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Glioblastoma
multiforme: The terminator
Eric
C. Holland*
Departments of Neurosurgery and Molecular Genetics, M. D. Anderson
Cancer Center, 1515 Holcombe Boulevard, Box 64, Houston, TX 77030
Article
Glioblastoma multiforme is the most aggressive of the gliomas, a collection of
tumors arising from glia or their precursors within the central
nervous system. Clinically, gliomas are divided into four grades;
unfortunately, the most aggressive of these, grade 4 or
glioblastoma multiforme (GBM), is also the most common in humans.
Because most patients with GBMs die of their disease in less than a
year and essentially none has long-term survival, these tumors have
drawn significant attention; however, they have evaded increasingly
cleaver and intricate attempts at therapy over the last half-century.
The paper by Gromeier et al. (1) in this issue of PNAS is the newest chapter in this saga,
describing a hybrid virus that infects and kills clonal human glioma
cell lines, in culture and implanted in athymic mice, without
affecting nonneoplastic cells within the brain. For those viewing
this battle from a distance, the continued unsuccessful attempts at
novel therapies for this disease may be difficult to understand.
However, for those treating these patients, and certainly for the
patients themselves, the importance and urgency of each attempt is
clear.
One of the reasons for the resistance of GBM to therapeutic intervention
is the complex character of the tumor itself. As the name implies,
glioblastoma is multiforme. It is multiforme grossly, showing regions
of necrosis and hemorrhage. It is multiforme microscopically, with
regions of pseudopalisading necrosis, pleomorphic nuclei and cells,
and microvascular proliferation. And it is multiforme genetically,
with various deletions, amplifications, and point mutations leading
to activation of signal transduction pathways downstream of tyrosine
kinase receptors such as epidermal growth factor receptor (EGFR) and
platelet-derived growth factor receptor (PDGFR), as well as to
disruption of cell-cycle arrest pathways by INK4a-ARF loss or
by p53 mutations associated with CDK4 amplification or Rb loss
(2).
These tumors also show intratumor genetic heterogeneity with
subclones existing within the tumor cell population (3).
It has been estimated that cultured neoplastic and p53-deficient cells
may have mutations in any given gene at a rate as high as 1 in
1,000 cells (4). If this is approximately correct for GBMs in vivo,
then one would expect a tumor of 109 cells to harbor as many as 106
cells with mutations in any given gene.
One of the main reasons that the gliomas are not cured by surgery is the
topographically diffuse nature of the disease. In addition to the
above-mentioned variability within the tumor proper, the location of
the tumor cells within the brain also is variable, resulting in the
inability to completely resect this tumor. In 1940, Scherer (5) described the appearance and behavior of glioma cells
migrating away from the main tumor mass through the brain parenchyma.
The patterns of glioma cell infiltration have since been referred to
as the secondary structures of Scherer. These glioma cells migrate
through the normal parenchyma, collect just below the pial margin (subpial
spread), surround neurons and vessels (perineuronal and perivascular
satellitosis), and migrate through the white matter tracks (intrafacicular
spread) (Fig. 1). This invasive behavior of the individual cells may correspond to
the neoplastic cell's reacquisition of primitive migratory behavior
during central nervous system development. The ultimate result of
this behavior is the spread of individual tumor cells diffusely over
long distances and into regions of brain essential for survival of
the patient. The extreme example of this behavior is a condition
referred to as gliomatosis cerebri, in which the entire brain is
diffusely infiltrated by neoplastic cells with minimal or no central
focal area of tumor per se (6). Furthermore, ~25%
of patients with GBM have multiple or multicentric GBMs at autopsy (7). Although GBMs can be visualized on MRI scans as mass
lesions that enhance with contrast, the neoplastic cells extend far
beyond the area of enhancement. Fig. 2 illustrates a typical result of "gross total
resection" of a temporal lobe GBM followed 6 months later
by recurrence at the surgical margin and elsewhere. Even with repeat
surgeries for tumor recurrences, the patients die from tumor spread
into vital regions of the brain.
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Fig.
1.
Secondary structures of Scherer demonstrating migration of glioma
cells through normal brain structures. (A) Glioma cells
surrounding blood vessels (perivascular satellitosis) (arrow). (B)
Perineuronal satellitosis (arrow). (C) Collection of cells
below pial surface (subpial spread) (arrow). (D)
Intrafascicular spread of tumor cells through the corona radiata.
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Fig.
2.
