I was recently made aware of an interesting fact:
Approximately 5% of people with Human immunodeficiency virus (HIV) infections develop Parkinson’s disease-like features.
Why is this?
In today’s post we will try to understand what is going on, and what it may mean for Parkinson’s disease.
HIV (in green) budding (being released) from a blood cell (lymphocyte). Source: Wikipedia
Ok, let’s start at the beginning:
What is HIV?
Human immunodeficiency virus (or HIV) – as the name suggests – is the virus.
It causes the infection which gives rise to Acquired Immune Deficiency Syndrome (or AIDS). AIDS is a progressive failure of the immune system – the body loses its ability to fight infections. Without treatment, average survival period after infection with HIV is between 9 – 12 years.
HIV can be spread by the transfer of bodily fluids, such as blood and semen. The World Health Organisation (WHO) has estimated that approximately 36.9 million people worldwide were living with HIV/AIDS at the end of 2014 (that is equivalent to the entire population of Canada!).
The structure of the HIV virus. Source: Wikipedia
Does HIV affect the brain?
At postmortem examinations, less than 10% of the brains from HIV infected individuals are histologically normal (Source).
HIV is a member of the lentivirus family of viruses, which readily infect immune cells (such as blood cells). HIV can also infect other types of cells though, including those in the brain. HIV will usually enter the central nervous system within the first month following infection. It enters the brain via infected blood cells which come into contact with brain ‘immune system/helper’ cells such as microglia and macrophages at the blood-brain-barrier.
How HIV enters the brain. Source: Disease Models and Mechanisms
HIV can also infect astrocytes (albeit at a lower frequency than microglia and macrophages), by direct cell-cell contact with infected T cells (blood cells) at the blood-brain-barrier (No. 1 in the image above). After infecting astrocytes, there is dysfunction in the astrocyte and it will no longer be so supportive to the local neurons (No. 2 in the image above). Once inside the brain, HIV-infected macrophages will allow for infection of other macrophages and microglia (No. 3 in the image above), and all together these HIV-infected astrocytes and microglia will cause damage to neurons by releasing viral proteins (two in particular, called Tat and gp120) and additional nasty chemicals which are bad for the neurons (No. 4 in the image above). Finally, as the disease progresses, the protective layer of the blood-brain-barrier becomes compromised and HIV-infected T cells eventually enter the brain and they cause damage to neurons by releasing pro-inflammatory chemicals (making the environment harsh for neurons).
There is remarkably little evidence of HIV actually infecting neurons (Click here for a review on this), so any cell loss in the brain that is associated with HIV does not result from neurons themselves being infected. This may be due to the fact that neurons do not have the HIV receptors (such as CD4) on their cell membrane. Similarly, oligodendrocytes (a supporting cell) does not appear to be easily infected by HIV. The bulk of the infected cells in the brain appear to be of the microglial, macrophage and astrocytes. And without these supporting cells doing their jobs in a normal fashion, it is easy to see how neurons can start dying off.
The severity, characteristics and distribution of HIV-induced injury in the brain varies greatly between affected individuals. It is most likely associated with the viral load (or the number of viral particles) in the brain, which can vary from a few thousand to more than a million copies per mL.
Do HIV-infected people show any signs of the virus entering the brain?
For the majority of people infected with HIV, this entry of the virus into the nervous system is neurologically asymptomatic (meaning they will not notice it), except for the occasional mild headache (for more on this read this review). As a result of the HIV virus entering the brain, however, many infected individuals will suffer from a specific set of neurological disorders, collectively called the AIDS dementia complex (ADC) (also known as HIV-associated cognitive/motor complex, or simply HIV dementia).
So how does HIV infection result in Parkinson’s disease-like features?
As we have suggested in the introduction to this post, on rare occasions (approximately 5% of cases), HIV-infected patients may present an illness virtually identical to Parkinson’s disease. More commonly, people with HIV will exhibit an increased sensitivity to dopamine receptor-blocking agents, such as drugs with a low potential for inducing Parkinsonism, (for example prochlorperazine and metoclopropamide).
The exact mechanism by which HIV infection results in Parkinson’s disease-like features is the subject of debate, but what is clear is that the basal ganglia (a structure involved in Parkinson’s disease) faces the brunt of the HIV infection in the brain. HIV-infected microglia and macrophage are most prominent in the basal ganglia when compared to other brain regions (Click here and here for more on this), and the basal ganglia is where the chemical dopamine from the midbrain is being released.
In addition, there are other changes in the brains of HIV infected people which may aid in the appearance of Parkinsonian features:
Title: Increased frequency of alpha-synuclein in the substantia nigra in human immunodeficiency virusinfection.
Authors: Khanlou N, Moore DJ, Chana G, Cherner M, Lazzaretto D, Dawes S, Grant I, Masliah E, Everall IP; HNRC Group.
Journal: J Neurovirol. 2009 Apr;15(2):131-8.
PMID: 19115126 (This article is OPEN ACCESS if you would like to read it)
The researchers in this study used staining techniques to look at the amount of alpha synuclein – the Parkinson’s associated protein – in slices of brain tissue taken from postmortem autopsies of 73 HIV+ individuals aged between 50 and 76 years of age.
