Introduction – the scale of the problem
Dementia is the persistent loss of previously acquired
intellectual functions without impairment of consciousness (World Health Organisation) . Although the
prevalence of dementia increases with age, it is a disease, and not part of the
normal ageing process. 800,000 people are currently diagnosed with dementia in
the UK – this equates to a prevalence of roughly 1% for people aged 60-64
years, roughly doubling with every extra 5 years of age, reaching a prevalence
of 40% in people aged 85-89 years (Alzheimer's Association) . By 2021, it
is predicted that over a million people in the UK will have dementia; in 2012,
the estimated financial cost was already £23 billion.
The disturbing statistics and predicted trends with our
ageing population has prompted the Health Secretary and Prime Minister to
recently reiterate their commitment to finding a cure for dementia by 2025 (BBC) . They believe
this can be achieved through increased funding for research and offering the
pharmaceutical industry extra incentives, such as prolonged patents for new
drugs.
There are many causes of dementia, with Alzheimer’s disease (AD)
being the most common – it is thought to represent 60-70% of cases. At older
ages it often becomes more complicated as a combination of pathologies is
present in around 50% of cases, typically AD mixed with vascular dementia, or AD
mixed with Lewy-body dementia. What is irrefutable, however, is that a cure for
AD remains the biggest and most important challenge in our goal to cure
dementia. Fortunately, much progress is
being made. Two recent articles in Lancet Neurology Yan et al (Yan, 2014) and
Dubois et al (Dubois,
2014)
make this clear, and form the basis for this article.
The pathogenesis of Alzheimer’s disease
Potential therapeutic strategies arose from our increasing
understanding of AD pathology. It has long been recognised that the brains of
patients with AD are not only atrophic, but contain the specific microscopic
features of amyloid plaques and neurofibrillary tangles:
- Amyloid plaques – extracellular aggregates of an abnormally fold protein, Aβ amyloid. This is surrounded by dystrophic neuritis and activated glial cells
- Neurofibrillary tangles – intracellular aggregates of the abnormally phosphorylated protein tau, surrounding the nucleus of neurones. Such aggregates persist after the death of such neurones
A number of years of vigorous scientific debate centred
around which of these two features, the Aβ amyloid or
the abnormal tau, was the initial causal abnormality in AD. Although it
appeared that the amount of tau correlated more strongly with the severity of
the disease (Braak, 1991) , the
discovery of genetically inherited forms of AD, where affected family members
almost always developed the disease at a young age, provided strong evidence in
support of Aβ (Rogaev, 1995) (Levy-Lahad, 1995) . An
understanding of how Aβ is formed is required
before introducing these cases.
Amyloid Precursor Protein and the formation of Aβ
Amyloid precursor protein (APP) is a transmembrane protein
that is subjected to proteolysis by multiple potential enzymes. Three of these
are key to the understanding of AD pathology:
- β-secretase (aka β-site amyloid precursor protein cleaving enzyme 1, BACE) – cuts APP so to release the distal fragment, known as soluble APP β (sAPPβ)
- γ-secretase – acts after BACE, cutting APP centrally within its transmembrane region, releasing the Aβ. Depending exactly where it cuts, it either forms Aβ with a length of 40 or 42 amino acids (Aβ1-40 or Aβ1-42); Aβ1-42 is known to be more toxic.
- α-secretase – cuts APP slightly more centrally than BACE does, within the Aβ segment, therefore preventing the formation of Aβ protein. The fragment this releases in known as soluble APP α (sAPPα)
Familial cases of Alzheimer’s disease
More than 200 autosomal dominant mutations are now known to
cause AD (Yan, 2014) , all of which
lead to either an increase in the total production of Aβ,
or an increase in the proportion of the more toxic Aβ1-42 form.
- Mutations in APP result in increased hydrolysis by BACE
- Mutation in presenilin, the catalytic subunit of γ-secretase, increase the formation of Aβ1-42
- Mutations in ADAM10, the main α-secretase in neurones, decreases its activity, hence more Aβ is instead produced via BACE
- Duplications of APP, either in isolation, or as part of trisomy 21, result in early onset AD (patient’s with Down’s syndrome typically develop the disease around 40 years of age)
Furthermore, mutations in APP that reduce the ability of BACE to cleave it are protective again AD, and mutations in
tau proteins have been shown to be associated with other forms of dementia,
such as fronto-temporal dementia, but do not seem to increase the risk of AD (Hutton, 1998) .
