This post was first published in Jump! an online magazine for pre-teen girls.
Science is fun
 |
| What scientists do on holiday |
Science is not just for geeks and nerds. It’s not only for boys, or girls, who wear glasses. It’s for those of us with freckles and dimples and turned-up noses. Science is for animal lovers, tongue-rollers, bird-watchers, and teddy bear vets everywhere.
You see science is the world. And we are the world. So science is us, humans.
I love all science, but I especially love human science. The kind of science that looks under your skin, inside your cells, and zooms in, right down to your genes. This is what makes us human, and each one of us is unique and exciting.
I became a scientist because I was inspired to by a biology teacher at school. She asked me to help her clear out the cupboard in the lab. What we didn’t find in there. And lurking at the back, in a dark jar, was the most gorgeous pig foetus. We changed the preserving fluid, to reveal the tiny, perfect animal; when was he put in there, kept for me to find? I was hooked.
At university I studied human anatomy. I was able to study bodies donated to medical research, to look inside each and every part of the body, to learn where everything goes and how everything fits perfectly together. We prepared glass slides of the microanatomy too. We studied how the cells in the body connect to each other and to the rest of the body. It was fascinating study.
In my work since, I have used this knowledge of the human body every day. Every single experiment we carry out, is done in the knowledge that someday, somewhere, someone will one day benefit from the work we are doing to find out more about the genes which control all aspects of human life and variety.
Interested?
If you want to read a bit more, the next two sections are more advanced, but I’m sure you’ll be able to follow.
DNA unwound
DNA is fascinating. I have spent nearly twenty years getting inside this dynamic molecule, the basic component of human life, that controls hair colour and how long you will live and everything in between.
 |
| Laboratory analysis of DNA |
DNA is divided into functional regions, which we call genes. These genes contain naturally occurring variations, which makes us different from one another. Many of these variants are completely compatible with normal life; that is, the cell will grow and divide in the normal way. This is different from mutations such as those in cancerous cells, which cause aberrant cell proliferation and division.
In order for a region of DNA to respond to a signal from outside the cell, it must be in a relaxed or open state. A number of carrier or transport molecules including cytokines are responsible for presenting the stimulus to the open DNA molecule, in the correct functional position or gene. Once this has happened, the region of DNA closes, a bit like pushing a spring between your hands. In this closed the position, the function of the gene is turned off and no other molecules can interact with the DNA. Imagine a very fine orchestra with a very busy conductor making sure that nothing goes out of tune. All these processes happen without our conscious intervention, and that is what makes DNA fascinating.
 |
| Human macrophages, from white blood cells |
Cellular communication
No, nothing to do with a cell phone, because before mobiles or cell phones there was a time when this only meant cell to cell interaction within an organ or tissue. This important cellular behaviour drives diverse functions from contracting myocytes in heart muscle to effecting action potentials in nerves.
We can visualise these fascinating events in the laboratory ex vivo (in cells outside of a living body). For example, immortalised cardiac myocytes (heart muscle cells kept alive) can be cultured in a monolayer in a petri dish. A stimulant introduced into a single cell causes that cell to contract. This stimulates the adjacent cell to contract, and so on, mimicking the heartbeat. This can be seen microscopically and contributes to our better understanding of the function of this important tissue.
 |
| Cross section through mitochondrion, a part of the cell which makes energy |
Similarly, action potentials in nervous tissue can be measured and studied by subjecting ultra-thin sections of tissue to chemical modulators in solution. Sensitive electrophysiology equipment detects the release of neurotransmitters from neurons in the tissue slice and complex algorithms translate this effect into an audible thump. It's really amazing to hear this happening in the lab, these are very elegant experiments indeed.
A different kind of communication is seen in the immune system, where antigen-presenting cells identify foreign bodies, such as bacteria, and 'show' them to the T lymphocyte cells which effect an immune response. Where this system is compromised or overwhelmed, an infection can set in, for example pneumonia, which requires a trip to the doctor for antibiotics.
And who said biology was just a pretty face?