Tagged: ATP

NIX-ing the PARKIN and PINK1 problem

In American slang, to ‘nix‘ something is to ‘put an end to it’.

Curiously, a protein called NIX may be about to help us put an end to Parkinson’s disease, at least in people with specific genetic mutations.

In today’s post we will look at what NIX is, outline a new discovery about it, and discuss what this new information will mean for people living with Parkinson’s disease.


Sydney harbour. Source: uk.Sydney

Before we start, I would like the reader to appreciate that I am putting trans-Tasman rivalry side here to acknowledge some really interesting research that is being conducted in Australia at the moment.

And this is really interesting.

I have previously spoken a lot about mitochondria and Parkinson’s on this website. For the uninitiated, mitochondria are the power house of each cell. They help to keep the lights on. Without them, the party is over and the cell dies.

Mitochondria

Mitochondria and their location in the cell. Source: NCBI

You may remember from high school biology class that mitochondria are tiny bean-shaped objects within the cell. They convert nutrients from food into Adenosine Triphosphate (or ATP). ATP is the fuel which cells run on. Given their critical role in energy supply, mitochondria are plentiful (some cells have thousands) and highly organised within the cell, being moved around to wherever they are needed.

Like you and I and all other things in life, however, mitochondria have a use-by date.

As mitochondria get old and worn out (or damaged) with time, the cell will recycle them via a process called mitophagy (a blending of the words mitochondria and autophagy – the waste disposal system of each cell).

What does this have to do with Parkinson’s disease?

Well, about 10% of Parkinson’s cases are associated with particular genetic variations that render people vulnerable to developing the condition. Some of these mutations are in sections of DNA (called genes) that provide the instructions for proteins that are involved in the process of mitophagy. Two genes, in particular, are the focus of a lot of Parkinson’s-related research – they are called PARKIN and PINK1.

What do PARKIN and PINK1 do?

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QUATS going on?!?

BE WARNED: THIS POST MIGHT UPSET SOME READERS

A recently published research report has caused a bit of a fuss in the media, and I have been contacted by a lot of concerned readers regarding this particular study.

It deals with some chemicals – which can be found in everyday products – that may be having a negative effect on biological processes that are related to Parkinson’s disease – specifically, the normal functioning of the mitochondria (the power stations of each cell).

In today’s post we will discuss the new research, what the chemicals do, and whether the Parkinson’s community should be concerned.


Source: Sacramentodentistry

Toothpaste.

It is something that most of us take completely for granted in the modern world. A product that sits in our bathroom, by the sink or on a shelf, and 2-3 times per day we stick some of it in our mouth and brush it around a bit. Given the well ingrained habit of repetitively ingesting of the stuff, we have little trouble with the idea of switching brands or trying new variations (“Oooh look, this one will make your teeth whiter. Let’s try it”).

I mean, come on – it’s just toothpaste. It’s safe, right?

It probably won’t surprise many of you to learn that the composition of toothpaste has changed quite a bit over the years, but what might amaze you is just how many years are involved with that statement: 

Egyptian toothbrush. Source: Nathanpaarth

The Egyptians recognised the importance of looking after one’s teeth at a very early stage. Apparently they had a lot of trouble with their teeth because their bread had grit in it which wore away their enamel. As far back as 5000BC, they had a form of toothpaste that they used to clean their teeth. It was a mix of powdered ashes of ox hooves, myrrh, powdered and burnt eggshells, and pumice (Source: Wikipedia). The Greeks, followed by the Romans, improved on the recipes (by adding abrasive ingredients such as crushed bones and oyster shells – delightful, huh?), but it wasn’t until after World War I that the modern day pre-mixed toothpastes became popular.

The cavity fighting chemical, Fluoride, was first added to toothpastes in the 1890s, and in 1908 Newell Sill Jenkins (an American dentist) invented the first toothpaste that contained disinfectants. It was called Kolynos (from the Greek words Kolyo nosos (κωλύω νόσος), meaning “disease prevention”). 

Source: Flickr

Following the advent of Kolynos, most toothpaste companies added antiseptic and disinfectant agents to improve the quality and effectiveness of their product. Being offered a tooth cleaning product with magical antibiotic properties seemed to reassure consumers that they were buying something that might actually work. And this led to more and more chemicals being added to toothpaste. Such additions included chemical like triclosan, cetylpyridinium chloride and benzalkonium chloride.

These chemicals are safe though…right?

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Mdivi-1: the small molecule that could?

Mitochondrial division inhibitor-1 (mdivi-1) is a small molecule drug that is demonstrating very impressive effects in preclinical models of Parkinson’s disease. With further research it could represent a potential future therapy for people with Parkinson’s disease, particularly those with genetic mutations affecting the mitochondria in their cells. 

What are mitochondria?

In this post, we will explain what mitochondria are, how they may be involved in Parkinson’s disease, and we will discuss what the results of new research mean for future therapeutic strategies.


 

Mitochondria are fascinating.

Utterly. Utterly. Fascinating.

On the most basic level, Mitochondria (mitochondrion, singular; from the Greek words mitos (thread) and chondros (granule)) are just tiny little bean-shaped structures within the cells in our body, and their primary function is to act as the power stations. They supply the bulk of energy that cells require to keep the lights on. This chemical form of energy produced by the mitochondria is called adenosine triphosphate (or ATP). Lots of mitochondria are required in each cell to help keep the cell alive (as is shown in the image below, which is showing just the mitochondria (red) and the nucleus (blue) of several cells).

Lots of mitochondria (red) inside cells (nucleus in blue). Source: Clonetech

That’s the basic stuff – the general definition you will find in most text books on biology.

But let me ask you this:

How on earth did mitochondria come to be inside each cell and playing such a fundamental role?

I don’t know. Are you going to tell me?

No.

Why not?

Because we simply don’t know.

But understand this: Mitochondria are intruders.

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