Conclusions – known causes and potential targets
As a result of this genetic evidence, there is a strong case
for the primary cause of AD to be the formation of Aβ,
particularly Aβ1-42, with the associated tau pathology being a
downstream consequence of this. Together, this is known as the amyloid cascade
hypothesis (Higgins, 1992) . Furthermore,
the existence of protective mutations that act via a reduction in BACE activity
makes it a strong candidate drug target. Other strategies based upon the
amyloid cascade hypothesis involve using immunotherapies to target Aβ1-42.
Phase 3 trials of both solanezumab (Doody, 2014) and bapineuzumab (Salloway, 2014) in patients
with mild-moderate AD have, however, failed to show differences in cognitive
outcomes. As will be discussed later, this may be due to the timing of
treatment, rather than lack of potency.
Mouse models
Transgenic mice designed to over-express APP develop amyloid
plaques and memory impairment, apparently mimicking AD in humans (Saito, 2014). In order to
model the potential for drugs that inhibit BACE,
further transgenic mice with over-expression of APP but no BACE genes were
produced. Such knock-out mice do not develop amyloid plaques or memory
impairment. They do, however, experience side effects – reduction in the
myelination of neurones, axonal guidance defects and neurogenesis problems, to
name as few. The exciting prospects such models suggests for treatments in humans must therefore be interpreted with caution – drugs
inhibiting BACE may reduce the amount of Aβ produced and so potentially help in
AD, but they may also cause problems. We known that BACE enzymes do not only
act upon APP, but also on many other proteins found on the surface of neurones (Yan, 2014) . If you
prevent BACE from producing Aβ, you also therefore prevent it from producing a
number of other protein. Many of these are thought to be involved in the
communication within a neuron and between nearby neurones, and hence the side
effects that have been seen in mice.
The development of BACE inhibitors
Following the results of the BACE
knock-out mice, a number of inhibitors went into development, hoping to produce
a drug that could be taken orally and result in the same prevention of Aβ
amyloid production. Initial difficulties with oral bioavailability and
blood-brain barrier penetration were eventually overcome, leading to a number
of such inhibitors entering clinical trials in humans. The main outcome
measures were safety and tolerability of the BACE inhibitors, as well as
efficacy as measured via CSF Aβ concentrations.
Drug
|
MK-8931
|
LY2886721
|
E2609
|
Trial
|
Phase 1b RCT vs placebo, n=32,
mild-mod AD patients, 7 days treatment
|
Phase 1 RCT vs placebo, n=47,
healthy volunteers, 14 days
|
2x phase 1 RCT vs placebo, n= 73
and n=53
|
Maximum CSF Aβ reduction
|
84%
|
74%
|
85%
|
Major side effects
|
Nil
|
Nil
|
Nil
|
What level of BACE inhibition is required to treat Alzheimer’s disease?
The results of the initial phase 1 trials of BACE inhibitors are very promising, but a number of
questions remain unanswered. The absence of major side effects in such short
trials is not unexpected; the concerns regarding side effects that arose from
the mouse knock-outs, such as problems with myelination, neurogenesis and axon
guidance, would be unlikely to manifest in humans over such short periods. One
potential strategy to avoid such effects would be to use lower levels of
inhibition. Homozygous knock-outs clearly represent 100% inhibition of BACE
activity – an unachievable and potentially undesirable figure with oral
inhibitors. Support for targeting lower levels of inhibition comes from two
sources:
- The protective mutation in APP that reduces the ability of BACE to cleave it. Heterozygous humans have around a 20% overall reduction in cerebral Aβ production; this is enough to protect them against AD, but they also do not seem to suffer from any of the other potential problems
- Heterozygous BACE knock-outs in AD mouse models have a 50% reduction in BACE activity, resulting in around a 20% reduction in Aβ production. They do not develop amyloid pathology or memory deficits, and neither do they develop the side effects that homozygous knock out mice do.
It would therefore seem that if drugs could achieve 50%
inhibition of BACE activity, the overall Aβ
production might drop by around 20%; this would hopefully be enough to prevent
AD pathology from forming without the patients developing any other side
effects from the reduced BACE activity.
When should we be using BACE inhibitors to treat Alzhiemer’s
disease?
In both the heterozygous human and mouse examples above, the
reduction in BACE activity is clearly present from
the moment of conception. There is a life-long reduction in Aβ production, and
this leads to the protective effect. A difficult question therefore remains –
when using BACE inhibitors to treat AD, at what stage would they need to be
started? It is well known from studies of familial AD that the
neuropathological changes begin long before the disease becomes symptomatic,
and it is unlikely that inhibiting BACE would reverse the neuropathological
changes once the amyloid plaques and neurofibrillary tangles have already
formed. It therefore seems likely that in order to be effective, such drugs
would need to be given long before symptoms develop; rather than treating AD,
they should be seen as more of a preventative strategy.
