Lundqvist, Jing Ma, Lu Zhang, Xi Chen, Di Yu and Chuan Jin, for the
difficulties, happiness and gossip we are sharing together. My life would
have been boring without your accompany.
To all my friends else where, especially to Lu Li, Hualian, Chunyu, Yiwen
Liang and Guangting for caring about me and supporting me.
Mum and Dad, for always loving, encouraging and believing in me all the
time.
爸爸妈妈,谢谢你们爱我,鼓励我,相信我直到永远。
My dear Hao, thank you for always loving and supporting me, for always
tolerating my bad tempers (seems only to youJ). Looking forward to the
third member in our family!
42
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49
Acta Universitatis Upsaliensis
Digital Comprehensive Summaries of Uppsala Dissertations
from the Faculty of Medicine
Editor: The Dean of the Faculty of Medicine
A doctoral dissertation from the Faculty of Medicine, Uppsala
University, is usually a summary of a number of papers. A few
copies of the complete dissertation are kept at major Swedish
research libraries, while the summary alone is distributed
internationally through the series Digital Comprehensive
Summaries of Uppsala Dissertations from the Faculty of
Medicine. (Prior to January, 2005, the series was published
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