MRI scans of a patient with a right temporal GBM illustrating the
spread of the disease. (A) Presurgical scan, GBM (arrow) is
surrounded with edema. (B) Scan after surgery and radiation
therapy showing "gross total resection" and clear
resection cavity, and (C) six months later, showing
recurrence not only at the resection margin (arrow) but a second
focus of GBM across the Sylvian fissure in the frontal lobe
(arrow). (D) Postresection scans of both recurrent tumors.
(E) Scan 3 months later, showing the tumor recurring
at the resection margin and crossing the corpus callosum to the
other hemisphere (arrow).
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The standard of care for treatment of GBM has been essentially unchanged
for many decades–surgical
resection of as much of the tumor as is safe, followed by radiation
therapy and chemotherapy (usually designed to damage DNA or to
otherwise inhibit DNA replication). Even under the best of
circumstances, in which essentially all of the enhancing tumor seen
on MRI scan can be surgically removed and the patients are fully
treated with radiation and chemotherapy, the mean survival of this
disease is only extended from 2 to 3 months (8)
to 1 year (Fig. 3).
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Fig.
3.
Kaplan-Meier survival plots for patients diagnosed with GBM.
Curves A, B, and C are historical data from
Jelsma and Bucy (8)
published in 1967 before the availability of MRI scans:
biopsy only (A), extensive resection (undefined) (B),
and extensive resection followed by radiation therapy (C).
Curve D is current data from the M. D. Anderson
Cancer Center on patients with >95% resection (by volumetric
MRI measurements) followed by both radiation therapy and
chemotherapy. Although there are essentially no long-term
survivors, removal of tumor mass clearly increases longevity.
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Because of the poor outcome of the standard treatments for GBM and of the
diffuse nature of the disease, a number of clever attempts at novel
therapeutic approaches recently have been made with the aim of
killing neoplastic cells far from the tumor proper. These approaches
have been designed to entice the immune system to reject the tumor,
to transfer lethal genes to the tumor cells with gene therapy, or,
more recently, to infect with viruses that kill the tumor cells lytically.
The immunologic approach has been investigated extensively with many
successes in laboratory animals. However, translation of success in
rodents to humans has not occurred. Potential explanations for this
apparent paradox center on the animal models used in the preclinical
experiments. Until recently, animal models for gliomas have consisted
of clonal glioma cell lines, maintained in culture, that are injected
in the flanks or brains of rodents. These cells grow into mass
lesions that eventually kill the animals (9, 10).
To what extent either the genetic alterations selected for during
passage of the cells in culture or the interactions between tumor
cells and the host tissues in these experimental gliomas represents
the biology of human gliomas is questionable, especially in the area
of immune rejection. Early experiments scored treatment successes as
rejection of the implanted allograph by the animals. Since then,
syngenic grafts have been used to avoid the non-self-recognition by
the host animal (11).
Another approach is the transfer of lethal genes to tumor cells by gene
therapy. The classic example of this strategy was the retroviral
transfer of the herpes simplex virus thymidine kinase (TK) gene to
tumor cells followed by treatment with the antiviral compound
gancyclovir to kill cells expressing TK. Early reports showed this
strategy to eradicate experimentally implanted gliomas in rodents (12). Unfortunately, the application of this strategy to human
gliomas has not seemed to have a therapeutic benefit in humans,
presumably attributable, at least in part, to the low infection rate
within the human tumors (13). In these rodent models, complete tumor regression was
obtained with infection of substantially less than 100% of cells,
caused by bystander effects in which infected cells are capable of
killing adjacent, uninfected tumor cells. However, the rodent models
used in these experiments, again, do not fully recapitulate the
behavior of the human disease. Specifically, the invasive character
of human gliomas rarely is recapitulated by grafting models. Although
implanted rodent gliomas might appear to invade surrounding
structures, they frequently do not do so on a cell-by-cell basis.
Rather, implanted gliomas are comprised of cells in direct contact
with each other and, therefore, a bystander effect probably is more
likely to be seen in these animal models than in the diffuse portions
of human gliomas, illustrated in Fig. 1.
A more recent approach to solving the low rate of infection and gene
transfer is the use of viral vectors that replicate in and thereby
lytically kill tumor cells. These approaches use viruses that
normally infect the central nervous system that have been modified to
become nonpathogenic to normal tissues but remain lytic to neoplastic
cells. Attenuated, nonneurovirulent versions of herpes simplex virus
have been used previously and have been shown to kill glioma cells in
culture and implanted in rodents (14). These viruses are currently in clinical trials. The paper by
Gromeier et al. (1) now reports the use of a polio virus-human rhinovirus that
does not have the neurovirulence of polio virus but does infect and
kill clonal human glioma cell lines both in culture and as xenographs
in athymic mice (1).