At the heart of the question on
when to use BACE inhibitors is the problem of our understanding of the exact
role of Aβ in AD pathophysiology. It is thought the Aβ oligomers are more
likely to mediate neuropathology than the larger aggregates (Shankar, 2008) , but it is
still the tau neurofibrillary tangles that correlate with neurodegeneration,
not the amyloid plaques. We also know from familial fronto-temporal dementia
that isolated tau pathology is sufficient to cause neurodegeneration and
dementia. The amyloid cascade hypothesis therefore has room for various
situations (Karran, 2011) :
- Aβ amyloid trigger – the production of Aβ triggers the formation of tau pathology, which is then self perpetuating
- Aβ amyloid threshold – Aβ results in self-perpetuating production of tau once a sufficient threshold level of Aβ is produced
- Aβ amyloid driver – the continuous production of Aβ is necessary in order to perpetuate tau pathology and neurodegeneration
The amyloid trigger and amyloid
threshold hypotheses would require earlier use of BACE inhibitors, preventing
the triggering or threshold levels of Aβ from arising. The amyloid driver
hypothesis would be more hopeful, suggesting that even in people with existing
AD pathology, reductions in Aβ production would lead to a plateau in
neurodegeneration.
The above questions are only going
to be answered a combination of more basic research furthering our knowledge of
the interaction between Aβ, tau and neurodegeneration, and clinical trial
results using agents that reduce Aβ production, such as BACE inhibitors. We can
already be fairly sure, however, that when it comes to reducing Aβ production,
earlier is certainly going to be better.
Current phase 3 trials using the
agents mention above are recruiting patients with mild-moderate AD or mild
cognitive impairment (10-15% of which convert to full AD every year). Their primary
outcome measures will involve cognitive assessments, but also CSF biomarkers
and PET amyloid imaging; the data produced will, therefore, undoubtedly greatly
advance our understanding of the potential for BACE inhibitors and how best to
use them. It would seem reasonable to predict, however, that they will not
“cure” many of the patients – cognitive stabilisation is probably the best that
can be hoped for (via the amyloid driver hypothesis). A potential cure would
require earlier treatment – it is thought that this may have contributed to the
failure of the phase 3 trials using immunotherapies in mild-moderate AD
patients (Doody, 2014) (Salloway, 2014) .
Pre-symptomatic diagnosis allowing disease prevention
The analogy of our advances in prevention of heart disease
is put forward by Yan et al (Yan, 2014) . When someone
has a heart attack, they will be put on statins (amongst other drugs). These
will significantly reduce their cholesterol, hence reducing their risk of
having further heart attacks. This might prevent their heart from getting too
much worse (or at least slow the rate of decline), but they are not going to
reverse the damage that has already happened. The good thing about heart
attacks, however, is that you can, with reasonable accuracy, predict the chance
that someone is going to have a heart attack. Various tools, such as the widely
used Q-risk, can be used to predict an individual’s risk based upon factors
such as their age, sex, ethnicity, smoking status, diabetic status, cholesterol
levels, blood pressure and body mass index. When their risk is sufficiently
high, drugs such as statins can be started years in advance of any heart attack
they might have, greatly reducing their risk of it ever happening.
Once AD becomes symptomatic, the best that we can
realistically hope for is that BACE inhibitors will
be able to slow the rate of decline, but not reverse the damage. What is
therefore needed is the equivalent of a Q-risk for AD, allowing us to predict
who is going to be affected years in advance of their first symptoms arising. This
will allow prevention of disease by avoiding the amyloid trigger or amyloid
threshold. Progress towards this is being made, as outlined by the publication
of the International Working Groups second diagnostic criteria of AD (Dubois, 2014) .
Biomarkers in the diagnosis of AD
The diagnosis of AD has previously relied upon clinical
features. The original 1984 criteria relied upon clinical features, only
allowing the diagnosis to be “probable AD” upon confirmation with post-mortum
histology (McKhann, 1984) . Since then,
however, our knowledge of biomarkers has greatly improved, allowing them to be
incorporated into diagnostic criteria.
CSF biomarkers
CSF levels of Aβ1-42
inversely correlate with cerebral amyloid burden – the more amyloid plaques
that are present, the lower the CSF Aβ1-42
levels. When correlated with post-mortum histology, a low CSF Aβ1-42
had a 96.4% sensitivity for the diagnosis of AD. Low levels are also
seen in some other dementia, however, such as Lewy-body dementia and vascular
dementia, limiting the specificity. This, however, can be improved by instead using
the Aβ1-42 : Aβ1-40 ratio – a low ratio is more specific to
AD.