The presence of alpha synuclein in the substantia nigra (an area of the brain affected by Parkinson’s disease) was a lot higher in the HIV+ brains when compared with healthy control samples (16% of the HIV+ brains had high levels of alpha synclein vs 0% for the healthy brains).
Interestingly, nearly all of the brains analysed (35 out of 36 HIV+ brains) had high levels of the Alzheimer’s disease associated protein, beta amyloid (which again raises the question of whether beta amyloid could be playing a defensive role in infections – see our previous post on this). Also interesting, was that there was no correlation between these proteins being present and the age of the person at death – that is to say, older brains did not have more of these proteins when compared with younger brains.
There are also additional ways in which HIV could be causing Parkinson’s-like features, such as:
- HIV has been shown to affect the protein levels of Parkinson’s disease associated proteins, such as DJ1 and Lrrk2 (Click here and here to read more on this).
- HIV can, in some cases, increase the level of Dopamine transporter, which would reduce the levels of free floating dopamine in the brain (Click here to read more about this).
How is HIV treated?
Treating HIV. Source: NPR
There is currently no cure for HIV infection.
There are, however, treatments which help to slow the virus down. These are called Anti-retroviral drugs (HIV is a retrovirus). There are different kinds of anti-retroviral drugs, which act at different stages of the HIV life cycle. Combinations of several anti-retroviral drugs (generally three or four) is known as ‘Highly Active Anti-Retroviral Therapy'(or HAART).
Mechanism by which four classes of anti-retroviral drugs work against HIV. Source: Wikipedia
As the schematic image above highlights, there are many ways to slow down the HIV virus. For example, you can prevent it from attaching to a cell and fusing with the cell membrane (fusion inhibitors). By treating HIV infected people with multiple medications attacking different parts of the HIV life cycle, the virus has been slowed down.
Does HAART treatments for HIV help with these Parkinson’s-like features?
In some cases, the answer appears to be yes.
There are numerous case studies in the literature which demonstrate the alleviation of HIV-associated Parkinsonian symptoms with HAART, such as this report:
Title: Parkinsonism as the presenting manifestation of HIV infection: improvement on HAART.
Authors: Hersh BP, Rajendran PR, Battinelli D.
Journal: Neurology. 2001 Jan 23;56(2):278-9.
In this study the researchers described the case of a 37 year old man who developed Parkinson’s like features in the setting of an HIV infection, which were resolved after 1 year of HAART.
Over a period of 4 months, the man developed co-ordination issue, clumsiness and an irregular tremor in his right hand (there was, however, no resting tremor). He noted a generalised slowness and exhibited a tendency towards decreased right arm swinging. He also developed dystonia in the right hand/arm. Following L-dopa treatment (25/100; one tablet 3x per day) there was improvement in balance & co-ordination, speech, facial expression, and the tremor (L-dopa does appear to improve most cases of HIV-associated Parkinson’s-like features).
Six months after first displaying these Parkinsonian features (and two month after initiating L-dopa treatment), the subject was placed on HAART treatment. Four months later, he discontinued L-dopa treatment and 12 months after starting the HAART regime his Parkinsonian features were largely resolved.
What does this mean for Parkinson’s disease?
This post was written for the research community rather than people with Parkinson’s disease. I thought the fact that some people with HIV can start to have Parkinson’s like features was an interesting curiosity and wanted to share/spread the information.
Having said that, this post raises some really interesting questions, such as if a virus like HIV can have this effect on the brain, could other viruses be having similar effects? Could some cases of Parkinson’s disease simply be the result of a viral infection? Either multiple hits from a particular virus or different viruses each taking a varying toll over the course of a life time.
This idea would explain many of the curious features of Parkinson’s disease, such as:
- the asymmetry of the symptoms (people with Parkinson’s usually have the disease starting on one side of the body.
- the fact that some cells in the brain are more vulnerable to the disease than others (perhaps they are more receptive to a particular virus).
- the protein clusterings in the cells (Lewy bodies may be defensive efforts against viral infections).
As we have previous mentioned, theories of viral causes for Parkinson’s have been circulating ever since the 1918 flu pandemic (Click here to read our previous post on this topic). About the same time as the influenza virus was causing havoc around the world, another condition began to appear called ‘encephalitis lethargica‘. This disease left many of the victims in a statue-like condition, both motionless and speechless – similar to Parkinson’s disease. Initially, it was assumed that the influenza virus was the causal factor, but more recent research has left us not so sure anymore.
The point is, however, perhaps it is time for us to re-examine the possibility of a viral agent being involved in the development of Parkinson’s disease.
There is new technology that allows us to determine the viral history of each individual from a simple blood test (Click here for more on this), so it would be interesting to compare blood samples from people with Parkinson’s disease with healthy controls to determine any differences.
In addition to the overall question of a viral role in Parkinson’s disease, there also remains the question of why only a small fraction of people with HIV are affected by Parkinsonisms. It could be interesting to genetically screen those people with HIV that exhibit Parkinsonisms and compare them with people with HIV that do not. Do those affected individuals have recognised Parkinson’s related genetic mutations? Or do they have novel genetic variations that could tell us more about Parkinson’s disease?
Food for thought. Would be happy to hear others thoughts.
The banner for today’s post was sourced from AidsServices