All strategies for killing gliomas with viruses or viral vectors are
hindered by the need for the tumor cells to undergo infection. Although
it may seem obvious, it is worth pointing out that virus infection
requires the target cell to express the viral receptor (specifically
illustrated in the paper by Gromeier et al. (1) by the requirement for expression of the polio virus
receptor CD155 for cells to be infected by the polio virus). Given
the genomic instability and heterogeneity of gene expression within
GBMs, it is likely that many cells within each tumor will be inherently
resistant to viral infection because of lack of expression of the
viral receptor. To this point, Gromeier et al. report that by
immunohistochemical staining, 19 of 25 tumors showed expression of
the polio virus receptor CD155, therefore 6 of 25 did not. The
fact that these CD155 nonexpressing gliomas exist implies that CD155
expression is not required for survival or for the neoplastic glioma
phenotype. Therefore, even within gliomas that predominately express
CD155, infection-resistant subclones of CD155 nonexpressing cells may
exist, giving rise to recurrence. This scenario is under the best of
circumstances, where each cell has unrestricted access to viruses. In
reality, however, cells diffusely spread throughout the brain and are
not in contact with each other and are therefore unlikely to have
access to viral particles.
Now that we have identified some of the theoretical difficulties of
successfully treating this disease with viruses and other approaches,
let us more clearly define success. Even though the current standard
of care (surgery, radiation, and chemotherapy) ultimately fails,
leading to the patient's death, refusing to treat GBM patients for
this reason is more nihilistic than most of these patients, their
families, and their physicians are comfortable with. It is clear that
surgically resecting greater than 95% of a GBM in many cases results
in an improvement of symptoms, even if only temporarily. Although
surgeons realize they are ultimately not going to cure the patient,
in many cases surgical resection is worth the effort because it
frequently increases survival and quality of life. Fig. 3 demonstrates the improvement in survival of GBM patients
fully treated to reduce tumor cell burden as compared with historical
data of patients receiving biopsy only (8). If the goal of viral therapy is to similarly reduce the
tumor cell burden significantly, such a strategy could be equally
useful and potentially additive to current palliative treatments.
It should be with guarded optimism that we view each successive attempt
at treating this devastating disease. It is equally important to
clearly establish the useful effects each approach is expected to
achieve, and to define success accordingly. Nonetheless, we should
not lose sight of the final goal, actual cure. Cure for GBM will
require testing treatments in better animal models that accurately
recapitulate the histology and genetics of the human disease. Also,
essential therapeutic targets for GBM are likely to be the pathways
that represent the etiology of the disease, abnormalities of which
lead to glioma formation. It is encouraging that experimental
transgenic mouse models of melanoma and lymphoma, generated by
inducible transgenes expressing Ras and Myc, respectively, are cured
by removal of these initiating agents (15-17).
These results are even more impressive given the genomic instability
of the cells in these experimental tumors. In theory, these tumor cells
could genetically evolve during tumor progression and no longer
require the initiating agents for tumor maintenance. In reality, the
tumors appear to evolve primarily so as to continue requiring
elevated Myc and Ras activity; removal of these causative agents
destroys them. These data imply that if the causative pathways for
GBMs can be identified and pharmacologically blocked, then there is
some hope of actual cure of this disease in humans. Then again, until
we start curing patients of their GBMs by one of these new
strategies, there remains the possibility that we are continuing to
underestimate the complexity of this disease. These approaches may
simply be added to the ever-growing list of attempts that work in
mice but not humans.
Acknowledgements
I thank Greg Fuller and Raymond Sawaya for their thoughtful input on this
manuscript and Dima Abi-Said for help with the M. D. Anderson
GBM patient data set.
Footnotes
See companion article on page 6803.
*E-mail: eholland@mdanderson.org.
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Companion article to this
Commentary:
Matthias Gromeier, Sylvie Lachmann, Myrna R. Rosenfeld, Philip H. Gutin, and Eckard Wimmer
Intergeneric poliovirus recombinants for the
treatment of malignant glioma
PNAS 2000 97: 6803-6808. [Abstract] [Full
Text]
Copyright
© 2000 by the National Academy of Sciences
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