CSF tau levels have also been shown to be predictive, with
higher levels being able to distinguish AD from other non-AD dementias. Both
P-tau and T-tau can be used: T-tau is thought to be a direct reflection of
neuronal degeneration, where as P-tau reflects the total tau burden.
Overall, a combination of tau and Aβ
appears to be the best strategy for interpretation of CSF biomarkers; the T-tau
to Aβ1-42 ratio had a 96%
specificity for distinguishing between FTD and AD, and the ADNI, DESCRIPA and
SBP projects have all confirmed the utility of the combined biomarkers. Perhaps
most interestingly of all, the DIAN project, using a cohort of patients with
autosomal dominant AD associated mutations, has demonstrated that significant
predictive changes in such CSF biomarkers are present 10-20 years prior to the
onset of the first symptoms (Bateman, 2012) . This opens
the door for effective, early preventative treatment with β-secretase
inhibitors.
Imaging biomarkers
PET imaging with various ligands has demonstrated the
ability to accurately quantify the cerebral load of Aβ
amyloid. This correlated well with post-mortum studies (Clark, 2011) .
Clark. (2011). Use of florbetapir-PET for imaging beta-amyloid pathology - correlation of amyloid PET imaging with post-mortem histology confirming the strong predictive value of PET |
When the CSF biomarkers are compared
with PET amyloid imaging, a strong association is also seen – a reduction in
soluble Aβ and tau in the CSF correlates with
those who have higher cerebral amyloid burdens (Roe, 2013) (Fagan, 2011) . This is a
very positive finding in terms of validating the biomarkers – it would seem to
support the notion that a reduction in CSF amyloid occurs because more of it is
being deposited in the brain parenchyme; as this happens, with the initiation
of neurodegeneration, levels of tau begin to rise.
A target for clinical trials – “asymptomatic at risk for Alzheimer’s
disease”
In light of the above evidence for the value of biomarkers
in diagnosis of AD long before symptoms arise, the IWG-2 criteria now include
the following definition (Dubois, 2014) :
Asymptomatic at risk AD (A plus B)
a.
Absence of specific clinical phenotype
i. Absence
of amnestic syndrome of the hippocampal type
ii. Absence
of clinical phenotype of atypical AD
b.
In-vivo evidence of Alzheimer’s pathology (one
of the following)
i. Decreased
Aβ1-42 together with increase T-tau or
P-tau in CSF
ii. Increased retention of fibrillar amyloid PET
The acceptance of this category is a landmark event in AD
research, representing the extent to which the field of biomarkers has advanced
in recent years. It clearly states that either a combination of CSF Aβ and tau or PET imaging is sufficient to determine whether
an asymptomatic patient should be placed in the asymptomatic at risk category.
Conclusions
The papers by Yan et al and Dubios et al summaries two areas
where significant developments have recently been made in the field of AD. The
true significance of these advances, however, is only revealed when they are
taken together – the development of new drugs that could potential prevent AD
from developing if started early enough, and the development of new biomarkers
that allow presymptomatic diagnosis.
Any clinical trials to test such combined potential would
still, however, be demanding to complete. With the potential to diagnose
patients 10-15 years before symptoms develop comes the commitment to continue
clinical trials for 10-15 years after randomised treatments are started in such
individuals. Perhaps this is where the
promises of the Health secretary and the Prime Minister may come in – increases
in funding and government-pharmaceutical partnerships may be required in order
to facilitate such studies.
Examples of such partnerships already exist in the trials of
immunotherapies in AD. The Anti-Amyloid Treatment in Asymptomatic Alzheimer’s
study (A4, NCT02008357) is recruiting asymptomatic individuals who
are at risk of developing AD as determined by a PET amyloid scan. Funding is
being provided by a partnership between the National Institute on Ageing and
Eli Lilly. Those meeting the criteria will the randomised to receive solanezumab,
an anti- Aβ1-42 antibody, or placebo.
Other similar immunotherapy studies recruiting asymptomatic patients are also
on-going (Dominantly Inherited Alzheimer
Network Trial (DIAN-TU; ClinicalTrials.gov number, NCT01760005), Alzheimer's
Prevention Initiative (API; NCT01998841)). One hopes that such trials can
produce better outcomes than the results in early AD patients. If this occurs,
and similar trials can be initiated for BACE inhibitors, perhaps by 2025, as
targeted by the Prime Minister, we will not only have one cure for Alzheimer’s
disease, but two.
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