Monster Maker

show/hide words to know

Fertilize: when a sperm and an egg join.

Mutation: a change in the lineup of DNA instructions. Sometimes, if the DNA changes, then the instructions for what to build will change, or mutate.

How to Build a Monster

By Karla Moeller
Illustrated by Sabine Deviche

blueprint

Blueprint for a monster body.

If you wanted to build a monster, a plant, or an animal, where would you start?  Where do architects start when they are building a house?  The best place to start if you are building a house, or any living thing, is with instructions.  For a house, this usually comes in the form of a large blueprint that maps out all the rooms, their location, and how much space they each have.  For plants, animals, and even monsters, there are teeny, tiny instructions that we call our genetic code that act as our blueprint.

These instructions are held in each cell of every living organism. Cells are the compartments that make up all of the tissues in our body like skin and bones, and most are so small they cannot be seen without a magnifying glass or microscope. If you unravel the DNA in each of these cells, the genetic code can be stretched out to over 6 feet long! Within this strand is all the information required to build and keep an organism alive. These instructions are made of various combinations of only 4 different molecules.

Combinations of Molecules

Molecules are tiny compounds of smaller atoms, which are the smallest units of matter that still act as an element, such as oxygen or carbon.  DNA strands are made of long connections of different combinations of 4 molecules, which we can think of as letters or colors. For example, let’s take 2 colors: yellow and red. We will use the letters Y and R to stand for these colors. If you are allowed to make a string of 3 colors, let’s see how many different combinations you can make.

1 combination

Let’s start with just one color: yellow. What combinations can we make? Only one, right?

The whole thing would have to be yellow, since that’s the only color we have.

What if we add a second color? Let’s add red. Now how many combinations can we make?

8 red and yellow dot combinations

Two colors can make eight different combinations.

So all together, using yellow and red, we already have 8 different combinations we could make. 

If we had 3 colors, we could make 27 combinations.

27 combinations with red, yellow, blue

Three colors can make 27 different combinations.

If we had 4 colors, we could make 64 combinations. Each of these combinations gives a unique instruction to the cell.

64 combinations from red, green, yellow, blue

Four colors can make 64 different combinations.

This table shows how many different orders of combinations you can make with different string lengths and different numbers of colors:

combinations chart

A chart showing how many combinations you can make with up to 4 colors and 4 beads.



What’s really amazing is how complex these instructions can be, using only 4 different colors. If we put some of these 3-color combinations together, as if we were putting different letters together to make words, we could make even more combinations.

Let’s think again about our 4 colors that can stand for different DNA molecules… red, yellow, blue, and green. These colors could join together like colored beads in a long necklace (or strand), hundreds or thousands of beads long.

DNA Instructions

DNA instructions.

One more thing to think about when you are imagining these necklaces is that DNA actually has two strands of colors, or molecules, that are connected, with certain colors almost always sticking together. For example, red would go with yellow, and blue would go with green.

Once we have these long, double strands, we have long sections in them that we call “genes.”  A gene is a section of DNA that decides what traits we will have, such as if our eyes will be blue, or what color our hair is. Monster DNA might decide if they have polka-dots on their body, or if they have one or two eyes or horns.

monster game button

Click on the monster maker button to build a monster.

The Monster Game

Now let’s try to understand this idea further by playing a game with monster DNA.  In the game, you will see lines of 3 colors of dots, which you will match to sets in the decoding section. For example, the set of 3 colors red-green-blue stands for the capital letter “C”.  Once you’ve decoded all the color sets, you can see the words, or genes, that decide what your assigned monster picture will look like.

scientist

 

Scientists Use DNA to Try to Fight Disease

Using computers that can search through the long, long instruction set, or code, that make up human DNA, scientists try to find patterns in the instructions. Most of the time, scientists expect humans to have the same code as each other.

However, even for important traits like the structure of your cells, sometimes a single DNA molecule will be different than it should be, or there can be missing or extra molecules. These are called DNA mutations, which means the DNA is changed. By finding these mistakes in the pattern, scientists may learn what part of the code may be causing problems, such as different diseases, or which instructions may help a person to avoid disease.

Where Your DNA Started

Now that you understand how the same 4 molecules can code for so many different combinations of instructions, where do you think the instructions come from? The two parents of a child or a monster each make special types of cells. Females make what are called eggs, and males make what we call sperm. These two special types of cells, eggs and sperm, each have half of the instructions required for building a body, made of bits of each parents’ own instructions. A female’s eggs have some of her own DNA, and a male’s sperm has some of his DNA.

Sperm + Egg

Sperm + Egg = Fertilized cell with full set of DNA

When the egg joins with sperm, the egg is activated, or fertilized. This joins together the instructions of both the egg and the sperm, to make the new set of DNA for a child. This is why sometimes children have features that look a bit like their mom’s and sometimes they have features that look a bit like their dad’s.

Cells multiplying

As your first cells grew and split into more and more cells to form your body, the instructions from this activated egg were passed along to each new cell. The instructions would be copied within a cell, and then as that one cell breaks into two different cells, each cell only takes one copy of the instructions.

These instructions are so long, that each cell only ends up using part of them, and this allows us to grow different types of tissue, such as skin, bone, and blood. Just imagine, all the instructions needed to make an entire human or monster are all curled up and packed into a tiny fertilized egg.


Author Karla Moeller earned her PhD in Biology at Arizona State University. She is an animal physiologist, a science writer, and a children's book author.

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Bibliographic details:

  • Article: How to Build a Monster
  • Author(s): Karla Moeller
  • Publisher: Arizona State University School of Life Sciences Ask A Biologist
  • Site name: ASU - Ask A Biologist
  • Date published: September 12, 2011
  • Date accessed: November 12, 2024
  • Link: https://askabiologist.asu.edu/build-monster

APA Style

Karla Moeller. (2011, September 12). How to Build a Monster. ASU - Ask A Biologist. Retrieved November 12, 2024 from https://askabiologist.asu.edu/build-monster

American Psychological Association. For more info, see http://owl.english.purdue.edu/owl/resource/560/10/

Chicago Manual of Style

Karla Moeller. "How to Build a Monster". ASU - Ask A Biologist. 12 September, 2011. https://askabiologist.asu.edu/build-monster

MLA 2017 Style

Karla Moeller. "How to Build a Monster". ASU - Ask A Biologist. 12 Sep 2011. ASU - Ask A Biologist, Web. 12 Nov 2024. https://askabiologist.asu.edu/build-monster

Modern Language Association, 7th Ed. For more info, see http://owl.english.purdue.edu/owl/resource/747/08/
Scientists are working with our own genetic code to help treat and cure diseases.

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