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Eukaryotic Cells: Inception of Complex Life

Comparing eukaryotic cells with prokaryotic cells

The Origins of Eukaryotic Cells

Life has obviously come a long way from its origins in the ancient seas of Earth. Life had to overcome many obstacles in order to thrive. The first milestone was obviously formation of the original replicating molecules. The next important step to generate diversity was the ability to access large amounts of energy. This mechanism will be covered in a later post.

Along with this step, the cells themselves had to evolve in a way that helps them survive in very specific environments. This means they needed to generate new tools (proteins) which would grant them the unique abilities needed for survival. These complex cells are known by their general name: eukaryotic cells.

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The Concentration Gradient: Transport of Molecules

examples of the concentration gradient

What is the Concentration Gradient?

We have discussed equilibrium in organisms through the topic of homeostasis. However, as per usual, the evolution of complex life derives its properties from fundamental laws of the universe. In this post, we will be discussing the force that is responsible for everything from nerve impulses to energy production: the concentration gradient.

The concentration gradient stems from the basic law of expansion that drives the universe. Instead of looking at expansion from a macroscopic view, we can see how it affects the chemical properties of molecules. These properties, in turn, are harnessed by living organisms to their advantage. This property enables almost every process in your body to occur. For example, let’s look at breathing.

The Physics of Breathing and Respiration

What is happening when you inhale? Your lungs are expanding, increasing the amount of space inside them. Because of this increase in volume, the surrounding air, constantly seeking to expand, moves to fill the new area. Once the air is inside the lungs, it interacts with the small blood vessels known as capillaries.

These capillaries are filled with carbon dioxide rich and oxygen poor blood. Once again both gases, seeking to expand, fill the space where there is less of its kind: the oxygen enters the blood as carbon dioxide leaves in an attempt to level off the concentration gradient and reach equilibrium. Essentially, equilibrium is the point where the law of expansion is exerting its maximum force on a system.

Circulation

Next, the blood is pumped by the heart to the rest of the body. So how does the heart pump blood? By contracting its chambers, the volume of the heart decreases. In order to make use of the space in the vessels, blood squeezes into the arteries with each beat. Upon reaching its destination, the oxygen and carbon dioxide swap near the cells as the try to bridge the concentration gradient and the blood travels back to the heart and lungs, restarting the cycle.

As you can see, the importance of this phenomenon cannot be overstated. So what is the concentration gradient? We know that every molecule in the universe wants to spread out as much as possible. This means gases will spread out to take up as much space as is given and things dissolved in water will be evenly distributed. In addition, large molecules have trouble following these rules because of barriers to expansion or due to counter-forces like gravity.

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DNA and Consciousness: The Brains Behind Biology

DNA in action

What is DNA?

Regardless of which field of biology is being studied, it is important to make sure you don’t lose perspective of the driving force of life: information. We have established earlier that DNA is the replicator which enables organisms to arise on Earth. However, life has grown so incredibly complex that it is very easy to lose sight of this fact and focus on an entire organism as the basic unit of life.

Under this assumption, Organisms simply use DNA to reproduce and store essential information. This cannot be farther from the truth. In fact, this is the reverse of the truth: organisms are complex creations used by DNA that enable the molecule to survive in harsh environments and replicate itself. The replicator creates and uses the body as a temporary vessel along its “quest for immortality”. The information in DNA will live forever as long as it creates bodies that survive and reproduce.

Information Storage

Now that we have cleared that up, let’s discuss the information itself. What does this information accomplish for the organism? Simply put, DNA is most well known as a blueprint for creation of proteins. Proteins are the functional units that enable DNA to exert an influence on the universe. From bodies to beaver dams to skyscrapers, DNA provided the powers of creation that enable life to impact its surroundings.

Condensing Capacity of DNA

A segment of DNA that stores information for a protein is called a gene. These genes are the primary driving force of natural selection. Genes that create efficient proteins that serve a need succeed over less useful competitors, much like the capitalistic economic model. However, proteins are incredibly complex and require intricate details to be functional. Thus, DNA has to be able to store very detailed information, more detailed than any present day computers.

This challenge is addressed by the architecture of the DNA molecule; the DNA code is composed of 4 different basic units (abbreviated A,T,C, and G). In order to appreciate the enormous level of detail 4 units provide, it is useful to use computation as an analogy. Computers run based on two units, 0 and 1. That means for x number of points, there are 2^n combinations of units possible. This system is responsible for all the technological advancements we have seen from robots to i Phones. However, for the same number of positions, a DNA molecule has 4^n combinations of units possible.

DNA vs. Binary Code
The information storage capacity of DNA is exponentially higher than computer binary.

As you can see, the amount of information that can be stored in DNA vastly exceeds the storage capacity of computers. This is why life is able to develop in such an intricate fashion with the ability to crate amazing adaptations. This characteristic allows genes to store incredibly dense amounts of code in a small space. This code is what is processed and transformed into functional proteins that carry out work to keep the organism alive. The process of this transformation occurs via transcription and translation.

 

 

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